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    SYSTEM AND METHOD FOR ESTIMATING AND PROVISION OF ENERGY RESERVE CAPACITY FOR DISPATCHABLE OPERATION THROUGH THE USE OF ACTIVE LOAD MANAGEMENT.A utility service employs an active load management system (ALMS) to estimate the operating reserve available for a possible dispatch to the concessionaire or another requesting entity (for example, an independent system operator). According to one modality, ALMS determines the amounts of electrical power stored in power storage devices, such as electric or hybrid electric vehicles, distributed throughout the concessionaire's service area. ALMS stores the stored power data in a repository. In response to receiving a request for an operation reservation, ALMS determines whether the stored power data alone or in combination with energy savings projected from a control event is sufficient to meet the operation reservation requirement. If so, ALMS dispatches power from the power storage devices to the power network to suit the need for operational reserve. The need for operating reserve can also be communicated to mobile power storage devices, to allow them to provide the operating reserve as market conditions require.
    公开号:BR112013019784A2
    申请号:R112013019784-6
    申请日:2012-02-01
    公开日:2020-11-17
    发明作者:Joseph W. Forbes Jr.
    申请人:Consert Inc.;
    IPC主号:
    专利说明:

    "':! r : " "j ',:, b W. SYSTEM AND METHOD FOR ESTIMATING AND PROVISION OF CAPACITY OPERATING RESERVE POWER DISPATCHABLE THROUGH THE USE OF ACTIVE LOAD MANAGEMENT
    BACKGROUND OF THE INVENTION 5 Carnation of the Invention The present invention generally relates to the carnation of electric power supply and generation systems and, more particularly, to a system and method for estimating and / or providing an energy capacity 10 dispatchable operation reserve for an electric utility using management: the active load, so that the reserve capacity can be made available to the utility or the power market in general (for example, through a national network) .
    15 Description of the Related Art An energy demand in a utility service area varies constantly. This variation in demand can cause undesirable fluctuations in the line frequency, if not timely adjusted. To suit variable demand, a utility must adjust its supply or capacity (for example, increase capacity when demand increases and decrease c) supply when demand decreases). However, due to the fact that the power cannot be economically stored, 25 a concessionaire must regularly put the new capacity online or take the existing capacity offline, in an effort to match demand and maintain frequency. Putting the new capacity online involves the use of a concessionaire reserve power, typically 30 called an "operating reserve". A table illustrating
    2, / 103> m.
    "r" Kb '
    T "" a typical power consumption of "co'nc'essíonár-ía is shown in figure 1. As shown, the operating reserve typically includes three types of power: the so-called" regulation reserve ", the" power reserve " spin "and 5" non-spin reserve "or" supplementary reserve ". The various types of operating reserve are discussed in more detail below.
    Normal fluctuations in demand, which typically do not affect line frequency, are responded to or accommodated through certain activities, such as by increasing or decreasing an existing generator output or by adding new generation capacity.
    This accommodation is generally referred to as an "economic dispatch". A type of power referred to as a "contingency reserve" is an additional generation capacity that is available for use as the economic dispatch to suit changing demand (increasing). The contingency reserve consists of two types of operating reserve, specifically the working reserve and the non-operating reserve 20. Therefore, the operating reserve generally consists of the regulation reserve and the contingency reserve.
    As shown in figure 1, the spin reserve is an additional generation capacity that is already online (for example, connected to the power system) and, therefore, is immediately available or is available within a short period of time after a need determined (for example, in ten (10) to fifteen (15) minutes, as defined by the applicable regulation of North American 30 Electric Reliability Corporation (NERC)). More
    ; m ~.
    "l- -" p "aFtic.u1arly, so that the contingency reserve is classified as" spin reserve ", the reserve power capacity must meet the following criteria: a) be connected to the network; 5 b ) be measurable and verifiable, and C) be able to fully respond to the load, typically within 10 to 15 minutes of being dispatched by a concessionaire, where the time requirements for dispatching the turnover reserve are generally governed by 10 operator network system or other regulatory body, such as NERC.
    The non-spin reserve (also called supplementary reserve) is an additional generation capacity that is not online, but that is required to respond within the same 15 time period as the spin reserve. Typically, when additional power is required to use an economic dispatch, a power utility will make use of its spin reserve before using its non-spin reserve, because (a) the generation methods used to produce 20 spin reserve typically tend to be cheaper than methods, such as a traditional one-way demand response, used for non-spin reserve production, or (b) the impact on the consumer for non-spin reserve production it is generally less desirable than the options used for the production of spin reserve, due to other considerations, such as environmental concerns.
    For example, the spin reserve can be produced by increasing the torque of rotors for turbines that are already connected to the utility's power network or by using 30 fuel cells connected to the power network.
    "With the Assignee; whereas the non-spin reserve can be produced simply by switching off resistive and inductive loads, such as heating / cooling systems attached to consumer locations.
    5 However, making use of the spin reserve or non-spin reserve results in additional costs for the concessionaire, because of fuel costs, incentives paid to consumers for responding to traditional demand, maintenance and so on.
    10 If the d-demand changes so abruptly and in a quantifiable manner to cause a substantial fluctuation in the line frequency in the utility power grid, the utility must respond to and correct the change in line frequency. To do this, concessionaires 15 typically employ an automatic generation control (AGC) process or subsystem to control the concessionaire's regulatory reserve. To determine whether a substantial change in demand has occurred, each concessionaire monitors its area control error (ACE). A concessionary ACE of 20 is equal to the difference in the programmed and actual power flows in the concessionaire's network connection lines, plus the difference in the actual and programmed frequency of the supplied power multiplied by a constant determined from the bias regulation of the 25 dealership flr'equêhcia. Thus, the ACE can be written generally as follows: ACE - (NI ,, - NIs) + (-IOBJ (R - R), [Equation 1] where NIa is the sum of the real power flows in all .
    '30 connecting lines -
    r - NTS is the sum of programmed flows in all connection lines, B, is the frequency bias regulation for the concessionaire, 5 R is the real line frequency, and & is the programmed line frequency (typically 60 Hz).
    In view of the preceding ACE equation, the amount of charge in relation to the capacity 'on the 10 connection lines makes the amount (NIa - NIs) positive or negative. When the demartda is greater than the supply or capacity (that is, the concessionaire is with subgeneration or under-supply), the quantity (NIa - NIs) is negative, which typically makes the ace 15 negative. On the other hand, when the demand is less than the supply, the quantity (NIa - NIs) is positive (that is, the concessionaire is overgenerated or over-supplied), which makes the ace positive. The amount of demand (for example, the load) or the capacity directly 20 affects the quantity (NIa - NIs); thus, the ACE is a measure of generation capacity in relation to the load. Typically, a dealership. tries to keep your ACE very close to zero using AGC processes. If the ACE is not maintained close to zero, the line frequency 25 'may collapse and cause problems for power consumption devices attached to the utility network. Ideally, the total amount of power supplied to the concessionaire connection lines should be equal to the total amount of power consumed through the loads (power consumption devices) and the transmission line losses at any time. However, in real power system operations, the total mechanical power supplied by the concessionaire's generators is rarely exactly equal to the total electrical power consumed by the loads plus the losses of the transmission line. When the supplied power and the consumed power are not the same, the system accelerates (for example, if there is too much power in the generators), causing the generators to rotate more quickly and, therefore, to increase the line frequency, or decelerates (for example, if there is not enough power in the generators), causing the line frequency to decrease. Thus, a variation in line frequency can occur due to an excess supply, as well as due to an excess demand.
    To respond to fluctuations in line frequency using AGC, a utility typically uses a "regulation reserve", which is a type of operating reserve, as shown in figure 1. The regulation reserve is used as needed to keep the line frequency. Therefore, the adjustment reserve should be available almost immediately when necessary (for example, in as little as a few seconds less than around five (5) minutes). Governors, which are typically incorporated into a concession generation system to respond to minute-to-minute changes in load by increasing or decreasing the output of individual generators, and thereby erecting or disengaging, as applied, in the reserve of regulation of the concessionaire.
    The Federal Energy Reliability Commission (FERC) and m NERC have proposed the Demand Side Management (DSM) concept as an additional approach to accounting for changes in deinanda. Q DSM is a method in which a power utility performs actions to reduce demand during peak periods. Examples of DSM include encouraging energy conservation, changing prices during peak periods, direct charge control and others.
    Current approaches to using DSM in response to 10 increases in demand have included the use of one-way load switches that interrupt loads, as well as "tactics to approximate the average amount of projected load removed by DSM. A statistical approach is employed because of the concessionaire's inability to measure the actual load removed from the network as a result of a DSM load control event, and current DSM approaches have been limited to the use of a single meter of patency among a hundred (100) or more service points (for example, homes and / or businesses). Therefore, the current 20 DSM approaches are inadequate because they are based on statistical trends and sampling, rather than on data empirical data for making projections and measuring real load removal events.
    More recently, FERC and NERC introduced the concept of flexible load format programs as a DSM component. These programs allow consumers to make their preferences known to the concessionaire regarding the timing and reliability of DSM load control events. However, the 30 DSM approaches using traffic conformation programs
    8 / 1'03 © t "cargo are not suitable for all the criteria for the implementation of regulation reserve or spin reserve, such as being dispatchable in 15 minutes or less.
    In addition, so that a generation source is considered to be dispatchable energy, it must be provided twenty-four (24) hours before being delivered to a concessionaire. Current DSM approaches do not facilitate an accurate twenty-four (24) hour forecast in advance, due to their heavy reliability in 10 statistics.
    Therefore, there is a need for concessionaires to be able to create an operating reserve, especially a regulating and / or turning reserve, by using accurate forecasting and flexible load matching techniques. There is an additional need to involve the consumer in a two-way approach, in which the consumer can make his energy consumption preferences known and the utility can make use of those preferences to respond to increased demand 20 and maintain energy regulation. line frequency.
    BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a table showing the basic load power requirements and the operating reserve available to an electric power utility.
    Figure 2 is a block diagram illustrating how an active load management system according to the present invention provides an additional operating reserve (for example, regulation, turning and / or not turning) for a power utility.
    30 Figure 3 is a block diagram of a safety system.
    C9 b 'active load management based on external IP according to a mode of the present invention.
    Figure 4 is a block diagram that illustrates an example active load director, as shown in Figure 3's power load management system.
    Figure 5 is a block diagram that illustrates the generation of an example sample repository from the active load director in figure 4 or some other location in an electrical utility.
    10 Figure 6 is a screen snapshot of an example web browser interface through which a consumer can assign their device performance and energy saving preferences to a power dependent device in environmental terms according to 15 one embodiment of the present invention.
    Figure 7 is a screen snapshot of an example web browser interface through which a user can assign their device performance and energy saving preferences to an environmentally independent power consumption device according to another embodiment of the present invention.
    Figure 8 is an operational flowchart that illustrates a method for the empirical analysis of the power usage of power consumption devices and filling a repository with samples of data resulting from this power usage analysis, according to an example modality. of the present invention.
    Figure 9 is an operational flowchart that illustrates a method for projecting energy use for a power consumption device 30 according to a
    - example of this invention.
    Figure 10 is an operational flowchart that illustrates a method for estimating the power consumption behavior of a power consumption device according to an example embodiment of the present invention.
    Figure 11 is an operational flow chart illustrating a method for projecting energy savings through power interruption for a power consumption device during a control event, according to an example embodiment of the present invention.
    Figure 12 is a graph that describes a load profile of a concessionaire over a projected period of time, showing the actual energy use, as well as a projected energy use determined with and without a control event, according to a example embodiment of the present invention.
    Figure 13 is a block diagram of a system for implementing a virtual electric utility according to an example embodiment of the present invention.
    20 Figure 14 is a block diagram illustrating an example residential and active load client and an intelligent breaker load center, as used in the active load management system in figure 3.
    Figure 15 is an operational flowchart - which illustrates a method for a control device, such as an active load client, for supplying data to a central controller, such as an ALD 100, and power to a grid. concessionaire power, to allow the central controller to design and enter a reserve of 30 available operations, according to an alternative m - example 'of the present invention. .
    Figure 16 is an operational flowchart that illustrates a method for estimating and supplying operation reserve to a concessionaire according to an example embodiment 5 of the present invention.
    DETAILED DESCRIPTION Before the detailed description of example modalities that are in accordance with the present invention, it should be noted that the modalities reside primarily in the combination of device components and processing steps related to active monitoring and monitoring. management of power loading at an individual service point (for example, on an individual subscriber base) and across an entire service area of 15 members, as well as the determination of an available reserve power or derived dispatch power of projected power savings resulting from power loading monitoring and management. Therefore, the device and method components were represented, 20 where appropriate, by conventional symbols in the drawings, showing only those specific details that are pertinent to the understanding of the modalities of the present invention, so as not to obscure the exposure with details that will be readily available. evident to those of 25 knowledgeable in the art having the benefit of the description here.
    In this document, relational terms such as "first" and "second" ', "top" and "bottom" and the like can be used uniquely to distinguish an entity or an element from another eritity or element, without
    12 '/ 1'03 necessarily require or initiate any logical or physical relationship or order between these entities or elements. The terms "comprises", "comprising" and any other variation thereof are intended to cover a non-exclusive inclusion, so that a process, method, article or apparatus comprising a list of elements does not include only those elements, but can include other elements not expressly listed or inherent in that process, method, article or device. The term "plurality of" as used in relation to any object or action means two or more of that object or action. - A claim element preceded by the article "one" or "one", without further restrictions, does not preclude the existence of additional identical elements in the process, method, article or device that includes the element.
    Additionally, the term "'Zig8ee" refers to any wireless communication protocol adopted by the Institute of Electronics and Electrical Engineers (IEEE), in accordance with the 802.15.4 standard or any successor standards, and the term "Bluetooth" refers to any short-range communication protocol implementing the IEEE 802.15.1 standard or any successor standards. C) "High speed packet data access (HSPA)" refers to any communication protocol adopted by the Third Generation Partner project (3GE P), by the Telecommunications Industry Association (TIA), by the International Telecommunications Union ( ITU), or any other body of mobile telecommunications standards with reference to evolving the global system standard for mobile communications (GSM) in addition to its universal system protocols.
    P- third generation mobile telecommunications (UMTS ') (for example, 3GPP Version 7 or later). The term "long-term evolution (LTE)" refers to any communication protocol adopted by the Third Generation Partner project (3GPP), TIA, ITU or another body of mobile telecommunications standards for the evolution of GSM-based networks for voice, video and data standards to be replacement protocols for HSPA (for example, 3GPP Version 8 or later). The term "optimized evolution 10 for multiple access data with code display (CDMA) (EVDO) (CDMA EVDO Rev. A)" refers to the communication protocol adopted by ITU, according to standard number TIA-856 Rev. A The term "GPS" means the global positioning system, well understood in the art, and any positioning unit or software used in connection therewith.
    The terms "concessionaire", "electric concessionaire", "power concessionaire" and "electric power concessionaire" refer to any entity that manages and / or distributes electrical power to its consumers, which buys power from an entity of power generation and distribute the purchased power to its consumers, or which supplies electricity created in a real or virtual way by alternative energy sources, such as solar power, wind power, load control, or otherwise, to generation entities of power or distribution through the FERC electrical network or otherwise. Thus, a concessionaire can start a power generation concessionaire, a municipality, 30 an electric cooperative, an operator. of system
    Independent independent (IS'O), a network operator, a regional transmission organization (RTO) or a virtual concessionaire that supplies at least some power virtually through load deferral or other non-load mechanisms.
    5 delivery.
    The terms "energy" and "power" are used interchangeably here.
    The terms "operating reserve",
    "working reserve", "regulation reserve", "non-operating reserve", "supplementary reserve" and "contingency reserve"
    are conventional in technique and its uses and interrelations
    10 are described in the paragraphs above.
    The term "environment" refers to general conditions, such as air temperature,
    humidity, barometric pressure, wind speed,
    amount of rainfall, water temperature, etc., at or near a service point or
    15 associated with a device (for example, the water temperature of the water in a hot water heater or a swimming pool). The term "device" as used herein means a power consumption device, a power storage device, and / or a-
    20 power generation device, as contemplated by the particular context of use of this term.
    With respect to power consumption devices,
    generally they can be two different types of devices at a service point, specifically, a
    25 an environmentally dependent device and an environmentally independent device.
    An environmentally dependent device is any power consumption device that switches on or off, or modifies its behavior, based on one or more sensors that detect characteristics,
    30 such as temperature, humidity, pressure or several others
    ..
    ÇT characteristics, of an environment. An environment-dependent device can affect and / or be affected directly by the environment in which it operates. An environmentally independent device is any power consumption device that switches on and off, or modifies its behavior, without reliance on inputs from any environmental sensors. Generally speaking, an environmentally independent device does not directly affect, and is typically not affected by, the environment in which it operates, although, as someone skilled in the art will readily recognize and appreciate, an operation of an environmentally independent device can affect iridirectly or occasionally being affected by the environment. For example, as those skilled in the art will readily understand, a recorder or other apparatus generates heat during an operation, thereby causing some heating of the ambient air near the device. Power consumption devices may include any resistive load consuming devices 20 and / or any inductive devices (e.g., motors) that consume electricity. Some devices may have the ability to change their geodetic locations and / or change their functions. By e.xemplc), hybrid electric or electric vehicles can move from service point to service point and function as power consumption devices (for example, while consuming the electricity stored in their batteries) or power storage devices (for example, during periods of time when your batteries 30 are fully or partially charged and the vehicle is not being used for transportation).
    It will be appreciated that the modalities or components of the systems described here can be understood by a Dü plus conventional processors and unique stored program instructions that control one or more processors for implementation, in conjunction with certain non-processor circuits, some at Most or all functions for determining an available or dispatchable operating reserve (for example, regulation and turning) from an electrical utility that is derived from projected power savings resulting from monitoring and managing loads in a or more active load management systems, as described here. Non-processor circuits may include, but are not limited to, radio receivers, radio transmitters, antennas, modems, signal drivers, clock circuits, power source circuits, relays, meters, memory, smart circuit breakers, sensors, current and user input devices. As such, these functions can. be interpreted as steps in a method for storing and distributing information and control signals between devices in a power load management system. Alternatively, some or all of the functions could be implemented by a state machine that would not have stored program instructions, or in one or more application-specific integrated circuits (ASICS), where each function or some combination of functions is implemented as a custom logic.
    Obviously, a combination of the preceding approaches could be used. Thus, methods and means for these functions have been described here. Still, it is expected that someone of common knowledge in the technique, despite possibly with significant effort and motivated by many design choices, for example, available time, current technology and economic considerations, when guided by the concepts and principles exposed here, will be promptly able to generate these software instructions, programs and integrated circuits (ICs), and appropriately dispose and tuncally integrate these non-processor circuits, without undue experimentation.
    Generally, the present invention encompasses a system and method for estimating operating reserve (for example, gyro and / or regulation reserve engine) for a concessionaire serving one or more service points.
    In one modality, the concessionaire employs an active load management system (AMLS) to remotely determine, for at least a period of time, the power consumed by at least one device located at one or more service points and receiving power from concessionaire for the production of power consumption data. Power consumption data is regularly stored and updated in a repository. The AMLS or a control component thereof, such as an active load director (ALD), determines an expected future time period for a control event during which power is to be interrupted or reduced for one or more devices. Before the start of the control event, ALMS Olj its control component: (í) estimates a corriport of expected power consL1n1Q of the device (s) during the time period of the control event, based on at least the stored power consumption data, (ii) determines the projected energy savings resulting from the control event based at least on the estimated power consumption behavior 5, and determines the operating reserve (for example, regulation and / or spin) based on projected energy savings. the determined operation reserve can be made available to the current power utility or the power market through the existing power network (for example, a federal energy regulatory commission). In one embodiment, the ALD populates an internal repository (for example, database, matrix or other storage medium) with measurement data indicating how devices at individual service points consume power or otherwise behave under normal operation and during control events. The power consumption data is updated through regular sampling (for example, periodic or other lorma) of device operating conditions (for example, power outlet, charge cycle, operating voltage, etc.).
    When an ALD is first installed in an ALMS for an electric utility power grid, there is little data with which to create regulation and turnover forecasts. However, over time, more and more data samples are used to improve the quality of data in the repository. This repository is used for the projection of energy use and energy savings. These projections can be aggregated for an entire service point, a group of service points or the entire utility.
    In an alternative way, additional data can. be used to help differentiate each sample of data stored in the repository. Additional data are associated with variability factors, such as, for example, outside air temperature, day of the week, time of day, humidity, sunlight, wind speed, altitude, window or door orientation, barometric pressure, energy efficiency rating of the service point, insulation used at the service point, and out: ros. All 10 of these variability factors can have an influence on the power consumption of the device. Some of the variability factor data can be obtained from public sources, such as local, state or national meteorological services, calendars and published specifications. Other variability factor data can be obtained privately from a user input and from sensors, such as humidity, altitude, temperature (for example, a thermostat) and optical or light sensors, installed in or near a service point (for example, inside or in a residence or business).
    Figure 2 is a block diagram illustrating how an ALMS operating in accordance with the present invention provides additional operation reserve (for example, regulation, 25 turn and / or not turn) for a power utility.
    Without the use of an ALMS operating in accordance with the present invention, the concessionaire has a capacity equal to its base load plus its regulation reserve, swing reserve and non-swing reserve, as shown on the left side of the figure. However, with the use of an ALMS operating 'P· ¶',
    S r, T: 'd / e According to the present invention, the concessionaire has urine. additional operation reserve, which can preferably be used as a regulation, rotation and / or rotation reserve (as shown in figure 2), when 5 power is selectively taken from service points by interrupting or reducing power -a for devices such as air conditioners, ovens, hot water heaters, pool pumps, washers, dryers, boilers, and / or any other inductive or resistive loads at points d and e.
    The present invention can be more readily understood with reference to figures 3 to 16, in which like reference numbers designate like items. Figure 3 describes an example IP-based active load management system 15 (ALMS) 10 that can be used by an electrical utility or a virtual utility according to the present invention.
    The description below of ALMS 10 is limited to a specific exposure with respect to the modalities of the present invention.
    20 A more general and detailed description of ALMS 10 is provided in commonly assigned US Application No. 11 / 895,909, which was published in US Patent Application Publication No. US 2009 / 00629'70 Al on March 5, 2009 and is incorporated here by reference, as if fully established here. US Patent Application Publication No. US 2009/0062970 Al provides details regarding the operational example implementation and the execution of control events for interruption or power reduction for devices located at service points, such as homes and 30 businesses. The use of an ALMS 10 for the implementation of a virtual concessionaire is described in detail in the commonly requested and copending US Order No. 12 / 001,819, which was filed on December 13, 2007, has been published as Application for Publication. US Patent No. 5 2009/0063228 Al on March 5, 2009 and is incorporated herein by reference, as if fully established here.
    ALMS 10 monitors and manages power distribution through an active load director (ALD) 100 connected between one or more 200 control center (UCCS) 200 (one shown) and one or more active load customers (ALCs) 300 (one shown) installed at one or more service points 20 (an example residential service point shown). The ALD 100 can communicate with the dealership control center 200 and each active load customer 300 directly or over a network 80 using Internet protocol (IP) or any other connection based protocols (IP or Ethernet). For example, the ALD 100 can communicate using RF systems operating via one or more base stations 90 (one shown) using one or more wireless communication protocols, such as GSM, ANSI C12.22, improved data GSM environment (EDGE), HSPA, LTE, time division multiple access (TDMA), or CDMA data standards, including CDMA 2000, CDMA Revision A, CDMA Revision B, and CDMA EVDO Rev. A. De · 25 alternatively or additionally, the ALD 100 can communicate over a connection capable of digital subscriber line (DSL), a connection capable of IP based on cable television, or any combination thereof. In the example example shown in figure 3, the ALD 100 communicates with one or more active load clients 300 using a combination
    T '.d'e. Traditional IP-based communication (for example, over a Telephone Trunk Line) for a base station 90 and a wireless channel implementing the HSPA or EVDO protocol from base station 90 to the cargo client active 5 300. A. distance between base station 90 and service point 20 or active charge client 300 is typically referred to as the "last mile", although the distance may not actually be one mile (-1 , 6 km). The ALD 100 can be implemented in a variety of ways, including, but not limited to, as an individual server, as a blade on a server, in a distributed computing environment, or in other hardware and software combinations. In the following exhibition, the ALD 100 will be described as performed on an individual server to facilitate understanding of the present invention. Thus, the ALD 100 server modality described below generally corresponds to the description of ALD 100 in U.S. Patent Application Publications No. US 2009/0062970 Al and US 2009/0063228 Al.
    Each active load client 300 is preferably 20 accessible via a specific address (for example, an IP address) and controls and monitors the status of smart circuit breaker modules or smart devices 60 installed at service point 20 (for example , in business or at home) to which the customer of 25 active charge 300 is associated (for example, connected or supporting). Each active cargo customer 300 is preferably associated with a single residential or commercial consumer. In one mode, the active load client 300 communicates with a residential load center 30 that contains circuit breaker modules tt Y>, r interé'ligente, which are capable of switching between a state -I "ON" ( active) to an "OFF" (inactive) state, and vice versa, in response to a signal from the active load switch 300. The smart circuit breaker modules can include, for example, the smart circuit breaker panels manufactured by Schneider Electric SA under the registered trademark "Square D" or by Eaton Corporation under the registered trademark "Cutler-Hammer" for installation during new construction. For retrofitting in existing buildings, 10 smart breakers having means for individual identification and control can be used. Typically, each smart circuit breaker controls a single appliance (for example, a washer / dryer 30, a hot water heater 40, an HVAC 50 heater or a pool pump 15 70). In an alternative embodiment, IP addressable relays or device controllers that operate in a similar manner to an "intelligent circuit breaker" can be used in place of intelligent circuit breakers, but would be installed coincident with the load under control and would measure 20 the starting power , the steady state power, the power quality, the charge cycle and the energy charge profile of the individual appliance 60, the HVAC unit 40, the pool pump 70, the hot water heater 40, or any other controllable cargo, as determined by the concessionaire or a final consortenor.
    In addition, the active load client 300 can control the individual smart devices directly (for example, without communication with the residential load center 400) via one or more of a variety of known communication protocols (eg, IE ', ban-dà làrga per power line (BPL) in its various forms, including through promulgated specifications or being in development by HOMEPLUG Powerline Alliance and the Institute of Electrical and Ele'ctronic Engineers (ÍF, EÉ), Ethernet, Bluetooth , Zig8ee, Wi-Fi (IEEE 802.11 protocols), HSPA, EVDO, etc.).
    Typically, an intelligent apparatus 60 includes a power control radio (not shown) that has co-communication capabilities. The power control module is installed in line with the power supply for the appliance, between the actual appliance and the power source (for example, the power control module is plugged into a power outlet in the home or business and the power cord for the appliance is plugged into the power control module). Thus, when the power control module receives a command to switch off the apparatus 60, it discourages the real power supplying the apparatus
    60. Alternatively, the smart device 60 can include a power control module integrated directly into the device, which can receive commands and control the operation of the device directly (for example, an intelligent thermostat can perform functions such as raising or lowering the temperature switched unit d (= HVAC to on or off, or to switch a fan to on or off). The active load client-e 300 can still be coupled to one or more sensors of variability factor 94. These sensors 94 can be used to monitor a variety of variability factors affecting the operation of devices, such as internal temperature and / or
    ~ externâ ', internal and / or external humidity, time of day, pollen count, amount of rainfall, wind speed and other factors or parameters.
    Referring now to Figure 4, the ALD 100 can serve as the primary interface for consumers, as well as service personnel, and operates as the system controller by sending control messages to and collecting data from active load clients. 300 installed, as described in sections below and in US Patent Application Publication No. US 2009/0062970 Al. In the example embodiment described in Figure 4, the ALD 100 is implemented as an individual server, and includes an interface concessionaire control center (UCC) security
    102., a UCC command processor 104, a master event manager 15, an ALC manager 108, an ALC security interface 110, an ALC 112 interface, a web browser interface 114, a web application consumer subscription 116, personal consumer settings 138, a consumer reporting app 20 118, a power saver app 120, an ALC diagnostic manager 122, an ALD 124 database, a dispatch manager service 126, a problem management generator 128, a call center manager 130, a 25 carbon savings application 132, a power and carbon (P&C) d database, and dealer 134, a meter application reader 136, a security device manager 140, a device controller 144, and one or more processors 160 (one shown). The operational details of several of the 30 elements of the ALD 100 are described below with respect to their use in connection with the present invention. The operational details of the remaining elements of the ALD 100 can be found in the U.S. Patent Application Publications
    US '2009/0062970 Al and US 2009/0063228 Al, where ALD 5 100 is also described in the context of an individual server modality.
    In one embodiment, a sampling repository is used to facilitate determining the power or energy of the dispatchable operation reserve (for example, spin and / or regulation reserve) for a utility. An example sampling repository 500 is shown as a block diagram in figure 5. As shown in figure 5, sampling repository 500 is a medium for storing device monitoring data and other data that collectively detail how the devices (for example, a hot water heater 40, as shown in figure 5) behaved under specific conditions. The repository 500 can be in various forms, including an array, an L) and data, etc. In one embodiment, the sampling repository 500 is implemented in the ALD 124 database or in the ALD 100.
    Alternatively, the 500 sample repository may reside elsewhere in the ALD 100 Dü be external to the ALD
    100. Sampling repository 500 contains all power consumption data for devices located at a service point 20 or at a dealership. Power consumption data may include, but is not limited to: current reading, energy / power used or consumed, energy / power saved, drift or drift rate, power time, user settings for maximum environmental variances. and / or time periods (e.g. hours of the day,
    days of the week and calendar days). Taken collectively, this data is used to show how devices performed during normal operation,
    5 as well as during control events in which the power is temporarily interrupted or reduced to one or more devices.
    Data can be obtained through passive sampling (for example, regular monitoring of devices at a service point 20 in particular by the active load clíent-e 300 associated with the service point
    20) and / or active sampling (for example, directly interrogating devices for data by the active load client 300 or ALD 100). As discussed below,
    q sampling repository 500 is used by the ALD 100 or other components of the ALMS 10 to estimate or project the power consumption behavior of the devices and to determine the projected power / energy savings from an event. control.
    The projected power savings can be determined using c) power saving application
    120 based on the power consumption data in the 500 repository. Figure 6 is an example snapshot displayed to a user (for example, a consumer) while running a consumer personal settings application 138. The illustrated instaritanne shows a screen being used to adjust consumer preferences for an environmentally conscious device, such as an HVAC 50 unit, a humidifier or a swimming pool heater.
    The illustrated snapshot can be provided for c)
    , R + 7
    L & consumer, in one form, via a web portal accessible via the Internet 98 (referred to here as the "consumer panel"), when that portal is accessed by the consumer through a computer, smartphone or other comparable device. As shown in figure 3, consumer panel 98 can be connected to ALD 100 via an internet service provider for service point 20, or can be implemented as a consumer Internet application 92, when consumer service Internet 10 is supplied through the active charge client 300, as described in US Patent Application Publication No. US 2009/0063228 A1. Consumer panel 98 effectively provides consumers with access to ALD iOO. The ALD 114 web browser interface accepts input from consumer panel 98 and extracts information to consumer panel 98 for display to the consumer. Consumer panel 98 can be accessed from service point 20 or remotely from any device accessible via the Internet, preferably 20 using a username and password. Thus, consumer panel 98 is preferably a secure web-based interface used by consumers to specify preferences associated with devices controlled by the ALD 100 and located at service point 25 of consumer 20, as well as to provide information requested by the application. personal consumer regulations 138 or consumer subscription application 116 in relation to controlled devices and / or service point conditions or parameters. The 30 consumer preferences can include, for example,
    control event preferences (for example, times, durations, etc.), tax management preferences (for example, target or target for maximum monthly tax cost), maximum and minimum 5 limit settings for environmental characteristics, and others .
    Figure 7 is another example snapshot displayed to a consumer through the consumer panel 98 during a run of a different portion of the consumer personal setting application 138. Figure 7 shows how consumer preferences could be set for a device independent of the environment, such as a hot water heater 40, a pool pump 70, or a sprinkler system water pump (which can also be an environmentally dependent device, if it includes, for example, a sensor rainfall). Using the web browser interface 114, consumers interact with the ALD 100 and specify the personal consumer settings 138 that are saved by the ALD 100 and stored in the ALD 124 database or in another 500 repository. Personal settings 138 can specify time periods during which load control events are allowed, time periods during which load control events are prohibited, maximum allowable variances for an operating environment at a particular service point 20 (for example, temperature and / or maximum and minimum humidity), normal operating conditions for devices at different times of the day, and other personal preferences related to the operation of devices under ALD 100 control through the active load client 300 at service point 20.
    As mentioned abovei '.a', the present invention optionally tracks and takes into account the "drift" of an environmentally dependent device.
    Drift occurs when the environmental characteristic (s) (for example,
    5) temperature (s) monitored by an environment-dependent device begins to deviate (for example,
    heating or cooling) from a set point that is to be maintained by the environment-dependent device.
    This deviation or drift can occur normally and during control events.
    Thus, the drift is the time it takes for the 'monitored environmental characteristic to move from an adjustment point to an upper or lower comfort limit, when power, at least a sub-substantial power, is not being consumed by the device. .
    In other words, the drift is the rate of change in the monitored environmental characteristic of a setpoint, without using significant power (for example, without driving an HVAC unit compressor, but continuing to drive an associated digital thermostat and a HVAC unit control system). Someone of ordinary skill in the art will readily appreciate that devices, such as HVAC 50 units, which control one or more environmental characteristics at a service point 20, are also influenced or affected by the environment at service point 20, because their activation or deactivation is based on one or more environmental characteristics detected at service point 20. For example,
    an HVAC 50 unit in cooling mode that tries to maintain an internal temperature of 77 ° F (25 ° C) activates when the internal temperature is some t greater than 77 ° F
    -, (25 '"C'), and therefore is influenced '.or. Affect, d, by the environment in which the HVAC 50 unit operates. The reverse of deri.va is the" power time ", which is the time it takes for the detected environmental characteristic 5 to move within a comfort limit to a regulation point, when significant or substantial power is being supplied to the environmentally dependent device. In other words, the "power time" is the rate of change of the ambient-monitored characteristic at 10 from a comfort limit to a regulation point with significant use of potency. Alternatively, the "drift" can be considered the time required for the monitored environmental characteristic moves to an unacceptable level after the power is generally switched off to an environmentally dependent device 15. In contrast, the "power time" is the time required for the monitored environmental characteristic to move from one environment to another. an unacceptable level for a ni.ve The target, after power has generally been supplied or supplied again to the environment-dependent device 20.
    Power consumption data for an environmentally dependent device, which is usually accumulated either actively or passively as described above, can be used empirically to determine the drift and the power time (rate of change, temperature slope or other dynamic equation (f {x})) that "ieiimine a variation of ambierital characteristic at a service point 20, or at least in the operating area of the environmentally dependent device, in order to allow the determining a "fingerprint" of, uniquely shaped rivadan or a pattern of use / consumption of power or behavior for service point 20 or the environment dependent device.
    Consumers set the upper and lower 5 comfort limits by introducing consumer preferences 138 through the web browser interface 114, with the setpoint optionally being in the middle of those limits. During normal operation, an environmentally dependent device will attempt to maintain the applicable .ambie-ntal feature or features close to the set point or set points of the device.
    However, all devices, whether environmentally dependent or environmentally independent, have a charge cycle that specifies when the device is in operation, because many devices are not continuously in operation. For an environmentally dependent device, the charge cycle ends when the environmental characteristic (s) being controlled reaches the set point (or at a given tolerance or variance of the set point). adjustment). After the setpoint has been reached, the environmentally dependent device is generally turned off and the environmental feature is allowed to "drift" (for example, up or down) towards the comfort limit. Once the environmental characteristic (for example, the temperature) reaches the limit, the environment dependent device is usually activated or switched on again, until the environmental characteristic reaches the regulation point, which terrrLirla the cycle of load and power time.
    Drift can also occur during an event of
    & contr'ol.e .. A control event is an action that temporarily reduces, terminates or otherwise interrupts the 'power supply to a device. During a control event, the environmental characteristic (for example, the temperature) monitored and / or controlled by an environmentally dependent device will drift towards a comfort limit (for example, upper or lower), until the environmental characteristic reaches that limit. Once the environmental characteristic reaches the 10 border, c) ALMS 10 usually returns or increases the power to the device, to allow the environmental characteristic to reach the set point again.
    For example, an HVAC 50 unit can have a setpoint 15 of 72 ° F (22.2 ° C) and minimum and maximum comfort limit temperatures of 68 ° F (20 ° C) and 76 ° F ' (24.4 ° C), respectively. On a cold day, a control event can interrupt the power to the HVAC 50 unit, causing the temperature monitored at service point 20 to move to the minimum comfort threshold temperature. Once the temperature monitored within service point 20 reaches the minimum comfort limit temperature, the control event would end, and the power would be restored or increased for the control unit.
    25. HVAC 50, thus causing the monitored temperature to rise to the set point. A similar effect, but Qj3osto, can occur on a hot day. In this example, "drift" is the rate of change with respect to the time it takes for the HVAC unit 50 to move from set point 30 to the upper or lower boundary limits. In order to 'nálQga,' power time 'is' the rate of change with respect to the time required for the HVAC 50 unit to move the monitored temperature from the upper or lower comfort limits to the set point. In one embodiment of the present invention, the drift and the power time are calculated and recorded for each environment-dependent or environment-independent device or for each service point 20.
    In another modality, drift and other measurement data available from the ALD 124 database are used to create a power consumption pattern or pattern for each environment-dependent or environment-independent device or for each service point 20. The other measurement data may include vacant times, inactive times, times in which control elements are defined and / or other factors of variability.
    The environment in an energy efficient structure will have a tendency to exhibit a lower rate of drift. Therefore, environmentally dependent devices operating in these structures may be subject to control events for long periods of time - because the amount of time it takes for the monitored environmental feature to reach a comfort limit due to drift after being regulated for a setpoint to be longer than for less efficient structures.
    In another modality, the ALD 100 can identify service points 20 that would have an optimal drift for power savings. The power saving app
    SM - 12: 0 'calcµ'la drift for each service point 20 and / or m for each device dependent on ambient medium at service point 20, and save drift information in the ALD 124 database as power consumption data part 5 for c) device and / or service point 20. Thus, the power saved as a result of drifting during an event. control system increases the overall power saved by the medium-dependent device at the service point 20.
    10 Figure 8 is an example operational flowchart 800 providing the steps performed by the ALD 100 to # empirically analyze the power usage of devices and fill a repository 500 with data samples resulting from this power usage analysis. The steps in figure 8 can be 15 corisidered for the implementation of a passive sampling algorithm. A3 steps in figure 8 are preferably implemented as a set of computer (software) instructions stored in an ALD 100 memory (not shown) and executed by one or more 20 ALD 100 processors 160. According to the logical flow, the active charge customer 300 interrogates devices at service point 20, such as a washer / dryer 30, a hot water heater 40, an HVAC unit 50 with smart apparatus 60, a pool pump 25, or other devices at the point of service service 20, and obtains the current readings. Upon receiving the current reading data from the active load client 300, the ALC 112 interface sends the data to the ALC 108 manager. The ALC 108 manager 30 stores the data in the sampling repository 500, the which can be implemented in the ALD 124 database using it. if the operational flow i.lustrated in figure 8.
    The following information can be provided as parameters for the operational flow of figure 8: a device identification 5 (ID), a temperature mode (for example, "heating" or "cooling"), load cycle, current temperature read by device and previous temperature read by device. Each temperature reading includes a device ID, a setpoint (which 10 is only useful for environmentally friendly devices) and variable factor measurement data -age (as previously described).
    Initially, the ALD 100 determines (802) whether the device used any or at least an appreciable amount of energy. If not, then the logical flow ends. Otherwise, the ALD 100 determines (804) the length of time for the data sample, the length of time when the device was on, and the length of time when the device was off, based on the data sample 20. The ALD 100 then determines (806) whether the data received came from an environment-dependent device or an environment-independent device (for example, binary state). If the data received came from an environmentally dependent device 25, then the ALD 100 will determine (808) the energy used per minute for the device, and will determine (810) whether the device is deriving from or using power. The ALD 100 determines that the device is drifting if the environmental characteristic monitored by the device 30 is changing in an opposite way to the device's mode (for example, the ambient temperature is rising when the device is set in cooling mode or the temperature environment is decreasing when the device is regulated by the heating node).
    5 Otherwise, the device is not drifting.
    If the device is drifting, then the ALD 100 will determine (814) the drift rate (degrees- per minute). On the other hand, if the device is not drifting, then the ALD 100 will determine (812) the power time rate.
    Once the drift rate or power time rate has been calculated, the ALD 100 determines (880) whether there is already a record in the sampling repository 500 for the device being measured under the current operating conditions of the device (for example, set point and other variability factors (for example, external temperature)). If there is no existing record, then the ALD 100 will create (882) a new record using, for example, the device ID, the record time, the current setpoint, the current external temperature, the energy used per minute , the power time rate and the drift rate (assuming a power time rate or a drift rate has been determined). However, if there is an existing record, then the ALD 100 will update (884) c) existing record by averaging new data (including energy usage, drift rate and power time rate) with existing data and storing the result, in repository 500. If q ALD 100 determines' (806) that the data received comes from a device independent of ambient medium, then the ALD 100 will determine (842) the energy used per minute for q device and determine output (-844) the energy saved per minute provides the device. The ALD 100 then searches the repository 500 (for example, the ALD 124 database) to determine (890) whether there is already a record for the 5 device for the applicable period of time. If there is no existing record, then the ALD 100 will create (892) a new record using the device ID, the record time, the current time block, the energy used per minute and the energy saved per minute. However, if there is an existing record, then the ALD 100 will update (8'94) the existing record by averaging the new data (including energy usage and energy savings) for the ccni time block. existing data for q block of time and will store the result in the 500 repository. For environmentally independent devices, energy usage and energy savings are saved with respect to a block or time period.
    Figure 9 illustrates an example operating flow chart 900 providing steps taken by the ALD 100 to project or estimate the expected energy usage of a device over a future period of time in a given environmental scenario, according to a modality of present invention. The steps in figure 9 are preferentially implemented as a 'set of computer instructions (software) stored in an ALD 100 memory (not shown) and executed by an OLI plus processors 160 of the ALD 100. According to a modality, the "operational flow of figure 9 can be performed by the power saving application 120 of the ALD 100, when a utility operator, or another operator of the ALD 100, wants to project the energy usage for a device for a period of time specified in the future, such as during a period of time in which a control event is to occur.
    5 The following information can be provided as parameters for the operational flow of figure 9: the device ID, start time of the future time period, end time of the future time period, the management mode of the device, and, for an environmentally independent device, a binary control factor. The management mode can be "control" or "normal" to indicate whether the device is being controlled during a control event or during normal operation, respectively. The binary control factor is preferably used for devices independent of ambient medium and represents the load cycle of the device. For example, if a hot water heater 40 operates at a load cycle of 20%, the binary control factor will be 0.2.
    Initially, the ATjD 100 (for example, the power saving application 120) determines (902) a future time period based on the start and stop times. The future period of time can be regulated by the concessionaire by implementing the load control procedure of the present invention or by a second dealer who requested the delivery of operating reserve power from the concessionaire by implementing the load control procedure of the present invention. After the time period in question is known, the power saving application 120 starts the procedure for projecting or estimating the amount of
    . power that can be saved as a result of running a control event during the future time period.
    Therefore, the power saving application 120 analyzes the devices to be used. controls during the 5 control-e event. Thus, the power saving application 120 determines (904) whether the devices include environment-dependent and environment-independent devices (e.g., binary state). For each environmentally dependent device, the power saving application 120 determines (920) whether the device is in ambient air control mode (for example, heating or cooling). Then, the power saving application 120 retrieves (922) the anticipated regulation porits for the device during the 15 th period [npQ future of the control event, and obtains (924) information regarding the characteristic (s) ( s) external ambient (s) (for example, outside temperatures) expected during the control event time period.
    The power saving application 120 then makes 20 projections (926) on the expected power consumption behavior of the device during the future period of time. In one embodiment, the block projection determination 926 is i.mplew "ntada" - using a better matching algorithm, as described in detail below with respect to figure 10, to find stored repository records that best suit match the behavior of the device for each combination of set points, external environmental characteristics (eg temperatures) and time periods, as measured 30 and stored using the logical flow in figure 8. The power consumption behavior of the device is used to determine the amount of energy that would be expected qi-r = to be used by the device, if the control event did not occur, and thus the amount of energy estimated or expected to be saved per unit of during the control event The power-saving application 120 multiplies (928) the power saved per unit of time by the time duration of the future control event, to determine air the total amount of energy projected to be used by the device in the absence of the control event. The power saving application runs (980) the projected total amount of energy used by the device in the absence of the proposed control event.
    However, if the power saving application 120 deterniinar (904) that the proposed control event is to affect an environmentally independent device, then the power saving application 120 will determine (960) whether the device is currently programmed to be on or off during the proposed time period of the control event. Then, the power saving application 120 creates, Qb, or otherwise determines (962) a list of time blocks for the "specific control event" time period. The power saving application 120 then makes projections ( 964) on q power consumption behavior of the device during the future control event time period.In one embodiment, the projection determination of block 964 is implemented using a better corabination algorithm, as described in detail below with respect to the figure
    42 '/ L03 10, to find the storage repository records that best match the device's behavior for each combination of setpoints, external environmental characteristics (eg 5 temperatures) and time periods, as measured and stored using the logic flow in figure 8. The device's power consumption behavior is used to determine the amount of energy that would be 'expected' to be used by the device if the control event did not occur, and, thus, the amount of energy estimated or expected to be saved per unit time during the control event. Then, the power saving application 120 multiplies (968) the ecanomized power per unit time by the time duration of the future control event, to determine the total amount of projected energy to be used in the absence of the power event. control. If the projected energy savings are based on the power consumption during a previous control event (970), er: so, the power saving application 120 will multiply (972) the total amount of energy by the binary control factor , to determine the projected amount of energy to be used by the device in the absence of the control event. The power saving application returns (980) the projected total energy used by the device in the absence of the proposed control event.
    Someone of ordinary skill in the art will readily recognize and appreciate that the operational flow of figure 9 can be used for each device controlled at a service point, for devices controlled at multiple service portions, or for all devices controlled at all service points supplied or supported by a concessionaire. The total projected energy use by the devices can be aggregated 5 through a single service point, for all (js service points in a group and / or for all groups served by the concessionaire.
    Figure 10 illustrates an example operational flowchart 1000 providing steps performed by the ALD 100 for estimating the power consumption behavior of a device according to an example embodiment of the present invention. The algorithm or operational flow illustrated in figure 10 provides a modality for the implementation of steps 926 and 964 in figure 9. The operational flow in figure 10 determines which region, "tro or which records in the sampling repository 500 provide the greatest conibination," close to a given environment or operational scenario for use in the projection of use / energy saving of device over a period of time of a future control event, according to a modality of the present invention. The steps in figure 10 are preferably implemented as a set of computer instructions (software) stored in a memory (not shown) of the ALD 100 and executed by one or · 25 more processors 160 of the ALD 100. The operational flow of figure 10 can be initiated by the ALD 100 when attempting to identify or determine the record or sampling repository records that best match a device's power consumption behavior in a specific scenario.
    @ ¢ In a periodicity, the operational flow of figure 10 is called during the execution of the operational flow of figure 9, as mentioned above. When so called, the operational flow of figure 9 provides the operational flow of figure 5 with parameters that indicate the type of records to be "searched. These parameters include, but are not limited to: a device ID, a charging mode ( on or off), a period of time (for example, corresponding to the time period of the proposed future control event 10), a setpoint delta, a delta or a variance related to one or more .features environmental (for example, external temperature), and a time block delta. The charge mode means the charge cycle of the device. If the charge mode is TRUE or 15 ON, significant power is being consumed.
    If the charging mode is FALSE or OFF, significant power is being consumed (ie the power is being saved). A load cycle exists for switch-controlled, binary-state, environment-independent devices, which go to ON and OFF regardless of the influence or effect of the environment. For HVAC 50 devices, the charging mode is always ON. The setpoint loop is the amount that a setpoint can be varied during a search in order to find a combination repository record. Delta of external temperature / environmental characteristic is the number of degrees of temperature or other change in the environmental characteristics so that the data related to the external temperature or other characteristic L-environment can be varied during a
    "r: bus'eà, t in order to find a combination repository record. The time block delta is the amount of time that a time block can be varied during a search in order to find a record 5 combination repository.
    Initially, the ALD 100 determines (1002) whether the requested repository search refers to an environmentally dependent device or to an independent device from Ambient Ineio. If the search refers to an environmentally dependent device, then the ALD 100 will attempt to find (1004) power consumption records in the sampling repository 500 that match the device ID, the charge mode, the setpoint of environmental characteristic (for example, temperature), and the 15 data of external environmental characteristic. Power consumption records incj_uetn power consumption data, such as power consumed, current drawn, load cycle, operating voltage, operating impedance, period of use, regulation points, ambient and external temperature 20 during use (as applicable), and / or various other data, q of energy use. If a record existed that matches all the criteria for searching for potency consumption, that record would be considered the record that most closely matches the given scenario 25 of. environment. If no match is found (1010), then the ALD 100 will start looking for records that differ slightly from the given environment scenario. In one mode, the ALD 100 increments or decreases the search criteria related to the environment (for example, temperature setpoint and / or external / ambient temperature) using the setpoint delta and the delta temperature and: iterna / environmental characteristics as a guide to search for relevant records. This incremental / iterative modification of the search criteria continues until the relevant records are found or some applicable limit (for example, as indicated by the setpoint delta and / or other parameter deltas) is reached.
    If the ALD 100 determines (1002) that the search refers to an environmentally independent device, then the ALD 100 attempts to find (1040) power consumption records in the sampling repository 500 that match the device ID, the charge mode and operating time (corresponding to the expected future control event time). If a record is not found that matches all search criteria (1070), then the ALD 100 will modify your search to look for records that differ slightly from the given environmental scenario. In one mode, the ALD 100 modifies its search by increasing or decreasing the operating time in increments (1072) for a given load mode. The iterative search continues until relevant records are found or an applicable limit (for example, as indicated by the time block delta or other parameter deltas) is reached.
    Any records that were found as a result of the search are provided (1060) for the requesting program (for example, the operational flow in figure 9). C) result of the operational flow of figure 10 is a set of one or more power consumption records from the sampling repository 500 that are the closest match with the given environment or proposed scenario of the event. control.
    Figure 11 illustrates an example operational flow chart 1100 providing steps performed by the ALD 100 for the projection of energy savings through power interruption or reduction to a device during a control event, according to a modality of the present invention. - The steps in figure 11 are preferably shown as a set of computer instructions (s.oftware) stored in a worthwhile (no, show) of the ALD 100 and executed by one or more ALD processors 160
    100. As with the operational flow in figure 9, the operational flow in figure 11 can be performed by the power saver application 120, when an operator of the dealership or ALD 100 wants to project the energy savings to a device for a period of specified time during a control event operation.
    The following information can be provided as parameters for the operational flow of figure 11: a device ID, a control event start time, a control event end time, and a binary control factor, as described above in relation to figure 9.
    Initially, the ALD 100 (for example, the power saving application 120) projects (1102) q energy usage / power consumption for the device during normal operation within the expected period of time. , using, for example, the operational flow of figure 9. Then, the power saving application 120 projects (1104) the power consumption for the device during q control event using, for example, the operational flow of figure 9 For example, depending on the load cycle, m - set points, drift or drift rate, power time and other parameters for the device, the device may be designed to be
    5 switched on and consuming power: for some amount of time during the time period of the control event.
    Thus, the expected amount of power consumed during normal operation (that is, in the absence of any control events) and the expected amount of power consumed
    10 during the control event are determined to accurately assess any possible power savings as a result of the control event.
    After the two projected power consumption values have been determined, the power saving application 120
    15 calculates (1106) the difference between the two values, which is the power consumption projected for the device during the time period of the control event.
    Due to the fact that the projected power consumption is not realized during the control event, this power consumption corresponds to
    20 directly to a quantity of energy saved during the control event.
    The power saving app
    120 (1108) returns the projected energy saving value.
    Someone of ordinary skill in the art would readily recognize “and will appreciate that the
    25 power savings 120 can aggregate the projected power savings for all devices controlled at a service point 20, for all devices controlled at service points in t-m group, Oll for devices controlled in all point groups
    30 services served by the concessionaire, to obtain an aggregate amount of power savings, as a result of a control event.
    Another context in which ALMS 10 can be used is in conjunction with other sources of renewable energy.
    5 Various sources of renewable energy, such as wind power and solar power, are of a variable nature. That is, these sources of energy do not generate power at a constant rate. For example, the wind rises or falls from moment to moment. Wind turbines can generate a large amount of power due to high winds or they can stop generating completely due to a lack of any wind. Solar panels may be able to generate a large amount of power on sunny days, poor power on cloudy days and virtually no power at night.
    As a result, power utilities that make use of renewable energy must compensate for under- or over-generation of power from these sources. When renewable energy sources are generating, 2.0. ALMS 10 can use the processes set out above to provide an additional operating reserve to compensate for the lack of power generation by the renewable energy source and the resulting effects, including an output frequency instability. For example, a concessionaire using wind or soIar energy sources can still incorporate ALMS 10 into the concessionaire distribution system to provide a regulation reserve during periods of subgeneration time.
    Figure 12 is a 'jráficD that desc: review the "charge profile" of a color) cessory for a period of time r predetermined, showing the actual energy usage as well as the projected energy usage determined with and without a control event according to an exemplary embodiment of the present invention. The load profile graph describes the following 5: a. Baseline consumption 1202. This is the total possible load of or the power consumed by all devices controlled for a specified period of time.
    B. Use of interruptible projected load 1204 (ie projected load or energy use with a control event) for all controlled devices at all service points (or at selected service points) served by the utility in the absence 1'5 of a control event. The use of the projected interruptible load can be determined in a modality by executing the operational flow of figure 9.
    The available projected interruptible load 1204 indicates the load for all controlled devices, if 20 they are controlled 100% of the time using consumer preferences. The use of the projected interruptible load 1204 can be determined in a modality through the execution of the operational flow of figure 11.
    .2'5 c..Designable interruptible load available 1206 (ie, the projected energy used when no control events are used) for all controlled devices at all service points (or at selected service points) served by 30 concessionaire during a control event. Interruptible load, projected device 1209, indicates the load for all controlled devices, if they are controlled 100% of the time using consumer preferences.
    D. Use of 1208 actual interruptible load for all devices controlled at all service points (or selected service points) served by the utility. The use of real interruptible load 1208 is the power that is currently being used by all controlled devices.
    This type of load profile graph can be generated for all devices controlled at a service point 20, for devices controlled at all service points in a group, or for devices controlled in all groups served by the utility.
    In the graph of load p = figure of figure 12, the capacity under contract is shown as a straight line at the top of the graph and indicates the baseline power consumption 1202. Baseline power consumption 1202 represents the quantity t-total of power that the concessionaire is obliged to provide. The actual use of 1208 uninterrupted load is the actual energy use of all devices controlled by the utility. The use of jet interrupted load 1204 at the bottom of the load profile graph is the projected energy used when control events are used, and the available projected interruptible load 1206 is the projected energy use when control times are not used. The difference between using 1204 designed interruptible load and interruptible load
    . - proje'ta.da available 1206 is the capacity · and that can be used for operating reserve, including regulation reserve, gi.ro reserve and rotation reserve).
    In particular, when a utility observes an energy demand that is close to its peak capacity, it will attempt to initiate control events for consumers who voluntarily participate in power saving programs (ie, flexible charging format programs, as previously described). Typically, 10 these control events will provide sufficient c-capability to prevent the cc.mc'ess.ionary from using the spinning reser'i. However, there are situations in which a sufficient number of 'swine farmers may have manually decided to opt out of power saving programs and, as 15 r.result, the concessionaire would be unable to recover energy' sufficient to suit its turnover needs from its remaining consumers who voluntarily participate situation such as this could occur, for example, on a very hot day, when many people were at home, such as on a holiday or a weekend day, in which case the dealership would still be at risk of use the non-rotating reserve or even run out of reserve capacity entirely. In a situation like this, concessionaire 25 would be in a "critical control" mode. In the critical control mode, the concessionaire can suppress all pref consumer preferences, including those who voluntarily participate in power saving programs and those who do not c) do so. During periods of critical control, the concessionaire can use c) ALD 100 for · q adjustment of device settings depending on mI = io. ambierlte for adjustments outside normal comfort preferences (but not life threatening). Invoking a critical control allows a utility to return a power demand to acceptable levels. The use of ALMS 10 helps a utility to mitigate the likelihood of critical control situations. For example, whenever a consumer suppresses or chooses to leave a control event, ALMS 10 using the techniques outlined here, finds additional consumers who may be the target of a voluntary control event. Similarly, when it is recommended that controlled devices that are participating in a control event leave the control event, due to consumer preferences (for example, the amount of time that consumer devices can participate in an event control), the ALD 100 can release these "devices from the control event, and replace them with other devices voluntarily controlled. The replacement devices would then preferentially supply, through postponement, at least the same amount of reserve power that was being originated by the devices that were released from the control event Thus, system 10 of the present invention increases the likelihood that a utility will be able to disseminate control events to other consumers, before invoking critical control.
    In an additional modality, the entire ALMS 10 described in figure 3 can also be implemented on a proprietary network that is based on IP, in real time,
    & derived, verifiable, interactive, two-way temperature that responds to automatic generation control (AGC) commands for the production of reserve power through the implementation of control events.
    5 In an additional modality of the present invention, the sampling data stored in repository 500 using the operational flow of figure 5 could also include other factors (called "variability factors") related to power consumption, such as day of the 10 week, humidity, amount of sunlight, or the number of people in the residence. These additional data would allow the projected energy use and projected energy savings to be more accurate based on these additional factors. To make use of this data, ALD 100 can obtain additional data from sources inside and / or outside ALMS 10, such as climate databases, live climate feeds from sources, such as National stations. Weather Reporting, external environment sensors 94, or any input device 20 related to commercially available cities errt a base of real or preclective weather, calendars and voluntary consumer feedback. Some of the variability factor measurements are available from public sources, while others are available via private sources.
    In another alternative embodiment of the present invention, a loss of transmission line can be included in determining the projected energy savings of figure 11. As those skilled in the art 30 will recognize and appreciate, the amount of power supplied by a utility -a to a source of a device '- remote from the concessionaire is equivalent to the amount of power required by cHspositive, plus the amount of power lost in the transmission lines between the generation 5 plant of the concessionaire and the location of the device. Thus, the projected energy savings resulting from a control event can be determined by determining an expected amount of power to be consumed by the controlled device or devices 10 at a service point, at multiple service points or by the entire service area of the concessionaire, during the period of time of the control event, in the absence of a control event occurrence, for the production of first energy savings, by determining a quantity of power that is not expects that transmission lines will be dissipated as a result of not delivering power to the controlled device or devices during the control event for the production of second energy savings.
    20 In an additional modality of the present invention, the operating reserve (for example, the turnover reserve (already the reserve: adjustment range) d (= terminated by a concessionaire using the t-techniques explained above) sold to a requester dealer 1306, as shown in Figure 25, which is essentially a replica of Figure 9 of US Patent Application Publication No. US 2009/0063228 Al. As explained in US Patent Application Publication No. US 2009/0063228 Al, the saved power can then be distributed to the requesting concessionaire 30 1306 after the start of the control event {eg
    H d, úra.nte and / or after the completion of the control event.) Conducted by the concessionaire selling. The ion concession, the seller may be a virtual dealership 1302 or a service dealership 1304, as illustrated in Figure 5 and described in detail in U.S. Patent Application Publication No. US 2009/0063228 A1. Alternatively, a third party may serve as a management entity for managing the operation of ALMS 10 and the distribution i: resulting from the operation reserve for a requesting concessionaire 1306 subsequent to the start of a control event.
    In yet another modality, the ALD 100 for a concessionaire can determine the projected energy savings for each service point 20 served by the 15 concessionaire, according to the operational flow in figure 11, and aggregate the energy saving rn: ejected through de and all points of sej ^ ". 'jç: o served by the concessionaire, to obtain the total projected energy savings from which the operating reserve can be determined, 20 as described above.
    In an additional modality, instead of or in addition to the use of the operational flow of figure 10, in an attempt to find a data point of better combination in the repository 500 for use in the estimation of behavior of 25 power consumption a device, when the time period of the control event does not correspond to a time period in the repository 500, the ALD 100 can determine whether the repository 500 includes power consumption data for the device during periods of time before and after the expected time period of the control event and, if so.
    if so, interpolate a value corresponding to an amount of power that is expected to be consumed by the device a.
    during the p = time period of the control event, I ran based on the power consumption data for the device for 5 periods of time before and after the expected time period of the control event.
    In yet another modality, a requesting concessionaire may use a method to acquire operating reserve power from a source concessionaire. According to this modality, the requesting concessionaire requests the operation reserve power from the source concessionaire sufficiently before a transfer time in which to. operating reserve power will be required in order to facilitate a measurable and verifiable controlled load generation of operating reserve power. The generation of controlled load from the operating reserve power results from a determination of the operating reserve as detailed above with respect to figures 7 to 12. The requesting concessionaire receives an acknowledgment from the source concessionaire indicating that the source concessionaire will supply the reserve power of operation in transfer time. Then, in the transfer time and for the period of time thereafter, the requesting concessionaire receives at least part of the operating reserve power from the source concessionaire.
    In an additional modality, the operation reserve determination techniques can be used by a 1302 virtual concessionaire, as shown in
    U.S. Patent Application Publication
    US No. 2009 / 0.063228 Al. For example, virtual concessionaire 1302 may be operable to at least supply power to one or more requesting concessionaires 1306 for use as
    5 operation by requesting concessionaires 1306. In this case, virtual concessionaire 1302 may include, among other things, a repository 500 and a processor 160 (for example, in an ALD 100). In this mode, the processor
    160 is operable to determine, remotely, for at least
    10 less than a period of time, the power consumed by at least one device for the production of power consumption data.
    Processor 160 is additionally operable to store power consumption data in the repo, "itory
    500 and, at the appropriate time, determine a period of time
    15 expected future for a control event during which power is to be reduced for the device or devices.
    Processor 160 is also operable to determine, before the start of the control event, the expected power consumption behavior of the device or devices during the time period of the control event, based on at least the stored data power consumption.
    Processor 160 is additionally operable to determine, prior to the start of the control event, the projected energy savings 25 resulting from the control event, based at least on the estimated power consumption behavior of the devices' OL1 device.
    Furthermore, the processor
    160 is operable to determine, before the start of the control event, the operating reserve based on the economy of
    30 projected energy.
    After determining the operating reserve, processor 160 is operable to communicate an offer to supply the operating reserve to a requesting concessionaire 1306 or concessionaires.
    In yet another embodiment, the service point 20 5 can optionally also include one or more power storage devices 62 (one shown in figure 3) in the location for storing the energy supplied by the utility or produced by one or more optional power generation devices 96 (one shown in figure 3).
    10 The power storage device 62 can be used primarily for power storage or, more typically, it can have another primary purpose, such as power consumption, although power storage is a secondary purpose. Normally, c) 15 power storage device 62 is plugged into the power network and stores in increments the power which can be used or consumed later. An example of a power storage device 62 is an electric vehicle or a hybrid electric vehicle, which can be plugged into the power network through a recharging station located at the service point. When not in use, the power storage device 62 can be plugged into an outlet at service point 20 to remove and store power from the utility network. The power storage device 62 can then be unplugged later and used for its primary purpose. In the example of an electric vehicle, the power storage device 62 is unplugged for use in transportation. Alternatively, the power storage device 62, at a later time after
    G0llC3 can be loaded, it can serve as a power source, as well as a power generation device 96. For example, an electric vehicle can: plug into a socket at service point 20 and have some or all of its stored power 5 remaining supply to the concessionaire network, when, for example, the owner of the vehicle is not planning to use the vehicle for a while. In that case, the vehicle owner could choose to supply power to the dealer network at times of high peak load and receive or consume power from the network at times of low peak load, effectively treating the stored power as a commodity. Alternatively, the owner of the power storage device 62 may allow the energy stored in the power storage device 62 to be considered available energy for use as an operating reserve in the event that the stored energy may be required for this purpose by a utility. service 1304 or a requesting commissioner 1306.
    The ALMS 10 of the present invention supports the inclusion or use of power storage devices, such as batteries or O1E vehicles, in a service port 20.
    Referring again to Figure 3, a power storage device 62 can be used for energy storage and / or dispatch. When the power storage device 62 is located at a service point 20 and receives power from the grid and / or from a local power generation device 96, the control device for q service point
    2.0 (for example, a client: e cie cargo at_iva 300) notifies a
    + I - central cantro'lador, such the ALD 100. ALD 100 registers. ... the amount of energy supplied to and and stored by the power storage device 62 and c) time period of storage activity in the database of 5 ALD 124. C) ALD 100 can also determine the carbon area and credits carbon emissions associated with storage activity, as set out in US Patent E'edido
    No. 12 / 783,415, which was published as U.S. Patent Application Publication No. "US 20100235008 Al on September 16, 2010, and is incorporated herein by reference.
    When storage device 62 is used to send or dispatch power to the power grid, the active load client 300 again notifies the ALD 100. The ALD 100 records the amount of power dispatched and the time period of the activation. dispatch capacity in the ALD 124 database. The ALD 100 can also determine the carbon area and carbon credits associated with the dispatch activity, as set out in US Patent Application Publication No. US 20100235008 Al. For example, to determine the carbon area and carbon credits associated with the power dispatch activity, the ALD 100 can determine generation mixtures with respect to the power supplied by the power network to a service area containing service point 20 in gLia1 c) power storage device 62 was used during dispatch and storage activities. The ALD 100 can also determine the net carbon credits earned, if any, resulting from storage and shipping activities by subtracting the carbon credits associated with the carbon storage power activity from the carbon credits associated with the power shipping activity. , associate any earned credits with service provider 20 or the owner of the storage device, and store the earned credits in the dealer 5 power and carbon database 134. Thus, if the storage device 62 is loaded by a dealer during at night, when much of the energy supplied by the utility comes from a carbon-free source, such as wind turbines, and is then discharged or dispatched during the day and at peak times when much of the energy is supplied by the concessionaire is being generated from sources that emit carbon, such as coal and gas, energy dispatch may result in carbon credits. net profits earned by service point 20 or storage device owner 15, as set out in U.S. Patent Application Publication No. US 20O0235008 Al.
    In one embodiment, the power stored in the power storage device 62 can be managed by ALMS 10 (for example, via a central controller, such as the ALD 100). This management may involve control over when the power storage device 62 will withdraw or store power and using the power stored in the power storage device 62, when necessary, by a utility, including an operating reserve. A control over when the power storage device 62 will draw power may involve specifying the best times for the power storage device 62 to draw power.
    . power of the network, in order, for example, to minimize the carbon area associated with this storage activity or to mitigate the use of an operating reserve by a concessionaire. Allowing "the ALMS 10 to control when the 5 power stored by the power storage devices 62 is used allows a utility to draw power from the power storage devices 62 during times of critical need, such as maintaining frequency regulation in response at AGC 10 commands or provide an operation reserve in order to avoid a partial blackout or a total blackout. If power is allowed to be removed from the power storage device 62 in response to a request from a 1304 dealer, 1306 for ALMS IO, an alert may be sent to the consumer, 15 such as through the consumer panel 98. The consumer may be provided with a reward, a monetary credit or other benefit to encourage participation in the management of the storage device.
    20 (J management of power storage devices 62 by ALMS 10 can be provided through consumer panel 98 (for example, as an extension of consumer subscription application 116, as a power storage device management application 25 separate, as part of the consumer's energy program, or otherwise.) Consumer panel 98 can inform the consumer of preferred times for power storage device 62 to be powered or otherwise connected to the power grid for 30 power storage purposes in the power storage device 62 and preferred times for the 'I. power storage device 62 to be plugged into or connected to the power network for power dispatch purposes a from a 5-power storage device 62 to the power network, in order to, for example, maximize the carbon credits earned by the consumer. In addition, the consumer can indicate through the consumer panel 98 whether the power storage device or devices 62 can be used by ALMS 10 as an operating reserve for a 1304 service concessionaire or 1306 requesting concessionaire. the consumer indicates that the power stored in a power storage device 62, such as an electric vehicle or a hybrid electric vehicle 15, can be used by ALMS 10 for any reason, the consumer can also provide information related to the storage device power 62, such as a device type, device parameters or specifications (including loading and unloading parameters or characteristics, such as, but not limited to, loading rate, unloading rate, total storage capacity, and / or charger type), a control module identifier associated with a controllable device to which the device power storage 62 will be connected for charging, and any other relevant information, by entering this information into the ALD 100 through the consumer panel 98.
    Furthermore, the power storage device 30 62, such as an electric vehicle or a hybrid electric vehicle, can be implemented with wireless access technology, so that the power storage device 62 can communicate its relevant information (for example, device type, charge status, device parameters or specifications, location (for example, where the power storage device 62 still includes a location tracking feature, such as a GPS), time since the last recharge, and so on) directly to the ALD 100 over a wide area wireless network via the communications interface
    308. With this information, the ALD 100 or active load client 300 can determine how much power has been stored and / or can be dispatched over time. In addition, knowing the location of the power storage device, the state of the charge and other parameters, the ALD 100 or another central controller pc) to take this information into account err an attempt to balance the charge or increase the supply to the network (for example, by directing the power storage device 62 to urge a certain area of the network for recharging or dispatching power), or when responding to a power outage in a service area containing the power storage device 62. For For example, in one embodiment, the ALD 100 can use the information accumulated from power storage devices 62, such as electric vehicles, to negotiate a quote with one or more synchronization data for power supply from power devices. power storage 62 for the network at network points identified by the concessionaire, in order to help with a supply condition low price or to supply operating reserves.
    Alternatively, due to the loading presented. by certain power storage devices 62, such as electric vehicles (especially when using a fast or fast charging feature), adding these devices to the network during a new power start can cause an unwanted peak power, which could damage the network, unless the concessionaire used "its contingency reserve as a catch of 10 cold load. Therefore, to reduce the voltage in the network during a new start, while mitigating the use of contingency reserve, the ALD 100 can intelligently control the new power start for the affected concessionaire service area, such as by using the 15 new start techniques described in details in Order lj.S. commonly owned copending No. 12 / 896.307, the which was published as the US Patent Application Publication
    No. 20110022239 A1 on January 27, 2011, and is incorporated here for reference. By receiving 20 regular updates of electric vehicle locations across a network area, the ALD 100 can anticipate and project the impact of the network due to an electric vehicle recharge. Also, during a new controlled start, after a power failure, the ALD 100 25 can determine areas including service points 20 with high concentrations of electric vehicles needing recharging and configure those locations for the new start algorithm, so that the points of service 20 with high concentrations of electric vehicle do not have the 30 new start given simultaneously. Alternatively,
    each power storage device 62 can effectively be treated as its own service point and include its own control device with functionality similar to an active load client 300, 5 whose device can communicate with c) ALD 100 over a wide area wireless rpde or any other communication network and carry out the operations of the active load client 300 with respect to the controlled restart process described in the US Patent Application
    US No. 20110022239 Al. For example, due to the substantial charging presented by electric vehicles during a recharge (especially a quick recharge), the ALD 100 can be configured to treat each electric vehicle as a service point ( or at least each electric vehicle in a service area affected by a power failure) for the purposes of implementing a new controlled start. Alternatively, the ALD 100 can exploit a knowledge of the locations of mobile power storage devices for dispatching excess capacity back to the network, to assist in recovering from a power outage situation (for example, to serve as a reserve for the operation of a concessionaire in a situation of recovery from power failure), as may be permitted by the consumer profiles associated with the power storage devices 62 and for dispatch or power delivery prices, as can be negotiated with the concessionaire for ALD 100.
    As an alternative to receiving power storage device locations
    ; +
    Mobile 62 directly from these devices 62 over a wireless network via its associated control devices, the ALD 100 can determine the locations of devices 62 by receiving report messages 5 from active load clients 300 at service points 20 on which devices 62 are located.m For example, an active charge client 300 or a sirrtilar control device at a service point 20 or a recharging station can detect when the power storage device 10 62 attaches to the service point or station for recharging purposes.
    In that moment, the control device can retrieve identification information for the power storage device and supply it to the ALD 100, which then can determine the location of the device based on the location of the power consumption device. power / charging station.
    In another mode, the diSPO, power storage aitiVO 62 can be connected to the 20-power network at another service point in addition to your home or base service point. For example, a hybrid electric or electric vehicle can be plugged into a home being visited by the vehicle owner or user. In such an example, the 25 power storage device 62 (electric or hybrid electric vehicle) can still be managed by a central controller, as described above. When power storage device 62 is connected to the power grid and receives power from the grid, a service point control device, 3.0 such as an active load client 300, installed at the visited service point notifies the controller (for example, the ALD 100) and provides an identifier (ID) for the power storage device 62. Q ALD 100 records the amount of power used and the 5-time period of storage activity in a database entry. ALD 124, or another repository, associated with the device ID. ALD 100 can also determine the carbon footprint and carbon credits associated with storage activity, as set out in U.S. Patent Application Publication No. US 20100235008 Al.
    When the power storage device 62 is used to send Qü clespachar eriergia to the power network, the active charge clierite 300 at the service point where the power storage device 62 is currently located notifies the ALD 100 with the ID device for power storage device 62.
    ALD 100 records the amount of power dispatched and the time period for dispatch activity in the ALD 124 database. ALD lOC 'can also (= determine the carbon area and carbon credits associated with dispatch activity, as set out in US Patent Application Publication No. US 20100235008 Al. The ALD 100 can then determine the net carbon credits earned, if any, resulting from storage and dispatch activities, by subtracting the carbon credits associated with the activity of power storage of carbon credits associated with the power dispatch activity, associate any credits earned to the home or to the base 20 service point of the power storage device or to the owner of the power device.
    - - aEmazenamer1to, and store the credits earned in the dealer power and carbon database 134.
    Referring back to figure 4, the data associated with the storage and dispatch activities of the power storage device 62 can be received at the central controller (example, ALD 100) from the control device at the service point applicable (eg active load client 300) via the ALC 112 interface and the security interface 10 110. The data can be processed through the ALC manager 108 to the ALD 124 database. The savings application carbon 132 can use the data to calculate power and carbon savings, which is stored in bank d3 power and carbon data from dealership 134. The power savings application 120 can use q data to determine the amount of power stored in power storage devices 62, which may be available for use as an operating reserve for a 1304, 1306 dealership.
    20 To account for the mobility of power storage devices 62, the ALD database 124 optionally stores identifiers (IDS) for all controlled devices and storage devices 62 associated with each service point 20. When reporting 25 a power consumed, dispatched or stored by a power consumption device or a power storage device 62, the active load client 300 includes the device ID with the respective device data, thereby allowing the ALD 100 to associate c) s 30 data to the correct device and / or service point on the
    - 'ALD 124 data bank'. In this way, the service point 20 to which the power storage device was associated in the ALD 124 database receives credit for any carbon credits. net gains 5 as a result of dispatching power back to the network from the power storage device 62, regardless of oncle in the dealership service area or elsewhere that dispatch occurs. The mobility of certain 10-power storage devices 62, such as electric vehicles or hybrid electric vehicles, also facilitates the use of devices 62 as an operating reserve in the various locations to which devices 62 travel, as described in - more details below .
    15 Figure 14 illustrates a block diagram of an example active load client 300 (control device) and residential load center 400, as used according to an ALMS 10 modality in figure 3. The active load client 300 described includes an operating system 20 '302 (which can be based on Linux), a status response generator 304, an intelligent circuit breaker module controller 306, a communications interface 308, a security interface 310 , an IP 312-based communication converter, a 314 device control manager 314, an intelligent circuit breaker counter manager (BI-BN) 316, an IP router 320, an intelligent meter interface 322, an interface smart device 324, an IP 330 device interface, a 30 power 340 dispatch device interface and a prc) gram ('event jour 344. a' cadre a'tiva 300 client, in this modality, is tim computer or ba control system I use a processor located in Iocal and I am a service point 20 (for example, in the consumer's home or business). The primary function of active load client 5 is to manage the power load levels of controllable devices located at service point 20, which the active load client 300 supervises and controls on behalf of the consumer. In the exemplary modality, the load client activates 300 pQ out of 10 include a dynamic hosting configuration (DHCP) client functionality to allow c) active load client 300 to dynamically request IP addresses for itself and / or a or actual controllable devices 402-412, 60 managed in this way from 15 a DHCP server on the main IP network facilitating communications between the active load client 300 and the ALD
    100. The active load client 300 can also include a router functionality and maintain a routing table of IP addresses assigned in a memory of the active load client 300, to facilitate the delivery of messages to from the active load client 300 to controllable devices 402-412, 60. The active load client 300 may additionally include a power dispatch feature (for example, a 2 "interface to the power dispatch device 340) and provide information for the ALD 100 with reference to the power available for dispatch from a power generation device 96 and / or a power storage device 62 at service point 20. Details with reference to many of the components of the active cargo client 300 are set out in US Patent No. 7,715,951 and paragraphs - US Patent Application Publications No. US 20090063228 Al, US 20100179670 Al, US 20100161148 Al, and US 20100235008 Al, to 'of which being in incorporated here as a reference for this 5. Additional details with reference to the operation of the active load client 300 and certain components thereof to which that operation specifically refers to one or more features of the present invention are provided below.
    Referring now to figure 15, that figure 10 illustrates an example operational flow chart 1500 providing steps performed by a service point control device, such as an active load client 300, for data supply to a central controller , such as an ALD 100, and power for a concessionaire power network, according to an alternative mode of the present invention. The method of figure 15 provides operational steps performed by the control device to assist the c22rltFal controller in designing and delivering an available operating reserve resulting from stored power 20 or one or more power storage devices 62 partially or fully charged located at a service point 20. The steps in figure 15 are preferably implemented as a set of computer instructions (software) stored by a memory (not shown) of the control device and executed by one or more processors from the control device . For example, when the service point control device is an active load client 300, the operating flow of figure 15 can be performed primarily 30 through the power dispatch device interface 340,
    á + by device control manager 314 and event scheduler 344. In a modality, in which the. power storage device 62 is an electric vehicle, the cont-role device implementing method 5 of figure 15 can be integrated into a charging station for use by electric vehicles.
    One or more power storage devices 62, such as electric vehicles, hybrid electric vehicles, or batteries, can be connected to the 10 power network at one or more service points 20, When the power storage devices 62 are electric or hybrid electric vehicles, service points 20 may include vehicle recharging stations from which vehicles can be recharged (for example, via a plug-in or wireless vehicle charger) ). The active charge client 300 or a similar control device at the respective service point 20 detects (1501) the presence of a power storage device 67 at service point 20 through 20 of the power dispatch device interface 340.
    For example, the power dispatch device interface 340 may include a switching circuit that detects when a power storage device 62 or a power generation device, 96 is communicatively coupled to the active load client 300 or a control module in communication with the active caFga customer 300. 'A control module such as this can be integrated into a vehicle recharging station or other grid connection point at service point 20.
    30 Alternatively, each recharging station may include its own active charging customer 300 or another control device operating in a similar manner; provided, however, that the control device incorporated in a charging station cannot. include all the functionality of an active load client 300, provided that the control device includes at least the functionality necessary for carrying out one or more embodiments of the present invention.
    The active load client 300 may alternatively 10 determine that a power storage device 62 is present at service point 20 by receiving a registration and / or an authentication request from the arnia device: potency zen 62 through power dispatch device interface 340. The active load client 300 can receive a request like this either directly (for example, where the active load client 300 is located at a vehicle recharging station) or via a controllable device (for example, a Zig8ee, W1-Fi or BPL control module) 20 connected between the storage device 62 and the active charge client 300, such as in a vehicle charging station. The power dispatch device interface 340 notifies device control manager 314 of the presence of the power storage device 62, which in turn provides information regarding the power storage device 62 (for example, device type, device parameters or specifications (including loading and unloading parameters or characteristics), 30 control module identifier associated with the
    : Ca / 103 controllable device to which the power storage device 62 will be connected for charging, and so on) to the ALD 100 via an applicable communication protocol (for example, IP by
    5 HSPA or LTE). Alternatively or additionally, a service point consumer can inform the ALD 100 that a service point includes or will include a power storage device 62 by entering information related to the device storage device.
    10 power (for example, device type, parameters or device specifications (including loading and unloading parameters or characteristics),
    control module identifier associated with a controllable device to which the control device
    15 power storage will be connected for charging, etc.) for the ALD 100 as personal consumer settings
    138 (for example, a consumer profile) through the consumer panel 98. When the power storage device 62 is an electric vehicle or a
    20 hybrid electric vehicle, the consumer profile for the device may include ^ parameters for charging the vehicle (eg, hundredDc period) Â- pre-charge charging, preferred electricity charge price, and so on) that conform to the quotation policies of
    25 electric vehicle dealerships that can allow the consumer to receive a fee incentive for charging the vehicle at times that are considered "off-peak", where operating reservations are typically not required.
    The rate incentive can be referred to as a
    30 "hour of use (TOU)" price point, which can be unique for electric vehicles at the option of the dealership. O . consumer profile may also include market signals and supply rules that would allow the charging of the 62 ce.qs power storage device to last for 5 brief periods of time in response to a call to dispatch operating reservations, which can be received from the dealer via a central controller, such as the ALD 100.
    After the active load client-e 300 has notified the 10 ALD 100 that a power storage device 62 is coupled to the electrical power network at a service point 20, the ALD 100 can manage the power flow to and from of the storage device 62 by means of a message sending to the active load client 300.
    In this sense, c) active load client 300 may periodically or in response to a question inform the ALD 100 about a quantity of power stored in the power storage device or devices 62 at service point 20, so that the ALD 100 can 20 take this power into account when estimating the amount of operating reserve available at points of service 20 under the control of the ALD. E'or exernplo, in one embodiment, the active load customer 300 (or another control device.] ") Ç) service point 20) determines 25 (1503) an amount of electrical power stored by the device or power storage devices 62 at service point 20. The active load client 300 can make this determination by receiving reports of stored power from each power storage device 62 via the dispatch device interface
    , 1 of power 340 or by · estimating the stored power based on a timeout in cue c) power storage device 62 has been charging and the cax: charging characteristics of the 5 storage device (for example, the charge rate charging profile or power storage device 62). The active load customer 300 can determine that a power storage device 62 is fully charged by means of a determination that the power storage device 62 is still electrically coupled to the power network at service point 20 , but it is no longer receiving power from the power grid (for example, as determined by a power meter or a power control module in an electric vehicle recharging station).
    Alternatively, the power storage device 62 can send a message to the active load client 300 via the power dispatch device interface 340 informing the active load client 300 full status or. partially charged from the device (as well as optionally informing the active load customer 300 of the amount of stored power from the storage device). The amount of stored or estimated power to be stored in each power storage device 25 at a particular service point 20 can be set in the active load client.
    3.00 for service point 20.
    After determining the amount of power stored in the power storage device or devices 62 30 at service point 20, the active load client reports
    «(1'5.05) the amount of power stored for the ALD 100.
    ~ The stored power report can be on a storage device basis by storage device or on a service point basis. The information can be stored in a central office in the ALD 100 (for example, in the ALD database) or otherwise accessible by the ALD 100. As discussed in detail above, the central repository can also store power consumption data for 10 devices controlled at service points 20 from which the ALD 100 can project or estimate an available operating reserve obtainable through control events, so as to be continuously or at least regularly prepared to supply a dealership 15 1304, 1306 containing an operation reserve through power dispatched from power storage devices 62 and / or power saved through load deferral cont-role events, the ALD 100 can determine the amount total operating reserve available by adding 20 stored power from power storage devices 62 at service points 20 under general control of the ALD with the projected energy savings quantity available from these service points 20, as a result of a load delay during 25 control events. When the reservation of operation is required from the ALD 100 (for example, e: o response to a reissue from a dealer 1304, 1306, such as a market signal from an ISO or an AGC command, such as with a request or a regulation signal for cirna ("Reg
    - up ") from an AGC system of coricess.ionáría). ,, q ALD 100 can instruct one or more active load clients 300 to unload their power storage devices 62 and optionally start events of control.
    5 Thus, each active load customer 300 who is to be so instructed receives (1507) a power dispatch instruction from the ALD 100 and, in response, controls (1509) a flow of electrical power from üm ¢ jü more power storage devices 62 10 'p.will power grid to help adapt to the needs of the operating reserve concessionaire. The power dispatch instruction can be part of a control event instruction (for example, a "Cut" message) but can be sent separately to active load clients 15. The power dispatch instruction can indicate a predetermined amount or percentage of stored power in a power storage device 62 for dispatch back to the network. The predetermined quantity or percentage can be specified in üTt consumption profile for service point 20, or can be determined based on the type of device (for example, due to device parameters, such as discharge limitations) . For example, a consumer profile can limit the power 25 that can be dispatched from a power storage device 62 to no more than 50% or 75% "of the capacity of the storage device. When an event of control is measured at a service point 20 in relation to the supply of operating reserve and a power storage device 62 is in the process of being loaded at service point 20, the customer - active charge 300 at the service 20 (for example, for the entire service point or inside, for example, a vehicle charging station) can instruct the power storage device 62 or a cQn |: rQle assocclc module) to stop the process charge, in order to make available the power which would otherwise be supplied to the power storage device 62 for operating reserves. When the active load 10 client 300 determines (1511) that the power dispatch event (or which may coincide with a power reduction control event) has ended, the load client, active 300 again can begin loading (1513) of the power storage device 62.
    15 Referring now to figure 16, this figure illustrates an example 1600 operational flowchart providing steps performed by a central controller, such as an ALD 100, to estimate (for example, project) and suppose: go resulting available operating reserves of power 20 stored in power storage devices 62 fully or partially charged, according to an alternative embodiment of the present invention. The steps of figure 16 are preferably implemented as a set of computer (software) instructions stored 25 in, a memory (region shown) of the central controller and executed by one or more processors 160 of the central controller. The operational flow of figure 16 can be executed by the master event manager 106 and the ALC manager 108 before and / or in response to a reservation request for the operation.
    According to the operational flow of figure 16, the central controller determines (1601) amounts of electrical power stored by devices 62 located at one or more service points 20 for the production of stored power data. As discussed above, the central controller can receive a state of charge or other device parameters from devices çj € 'cont: rol.e -Located ÍJOq service points 20 or, optionally, from devices 62 directly where, for example, devices 62 include a functionality applicable for communicating directly with the central controller. When devices 62 are electric vehicles, control devices can be located at electric vehicle charging stations, so that a charging station control device controls power flows to and from a vehicle. electrically connected to the charging station.
    Alternatively, control devices (for example, active load customers 300) can be located more generally at service points 20, such as eni or near the main power panel or power meter for the service point, and coritolar o, power flips to and from various devices. Furthermore, each electric vehicle can include its own control device that communicates over a wireless network with the central controller. These communications can include charging status and information from there, which the central controller can determine the amount of stored power. The central controller stores
    (1603) stored power data or information - for devices 62 as respective entries in a repository, such as the ALD 124 database. Determining and storing data relating to the 5 amounts of power stored in devices 62 they can occur regularly or periodically, so that the central controller maintains an updated set of stored power data.
    After determining the amounts of power 10 stored in power storage devices 62 dispersed throughout the service area, the central controller can determine (1605) a current amount of available operation reserve based on at least stored power data. For example, the central controller can determine, from stored power data and other information, such as consumer profiles associated with devices 62 and / or service points where devices 62 are located, the amount of power stored that can be delivered 20 to the network in the required time period according to the FERC and NERC regulations for the qualification as the operation reserve. For example, the central controller can determine which devices 62 are electrically coupled to the network and any limitations using the stored capacity of these devices 62, in view of consumer profile restrictions (for example, capacity percentage limits, etc.) for the determination of the amount of operational reserve currently available resulting from the power stored in the device 62. Due to the fact that power storage devices, such as electric vehicles,
    to be able to intermittently engage and disengage from the network, and to move across an entire dealership service area or between dealership service areas,
    5 the stored power available for use as an operating reserve may change on a required basis.
    The central controller tracks changes in the amounts of stored power and the amounts of that stored power available for operating reserve, in order to estimate the operating reserves available for Ílins to respond to operating reserve requests (for example , AGC commands). In one case, the power quotas stored in devices 62 as reported by devices 62 or by service point control devices are used to determine the available operating reserve.
    Alternatively, and in a preferred way, the amounts of stored power (stored power data) ~ are considered in combination with projected energy savings resulting from a control event, and, optionally, power generated by 96-point power generation devices of service
    20, in order to determine the total amount of operation reserve available in the system.
    Thus, the determination of the amounts of power stored in power storage devices 62 at service points can be integrated into the reserve determination and detailed operation above with respect to figures 2 to 13, so that the reserve quantity operating 0 available determined (1605) by the central controller takes into account the projected energy savings resulting from a control event and the energy stored · available from the power storage devices 62 in a utility service area.
    After the available operation reservation has been determined, the central control determines (1607) whether a request for an operation reservation has been received from a concessionaire. When the reservation of operation is required from the central controller, the central controller can receive a request for reservation of operation from a dealer 1304, 1306, such as a market signal from an ISO or an AGC command, such as a request or a regulation up signal ("Reg up") from a dealership AGC system. When such a request is received, the central controller can determine (1609) whether the central controller can satisfy the request with the currently available operating reserve. If the central controller determines that the reservation request for operation cannot be satisfied, the central controller may 20 'inform the concessionaire and / or not respond to the request.
    If the central controller determines that an operation reservation request can be made, the central controller can manage (1611) a flow of stored electrical power from power storage devices 62 to a power network accessible by For example, the central controller can instruct one or more control devices (for example, active load customers 300) to download their power storage devices 62 to the network and optionally start power events.
    . coritrole.
    According to one embodiment, the central controller can send a power dispatch instruction to each control device associated with a power storage device, which the
    5 central controller has determined power that can be delivered to the grid to help meet the dealership's need for operation reserve.
    The power dispatch instruction can be part of a control event instruction (for example, a "Cut" message) or
    10 can be sent separately to the control devices.
    The power dispatch instruction may indicate either a predetermined amount or a percentage of power stored in a power storage device 62 to be released back into the network. THE
    15 predetermined quantity or percentage can be specified in a consumer profile for service point 20 or can be determined based on the type of device (for example, due to device parameters, such as discharge limitations). Per
    For example, a consumer profile can limit the power that can be dispatched from a power storage device 62 to no more than 50%, or
    75% of the storage device capacity.
    When a control event is started at a service point 20
    25 Regarding the supply of operation reserve and a power storage device 62 is in the process of being loaded at service point 20, the control event instruction issued by the central controller may cause the control device in the
    30 service point 20 (for example, for the service point
    . all. or inside, for example, a vehicle charging station) to instruct the power storage device 62 or an associated control module to cease the charging process, so as to make available the power which would otherwise be available. supplied to the power storage device 62 for operating reservations- When the power dispatch event (which may have coincided with a power reduction control event) has ended, the control device can again start the charging the 'power storage device 62.
    An example modality for using power storage devices 62 for an on-demand backup source uses an electric vehicle or a hybrid electric vehicle (collectively, an "electric vehicle") in the ALMS 10. The subsystem can include a control device, such as an active charge client 300, at a vehicle charging station or on the electric vehicle itself, to allow the electric vehicle 20 to receive charging information from the central controller (for example, an ALD 100). In this modality, the electric vehicle has a unique ability to deliver part or to vary its power in response to receiving an instruction (for example, from the central controller) for c) electric vehicle to charge or deliver electricity in response to a signal to from a concessionaire (including a network operator or an ISO), NERC, FÉRC or any other entity that routinely publishes market quotation for 30 operation reserves, including both working and non-working reserves. The
    88 / 10.3
    - vehicles. electric represent a single use uri for the concessionaire operator, due to its ability to move its electrical consumption and its capacity to deliver electric power to different locations in the network.
    An
    5 Since the network elements are stationary and have different charging (Volts / Vars / KVA) in their UE, the ability to control the impact of electric vehicles Tia rede through an ALMS 10 = their components (for example,
    ALD 100 and active load customers 300) can be
    10 important in maintaining network stability.
    In this modality, an electric vehicle located in your "home" or base location (for example, the service point associated with the owner or the electric vehicle) uses a charging station equipped with a
    15 control, such as an active load client 300. The charging station is an environmentally resistant device independent of charging a battery or an electric vehicle battery bank.
    A contractor using or subscribing to an ALMS 10 can establish a
    20 electric vehicle charging profile (for example,
    through consumer panel 98) which complies with the electric vehicle dealer pricing policies, which may include a fee incentive for charging the vehicle in hours that are
    25 considered "off-peak" (that is, when operating reservations may not be required). The fee incentive may be a "time of use (TOU)" price point, which may or may not be unique for electric vehicles.
    Even more,
    the consumer profile can also color) have market signals
    30 and rules for the offer for an electric vehicle to cease charging for short periods of time in response to a call to dispatch operating reservations by the utility through ALMS 10 (for example, in response to a control message from ALMS 10 to the active load client 5 associated with the vehicle, its charging station or the service point where the charging station is located).
    During an event in which operating reservations are dispatched by the utility, by the operator of the utility, or requested by ISO as a response to an offer to provide those resources by the utility's consumer, the electric vehicle may have its response instructions. changed to conform to the required operating reservations. For example, an ISO may dispatch a synchronized reserve / turnover reserve using a normal market signal. Under this scenario, depending on the rules established by the transporter organization: 3rd regional (RTO) or ISO, the request for operation reservations would require a response in 10 to 15 minutes. If ALMS 10 determines that it can satisfy the request for operating reservations, c) ALD 100 may send a "Cut" message to the active load client 300 controlling a power supply to the electric vehicle to interrupt the vehicle charging sequence. -icle. The "Cut" message can be sent in conjunction with a control url evenzo at service point 20 containing the electric vehicle or can be limited to a dispatch event, in which the power can only be dispatched from the power storage devices. .ia 62, including the electric vehicle, in response to
    9011'03 - call for operating reservations. The active c-mortar client. 300 can determine the vehicle's charging status at the "Cut" message mill, including the percentage of full charge and / or the amount of energy available for delivery from the electric vehicle battery, and report the vehicle's charge status. electrical, the active load client's compliance with the "Cut" message and a removed load measurement for the ALD 100. The ALD 100 can then store the data received from the active load 300 clients under the control of the ALD in a repository, such as the data bar of ALD 124, and supply relevant information, such as an aggregate power available for dispatch from electric vehicles and other power storage devices 62 and / or an aggregate load 15 removed , for ISO, according to ISO rules and in a format specified by the concessionaire, network operator, RTO or ISO for settlement.
    With respect to regulation or regulation reserves, as may be required by an AGC subsystem, the 20 ALMS 10 (for example, the 'íLD 100) can receive telernetry commands from the AGC subsystem used by the concessionaire, by network operator, RTO or ISO in accordance with the ACE equation. The commands can indicate the difference in the ACE equation representing deviations of frequency and voltage. For example, a "Reg up" command can indicate that the power must be returned to the grid to return ACE to zero; whereas a "Reg Down" command may indicate that the power must be removed from the grid to return the ACE to zero. These "Reg up" and 30 "Reg dawn" commands must be recognized by ALMS 10 (for example, ALD 100) and am a time window defined by the requesting entity or a governing body, such as NERC or FERC. AGC commands can also include the ACE equation for the utility to allow the ALD 100 5 to determine the appropriate response needed to return the ACE to near zero. Once the ace equation is received, the ALD can issue a "Cut" message or a "Turn On" message to the active load client 300 to compensate for any frequency deviation in the ACE and to correct the deviation , as instructed by the AGC subsystem, In one embodiment, an active load client 300 can cause the power stored in the vehicle's battery to be delivered to the network in response to a "Reg up" command, which indicates that more power is required to bring the ACE equation (and the frequency in the network being controlled) back into compliance (for example, ACE = 0).
    The present invention also takes into account the mobility of the electric vehicle. Substations, transformer and transmission and distribution lines do not move and the carriage, T [e! Lto Y relative in each of these network elements can be different, depending on the general network load at different times of the day.
    Thus, moving an electric vehicle to several charging stations that are in a remote or strange location from the "dornéstica" location of the vehicle can allow the dealership to establish an electric vehicle charging pattern by touching the network, especially where the vehicle recharges regularly or 3'0 repeatedly in the same locations (for example, work locations, restaurants, shopping malls, etc. '). The $ electric vehicle travel patterns can also be determined by receiving location data from the vehicles by the ALD 100 (for example, from 5 GPS units integrated into the vehicle or from other GPS units used with vehicles, such as portable GPS units or a GPS feature built into cell phones or smartphones and communicated to vehicle control devices via short range wireless links). An understanding of electric vehicle travel patterns may also allow the utility to develop zonal charging and delivery points for electric vehicles, thereby potentially requiring more precise control by ALMS 10. According to one modality, a customer active load 300 at any charging station, whether domestic or outside, can determine the "state" of the electric vehicle, the preferences of the consumer associated with the electric vehicle, and the current network conditions (eg, percentage of charge for the battery of the electric vehicle, consumer preferences, preferences of the dealer, network operator / operator, current market conditions, according to ISO: when the electric vehicle is in close proximity to the station (pair coupled electrically or communicatively to the station) by receiving data from the vehicle, measuring parameters of the vehicle battery and receiving a consumption information r and related to the network from the ALD 100.
    According to an additional modality, the electric vehicle can be 3upric.io with consumer information and related to the reaction (for example, including information regarding open requests for operation reservations),
    while the electric vehicle is mobile by sending the
    5 relevant information from the ALMS 10 over packet networks via machine-to-machine (M2M) connections made easier by the various wireless network configurations described above (For me: example, GSM, HSPA, LTE, CDMA and so on) against). The information transmitted to the vehicle from ALMS 10 (for example, from ALD 100) via M2M connections provides the electric vehicle with a regularly updated status of network condition, market prices, and the need for re , operating reserves while
    .the electric vehicle is on the move, in its home charging station or outside charging station.
    The status information provided for the electric vehicle informs the vehicle of various system conditions,
    based on the consumer profile and specific deletions, due to market conditions and / or the dealership operations / network operations available to be performed by the ALD 100. In addition, the electric vehicle may include a control device that sends packets of M2M information for the ALD 100 informing the
    ALD 100 of your lc) cali :: aç: ã3, acL'al charge status and other parameters.
    The ALD 100 can use this information to inform a assignee of potential loading problems and receive feedback from the consensus on whether the control devices (eg active load customers 300) managed by the ALD 100 can allow electric vehicles recharge in certain
    W t lQ'ca'1iz.ations and at certain times. The information supplied by the electric vehicles: cs can also provide the ALD 100 with one. opportunity to neaoci-ar the electric power clespacho from electric vehicles with excess capacity 5 (for example, more capacity than required to reach a target destination or which are currently immobile), which are located in the areas dealership service provider with capacity requirements (eg operation reserve).
    10 Data for an electric vehicle can be stored in a database together with its last known address location (for example, as determined by GPS coordinates wirelessly reported by the electric vehicle through its active charge client 15 300 or other control device), such as an "electric vehicle charging visitor location recorder" (EVCVLR) database contained in ALMS 10. Additionally, when the electric vehicle returned to its domestic 20 "charging station ", the data for the electric vehicle can be stored in a corresponding" home location recorder "(HLR) database iiq ALMS 10. The electric vehicle can register and be authenticated at each charging station in order to maintain a 25 security level for the information exchanged between the charging station (outside / visiting or domestic) and the 'electric' vehicle. The EVCVLR and HLR database entries can allow the consumer to travel abroad and participate in events, such as dispatching power 30 or cessation of loading events, to remove operating reserves for the network. Participation in these events may allow the electric vehicle owner to receive compensation for the provision of operating reserves while away from their domestic charging station 5. In addition or alternatively, an inclusion of the EVCVLR and HLR databases in ALMS 10 provides a method of "releasing" taxation for electric vehicles that charge using unsophisticated chargers (for example, chargers that do not include their own devices). , ALMS report control positives) in locations or through charging stations that are outside the service area of a domestic vehicle dealership or that do not include or are not otherwise associated with an ALMS control device, such as an active load customer 300. In all cases, the ALMS 10 (for example, via a communication from the electric vehicle to the ALD 100) can record the vehicle's location (for example, as determined using GPS or otherwise) and preferences established in the ALMS 10 river (for example, consumer profile) and receive specific location / geodetic commands from the dealership, operator and network, RTO or ISO, to be compliant with network conditions or in response to market conditions, such as offer responses, for the delivery of operating reservations.
    The methods shown above for projecting and supplying the operation reserve in response to concessionaire requests can be used by ALMS 10 for the implementation of a virtual concessionaire 1302, as detailed above with respect to figure 13 and described generally in US Patent Application Publication No. US 2009/0063228 A1. In that case, virtual concessionaire 1302 may include a repository and a processor, such as the ALD 124 database and processor 160 supplied by the ALD 100. In this case, the process "idor" can be programmed or operable in another way to execute the various functions of projection and delivery of operation reservation described above.
    For example, virtual utility 1302 can be operable through the processor to determine the amounts of electrical power consumed by a first set of devices located remotely (for example, power consumption devices at service points 20 in a service area of concessionaire) for at least one period of time for the production of power consumption data. The virtual dealership 1302 can also be operable through the processor to determine the amount of electrical power stored by a second set of remotely located devices (for example, power storage devices 62, such as batteries or hybrid electric Qü vehicles. at service points 20 in the dealership service area) for the production of stored power data. The processor can then store the data and power consumption and the stored power data in the repository.
    At a later point in time (that is, after storing power consumption data and giving stored power data n: 'repository), virtual dealer 1302 can be operable through the processor to
    , the determination that a control event is about to occur during which an electrical power supply is to be reduced for the first set of devices.
    The determination can be made in response to a request 5 from a dealership. For example, a concessionaire's AGC system, the: jcíé issues an AGC command, such as a Reg up command, requiring a reduction in earga and / or an increase in supply, in order to correct and stabilize (this is, regulating ) the frequency of the power 10 supplied by the concessionaire '(that is, in order to obtain the ACR cje-concessionaire equal to or close to zero). Such a condition and a need for regulation can occur as a result of a subgeneration by renewable energy sources from the utility, such as wind power and solar power, during certain periods of time when the utility typically relies on these energy sources. power. Upon making a decision that a control event is about to occur, virtual dealer 1302 can be operable through the processor for 20 e3timar, before the start of the control event and under the assumption that the control event is not to occur , an expected power consumption behavior of the first set of devices during a first term period based on at least 25 stored power consumption data, in which the control event is expected to occur during the first period of time . The details of making this estimate are set out as an example with respect to figures 8 to 11.
    Having estimated the expected power consumption behavior of the first cc) set of devices over the expected time period of the control event, a '
    virtua1 1302 concessionaire can also be operable
    through the processor, to determine, before the start of the control event, energy savings projected at
    5 from the control event, based at least on the estimated power consumption behavior of the first set of devices.
    The projected energy savings can be determined on a service point basis per service point or on a utility-wide basis.
    Where virtual concessionaire 1302 and its associated central controller (for example, ALD 100)
    control devices at multiple service points 20 via local control devices (for example, active load customers 300), the virtual dealership processor can determine projected interredial energy savings for each service point
    20 in which one or more devices are to be affected by the control event and aggregate or add the projected intermediate energy savings for all service points 20 to produce a projected energy savings for the entire utility or at least aggregate.
    The energy savings projected for a single service port 20 can be the projected savings resulting from participation in the control event through each power consumption device controlled at service point 20, as well as from the cessation of the charging process for each power storage device 62 at service point 20, which would otherwise be receiving charging power, absent the control event.
    The virtual concessionary 1302 can be additionally <operable through the processor to determine, before the completion of the control event, an amount of operating reserve based on energy savings. and the 5 data and stored power. Thus, by having an accurate and historical knowledge of how power consumption devices can be expected to work at various times and having knowledge of how much stored power is available for control-e by virtual concessionaire 1302, virtual concessionaire 1302 can accurately project in real time its capacity to adapt to the operational reservation needs of a requesting control everlto and, therefore, make an o: Eert, the informative way to supply reserves of 15 o'operation to requesting concessionaires . If virtual concessionaire 1302 is engaged in supplying the required operating services, virtual concessionaire 1302 may be additionally operable through the processor for the distribution and / or management of the distribution of the required quantity of reserves. of operation for the requesting concessionaire or synchronization data subsequent to the start of the control event.
    In an alternative modality, depending on the requesting concessionaire's 25 operating reserve requirements, as, for example, indicated in the operating reserve request (for example, an ISO market sign or an AGC Reg up command), virtual dealer 1302 can only dispatch power from the 30 power storage devices (62) without initiating any control events for power reduction or. postponement of load. This may be the case when the stored power available for use as operating reserves and accessible by virtual concessionaire 1302 is sufficient 5 to suit the concessionaire's operating reserve needs.
    Those of ordinary skill in the art will readily recognize and appreciate that the process set out above for projecting and supplying operation reserve in response to 10 dealership requests can be used by any dealership i: "incorporating an ALMS 10 which includes a central controller and a set of control devices, such as can be implemented as the ALD 100 and active load customers 300 above, thus a service concessionaire 1304 can use the present invention to design and supply its own operating reserves, or can offer these operating reserves on the open market (for example, in response to ISO market signals).
    As described above, the present invention encompasses a system and a method for determining and supplying operating reserve capacity using an ALMS that includes a central controller, such as an ALD, and multiple control devices, such as active load 25, dispersed throughout a geographic area (for example, one or more service areas of the concessionaire), for dispatching stored power from the power storage devices coupled to the power network.
    When a concessionaire requires power beyond its native load, the concessionaire must make use of its reserve of
    - ciperation or acquire additional power through the FERC network from other concessionaires. As discussed above, the operating reserve includes the spin reserve and the regulation reserve. The spin reserve is an additional generation capacity that is already connected to the power system and is thus almost immediately available. (A regulation reserve is also a capacity coupled to the power grid that can be supplied in an extremely short time to respond to fluctuations in line frequency. According to an embodiment of the present invention, a central controller, such as as an ALD, to "rna available rr) Dtc.r for gi-necological analysis and / or radio unit for a concessionaire for dispatching power stored in power storage devices coupled to the power network. another modality, the central controller may aggregate c) dispatch of stored power from power storage devices in conjunction with power conservation through control events 20 for the provision of operation reserve for a requesting concessionaire. of the use of ALMS, a concessionaire can determine or design an OLl spin reserve another operating reserve that is available through and power 25 stored at service points. The operation reserve provided is measurable and verifiable, and can be projected for a number of hours or days beforehand, thereby allowing these projections to be sold to other dealers on the open market.
    30 Confonne discussed above, ALMS 10 can be considered as implementing a type of flexible load format program. However, in contrast to conventional load control programs, the load format program implemented by ALMS 10 projects a quantity of operating reserve resulting from a selective control of devices (loads and storage devices) based on preferences of load. known real-time consumer. In addition, due to its communication and its control mechanisms, ALMS 10 can project power savings, as well as operating reserve (for example, rear panel, turning and / or not turning) that is active, in time real, verifiable and measurable, in order to comply with protocols and treaties established for the determination of carbon credits and dewios, as well as renewable energy credits. The information acquired by ALMS 10 is not simply samples of consumer preferences and data, but actual power consumption information.
    In the preceding descriptive report, the present invention has been described with reference to specific modalities. However, those of ordinary skill in the art will appreciate that various modifications and changes can be made, without departing from the spirit and scope of the present invention, as set out in the appended example claims. For example, the passive sampling algorithm of figure 8, the projected energy use algorithm of figure 9, the best sampling combination algorithm of figure 10 and the µjetjet energy saving algorithm of figure 11 can be performed by one or more equivalents.
    Additionally, all the functionality exposed as s.endo.
    performed by an active carcass customer 300 can be performed, instead, by an alternative control device (for example, an electric vehicle charging station or other control device) located at a service point. In addition, all the functionality exposed as being performed by an ALD 100 can be performed instead by an alternative ce.ntral controller communicatively coupled between one or more dealers and one or more service point control devices. Therefore, the specification and the drawings must be considered in an illustrative sense instead of in a restrictive sense, and it is intended that all these modifications are included in the scope of the present invention.
    The benefits, other varitacens and solutions to the problems have been described above with respect to specific embodiments of the present invention. However, the benefits, advantages, solutions to problems and any elements that may cause or result in these b (= benefits, advantages or solutions becoming more pronounced should not be constructed as a resource or a critical element, required or essential of any and all claims.The invention is defined solely by the appended claims, including any amendments made pending this application and all equivalents of those claims, as issued.
    权利要求:
    Claims (1)
    [1]
    1 / C}
    1. Method of estimating the operating reserve of a concessionaire attending one or more service points, a method characterized by the fact that it comprises: 5 the determination of quantities of electrical power consumed by at least one first set of devices for at least one period of time for the production of the power consumption data, the first set of devices being located in a network plus 10 service points; c) storage of power consumption data in a repository; determination that a control event is to occur during which an electrical power supply is to be reduced for at least the first set of devices, the estimate, before the start of the control event and under the hypothesis that the control event is not to occur, of an expected power consumption behavior of the first set of devices during a first period of time based at least on the consumption data the stored power, in which the control event is expected to occur: during the first period of time, the determination, before the beginning of the control event, of projected energy savings resulting from the control event, based on at least in the estimated power and consumption behavior of the first set of devices; the reading, before the start of any control event, of amounts of electrical power stored by a second set of devices located at one or more service points for the production of the stored power data; and the determination, before the start of the control event, of an amount of available reserve of operation based on the projected energy savings and the stored power data.
    2. Method, according to claim I, characterized by the Fact that it still comprises: the distribution of the available operating reserve below the beginning of the control rail.
    3. Métoão, in accordance with claim 2, is characterized by the fact that the concessionaire uses at least some renewable energy produced by one. renewable energy source, and the fact that the available operating reserve is distributed to the provision of a regulation reserve during the subgeneration periods by the renewable energy source, "el.
    4. Method, according to claim 1, characterized by the fact that it still comprises: the management of the distribution of the operating reserve available subsequent to the beginning of the first event of e'ontroj-e.
    5. Method, according to claim 1, characterized by the fact that the determination that a first cantrol event is to occur comprises: the determination that a first control event is to occur in response to the receipt of a command with automatic generation control.
    6. Method, according to claim I, characterized by the fact that the determination of the economy
    3 / '9 of projected energy comprel1de: the determination of an intermediate projected energy saving for each service point in which one or more devices must be affected by the control event; and 5 the aggregation of the projected intermediate energy savings for a plurality of service points for the production of the projected energy savings.
    "7. Method, according to claim IL, characterized by the fact that the step of determining the projected energy saving is carried out on a point-by-service basis and by service point.
    8. Method, according to claim 1, characterized by the fact that the step of determining the projected energy savings is carried out on a per-utility basis.
    9. Method according to claim 1, characterized in that the second set - and devices includes an OL plus hybrid electric or electric vehicles, 10. Method for supplying the operation reserve for a concessionaire serving one or more service points, the method characterized by Eato, which comprises: the detection of quantities of stored electrical power by: r device ivcjs located in a or more service points for the production of stored power, q storage of stored power data in a repository; 3 C) ceterrimimizing a reserve amount of
    4 / g 4
    V available operation was based at least on the stored power data; c) receipt of a requisition for an operation reserve from the concessionaire; and 5 in response to the demand for the operation reserve, the management of a flow of electrical power from the devices to a power network accessible by the ion concession.
    11. Method according to claim 10, 10 characterized by the fact that the receipt of a request for operation reservation comprises: the receipt of an automatic generation control command and a market signal from an independent service operator.
    15 12. Method, according to claim 11, characterized by the fact that the devices, "include at least one among electric vehicles and hybrid electric vehicles.
    13. Method for supplying operation reserve to a concessionaire, the method characterized by the fact that it comprises: the determination, by a control device located in a service point, at the amount of electrical power stored by at least one device 25 at the service point; the report, by the control device, of the quantity of the patent stored for a controller c: between; and c) control, by the control device, of a f! luxury 30 of electric power from at least one device sl 9 b for a network of power accessible by the concessionaire, in response to a request from the central controller, the request responding to a need for a reserve of operation by the operator. - 5 1a. Method according to claim 13, characterized by the fact that at least one device includes an electric vehicle.
    15. Method, according to claim 14, çÊLraçteL "ized by the fact that the control device is integrated into a charging station for the electric vehicle.
    16. Method, according to claim 13, characterized by the fact that it still comprises: the determination, by the control scientist, that at least one other device is in the process of being loaded from the concessionaire; receiving, by the control device, a message from the central controller to start a control event at the service point; and cease c) uploading to the other device and responding to the message.
    17. Concessionaire that provides an electrical service to one or more service points located remotely, each service point including at least one ãispQsitivo that consumes power during t and its operation, the concessionaire characterized by the fact that it comprises: a repository; and at least one processor coupled to the repository, at least one processor operable with parm 30 to determine the amounts of electrical power consumed by at least a first set of devices for at least one period of time for production power consumption data;
    q storage of power consumption data
    5 eni a repository;
    the determination that a control event is to occur during which an electrical power supply is to be reduced to at least the first set of devices;
    1 is the estimate, before the start of the control event and under the hypothesis that the control element is not to occur, of a behavior of power consumption expected from the first set of devices during a first period of time based on at least in the stored power consumption data, since the event of control is expected to occur during the first period of time;
    the determination, before the start of the control event, of projected energy savings resulting from the control event, based at least on the expected power consumption behavior of the first set of diSPOSi-tiVQ1q;
    the determination, before the start of the control event, of quantities of electrical power stored by a second set of devices located at one or more service points for the production of the Argentine power data; and determining, before the start of the control event, an amount of available operating reset based on projected energy savings and
    7 / '9 given us "of stored power.
    18. Concessionaire, according to claim 17,, characterized by the fact that at least one processor is - additionally operable to determine that the 5 control event is to occur in response to the receipt of a control command automatic generation,
    19. Concessionaire, according to claim 17, characterized by the fact that at least one processor is additionally operable to manage the distribution of the available operation reserve subsequent to the beginning of the control event.
    20. Operable virtual concessionaire to at least offer power to one or more requesting concessionaires, for use as an operation reserve for a more demanding OLl IS requesting, the virtual concessionaire characterized by the fact that it comprises: a repository; and Ic) minus one processor coupled to the repository, at least one processor operable for: the determination of quantities of electrical power consumed by at least a first set of devices3 during at least one period of time for the production of data) s of power consumption, the first set of devices being located remotely from the 2nd processor; storage of power consumption data in a repository; the determination that a control event is to occur, during which time an electrical power supply is to be reduced to c) the first set of devices; the estimate, before the start of the control event and under the hypothesis that c) control event is not to occur, of a power consumption behavior 5 expected from the first set of devices during a first period of time with bage at least in stored power consumption data, in which the control event is expected to occur during the first period of time; the determination, before the beginning of the control event, of projected energy savings resulting from the control event, based at least on the power consumption behavior estimated from the first set of devices; the determination, before the start of the control event, of quantities of electrical power stored by a second set of devices located at one or more service points for the production of the stored power data; the determination, before the start of the control event, of an amount of available operational reserve based on the projected energy savings and on the stored energy capacity; and c) managing the distribution of the operating reserve amount to at least one of the concessionaires requesting subsequent to the completion of the control event.
    21. Virtual ionic concession, according to claim 20, characterized by the Eato that at least one processor is additionally operable to determine
    9/9 that the control event is to occur in response to the receipt of an automatic generation control command.
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    同族专利:
    公开号 | 公开日
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    WO2012106431A1|2012-08-09|
    MX340268B|2016-07-04|
    JP2014509177A|2014-04-10|
    AU2012212224B2|2015-06-18|
    JP5710028B2|2015-04-30|
    US9881259B2|2018-01-30|
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    法律状态:
    2020-12-08| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2020-12-15| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2020-12-22| B25A| Requested transfer of rights approved|Owner name: LANDIS+GYR TECHNOLOGY, INC. (US) |
    2021-01-12| B25A| Requested transfer of rights approved|Owner name: LANDIS+GYR INNOVATIONS, INC. (US) |
    2021-04-13| B07A| Application suspended after technical examination (opinion) [chapter 7.1 patent gazette]|
    2021-08-10| B09B| Patent application refused [chapter 9.2 patent gazette]|
    2021-10-19| B12B| Appeal against refusal [chapter 12.2 patent gazette]|
    2021-12-07| B350| Update of information on the portal [chapter 15.35 patent gazette]|
    优先权:
    申请号 | 申请日 | 专利标题
    US13019,867|2011-02-02|
    US13/019,867|US8996183B2|2007-08-28|2011-02-02|System and method for estimating and providing dispatchable operating reserve energy capacity through use of active load management|
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