• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
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  • 优先权
    • 专利摘要:
    Method for controlling the distributed cooling power in a district cooling network to which several properties (2) are connected, characterized in that the method comprises the steps a) to establish a certain group (6) of said properties (2), which properties comprise at least one sensor (38) for indoors temperature each and are associated with a respective upper temperature limit for the indoors temperature; b) for each of the properties in the certain group (6), to measure the indoors temperature in the property in question using said sensor (38) for indoors temperature and to establish a certain time value, constituting the expected time until the indoors temperature of the respective property reaches the respective upper temperature limit at a certain decreased cooling power, which decreased power is lower than a certain respective normal power level; c) to calculate an expected total power in the district cooling network during a future time period; and d) in case the said expected total power exceeds a predetermined value, during said time period only to distribute the respective decreased cooling power to one or several of the properties in said group (6) for which the respective time value is larger than the length of the future time period, so that the total power no longer exceeds the predetermined value.
    公开号:SE536069C2
    申请号:SE1250487
    申请日:2012-05-14
    公开日:2013-04-23
    发明作者:Thomas Wildig
    申请人:Ecofective Ab;
    IPC主号:
    专利说明:

    25 30 536 069 However, high maximum effects in district cooling systems are associated with large marginal costs. For this reason, and since the plant's maximum power is typically only rarely used, such as only between 15 and 17 weekdays and in hot weather, this problem is conventionally often solved with the help of an additional capacity, one which produces cooling in ways that are often less environmentally friendly. Compared with the case for, for example, district heating, the marginal cost of increasing the power in a district cooling system is even higher per kWh. produced It would thus be desirable to be able to provide a way of operating a district cooling system so that the highest power peaks are lower than in conventional operation, which would then have the consequence that the maximum capacity of the plant may be smaller or that the available capacity in a given network can be utilized. more efficient, which for example can mean that more properties can be connected to a certain cooling source.
    Furthermore, such a method would be desirable which reduces the cooling losses during operation of such a district cooling system.
    The present invention solves the problems described above.
    Thus, the invention relates to a method for controlling the cooling power output in a network for district cooling, to which a plurality of properties are connected, and is characterized in that the method comprises the steps of a) determining a certain group of said properties, which properties comprise at least each its sensor for indoor temperature and are associated with a respective upper temperature limit for indoor temperature; b) for each of the properties in the certain group, measure the indoor temperature in the property in question 10 15 20 25 30 536 069 with the aid of said indoor temperature sensors and determine a certain time value, which constitutes the expected time until the respective the indoor temperature of the property has risen from the current indoor temperature and up to the respective upper temperature limit at a certain restricted cooling effect, which restricted cooling effect is lower than a certain respective normal cooling effect level; c) calculate an expected total cooling power output in the district cooling network for a future period of time; and d) if said expected total cooling power consumption exceeds a predetermined value, during said time period only distribute the respective lower cooling power to one or more of the properties in said group, for which or which the respective time value so that it is greater than the length of the coming period, the total cooling power consumption no longer exceeds the predetermined value, after which the indoor temperature is measured in the property or properties to which the respective lower cooling power is calculated to be distributed, the time values for the properties in the group are updated, and one or more of the properties. which currently has a respective estimated time value greater than the time remaining of the period is brought to cool with its respective lower cooling power level, so that the total cooling power outlet does not exceed the predetermined value, while other properties in the group are brought to cool with a respectively normal cooling power level, and that the regulation in step d) of how much cooling power is distributed to the said one or more of the properties in the group takes place by bringing a locally arranged control device in each such property to regulate the circulation in a similarly locally arranged cooling circuit. The invention will now be described in detail, with reference to exemplary embodiments of the invention and the accompanying drawings, in which: Figure 1 is a schematic diagram of a property stock cooled according to the present invention by means of a district cooling system: and Figure 2 is a schematic diagram of a property to be cooled in accordance with the present invention.
    Figure 1 shows a district cooling system comprising a central cooling source 1, in the form of an absorption device in a combined heat and power plant, a central compressor device, a rock cooling system, a system for so-called free cooling or the like. The cooling source 1 is arranged to distribute cooling in hot weather, or when cooling is otherwise desired, the source 1 to a number of connected properties 2. The distribution takes place by means of a main line 3 for suitable cooling medium, such as cold water.
    The properties 2 can be of different types, but it is preferred that they are at least for the most part, preferably exclusively, office properties or premises, industrial properties such as server halls and / or multi-family properties.
    A central control device 4 is arranged to regulate the cooling effect distributed to each property 2. Here, the expression that a "cooling effect is distributed to a property" is to be interpreted as meaning that a certain heat energy per unit time is transferred from a certain property to the coolant and thus cools the property. in question. The regulation can for instance take place by means of a wireless transmitter 5 which communicates with receivers in each respective property (see below), which properties in this case are equipped with suitable conventional actuators for regulating the circulation of coolant in the property in question, such as the circulation in an indoor cooling circuit. Another example is that the coolant is thermally connected, via a heat exchanger, to an existing system for cooling in the property in question, such as a cooled ventilation circuit or one or more fans. In this case, either the circulation of the coolant past the heat exchanger or the internal circulation of coolant in said cooling system can be regulated with conventional actuators. Instead of the wireless transmitter 5, for example, a wired or Internet-connected signal system can be used.
    Cold water from the cooling source 1 arrives at a control unit 22 in the property Figure 2 shows an exemplary property 20 via an incoming line 21, and returns to the cooling source 1 via an outgoing line 23. The control unit 22 is in turn connected to a cooling loop 24 , which is illustrated in principle and is arranged to distribute the incoming cold water to cooling devices arranged in the various rooms in the property.
    The control unit 22 comprises a wireless receiver 27 which is arranged to communicate with the transmitter 5. A control device 28 for a ventilation system further comprises a receiver 29 arranged to communicate with the transmitter 5. Indoor air is ventilated away from the ventilation system through a chimney 30.
    Alternatively, all communication between the control device 4 and the property 20 can go through the control unit 22, which in turn controls, for example, the control devices 25 and 28. Other actuators in the property 20 can be controlled out either directly from the control device 4 or from the control unit 22. correspondingly, a sensor 26 for local weather, such as solar radiation, wind speed and / or temperature, can report either to the control unit 22 or to the control device 4.
    The regulation of how much cooling effect is distributed to the properties in a certain group of properties takes place by having a control device arranged locally in each such respective property regulate the circulation in a similarly locally arranged cooling circuit.
    This is exemplified by the fact that the central control device 4 communicates with the local control device 22, which in turn is connected to local radiator and ventilation circuits, which can be used for adjusting or down-regulating the power output from the network for district cooling.
    Wastewater drains from the property 20 through a sewer line 31.
    The energy balance in the property is thus essentially determined by the following energy flows: 0 The difference in heat energy between incoming cold water 32 and outgoing, hot water 33. 0 Supplied or absorbed heat energy via heated or cooled wastewater in the property 35. 0 Ventilated indoor air 34, possibly after venting.
    I Heat losses and heating 36 via the property's walls, foundation and roof. This parameter depends, among other things, on solar current values for the outdoor temperature, wind, radiation and precipitation. Supplied heat energy derived from the use of the property, from various internal sources, in the property 20 ex- 10 15 20 25 30 536 069 amplified with people and a computer 37. Cooling inside the property 20 of consumed domestic hot water also constitutes such an internal energy source.
    The property 20 further comprises at least one sensor 38 for indoor temperature, which is arranged to measure the indoor temperature in the property 20 and communicate the measured value to the central control device. 4 in a manner conventional per se, for example wireless as described above for the communication between the control device 4 and the control unit 22, the transmitter 5 also being a receiver for wireless signals from the sensor 38. The communication can also take place via the control unit 22. It is preferred that the property 20 comprises a plurality of such sensors for indoor temperature, preferably arranged in several different rooms in the property 20.
    According to the invention, a certain group 6 is first selected (see figure 1) Which of the properties 2 is selected depends on the current operating conditions of the properties 2 connected to the cooling source 1. the applications, but all properties 7 in the group 6 include at least each sensors 38 for indoor temperature arranged to communicate the measured value to the control device 4. Non-selected properties 8 may, for example, be those which do not have sensors connected to the control device 4 for indoor temperature; which does not have the possibility to be regulated from the central control device 4; or who for some other reason do not have the conditions to participate in the procedure described herein.
    Other properties 9 that are not selected may, for example, have special operating conditions, such as that they must maintain a certain, constant indoor temperature, which may, for example, be the case with hospitals, certain archives and so on. 10 15 20 26 30 535 069 Furthermore, each property 7 in the group 6 is associated with a respective upper temperature limit for the indoor temperature, above which the indoor temperature of the property must not rise.
    The method according to the present invention aims at the power control of the properties 2 in the network for district cooling for a certain future period of time. The future time period used depends on the specific application, but can be a period that begins immediately or later, and can for example consist of a certain part of a day, at 15 and 24, or 18 and 24, as between the next the evening.
    For each of the properties 7 in the group 6, the indoor temperature is measured, and communicated to the control device 4. A certain time value is then determined for all properties 7, which constitutes an estimate of the expected time until the indoor temperature of the respective property has risen from the current indoor temperature and up to the respective upper temperature limit if only a certain restricted cooling effect is distributed to the property in question immediately, which restricted effect is lower than a certain respective normal power level. Thus, the time value is the length of a certain time period.
    The normal power level is chosen to represent a cooling power that is distributed to the property in question during normal operation under the current operating conditions. The normal power level can be, for example, the cooling power distributed to the property in question at the current operating mode or the cooling power that is expected to be distributed to the property in question, during which normal operation would be maintained, the coming time period, given information 10 15 20 25 30 536 069 expected weather and control parameters for the distribution of cooling to the property.
    The certain lower power level consists of a suitable power level which is lower than the normal power level and preferably is lower than an expected lowest possible power level in order to be able to maintain the prevailing indoor temperature during the above mentioned time period, without raising the temperature above it and then expected operating conditions in terms of outdoor temperature and the like. According to a preferred embodiment, the lower power level corresponds to the distribution of cooling energy, ie the size of the heat transfer between the property and the coolant, to the property in question being completely interrupted.
    In addition, an expected total power output is calculated in the network for district cooling during the coming time period. It is preferred that this total power output represents an expected maximum, instantaneous power output during the coming time period, and that it be calculated based on available data regarding the properties' construction and use, weather forecasts and so on. See below for a more detailed description of this.
    According to the invention, a maximum power output is established for the cooling source 1, predetermined, i.e. a certain predetermined maximum amount of cooling transported from the cooling source l per unit of time. According to a preferred embodiment, this maximum power output is the actual maximum power for the plant, in other words the amount of cooling per unit time that the plant can emit, more preferably the actual maximum power minus a certain predetermined safety margin. In the event that the above-mentioned expected total power output exceeds this predetermined maximum power output, the control device 4 according to the invention will during said time period regulate the distribution of cooling energy so that a certain or some of the properties 7 in the group 6 only receives the respective lower cooling effects described above. By restricting the cooling power to at least one of the properties 7 sufficiently in this way, it can be achieved that the total power consumption during the coming period can thus not exceed the predetermined value during conventional operation of the plant. the power peak that, one, would have been the result of the increased outdoor temperature, the increasing solar radiation or the other circumstances that formed the basis of the forecast high total power, is eliminated by temporarily reducing the cooling power distributed during the period to one or several properties.
    According to the invention, the calculated respective time value described above for each property 7 in the group 6 is used to determine to which property or properties the respective lower power is to be distributed. More specifically, one or more of the properties 7 in the group 6 are selected to form an additional group 10, where all properties in the group 10 have a respective time value which is greater than the coming period. Said selection is furthermore made so that the expected total power output from the source 1, when the group 10 is operated with the respective lower power outputs, no longer exceeds the predetermined value during the coming period. As the respective time periods of the properties included in the group 10 are longer than the coming period, their respective indoor temperature will not rise above the respective upper temperature limit during operation at the respective lower power during the coming period.
    According to a preferred embodiment, the property or properties in group 6 that have the greatest respective time value are selected to be included in group 10.
    It is further preferred that the individual property having the greatest time value is selected in a first step, after which the property having the second greatest time value is selected, and so on, until the total expected total effect does not exceed the predetermined value, wherein the properties thus selected constitute the group 10.
    By arranging the control device 4 in this way to distribute a respective lower cooling power to a limited proportion 10 of the connected property stock 2, it is thus achieved that the impending power peak can be reduced, which means that the system can be dimensioned with lower maxi grind capacity and still be able to deliver cooling with an expected operational reliability.
    It has also been shown that in most district cooling connected property stocks there are generally properties at a given time for which the supplied district cooling can be temporarily restricted without their respective indoor temperature risking to rise above a contractually regulated maximum temperature. In fact, during operation according to the invention, the respective "thermal inertia" of the properties, i.e. their volumetric heat capacity, is used to even out the power peaks which load the cooling source 1. In addition, the losses of cooling in the network for district cooling as a whole, as these are proportional to the distributed cooling effect and therefore decrease with decreasing variance.
    It is also possible that the operating conditions will change during the coming period. In addition, properties other than those in group 10 some time into the coming period may prove to be more suitable for a restricted cooling supply.
    Therefore, it is preferable to, during the coming period, regularly update which properties are currently to be included in group 10 for lower power distribution. Such an update follows, according to a preferred embodiment, the same rules as the original selection, and preferably takes place periodically, such as at least once an hour, or continuously.
    In other words, the indoor temperature in the property or properties to which the respective lower cooling effect is currently distributed is measured, and the estimated time values for the properties in the certain group are updated. Then one or more of the properties, which currently have a respective estimated time value that is greater than the time remaining of the period, are cooled with their respective lower power level.
    The selection is coordinated so that the total power consumption for all connected properties 2 does not exceed the predetermined value, while other properties in group 6 except those included in group 10, including possibly properties that were previously cooled during the period with their respective lower power level, cooled with a respective normal power level. 10 15 20 25 30 536 069 13 In this way, the advantages described above can be achieved, at the same time as the variations in indoor temperature in individual properties are reduced.
    It is preferred that the control device, 4 calculates the above-described estimate of the total power output from the source 1 during the coming period based on available information about the plant, the individual connected properties 2 and additional available information regarding the expected operating conditions during the coming period. period.
    According to a preferred embodiment, the calculation is based at least in part on historical data regarding the total power consumption for the connected properties 2 under different types of operating conditions. For example, different historically measured total power outputs during periods with different outdoor temperatures can be tabulated, whereby the calculation can be done by interpolation or in another suitable, conventional way.
    According to another preferred embodiment, the calculation is based at least in part on a measured value for the outdoor temperature in the vicinity of at least one of the connected properties 2 in the certain group. The warmer it is outdoors, the higher the cooling effect required to maintain a desired indoor temperature. It is also preferred that the current solar radiation and the current local wind and precipitation conditions, as measured, for example, by means of the sensor 26, form the basis for said calculation, in a corresponding manner.
    According to a further preferred embodiment, the calculation is based at least in part on a weather forecast covering the said future time period and at least one of the properties 10 15 20 25 536 069 14 2. Although the current outdoor temperature gives a good indication of the power requirement for a future period , especially if the coming period soon begins, a weather forecast provides better precision in the calculation.
    In the event that an outdoor temperature measurement or a weather forecast is only relevant for some of the connected properties 2, for example due to local meteorological differences, an in itself conventionally performed estimate of the operating conditions for other properties can be used.
    It is preferred that the control device 4 is arranged to control the distribution of cooling power to non-throttled, connected properties by means of a prior art. It is in this case preferred that the expected total power output control algorithm, which may be conventional in itself. is calculated based at least in part on the known properties of this control algorithm. For example, a weather forecast covering a particular property can form the basis for a simulation of how the control algorithm will control the cooling effect to the property in question, given an initial indoor temperature and the upper temperature limit for the property, and based on such a simulation the total cooling effect over the time period is calculated for that property. Based on that, the total cooling effect for all connected properties 2 can then be calculated.
    In addition, it is preferred that the total power consumption be calculated at least in part on historical data regarding periodic patterns in the use 37 of the connected properties 2, and the possible changed need for cooling effect that such use is expected to give rise to inside the properties during the coming time period. Various types of use, such as the presence of humans and animals inside the properties; the use of technical equipment, lighting and tap hot water; ventilation and so on constitute either heat sources or heat sinks that affect the operation of the cooling system. As such activities are largely periodic and to some extent predictable in nature, they can be measured and then used in the calculation to give a more value-worthy value of the total effect during the coming period.
    It is also preferred to use a priori knowledge regarding at least one, preferably all the thermal properties of the properties, in particular their heat capacity, as a basis for the calculation of the total power consumption during the coming period. In other words, information is collected in an initial step regarding the heat leakage through the property's shell and ventilation 34, which information can for example be obtained from available type descriptions of different properties, and supplemented with information regarding heat recovery systems for the ventilation, and thus additional insulation, further, measurements on site. Then this information, together with the corresponding data describing additional energy sources or depressions, such as the wastewater 35, can be used to make a model of the property as a body with a certain heat capacity. Finally, the model can be used to calculate the expected power requirement during the coming period, especially in combination with historical data regarding utilization and / or the control algorithm used.
    It is possible to combine in different ways and depending on available information the different ways described above to calculate the expected total energy requirement for cooling during the coming period, with the overall aim of achieving such a reliable estimate as possible.
    In a manner similar to that described above regarding the calculation of the expected total power for cooling the property portfolio, it is preferred that the time value of at least some, preferably all, of the properties 7 in group 6 be calculated based on the volumetric property in question. heat capacity as modeled using available information regarding energy flows 34, 35, 36 and so on as above. With the help of such a thermal model, suitable conventional differential equations can be set up, for example, which describe the property's indoor temperature as a function of time, added cooling and operating conditions in general. Such equations can then be solved to calculate the expected time until the indoor temperature has risen to the upper limit.
    It is further preferred that the time value of at least one, preferably all, properties 7 in the group 6 is calculated based on a measured value for the outdoor temperature in the vicinity of the property in question and / or a weather forecast covering said future time period and the property in question, analogous to the described above for the expected total effect.
    Furthermore, and also analogous to that described above for the expected total effect, it is preferred that said time value for at least one, preferably all, of the properties 7 in the group 6 is calculated based on a control algorithm known per se, which controls the cooling effect which distributed to the property in question for the purpose of maintaining an indoor temperature therein below the maximum permissible level, and / or historical data regarding periodic patterns of use and the additional cooling and / or heating effect that this use is expected to give rise to in the property in the coming time period.
    The different types of information described above can be combined in many different ways to maximize the reliability in estimating the time value.
    A method according to the present invention thus achieves that a smoother operation can be achieved without the need for additional cooling sources to cope with power peaks. The inventors' calculations show that a central district cooling system can be designed with only 70-85% of the maximum capacity that would be required for conventional operation. In many cases, this can also be achieved by means of software installations in an existing plant, without additional additional equipment than communication links between various sensors which are often present in themselves and the control device 4.
    Alternatively, with the aid of the invention, more properties can be connected to a central cooling source 1, since the cooling can be taken out at a more even and higher level than before, when the maximum capacity was not utilized other than during power peaks.
    Preferred embodiments have been described above. However, it will be apparent to those skilled in the art that many changes may be made to the described embodiments without departing from the spirit of the invention.
    In the event of an approaching expected power peak, for example, the cooling deposits in one or more of the connected properties 2 can be increased Thus before the period in question begins. a property's indoor air can be cooled one or a few ° C below the normal temperature before the start of the period, which increases the property's time value and thus the possibilities to regulate the cooling distribution to the property in question during the coming time period without rise above the upper temperature limit.
    In addition to, or instead of, the historical data regarding the operation of the properties which can form the basis for the calculation of the expected total cooling effect and the time values of the individual properties, an adaptive method can further be used, according to which operating data is compiled by a central device, such as the control device 4, and where the parameters in a per se conventional energy model over the entire plant or individual properties are continuously adjusted based on actual outcomes of different operating situations. It is especially preferred that the energy impact from the use of the properties is quantified in this way, by measuring the actual outcome of the indoor temperature given the added cooling effect, outdoor temperature, solar radiation and the volumetric heat capacity of the house body. Such a procedure will be able to calculate increasingly expected value values for both the expected total effect and the time values described above.
    Thus, the invention should not be limited by the described embodiments, but may be varied within the scope of the appended claims.
    权利要求:
    Claims (12)
    [1]
    A method for regulating the cooling power outlet in a district cooling network, to which a plurality of properties (2) are connected, characterized in that the method comprises the steps of 8) c) d) determining a certain group (6) of said properties (2), which properties comprise at least each indoor temperature sensor (38) and are associated with a respective upper temperature limit for the indoor temperature; for each of the properties in the certain group (6), measure the indoor temperature in the property in question with the aid of said sensor (38) for indoor temperature and determine a certain time value, which constitutes the expected time until the indoor temperature of the respective property has risen from the current indoor temperature and up to the respective upper temperature limit at a certain throttled cooling power, which throttled cooling power is lower than a certain respective normal cooling power level; calculate an expected total cooling power output in the network for district cooling in a future time period; and total if said expected cooling power output exceeds a predetermined value, during said time period distributing only the respective lower cooling power to one or more of the properties in said group (6), for which or which the respective time value is greater than the coming period length, so that the total cooling power output no longer exceeds the predetermined value, after which the indoor temperature is measured in the property or properties to which the respective lower cooling power is currently distributed, the calculated time values for the properties in the group (6) is updated, and one or more of the properties, which currently have a respective estimated time value that is greater than the time remaining of the period, are brought to cool with their respective lower cooling power level, so that the total cooling power consumption is not exceeds the predetermined value, while the other properties in the group (6) are brought to cool with a respective normal cooling power level, and that the regulation in step d) of how much cooling power is distributed to the said one or more of the properties in the group (6) takes place by a locally arranged in each such respective property control device is caused to regulate the circulation in a similarly locally arranged cooling circuit.
    [2]
    Method according to claim 1, characterized in that in step d) the respective lower cooling effect is distributed only group <6), is greatest. to the one or the of the properties in the said for which or which the respective time value
    [3]
    Method according to claim 1 or 2, characterized in that the expected total cooling power output in step c) is calculated based on historical data regarding the total cooling power output under different types of operating conditions.
    [4]
    4. Procedure according to any. of the preceding claims, characterized in that the expected total cooling power output in step c) is calculated based on a measured value for the outdoor temperature in the vicinity of at least one of the connected properties (2). 10 15 25 30 536 069 21
    [5]
    Method according to any one of the preceding claims, characterized in that the expected total cooling power output in step c) is calculated based on a weather forecast, which covers said future time period and at least one of the connected properties (2).
    [6]
    Method according to one of the preceding claims, characterized in that the expected total cooling power output in step c) is calculated based on a control algorithm known per se, which controls the cooling power distributed to the connected properties (2). for the purpose of maintaining an indoor temperature in each of said properties (2) below a certain maximum permissible level.
    [7]
    Method according to one of the preceding claims, characterized in that the expected total cooling power output in step c) is calculated based on historical data (37) cooling (37) during the coming periodic period in the use of the connected properties (2) and / or and the additional heating effect that this use is expected to give rise to within the properties (2) period.
    [8]
    Method according to one of the preceding claims, characterized in that the time value of at least a certain (20) of the connected properties (2) is calculated based on the heating capacity of the property (20).
    [9]
    Method according to one of the preceding claims, characterized in that the time value of at least a certain (20) is a measured value for the outdoor temperature in the vicinity of the property (20). IV property in the certain group (6) is calculated based on 10 15 20 536 069 22
    [10]
    Method according to any one of the preceding claims, characterized in that the time value of at least a certain property in the certain group (6) is calculated based on a weather forecast, which covers said future time period and the property (20).
    [11]
    11. ll. Method according to one of the preceding claims, characterized by a control algorithm known per se (20), in that the time value of at least a certain property in the certain group (6) is calculated based on one which controls the cooling effect which is distributed to the property (20). ) for the purpose of maintaining an indoor temperature therein below a certain maximum permissible level.
    [12]
    12. Procedure according to any. of the preceding claim - drawing (20) historical data regarding periodic patterns in the use (37) of (20) that the time value of at least a certain property in the certain group (6) is calculated based on the property and the additional cooling ( 37) is expected to give rise to it in the coming time period. and / or heating effect, which this utilization
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    同族专利:
    公开号 | 公开日
    SE1250487A1|2013-04-23|
    EP2664864A1|2013-11-20|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    JP5036793B2|2009-11-27|2012-09-26|三菱電機株式会社|Air conditioner control device|
    DE102010039497A1|2010-08-19|2012-02-23|Siemens Aktiengesellschaft|Arrangement and method for room air conditioning|
    US8606374B2|2010-09-14|2013-12-10|Nest Labs, Inc.|Thermodynamic modeling for enclosures|
    GB201016200D0|2010-09-27|2010-11-10|Clarkson Controls Ltd|Improvements relating to climate control systems|
    GB2498275B|2010-10-13|2018-02-28|Weldtech Tech Shanghai Co Ltd|Energy-saving optimized control system and method for chiller plant room|SG11201909790UA|2017-04-28|2019-11-28|Space Pte Ltd|A district cooling system|
    EP3505832A1|2017-12-27|2019-07-03|Brunnshög Energi AB|Method for controlling a thermal distribution system|
    EP3637217A1|2018-10-08|2020-04-15|E.ON Sverige AB|A method for controlling a thermal energy distribution system|
    法律状态:
    2015-02-24| NUG| Patent has lapsed|
    优先权:
    申请号 | 申请日 | 专利标题
    SE1250487A|SE1250487A1|2012-05-14|2012-05-14|Procedure for regulating power output in a district cooling network|SE1250487A| SE1250487A1|2012-05-14|2012-05-14|Procedure for regulating power output in a district cooling network|
    EP13167531.6A| EP2664864A1|2012-05-14|2013-05-13|Method for controlling the power consumption in a district cooling system|
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