• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a system (1) comprising: - a heating device (11), the device (11) comprising a plurality of heating means (110, 111, 112) fed by an electrical network (2); a control module (12) of said heating device (11); the system being characterized in that each heating means (110, 111, 112) is supplied via a power actuator (120, 121, 122) of which at least one is a dimmer (120), each power actuator (120, 121, 122) being controlled by the control module (12) as a function of at least data describing a state of said power grid (2), so as to regulate in power the heating means (110, 111, 112 ) associated with said power actuator (120, 121, 122).
    公开号:FR3018593A1
    申请号:FR1452015
    申请日:2014-03-11
    公开日:2015-09-18
    发明作者:Stephane Bernasconi;Anne-Sophie Coince;Jacopo Testa;David Wiszniewski;Mathieu Zimmermann
    申请人:Electricite de France SA;
    IPC主号:
    专利说明:

    [0001] GENERAL TECHNICAL FIELD The present invention relates to a water heater type system with a modular energy capacity. STATE OF THE ART The "energy mix" designates the distribution of the various sources consumed for the production of electrical energy. This energy mix, in constant evolution, sees the constant progression of the Renewable Energies, which entails an increased need in flexibilities of the system. The latter, represented mainly by wind and photovoltaic, do not allow a constant and regulated production unlike a nuclear power plant, hence problems of variability and predictability of the associated production. This makes the risks of the very short term increase sharply. On the other hand, local problems of electrical supply quality will be amplified due to inhomogeneous geographical distribution of the installations, with for example photovoltaic in the South and wind power in the North. It appears essential to find solutions for controlling the associated load in order to control the risk associated with Renewable Energies 25 and to satisfy the constraints of the electricity network in the broad sense. For example, it has been proposed to charge stationary batteries to facilitate the massive insertion of photovoltaic panels ("NiceGrid" demonstrator). However, the high investment costs do not make it possible to envisage a large-scale deployment of this alternative solution. It is also planned to act on the reactive power provided by the photovoltaic panels to adjust the voltage. However, this last track does not answer to the stakes of control of the wind hazard.
    [0002] Alternatively to storage via batteries, it is possible to store the energy thermally. With nearly 12 million units installed in France, more than 80% of which are slaved to the Peak Hours / Off-Peak (HP / HC) tariff signal, the Joule water heater (CEJ) residential storage pool - used today for the daily smoothing of the load curve - is likely to meet these new challenges. The patent application US 2009/0188486 proposes for this purpose water heaters supplied with direct current by photovoltaic modules. The system is configured to maximize the solar fraction, i.e., minimize the electricity consumption drawn off from the grid while maintaining comfort for the user. This system is satisfactory, but only partially solves the problem: there may be a day with a surplus of electrical energy from the photovoltaic panel, and the next day with a cloudy weather necessitating the consumption of another source of electricity. In addition the system is complex and can only be used in homes equipped with a solar panel. Techniques known as "diffuse erasure" described for example in the application W02012 / 172193, which automatically cut an electrical equipment such as a radiator in case of peak energy consumption. However, these techniques provide no solution in the event of peak production of photovoltaic origin, and can alter the comfort of users. Thus, today, no satisfactory solution is available to control the charge related to renewable electric energy on a large scale and efficiently. It would be desirable to have a way of using the storage capacity of water heaters Joule which is easily deployable, effective and inexpensive.
    [0003] PRESENTATION OF THE INVENTION The invention proposes to overcome these disadvantages by proposing in a first aspect a system comprising: - a heating device, the device comprising a plurality of heating means powered by an electrical network; a control module of said heating device; the system being characterized in that each heating means is supplied via a power actuator of which at least one is a dimmer, each power actuator being controlled by the control module as a function of at least one descriptive data of a state said power network, so as to regulate the power of the heating means associated with said power actuator. The device according to the invention is advantageously completed by the following features, taken alone or in any of their technically possible combination: the system further comprises a water tank, the heating device heating the water of the tank; the system further comprises a management element configured to control the control module according to said descriptive data of a state of said power grid; the control module controls each power actuator as a function of a power setpoint emitted by the management element; the management element is configured to emit a power setpoint which reduces the consumption of the heating means when the data describing a state of said electricity network are characteristic of a current deficit and / or a future superabundance of energy of renewable origin within said electricity network, so as to reduce the energy capacity of the water reservoir; the control module is configured to ignore the power setpoint when a water temperature of the tank is lower than a first predefined threshold; the management element is configured to emit a power setpoint increasing the consumption of the heating means when the descriptive data of a state of said power grid is characteristic of a current glut and / or a future energy deficit. of renewable origin within said electricity network, so as to increase the energy capacity of the water reservoir; the control module is configured to ignore the power setpoint when a water temperature of the tank is higher than a second predefined threshold; the system furthermore comprises a box receiving said data describing a state of said electrical network from a communication network, the box being connected to said management element or to the control module; the heating means supplied via the dimmer has a nominal power of less than 1.2 kW; at least one power actuator is a relay. each power actuator is a dimmer or a relay; exactly one power actuator is a dimmer; the heating means are n resistors of equal resistance R 20 arranged on branches in parallel; the control module is configured to determine power ratios a-- [o, 1] and A - respectively associated with the dimmer and the n-1 relays, such that Fe = u2 / R with Pc the set power and U the voltage across each of the branches in parallel. According to a second aspect, the invention relates to a method for modifying the consumption of an electric heating device, the method being characterized in that it comprises steps of: - receiving data describing a state of an electrical network; generation by a management element of a power setpoint as a function of at least said data describing a state of said electrical network; sending said setpoint to a control module of a plurality of heating means of the heating device, each heating means being supplied by the electrical network via a power actuator of which at least one is a dimmer; - Control by the control module of each power actuator according to the power setpoint so as to regulate the power of the heating means. PRESENTATION OF THE FIGURES Other characteristics, objects and advantages of the invention will emerge from the description which follows, which is purely illustrative and nonlimiting, and which should be read with reference to the appended FIG. 1 and on which is represented a diagram of FIG. a preferred embodiment of the system according to the invention. DETAILED DESCRIPTION General Architecture FIG. 1 represents the general architecture of a preferred embodiment of the system 1 according to the invention. This system essentially consists of one or more heating devices 11 comprising a plurality of heating means 110, 111, 112 fed by an electrical network 2. These heating devices 11, or "transmitters", are typically domestic radiators. A Joule heating means 110, 111, 112 is typically one or more electrical resistors, which heat air or a coolant (for example oil), in heat exchange with a medium to be heated such as air of a room of a dwelling. In addition, two devices 11 may in fact be part of the same transmitter. Preferably, the heated fluid is water (in particular the water of a tank 10), and the system is thus a domestic Joule water heater (CEJ) (44% of the habitats are equipped). In the following description, we will take the example of a water heater type system, but it will be understood that the invention is not limited to the latter, and applies to any system comprising at least one heating device 11. The system 1 configured in CEJ thus comprises: a water tank 10 (commonly called a hot water "balloon"); - A heater 11 of the water tank 10, the device 11 comprising a plurality of heating means 110, 111, 112 powered by an electrical network 2; typically a temperature probe 20 configured to emit a signal representative of the water temperature of the tank 10; a control module 12 of said heating device 11 as a function of said signal emitted by the probe 20.
    [0004] The electric heating means of the heating device are in particular heating means by Joule effect, that is to say generally resistors, from which the heating of the water Joule effect. Alternatively, one or more of these means 110, 111, 112 may be a complete heat pump whose hot source is in heat exchange with the water of the tank 10 (and the cold source in heat exchange for example with the outside air ), so as to allow heating of the water with an efficiency greater than 100%.
    [0005] Preferably, the device 11 is entirely electric (it thus includes only heating means powered by the network 2, and no gas burners for example). The heating energy supplied to the water is then entirely of electrical origin. The system is however not limited to this configuration and the device 11 may alternatively furthermore comprise an alternative (non-electric) heating means such as a burner, an exchanger with a solar collector, etc. In a particularly preferred manner, the device 11 is composed of n equivalent resistance resistances R, as will be seen below.
    [0006] The network 2 is a large-scale network that connects a plurality of electrical sources. As explained above, this is both energy of non-renewable origin (nuclear and / or fossil) and energy of renewable origin (solar, wind, etc.). Renewable energy presents problems of variability and predictability, while non-renewable energy is more readily available. Assuming that the user of the system 1 comprises a personal source of energy of renewable origin (for example photovoltaic roof panels) it is understood that the network 2 includes both the overall power grid and the local power grid. of the user (in other words that the remote power plants and the local solar panels can as well, one as the other, feed the heating device 11). System 1 is in a "normal" mode of operation regulated in temperature. For this purpose, it advantageously comprises one or more temperature probes 20 and a control module 12 of the heating device 11. The probe or probes 20 continuously or intermittently send a signal representative of the temperature of the water of the tank 10. This signal can be a sending of data numerically representing the temperature, or an electrical signal whose parameter is a function of the temperature.
    [0007] The control module 12 is typically an electronic card that triggers or not the heating according to the temperature of the water and many other possible parameters (programming, season, time periods, off-peak hours / full hours, usual uses of the user, etc.). In general, a Joule water heater most often comprises two threshold temperatures (the value of which may vary according to the moment and the personal settings): a first threshold temperature which is the "minimum" temperature and a second temperature of threshold which is the "maximum" temperature (the first threshold is lower than the second threshold). These two thresholds are a few degrees around (for example +/- 4 ° C) a "comfort" temperature which is the desired average temperature set by the user (the range 50-65 ° C is current) . The control module 12 is thus configured to activate the heating device 11 when the received signal is representative of a temperature below the first predefined threshold, and / or configured to deactivate the heating device 11 when the received signal is representative of a temperature higher than the second predefined threshold. Thus, as the heater 11 is stopped and that is between the two thresholds nothing happens. If the temperature decreases (over time or because the user draws hot water) and falls below the first threshold, the heater 11 is activated until it reaches the second threshold (temperature maximum, greater than the first threshold). The temperature then goes down again, and so on. In other words, there is an alternation of "cooling" phases during which the temperature drops from the second threshold to the first threshold (see above if the user continues to use hot water), and "Heating" phases 25 during which the temperature rises under the effect of the device 11 lit from a temperature less than or equal to the first threshold to the second threshold. As explained before, this configuration may depend on other parameters, and there may be more than two thresholds, possibly mobile, for example in order to optimize energy consumption during off-peak hours (water heaters are often provided to increase the temperature of the water, preferably in the early morning, so as to maximize the use of off-peak hours and have hot water in quantity when showering). In practice, the first and second thresholds are often the consequence of a hysteresis phenomenon around a median value, which defines these two thresholds. The induced difference is then about 3 ° C. The present invention is not limited to any particular configuration, it will be understood that, in general, the control module 12 regulates the temperature of the tank 10 via the activation / deactivation of the heating device 11 as a function of signals which are emitted signals which may represent temperatures and / or operating instructions. Power actuators Each heating means 110, 111, 112 is supplied via a power actuator 120, 121, 122. This means that each heating means 110, 111, 112 is arranged in series with at least one power actuator 120 , 121, 122. Particularly preferably, each heating means 110, 111, 112 is uniquely associated with a dedicated power actuator 120, 121, 122, which can be translated as having, as seen in Figure 1, n branches in parallel, each branch comprising a heating means 110, 111, 112 and a power actuator 120, 121, 122 in series. Each power actuator 120, 121, 122 is a component for modifying the power of the heating means 110, 111, 112 with which it is associated. In particular, a power actuator modifies the intensity and / or the voltage (in particular only the voltage) of the current on the branch so as to measure the effective power consumed by the heating means 110, 111, 112 associated with 0 and 100% of its nominal value (ie its maximum power). In other words, to each heating means of nominal power P is associated an effective power P = A. P 'where A is a power ratio of the actuator, between 0 and 1. Many actuators of power, but they are in particular either relay type or converter type (including the dimmer).
    [0008] Relay (power actuators 121 and 122 in Figure 1) means a device in operation all-or-nothing, i.e. a switch. The associated power ratio A is 0 (open state) or 1 (on state). A relay can be classically electromechanical, but also semiconductor (see below).
    [0009] By converter (power actuator 120 in Figure 1) is meant a device capable of modifying an electrical signal for the purpose of varying its output voltage continuously (and not discrete as for a relay). The associated power ratio A has a value in the interval .1] (then the Kg notation is used for the power ratio of a dimmer). A dimmer is a type of converter based on components called "thyristors" (semiconductor electronic switches) controlled via a signal, used on alternating current. It can be defined as a direct-to-AC direct converter, as opposed to converters implementing an AC-DC conversion (and optionally subsequently a DC-AC conversion). Many types of dimmer are known, most often using a triac (that is to say two thyristors mounted head to tail in parallel) controlled by a dedicated circuit. For example, in a dimmer with "phase angle control", the triac allows the passage of the current for a shorter or longer period of the half-period. This time is defined by the duty cycle which is the ratio of the closing time divided by the half-period, so it is between 0 and 1. When it is equal to 0 the output voltage is almost zero and when it is equal at 1 the output voltage is the same as that of the input (of the network). The triac control signal, called the opening delay angle, must be synchronous with the voltage across the triac itself.
    [0010] It should be noted that although semiconductor solid state relays including thyristors / triacs exist, these must not be confused with dimmers. Such a solid-state solid state relay does not in fact comprise a circuit capable of transmitting a synchronous control signal, and is thus only capable of making the semiconductor go on or off. It will therefore be understood that in the present description the term relay designates only an all-or-nothing actuator (the transition from one state to another is discontinuous), and therefore that a converter is not a relay.
    [0011] By way of illustration, mention may be made of application EP0104979, which describes a water heater equipped with triac type semiconductors used as switched power actuators (at a predetermined time of the day): in a first embodiment, the only means heating is supplied via a dimmer (triac controlled in phase by a dedicated circuit), and in a second embodiment, two heating means are each fed via a relay (two static triacs). The purpose of this request is only to spread over time a rise in power. In the present system, the power actuators make it possible to regulate the power device 11 as a function of data describing a state of said electric network 2 (see below). For this, each power actuator 120, 121, 122 is controlled by the control module 12 so as to regulate the power of the heating means 110, 111, 112 associated with said power actuator 120, 121, 122. By control, one It is intended that the control module 12 is adapted to determine and impose the power ratios A of the power actuators 120, 121, 122 as a function of the instructions it receives. The system according to the invention is distinguished in that at least one power actuator 120, 121, 122 is a dimmer 120. Preferably, at least one other power actuator 120, 121, 122 is a relay 121, 122 Particularly preferably, exactly one power actuator 120, 121, 122 is a dimmer 120 and all the others are relays 121, 122. As will be seen below, such a configuration has a double advantage: it becomes possible to to regulate easily and simply power the heater 11 being able to operate at any power between 0 and the maximum power rating (that is to say, the sum of the nominal powers of the various heating means 110, 111 , 112), and this while limiting the harmonics. Indeed, tests carried out for the Applicant have shown that as long as the power across the dimmer 120 (nominal power of the associated heating means 110) does not exceed 1.2 kW, the harmonics remain acceptable and the system meets the requirements of the Electromagnetic Compatibility (EMC) standards. And the combined use of the dimmer 120 with relays 121, 122 allows any total power rating (including exceeding largely 1.2 kW) without the heating means 110 supplied via the dimmer 120 has a nominal power greater than 1.2 kW. This allows all the advantages of the dimmer (simplicity, robustness and cheapness) at any power level without the risk of strong harmonics. The power regulation mechanism thus makes it possible to use the installed water heaters to manage the electricity production of renewable origin, easily and efficiently: the modification of the effective power of the heating means 110, 111, 112 makes it possible to increase or decrease on demand the consumption of these water heaters and to play on the energy stored as hot water. The energy capacity becomes flexible. Several TWh are thus available on the French territory for example. This makes it possible, for example, to favor electricity consumption as long as photovoltaic power is widely available, and to limit the power consumption or fall back on other energies (for example via alternative heating means such as burners if the device 11 includes them). , when the photovoltaic is deficient.
    [0012] For example, during a water heating phase (and therefore the temperature rise of the tank 10), the power can be increased, which heats the water faster. Thus, more electricity is consumed, this electricity being stored as a heat capacity of water (41857 kg-1 K-1). By energy capacity of the tank 10 is meant in fact the maximum amount of energy stored in thermal form via hot water.
    [0013] Management Mechanism The data describing the state of the electrical network 2 can be transmitted directly to the control module 12. But preferably, the control module is standard equipment, and the system 1 further comprises a management element 30 connected to the control module 12. This management element 30 is configured to control the control module 12 as a function of at least data describing a state of said electrical network 2. In other words, the management element 30 acts as a module 20 for pre-processing data describing the state of the network 2. The management element 30 integrates with a control module 12 of an existing EYC, and does not require structural modification. In particular, there are only a few modifications of the control module 12 which only performs "post-processing" (see below what it consists of). It is thus easy and inexpensive to modify existing equipment. In the case of new water heaters, the management element 30 can be directly integrated into the control module 12 as an additional function in order to eliminate the need for an additional box (in other words the control module 12 processes directly data describing the state of the electrical network 2). These data generally indicate all the information on the load of the network 2, the energy rate of renewable origin, the forecasts of variation of this rate, the production / consumption in general, etc. These data can be generic data obtained locally, for example of meteorological origin, which can indicate to what extent the means of production of renewable energy will be productive, but preferably it is more complex data provided for a long time. communication network 3 (typically the internet network) via a box 31, in particular in real time. In a first embodiment, the housing 31 is an intelligent electricity meter (for example LINKY) having a Transmitter Tele-Information Client (TIC) integrated or not. The data used may in particular be the ICT fields such as for example: the binary state of one or more virtual contacts, the tariff index of the supplier grid and / or current distributor, the price of electricity, mobile peak notice and / or mobile tip (s), etc. In a second embodiment, the housing 31 is a box-type internet access equipment of an Internet access provider. The box 31 is connected to the management element 30 by network connection means such as Wi-Fi, an Ethernet link, the PLC, etc., the data can then be complete meteorological data (wind speed, sunshine , etc.), data pre-processed on servers of an electricity supplier to optimize the overall load, etc. In a third embodiment, the case 31 is a power manager connected via a wired / radio link to one or more electric meters associated with renewable energy production points (particularly if renewable origin has one or more dedicated local delivery points). The link can be mono or bidirectional. The access to meters allows a real-time monitoring of the photovoltaic energy production and the consumption of the housing (s).
    [0014] The present invention is not limited to a type of data descriptive of a state of said power grid 2, nor to a way of providing such data.
    [0015] Supercharging and Undervoltage Modes According to a preferred embodiment, the management element 30 determines a power setpoint (i.e., an effective power target value) based on the data describing the state of the network. 2. The control module 12 then controls each power actuator according to a power setpoint transmitted by the management element 30. In particular, the management element implements a first and / or a second type of control. operation.
    [0016] The first is the "boost mode" (in other words "forced operation") used to increase the consumption of the CEJ and therefore the amount of energy stored. In this mode, the management element 30 is configured to transmit a power increase instruction (in other words a power setpoint increasing the consumption of the heating means 110, 111, 112) when the descriptive data of a state of said electricity grid 2 are characteristic of a current glut and / or a future energy deficit of renewable origin within said electricity grid 2 (in other words if the production of renewable origin is at the short-term decline), so as to increase the energy capacity of the water tank 10. This supercharging mode is interesting either to absorb a large photovoltaic production, or to prevent low production. Thanks to the supercharging, the effect of the device 10 is amplified. This therefore increases the immediate consumption, but delays future consumption (since more energy is stored, the next crossing of the first temperature threshold is delayed).
    [0017] The value of the power setpoint may be such as to consume as much as possible of the surplus energy of renewable origin without affecting the energy of non-renewable origin. The value can also be a fixed value, or the current consumption value plus a predetermined deviation (eg + 500W). It should be noted that this supercharging mode can be supplemented with certain options: if the data triggering supercharging is provided by a counter equipped with an ICT module, the latter can temporarily increase, and simultaneously with the switching on of the water heater, the value cutting power to avoid any risk of tripping in the absence of a load shedder or energy manager. In addition, if the water heating system is slaved to the tariff signal via a dry contact or virtual contact, the latter must be controlled so as to allow the power supply of this system outside the normal ranges allowed if necessary. In addition, if the draw points of domestic hot water (shower, faucets, etc.) downstream are not all equipped with mixing valve, the addition of a mixing valve at the outlet of the tank 10 makes it possible to avoid risk of burns due to the supply of hot water.
    [0018] The second mode is the "under power" mode (in other words "reduced run") used to decrease the consumption of the CEJ and thus the amount of energy stored. In this mode, the management element 30 is configured to transmit a power reduction setpoint (in other words a power setpoint decreasing the consumption of the heating means 110, 111, 112), when the descriptive data of a state of said electricity grid 2 are characteristic of a current deficit and / or of a future superabundance of energy of renewable origin within said electricity grid 2 (in other words if the production of renewable origin is at the short-term rise), so as to reduce the energy capacity of the water reservoir 10. This can be very useful in anticipation of a peak in renewable energy production or peak consumption. This avoids the consumption of fossil energy while we know that renewable energy will soon be too abundant. This voluntary decline in consumption is called erasure. The power drop instruction can be calculated so as to minimize energy consumption of non-renewable origin. The idea is not to (or as little as possible) extract non-renewable energy from grid 2. It can also be a fixed value, or the current value of consumption minus a predetermined difference (for example -500W ).
    [0019] It should be noted that the two modes (reduced walking and forced walking) can coexist and be implemented in turn. In either case, the application of the power setpoint can be preceded and / or followed by a ramp to avoid a rebound effect, in other words the power setpoint is gradually increased / decreased ( for example linearly over an interval of 30 minutes), instead of switching immediately. Moreover, the activation of one or other of the modes, the choice of a fixed or variable power set point, the temperature thresholds, etc., can be controlled by the user via a suitable interface.
    [0020] It should also be noted that the power regulation can not be done to the detriment of user comfort, and for each of the modes, the control module 12 can be configured to ignore the power setpoint when a temperature of 1 reservoir water 10 (measured by a probe 20 connected to the control module 12) is less than the first predefined threshold (for the second mode) or greater than a second predefined threshold (for the first mode). Operation of the management element The management element 30 may comprise a data processing module (a processor) configured to receive said data describing a state of said power grid 2 and generate at the destination of the control module 12 the instruction power. If the control module 12 is an advanced electronic card already comprising a processor, the management element 30 may be, as explained, a software module directly implemented by the control module 2.
    [0021] Control of the power actuators As explained, the control module 12 determines the power ratios A of the power actuators 120, 121, 122 as a function of the power setpoint that it receives. In other words, it calculates the values of these ratios to be chosen such that the effective power corresponds to the power setpoint. Many algorithms can be used to determine these values. It should be noted that their calculation is particularly easy in the case where exactly one power actuator 120, 121, 122 is a dimmer 120 and all the others are relays 121, 122. In such a case, if the heating means by Joule effect 110, 111, 112 are n resistors of equal resistance R arranged on branches in parallel, then the nominal power of each resistor is given by the formula P = / P, and the maximum nominal power of the device 11 by the formula = R (with U the voltage across each of the branches in parallel). Typically, R> so to check the condition (.1.2k1: to limit the harmonics (remember that the voltage imposed in France is 230V) .The value of n is also set so as to reach the desired maximum power rating without risk of harmonics: as explained, n LP - 1. The total effective power is then Pe -1 _-1 / R. By imposing P- = Pc (with Pc the received target power, Pc <n 'R. If the setpoint power 30 is greater than the maximum nominal power it may be decided that the value of the nominal power is replaced by this maximum rated power), we obtain Kg + -A. = Poe R This equation is easy to solve : it suffices to divide by n: the integer part is worth that is to say the number of relays 121, 122 closed and the decimal part is the value of Kg.
    [0022] The use of a single dimmer 120 thus offers an injective function: there is at least one actuator configuration easily identifiable for any desired power. Note that it is quite possible to have resistors of different values (even if in this case certain powers of 10 setpoints may not be applicable), with a single dimmer 120 the calculation remains easy. In the example shown in FIG. 1, with 3 identical resistors R1 = R2 = R3 = R: The maximum rated power is: Pmax = 3 * U2 / R 15 - For a setpoint P <Pmax / 3, the two relay circuits 121, 122 are open and a control signal is applied to the dimmer 120 to provide the requested power P; - For a setpoint Pmax / 3 P <2 * Pmax / 3, only one relay circuit 121, 122 is open and a control signal is applied to the dimmer 120 to provide the power P-Pmax / 3; For a setpoint P 2 * Pmax / 3, the two relay circuits 121, 122 are closed and a control signal is applied to the dimmer 120 to provide the power P-2 * Pmax / 3. This three-resistance architecture is particularly suitable for any device 11 with a power of up to 3kW (which is the case for most consumer-grade CEJs). According to a second aspect, the invention also relates to a method of modifying the consumption of an electric heater 11 (it is more specifically a method of modifying the energy capacity of a fuel tank 11). water 10 if the system 1 is a water heater) implemented by the system 1 according to the first aspect of the invention. These methods comprise the steps of: receiving data describing a state of an electrical network 2 (as explained for example from a box 31); generation by a management element of a power setpoint as a function of at least said data describing a state of said power grid 2; sending said setpoint to a control module 12 of a plurality of heating means 110, 111, 112 of the heating device 11 (in particular a heater 11 for the water of the tank 10, but will understand that if the system 1 is a conventional heating system, the device 11 can heat the ambient air or another fluid), each heating means 110, 111, 112 being supplied by the electrical network 2 via a power actuator ( 120, 121, 122) of which at least one is a dimmer 120 (and advantageously all the others are relays 121, 122); control by the control module 12 of each power actuator 120, 121, 122 as a function of the power setpoint so as to regulate in power the heating means 110, 111, 112 (this step consists in determining the ratios of power Ai). It is recalled that the management element 30 may in fact be only a function integrated in the control module 12 (which then directly receives the data describing the state of the network 2).
    [0023] According to the first mode of operation described above, the system 1 is in "supercharging" mode. This mode is triggered when the descriptive data of a state of said power grid 2 are characteristic of a current glut and / or of a future energy deficit of renewable origin within said electricity grid 2. The power setpoint is an instruction to increase the consumption of the heating means 110, 111, 112, so as to increase the energy capacity of the tank 10. According to the second mode of operation described above, the system 1 is in "undernourishment" mode . This mode is triggered when the descriptive data of a state of said electricity grid 2 are characteristic of a current deficit and / or of a future superabundance of renewable energy in said electricity grid 2. The power setpoint is then an instruction to decrease the consumption of the heating means 110, 111, 112, so as to reduce the energy capacity of the tank 10.
    权利要求:
    Claims (16)
    [0001]
    REVENDICATIONS1. System (1) comprising: - a heating device (11), the device (11) comprising a plurality of heating means (110, 111, 112) fed by an electrical network (2); a control module (12) of said heating device (11); the system being characterized in that each heating means (110, 111, 112) is supplied via a power actuator (120, 121, 122) of which at least one is a dimmer (120), each power actuator (120, 121, 122) being controlled by the control module (12) as a function of at least data describing a state of said power grid (2), so as to regulate in power the heating means (110, 111, 112 ) associated with said power actuator (120, 121, 122).
    [0002]
    The system of claim 1, further comprising a water reservoir (10), the heater (11) heating the water of the reservoir (10).
    [0003]
    3. System according to one of claims 1 and 2, further comprising a management element (30) configured to control the control module (12) according to said descriptive data of a state of said power grid (2).
    [0004]
    4. System according to claim 3, wherein the control module (12) controls each power actuator (120, 121, 122) according to a power setpoint emitted by the management element (30).
    [0005]
    The system according to claims 2 and 4 in combination, wherein the management element (30) is configured to output a power setpoint decreasing the consumption of the heating means (110, 111, 112) when the descriptive data of a state of said electrical network (2) is characteristic of a current deficit and / or of a future superabundance of energy of renewable origin within said electricity grid (2), so as to reduce the energy capacity of the tank (10) .
    [0006]
    The system of claim 5, wherein the control module (12) is configured to ignore the power setpoint when a water temperature of the tank (10) is lower than a first predefined threshold.
    [0007]
    7. System according to claim 2 and one of claims 4 to 6, in combination, wherein the management element (30) is configured to emit a power setpoint increasing the consumption of the heating means (110, 111, 112) when the descriptive data of a state of said electricity grid (2) are characteristic of a current glut and / or a future energy deficit of renewable origin within said electricity grid (2), so as to increase the energy capacity of the tank (10).
    [0008]
    The system of claim 7, wherein the control module (12) is configured to ignore the power setpoint when a water temperature of the tank (10) is greater than a second predefined threshold.
    [0009]
    9. System according to one of claims 3 to 8, further comprising a housing (31) receiving said data describing a state of said electrical network (2) from a communication network (3), the housing (31) being connected to said management element (30) or to the control module (12). 30
    [0010]
    10. System according to one of the preceding claims, wherein the heating means (110) supplied via said dimmer (120) has a nominal power of less than 1.2 kW.
    [0011]
    11. System according to one of the preceding claims, wherein at least one power actuator (120, 121, 122) is a relay (121, 122).
    [0012]
    The system of claim 11, wherein each power actuator (120, 121, 122) is a dimmer (120) or a relay (121, 122).
    [0013]
    The system of claim 12, wherein exactly one power actuator (120, 121, 122) is a dimmer (120).
    [0014]
    14. System according to one of the preceding claims, wherein the heating means (110, 111, 112) are n resistors R equal resistance arranged on branches in parallel.
    [0015]
    The system of claims 13, 14 and one of claims 3 to 7, in combination, wherein the control module (12) is configured to determine power ratios R: g = [c; 11 and 20 1 associated respectively with the dimmer (120) and the n-1 relays (121, 122), such that Ier = -4 - U'IP with Pc the setpoint power and U the voltage across each of the branches in parallel. 25
    [0016]
    16. A method for modifying the consumption of an electric heater (11), the method being characterized in that it comprises steps of: - receiving data describing a state of an electrical network (2) - Generation by a management element (30) of a power setpoint according to at least said descriptive data of a state of said power grid (2); - sending said setpoint to a control module (12) of a plurality of heating means (110, 111, 112) of the heating device (11), each heating means (110, 111, 112) being powered by the power grid (2) via a power actuator (120, 121, 122) of which at least one is a dimmer (120); - Control by the control module (12) of each power actuator (120, 121, 122) according to the power setpoint so as to regulate the power of the heating means (110, 111, 112).
    类似技术:
    公开号 | 公开日 | 专利标题
    EP3117158B1|2020-01-22|Electric water heater with adjustable power
    FR3033391A1|2016-09-09|WATER HEATER SYSTEM WITH DEDICATED PHOTOVOLTAIC INSTALLATION
    EP3111154B1|2021-11-10|Device for driving at least one subassembly capable of transforming electrical energy and of storing said energy in thermal form, associated system and method
    FR3019882A1|2015-10-16|WATER HEATER SYSTEM WITH MODULAR ENERGY CONSUMPTION
    EP3117159B1|2020-02-12|Electric water heater with adjustable power
    EP2886971B1|2019-08-28|Water heating system with scalable energy capability
    FR2502813A1|1982-10-01|METHOD FOR OPERATING A VERSATILE SWITCH AND SWITCH FOR IMPLEMENTING THE METHOD
    EP3404334B1|2020-08-19|Method and facility for energy storage using a water heater
    EP3258187B1|2021-05-19|Method for modifying the power consumption of a device
    EP2886701B1|2021-09-08|System of boiler and equipment consuming hot water
    FR3015648A1|2015-06-26|POWER REGULABLE ELECTRICAL HEATING DEVICE
    EP3161775A1|2017-05-03|Power management method in an electrical installation and an electrical installation
    EP3101366B1|2019-06-26|Method for estimating a physical magnitude of a water heater water tank
    WO2015001055A1|2015-01-08|Simulation circuit of an alternating electric grid and method for controlling same
    FR3015653A1|2015-06-26|HEAT PUMP HEAT PUMP SYSTEM
    EP3234484B1|2018-10-17|Method for changing the consumption of a heat pump
    FR3068529B1|2019-09-06|SYSTEM AND METHOD FOR CONTROLLING THE VOLTAGE LEVEL ON A LOW VOLTAGE POWER SUPPLY NETWORK
    EP3671399A1|2020-06-24|Method for determining a preferential minimum power setting, method for controlling a plurality of water heaters and associated device
    EP3098536A1|2016-11-30|Method for estimating a temperature profile of a water heater water tank
    FR3104843A1|2021-06-18|Micro-grid with a sophisticated balance between consumption and production
    FR3087278A1|2020-04-17|OPTIMIZATION OF ELECTRICAL POWER SHARING IN THE CONTEXT OF COLLECTIVE SELF-CONSUMPTION AND SELF-PRODUCTION
    FR3036777A1|2016-12-02|METHOD OF ESTIMATING A TEMPERATURE PROFILE OF A WATER TANK OF A WATER HEATER
    FR3075322A1|2019-06-21|HEATING APPARATUS PROVIDING CONTINUOUS MODULATION OF POWER SUPPLY POWER OF ELECTRICAL RESISTANCE
    FR3015793A1|2015-06-26|POWER REGULATION OF AN ELECTRICAL HEATING DEVICE
    同族专利:
    公开号 | 公开日
    WO2015135934A1|2015-09-17|
    FR3018593B1|2019-05-31|
    EP3117158A1|2017-01-18|
    EP3117158B1|2020-01-22|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    FR2582788A1|1985-01-09|1986-12-05|Hebert Jean Paul|Device for controlling an electrically heated hydro-accumulator, virtually using only "off-peak" power, with a possibly associated electrical floor.|
    WO2008125696A2|2007-04-17|2008-10-23|Timothy Patrick Cooper|A load management controller|
    EP2610999A2|2011-12-29|2013-07-03|Werner Schmid|Method and device for using the electrical energy of a device connected to a domestic power grid for generating renewable electrical energy|
    FR2533792B1|1982-09-24|1986-07-11|Electricite De France|ELECTRICAL APPARATUS WITH PROGRESSIVE SWITCHING CALORIC ACCUMULATION|
    US20090188486A1|2008-01-24|2009-07-30|Thomasson Samuel L|PV water heater with adaptive control|
    FR2976654B1|2011-06-15|2013-07-12|Voltalis|DEVICE FOR HEATING, VENTILATION AND / OR AIR CONDITIONING WITH TARGETED FEED MANAGEMENT.|FR3048761B1|2016-03-14|2019-07-12|Cotherm|AUTONOMOUS ENERGY SAVING DEVICE FOR WATER HEATER|
    ES2635647B2|2017-04-17|2018-04-24|Ecoforest Geotermia, S.L.|SYSTEM AND METHOD OF USE OF ELECTRICAL ENERGY EXCEDENTS FROM AN INSTALLATION WITH RENEWABLE ELECTRICAL GENERATION|
    CN107269506B|2017-06-30|2018-06-26|佛山市顺德区约利节能设备有限公司|A kind of air-source water heater power regulation circuit|
    CN107367069B|2017-06-30|2018-06-26|佛山市顺德区约利节能设备有限公司|A kind of air-source water heater voltage regulating and controlling circuit|
    FR3068529B1|2017-06-30|2019-09-06|Electricite De France|SYSTEM AND METHOD FOR CONTROLLING THE VOLTAGE LEVEL ON A LOW VOLTAGE POWER SUPPLY NETWORK|
    法律状态:
    2016-03-31| PLFP| Fee payment|Year of fee payment: 3 |
    2017-03-31| PLFP| Fee payment|Year of fee payment: 4 |
    2018-03-30| PLFP| Fee payment|Year of fee payment: 5 |
    2020-03-30| PLFP| Fee payment|Year of fee payment: 7 |
    2021-03-09| PLFP| Fee payment|Year of fee payment: 8 |
    2022-02-11| PLFP| Fee payment|Year of fee payment: 9 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1452015|2014-03-11|
    FR1452015A|FR3018593B1|2014-03-11|2014-03-11|REGULABLE HEATING WATER HEATER|FR1452015A| FR3018593B1|2014-03-11|2014-03-11|REGULABLE HEATING WATER HEATER|
    PCT/EP2015/054951| WO2015135934A1|2014-03-11|2015-03-10|Power-adjustable electric water heater|
    EP15708544.0A| EP3117158B1|2014-03-11|2015-03-10|Electric water heater with adjustable power|
    [返回顶部]