JP6506918B2 - Ice storage system - Google Patents

Description

  The present invention relates to an ice heat storage system including an ice heat storage tank for storing cold heat from a cold heat source and a heat radiating unit for performing a heat radiation operation for radiating the cold heat stored in the ice heat storage tank to a heat radiation target fluid .

  In the above ice heat storage system, for example, an antifreeze solution (for example, brine) having cold heat from a cold heat source is supplied to the heat transfer tube of the ice heat storage tank, and ice is produced on the outer periphery of the heat transfer tube. The cold heat from the cold heat source is stored. Then, the heat radiating portion performs the heat radiating operation to take cold heat stored in the ice heat storage tank out of the heat storage tank, radiate the heat to the air conditioning fluid as the heat radiation target fluid, and perform air conditioning such as cooling. (See, for example, Patent Documents 1 and 2).

  In the systems described in Patent Documents 1 and 2 above, the heat dissipation unit supplies antifreeze to the inside of the heat transfer tube of the ice storage tank, thereby melting ice from the inside of the heat transfer tube and taking cold heat with the antifreeze. A so-called internal heat dissipation operation that dissipates the extracted cold heat to the fluid to be dissipated and a heat transfer medium such as water around the heat transfer tube of the ice storage tank to melt the ice from the outside and melt the water The cooling medium is taken out by the heat medium containing, and it is configured to be switchable to a so-called external melting type heat radiation operation in which the taken-out cold heat is radiated to the heat radiation target fluid. In addition to the heat radiating portion, an additional heat radiating portion is provided which performs an additional heat radiating operation for radiating heat from the antifreeze liquid having cold heat from the cold heat source to the heat radiation target fluid.

  In the system described in Patent Document 1 above, when the heat dissipation section performs the heat dissipation operation of the external melting type and the additional heat dissipation section performs the additional heat dissipation operation, if the air conditioning load decreases, the additional heat dissipation by the additional heat dissipation section The operation is stopped, and both the external melting type and the internal melting type heat dissipation operation are performed in the heat dissipation section.

  In the system described in Patent Document 2, when performing the additional heat dissipation operation by the additional heat dissipation unit, in addition to the external heat dissipation operation by the heat dissipation unit or the external heat dissipation operation by the heat dissipation unit. For example, at the end of the cooling period of a day, etc., in order to melt all of the ice made ice, the heat dissipation section does not perform the additional heat dissipation operation, and the heat dissipation section performs the external melting type and the internal melting type. Both heat dissipation operation is to be performed.

JP, 2006-292267, A Unexamined-Japanese-Patent No. 10-238828 gazette

  In the ice heat storage system as described above, for example, heat is stored in the ice heat storage tank using power during periods of low power demand such as night time, and is stored in the ice heat storage tank during periods of high power demand such as daytime By performing air conditioning such as cooling using cold energy, power consumption on the demand side during periods of high power demand is intended to be reduced.

  Recently, demand response (DR, demand response) technology in which the demand side adjusts the power consumption according to the demand for reduction of the power consumption to each customer when the power supply from the power company or the like is likely to run short has attracted attention. The ice storage system as described above is provided, for example, in a facility such as a commercial facility having a plurality of stores, so the area including the facility is targeted and the ice storage system takes some measures. It is desired to realize the area demand response response. However, in the systems described in Patent Documents 1 and 2 above, such area demand response is not considered.

  In view of this situation, the main object of the present invention is to provide an ice thermal storage system capable of realizing a demand response corresponding to an area including a facility having the ice thermal storage system.

According to a first aspect of the present invention, there is provided an ice heat storage tank for producing ice around a heat transfer tube and storing cold heat from a cold heat source;
A heat dissipation unit that performs a heat dissipation operation to dissipate the cold heat stored in the ice heat storage tank to the fluid to be dissipated;
And an additional heat radiation unit for performing an additional heat release operation to release the cold heat from the cold heat source to the heat radiation target fluid,
The heat dissipation unit may perform the heat dissipation operation as follows:
A first operation mode in which a first heat transfer fluid is supplied to the inside of the heat transfer tube in the ice heat storage tank, ice is melted from the inside of the heat transfer tube, and cold heat taken out is dissipated to the fluid to be dissipated;
A second heat transfer fluid is supplied to the outside of the heat transfer tube in the ice heat storage tank, and ice is melted from the outside and the cold heat taken out is dissipated to the fluid to be dissipated Is feasible and
When the heat dissipation unit is performing a heat dissipation operation in one of the first operation mode and the second operation mode, and the additional heat dissipation unit is performing the additional heat dissipation operation, When the operation switching condition is satisfied, the additional heat dissipation unit is stopped, and the heat dissipation unit is configured to perform the heat dissipation operation in both the first operation mode and the second operation mode,
In the first operation switching condition, the power consumption in a specific area including the facility having the ice storage system is expected to exceed the set power which is set as the demand response corresponding to the specific area. It is set to the condition that becomes the timing ,
A first heat exchange unit that exchanges heat between the first heat transfer fluid and the second heat transfer fluid before being supplied to the ice heat storage tank;
A second heat exchange unit for exchanging heat between the second heat transfer fluid and the heat radiation target fluid;
The heat dissipation unit performs a heat dissipation operation in the first operation mode by heat exchange in the first heat exchange unit and heat exchange in the second heat exchange unit, and heat exchange in the second heat exchange unit. It is comprised so that the thermal radiation driving | operation in said 2nd driving | running mode may be performed,
The additional heat dissipation unit is configured to perform the additional heat dissipation operation by heat exchange in the first heat exchange unit and heat exchange in the second heat exchange unit .

The timing at which the power consumption in the specific area is expected to exceed the set power is the timing when the power supplied from a power company or the like is insufficient for the specific area. Therefore, it is desirable to reduce the power consumption of the specific area at such timing as the area demand response to the specific area. Therefore, in the present characteristic configuration, the first operation switching condition is set to a condition at which it is expected that the power consumption in the specific area exceeds the set power amount, and the heat dissipation unit is set to the first operation mode and the first operation mode. When the heat dissipation operation is being performed in one of the two operation modes and the additional heat dissipation unit is performing the additional heat dissipation operation, if the first operation switching condition is satisfied, the additional heat dissipation unit is operated It is made to stop, the power consumption etc. for operating a cold heat source are reduced, and the reduction of the power consumption of a specific area is aimed at. In addition to stopping the operation of the additional heat radiating portion, the heat radiating portion performs heat dissipation operation in both the first operation mode and the second operation mode. The amount of heat released can be maintained. Thus, even when cooling is performed using, for example, the fluid to be dissipated, the air conditioning load can be sufficiently covered. Therefore, while appropriately performing cooling using a fluid to be dissipated, it is possible to reduce the power consumption of a specific area at an appropriate timing, and realize area demand response to the specific area.
According to the present feature configuration, in the heat dissipation operation in the first operation mode by the heat dissipation unit and the additional heat dissipation operation by the additional heat dissipation unit, heat exchange is performed in two stages in the first heat exchange unit and the second heat exchange unit. . As a result, only by providing two heat exchange units, not only the heat radiation operation in the first operation mode and the second operation mode by the heat radiation unit, but also the additional heat radiation operation by the additional heat radiation unit can be performed. Can be adopted. Then, in the first heat exchange unit, heat exchange is performed between the first heat transfer fluid and the second heat transfer fluid before being supplied to the ice heat storage tank, so the heat release operation and additional heat release in the first operation mode by the heat release unit In the additional heat release operation by the part, after the second heat transfer fluid is cooled by the first heat transfer fluid in the first heat exchange part, the second heat transfer fluid can be returned to the heat storage tank, and the ice heat storage tank It is possible to suppress premature melting of ice.

  According to a second aspect of the present invention, there is provided a receiving unit for externally receiving a stress request predicted that the power consumption in the specific area exceeds the set power amount, based on the stress request received by the receiving unit. The point is that it is determined whether or not the first operation switching condition is satisfied.

  According to this feature configuration, when the power consumption in the specific area is predicted to exceed the set power amount, a stress request is transmitted from the outside such as an electric power company to the ice heat storage system, so the stress request is received It is determined by the unit whether or not the first operation switching condition is satisfied based on the pressure request. By performing such a determination, it is possible to accurately determine the timing at which the power consumption should be reduced in the specific area, and it is possible to appropriately perform the power reduction as the area demand response.

According to a third aspect of the present invention, the apparatus for circulating the first heat transfer fluid can be selected to circulate the first heat transfer fluid among the cold heat source, the ice heat storage tank, and the first heat exchange unit. A first circulation circuit to cause
A second circulation circuit that circulates the second heat transfer fluid by selecting one of the ice heat storage tank, the first heat exchange unit, and the second heat exchange unit that allows the second heat transfer fluid to flow; The heat dissipating unit switches the first circulation circuit to a state in which the first heat transfer fluid is circulated between the ice heat storage tank and the first heat exchange unit, and the ice heat storage tank and the ice heat storage tank The second circulation circuit is switched to a state in which the second heat transfer fluid is circulated between the first heat exchange unit and the second heat exchange unit, and heat release operation is performed in the first operation mode,
The heat transfer operation is performed in the second operation mode by switching the second circulation circuit to a state in which the second heat transfer fluid is circulated between the ice heat storage tank and the second heat exchange unit.
The additional heat radiation unit switches the first circulation circuit to a state in which the first heat transfer fluid is circulated between the cold heat source and the first heat exchange unit, and the ice heat storage tank and the first heat exchange The second heat transfer fluid is circulated between the unit and the second heat exchange unit, and the second circulation circuit is switched to perform the additional heat release operation.

According to this feature configuration, only by switching the device that allows fluid to flow in the two circulation circuits of the first circulation circuit and the second circulation circuit, only the heat dissipation operation in the first operation mode and the second operation mode by the heat dissipation unit In addition, additional heat dissipation operation can be performed by the additional heat dissipation unit, and a simple circuit configuration can be adopted. Moreover, switching of the operation mode in the heat radiating portion and switching of the additional heat radiating operation in the additional heat radiating portion can also be performed by a simple operation of switching the device through which the fluid flows, from this point as well, the circuit configuration is simplified. Can be implemented.
The fourth feature of the present invention is provided in a commercial facility,
Since the heat dissipation unit performs the heat dissipation operation in one of the first operation mode and the second operation mode, and the additional heat dissipation unit is executing the additional heat dissipation operation, the additional heat dissipation unit When the operation of the heat release unit is switched to a state in which the heat release unit performs the heat release operation in both the first operation mode and the second operation mode, the store visits to the commercial facility with respect to the surrounding area is performed. The point is to send out information to promote store visits.

The figure which shows the flow-through state of the fluid in a thermal storage driving | operation in the schematic block diagram of an ice thermal storage system. The figure which shows the fluid flow in the thermal radiation operation of the 2nd operation mode in the schematic block diagram of an ice thermal storage system. A diagram showing a heat release operation in the second operation mode and a fluid flow state in the additional heat release operation in the schematic configuration diagram of the ice heat storage system The figure which shows the fluid flow in the thermal radiation operation in the operation mode of both the 1st operation mode and the 2nd operation mode in the schematic block diagram of an ice thermal storage system. Diagram showing a specific area Schematic configuration diagram of an ice storage system in another embodiment

An embodiment of an ice heat storage system according to the present invention will be described based on the drawings.
1 to 4 all show the schematic configuration of the ice heat storage system 100, but the portions through which the fluid flows are different, and the portions through which the fluid does not flow are shown by thin lines, and the fluid is The portions passing through are indicated by thick lines.

  The ice heat storage system 100 stores the cold heat of the cold heat source 1, the ice thermal storage tank 2 for storing cold heat from the cold heat source 1, and the cold heat of the cold heat source 1 in the ice thermal storage tank 2, as shown in FIGS. A heat storage unit 7 (see FIG. 1) that performs a heat storage operation to cause heat radiation, a heat radiation unit 3 (see FIG. 2) that performs a heat radiation operation to radiate the cold heat stored in the ice heat storage tank 2 to the heat radiation target fluid H An additional heat radiating portion 4 (see FIG. 3) is provided which performs an additional heat radiating operation for radiating the cold heat from the heat to the heat radiation target fluid H. For the heat radiation target fluid H, for example, various air conditioning fluids such as air conditioning water can be used.

  In the ice heat storage system 100, the first heat transfer fluid N1 for transferring the cold heat of the cold heat source 1 to the ice heat storage tank 2 and the heat storage tank 2 are stored as the fluid for transferring heat. And a second heat transfer fluid N2 for transferring the cold heat to the fluid H to be dissipated. Although the detailed illustration is omitted, the ice heat storage tank 2 is provided with a heat transfer pipe 2a through which the first heat transfer fluid N1 flows, and the first heat transfer fluid N1 having the heat of the cold heat source 1 in the heat transfer pipe 2a. By making it flow, ice is produced around the heat transfer tube 2 a so as to store cold heat from the cold heat source 1. The first heat transfer fluid N1 can use, for example, an antifreeze liquid such as brine, and the second heat transfer fluid N2 can use, for example, water flowing around the heat transfer pipe 2a in the ice thermal storage tank 2 . Although not shown, a water sprinkling portion for sprinkling water is provided on the outer peripheral portion of the heat transfer pipe 2a and the like, and water flowing around the heat transfer pipe 2a including the water sprinkling from the water sprinkling portion It can be the carrier fluid N2.

  As a configuration for the first heat transfer fluid N1, a first heat exchange unit 5 that exchanges heat between the first heat transfer fluid N1 and the second heat transfer fluid N2, a cold heat source 1, an ice heat storage tank 2, and a first heat exchange unit Among the five, the first circulation circuit 10 for circulating the first heat transfer fluid N1 is provided by freely selecting an apparatus through which the first heat transfer fluid N1 flows. The first heat exchange unit 5 is arranged to exchange heat between the first heat transfer fluid N1 and the second heat transfer fluid N2 before being supplied to the ice storage tank 2.

  The first circulation circuit 10 includes a first flow passage portion 11 capable of circulating the first heat transfer fluid N1 in the order of the cold heat source 1, the inside of the heat transfer pipe 2a in the ice heat storage tank 2, and the first heat exchange unit 5; 1) A first circulation pump 12 is provided to circulate the heat transfer fluid N1. In the first flow passage portion 11, a first bypass portion 13 for bypassing the cold heat source 1, a second bypass portion 14 for bypassing the ice storage tank 2, and a third bypass portion 15 for bypassing the first heat exchange portion 5. Each of the three bypass sites is connected by branching and joining. Although not shown, a switching valve such as a three-way valve is provided at a branch point of each bypass portion 13, 14, 15, and the cold heat source 1, ice heat storage tank 2, and Among the first heat exchange units 5, an apparatus through which the first heat transfer fluid N1 flows can be selected. The first circulation pump 12 is disposed at a portion between the joining portion of the second bypass portion 14 and the branch portion of the first bypass portion 13 in the first flow passage portion 11.

  As a configuration for the second heat transfer fluid N2, the second heat exchange unit 6 that exchanges heat between the second heat transfer fluid N2 and the fluid H to be dissipated, the ice heat storage tank 2, the first heat exchange unit 5, and the second heat exchange The second circulation circuit 20 for circulating the second heat transfer fluid N2 is provided by selecting an apparatus through which the second heat transfer fluid N2 flows in the section 6.

  The second circulation circuit 20 is a second flow passage portion 21 capable of circulating the second heat transfer fluid N2 in the order of the second heat exchange portion 6 and the first heat exchange portion 5 outside the heat transfer pipe 2a in the ice heat storage tank 2. And a second circulation pump 22 that circulates the second heat transfer fluid N2. A fourth bypass portion 23 for bypassing the first heat exchange unit 5 is bifurcatedly connected to the second flow passage portion 21. Although not shown, a switch valve such as a three-way valve is provided at a branch point of the fourth bypass portion 23, and the second heat transfer fluid is transferred to the first heat exchange unit 5 by switching the switch valve. It is possible to select whether to let N2 flow or not. The second circulation pump 22 is disposed at a portion between the ice heat storage tank 2 and the second heat exchange unit 6 in the second flow passage portion 21.

  As a configuration for the heat radiation target fluid H, an air conditioning side circuit 30 that supplies the heat radiation target fluid H that has passed through the second heat exchange unit 6 to the air conditioner 31 is provided. Although not shown, the air conditioning side circuit 30 distributes and supplies the heat radiation target fluid H that has passed through the second heat exchange unit 6 to the plurality of air conditioners 31, and the heat radiation that has passed through each of the plurality of air conditioners 31. The target fluid H can be combined and configured as a circulation circuit to be supplied to the second heat exchange unit 6. For the air conditioner 31, for example, a fan coil unit having a coil for flowing the fluid H to be radiated and a fan for supplying air conditioning air to the coil can be used, and the air conditioning is performed by the coil Air conditioning air is supplied to the air conditioning target space.

  In the illustrated embodiment, the fluid H to be dissipated on the return side from the air conditioner 31 is supplied as it is to the second heat exchange unit 6, but for example, although not shown, the air conditioning circuit 30 dissipates heat. An auxiliary cold heat source is provided upstream of the second heat exchange section 6 in the flow direction of the target fluid H, and the auxiliary heat source cools the fluid H to be dissipated before being supplied to the second heat exchange section 6 Alternatively, the fluid H to be dissipated after cooling can be supplied to the second heat exchange unit 6.

  The heat storage unit 7 is configured to perform a heat storage operation by switching an apparatus through which the first heat transfer fluid N <b> 1 flows in the first circulation circuit 10. As shown in FIG. 1, in the heat storage operation, the heat storage unit 7 switches the first circulation circuit 10 to a state in which the first heat transfer fluid N1 is circulated between the cold heat source 1 and the ice heat storage tank 2. That is, in the first circulation circuit 10, the first heat transfer fluid is placed between the cold heat source 1 and the ice heat storage tank 2 at the first flow passage portion 11 in a state of bypassing the first heat exchange unit 5 by the third bypass portion 15. It is circulating N1. Thereby, the first heat transfer fluid N1 having the cold heat of the cold heat source 1 is supplied to the heat transfer pipe 2a of the ice heat storage tank 2, and ice is produced around the heat transfer pipe 2a.

  As the heat release operation of the heat release unit 3, the first operation mode and the second operation mode are performed by switching the devices through which the heat transfer fluid N1, N2 flows in the first circulation circuit 10 and the second circulation circuit 20 as the heat dissipation unit 3 One or both of the operation modes are configured to be executable. The first operation mode is a so-called internal melting type, and as shown in FIG. 4, the first heat transfer fluid N1 is supplied to the inside of the heat transfer tube 2a in the ice storage tank 2 and ice is supplied from the inside of the heat transfer tube 2a. The cold heat that has been melted and taken out is dissipated to the fluid H to be dissipated. The second operation mode is a so-called external melting type, and as shown in FIG. 2, the second heat transfer fluid N2 is supplied to the outside of the heat transfer pipe 2a in the ice storage tank 2 to melt ice from the outside and take it out The cold heat is dissipated to the fluid H to be dissipated.

  In the first operation mode, as shown in FIG. 4, the heat dissipation unit 3 switches the first circulation circuit 10 to a state in which the first heat transfer fluid N1 is circulated between the ice heat storage tank 2 and the first heat exchange unit 5 The second circulation circuit 20 is switched to a state in which the second heat transfer fluid N2 is circulated among the ice heat storage tank 2, the first heat exchange unit 5, and the second heat exchange unit 6. That is, in the first circulation circuit 10, the first heat transfer fluid is transferred between the ice heat storage tank 2 and the first heat exchange portion 5 in the first flow passage portion 11 in a state where the cold heat source 1 is bypassed by the first bypass portion 13. It is circulating N1. In the second circulation circuit 20, the second heat is generated between the ice heat storage tank 2, the first heat exchange unit 5, and the second heat exchange unit 6 in the second flow passage section 21 without flowing into the fourth bypass section 23. The carrier fluid N2 is circulated. Thereby, the cold heat of the ice heat storage tank 2 is taken out by the first heat transfer fluid N1, and the second heat transfer fluid N2 is cooled in the first heat exchange unit 5 by the first heat transfer fluid N1. The heat transfer target fluid H is cooled in the second heat exchange unit 6 by the two heat transfer fluids N2.

  In the second operation mode, as shown in FIG. 2, the heat dissipation unit 3 switches the second circulation circuit 20 to a state in which the second heat transfer fluid N2 is circulated between the ice heat storage tank 2 and the second heat exchange unit 6 ing. That is, in the second circulation circuit 20, the second heat exchange portion 6 is disposed between the ice heat storage tank 2 and the second heat exchange portion 6 in the second flow path portion 21 in a state where the first heat exchange portion 5 is bypassed by the fourth bypass portion 23. The heat transfer fluid N2 is circulated. Thereby, in the second operation mode, the cold heat of the ice heat storage tank 2 is taken out by the second heat transfer fluid N2, and the heat radiation target fluid H is cooled in the second heat exchange unit 6 by the second heat transfer fluid N2. .

  Also in the additional heat dissipation operation of the additional heat dissipation part 4, as shown in FIG. 3, the additional heat dissipation part 4 causes the first heat transfer fluid N1 to circulate between the cold heat source 1 and the first heat exchange part 5 The circulation circuit 10 is switched, and the second circulation circuit 20 is switched to a state in which the second heat transfer fluid N2 is circulated among the ice heat storage tank 2, the first heat exchange unit 5, and the second heat exchange unit 6. That is, in the first circulation circuit 10, the first heat transfer fluid is interposed between the cold heat source 1 and the first heat exchange portion 5 in the first flow passage portion 11 in a state of bypassing the ice storage tank 2 by the second bypass portion 14. It is circulating N1. In the second circulation circuit 20, the second heat is generated between the ice heat storage tank 2, the first heat exchange unit 5, and the second heat exchange unit 6 in the second flow passage section 21 without flowing into the fourth bypass section 23. The carrier fluid N2 is circulated. Thereby, the second heat transfer fluid N2 is cooled in the first heat exchange unit 5 by the first heat transfer fluid N1 having the cold energy of the cold heat source 1, and the second heat transfer unit is cooled by the cooled second heat transfer fluid N2. At 6 the fluid H to be dissipated is cooled.

  As described above, switching of the heat transfer fluid N1 and N2 in the first circulation circuit 10 and the second circulation circuit 20 merely switches the first operation mode and the second operation mode by the heat dissipation unit 3 as well as switching the first operation mode and the second operation mode. It is possible to switch between the additional heat dissipation operation by the additional heat dissipation unit 4 and the heat storage operation by the heat storage unit 7. Thus, a simple configuration is adopted as a circuit configuration including the first circulation circuit 10 that allows the first heat transfer fluid N1 to flow and the second circulation circuit 20 that allows the second heat transfer fluid N2 to flow, Each of the heat storage operation, the heat release operation, and the additional heat release operation can be appropriately performed.

  The ice heat storage system 100 is provided with a heat storage unit 7, a heat radiating unit 3, and an operation control unit 40 that controls the operation of the additional heat radiating unit 4. When the operation control unit 40 determines that the heat storage setting condition is satisfied, as shown in FIG. 1, the heat storage operation by the heat storage unit 7 is performed. In this heat storage operation, for example, the amount of cold heat given by the cold heat source 1 is adjusted so that the temperature of the first heat transfer fluid N1 that has passed through the cold heat source 1 becomes the heat storage setting temperature (for example, -3.degree. C.) The first heat transfer fluid N1 having the heat storage setting temperature is supplied to the heat transfer tube 2a, and ice is produced around the heat transfer tube 2a. The conditions for setting the heat storage setting condition can be changed as appropriate, but for example, when the night time zone is reached, the setting is made according to the time zone so that the heat storage setting condition is satisfied. can do. Further, the setting condition for heat storage can be set to be satisfied also when there is a request for artificial heat storage operation, such as an ON operation of a manual operation type switch.

  The operation control unit 40 monitors whether or not the air conditioner 31 is operating, and as shown in FIG. 2, the heat dissipation operation in the second operation mode by the heat dissipation unit 3 is performed while the air conditioner 31 is in operation. To do. The temperature change of the fluid in the heat release operation in the second operation mode will be described. For example, the temperature of the second heat transfer fluid N2 taken out of the ice heat storage tank 2 becomes 1 ° C. and supplied to the second heat exchange unit 6 The temperature of the fluid H to be dissipated is 12.5 ° C. Then, the temperature of the second heat transfer fluid N2 that has passed through the second heat exchange unit 6 is raised to 11.5 ° C. by heat exchange in the second heat exchange unit 6, and heat radiation that has passed through the second heat exchange unit 6 The temperature of the target fluid H drops to 7 ° C. As a result, the fluid H to be radiated at a sufficiently low temperature of 7 ° C. is supplied to the air conditioner 31 so that cooling can be properly performed.

  The operation control unit 40 performs the heat radiation operation in the second operation mode by the heat radiation unit 3 (see FIG. 2), and when the setting condition for addition is satisfied, as shown in FIG. In addition to the heat dissipation operation in the second operation mode according to the above, the additional heat dissipation operation by the additional heat dissipation unit 4 is performed. The setting condition for addition is set so that the setting condition for addition is satisfied when the air conditioning load in the air conditioner 31 becomes larger than the setting load.

  In this manner, the operation control unit 40 performs the heat release operation in the second operation mode by the heat release unit 3 along with the operation of the air conditioner 31, and determines whether the air conditioning load in the air conditioner 31 is larger than the set load. It is determined. Then, if the air conditioning load in the air conditioner 31 is equal to or less than the set load, the operation control unit 40 continues the state of performing the heat dissipation operation in the second operation mode by the heat dissipation unit 3, and the air conditioning load in the air conditioner 31 When the load is larger than the set load, in addition to the heat dissipation operation in the second operation mode by the heat dissipation unit 3, the additional heat dissipation operation by the additional heat dissipation unit 4 is performed.

  The temperature change of the fluid in the simultaneous operation of the heat release operation of the second operation mode and the additional heat release operation will be described. For example, the temperature of the second heat transfer fluid N2 extracted from the ice heat storage tank 2 is 1 ° C., and the temperature of the fluid H to be radiated supplied to the second heat exchange unit 6 is 12.5 ° C. Then, the temperature of the second heat transfer fluid N2 that has passed through the second heat exchange unit 6 is raised to 11.5 ° C. by heat exchange in the second heat exchange unit 6, and heat radiation that has passed through the second heat exchange unit 6 The temperature of the target fluid H drops to 7 ° C. As a result, the fluid H to be radiated at a sufficiently low temperature of 7 ° C. is supplied to the air conditioner 31 so that cooling can be properly performed. Further, the second heat transfer fluid N2 at 11.5 ° C. is not returned to the ice heat storage tank 2 as it is, but by the heat exchange in the first heat exchange unit 5, the first heat transfer fluid N1 at 5 ° C. The temperature is lowered to 6 ° C., and the second heat transfer fluid N2 at 6 ° C. is returned to the ice heat storage tank 2, and it is possible to suppress premature melting of ice in the ice heat storage tank 2. Here, in the cold heat source 1, the temperature of the first heat transfer fluid N1 that has passed through the cold heat source 1 becomes an additional setting temperature (e.g., 5 ° C.) higher than the heat storage setting temperature (e.g., −3 ° C.) The amount of cold heat given by the cold heat source 1 is adjusted.

  The operation control unit 40 satisfies the first operation switching condition when the additional heat dissipation operation by the additional heat dissipation unit 4 is performed in addition to the heat dissipation operation in the second operation mode by the heat dissipation unit 3 (see FIG. 3) And, as shown in FIG. 4, the additional heat dissipation operation by the additional heat dissipation unit 4 is stopped, and the heat dissipation operation is performed in both the first operation mode and the second operation mode by the heat dissipation unit 3 .

  The temperature change of the fluid in the heat release operation in both operation modes will be described. For example, the temperature of the second heat transfer fluid N2 extracted from the ice heat storage tank 2 is 1 ° C., and the temperature of the fluid H to be radiated supplied to the second heat exchange unit 6 is 12.5 ° C. Then, the temperature of the second heat transfer fluid N2 that has passed through the second heat exchange unit 6 is raised to 11.5 ° C. by heat exchange in the second heat exchange unit 6, and heat radiation that has passed through the second heat exchange unit 6 The temperature of the target fluid H drops to 7 ° C. As a result, the fluid H to be radiated at a sufficiently low temperature of 7 ° C. is supplied to the air conditioner 31 so that cooling can be properly performed. Further, the second heat transfer fluid N2 at 11.5 ° C. is not returned to the ice heat storage tank 2 as it is, but by the heat exchange in the first heat exchange unit 5, the first heat transfer fluid N1 at 5 ° C. The temperature is lowered to 6 ° C., and the second heat transfer fluid N2 at 6 ° C. is returned to the ice heat storage tank 2, and it is possible to suppress premature melting of ice in the ice heat storage tank 2.

  A description of the first operation switching condition will be added. As shown in FIG. 5, for example, an area including the facility 200 having the ice storage system 100 and the peripheral area R1 of the facility 200 is defined as a specific area R2, and the first operation switching condition is the power consumption in the specific area R2. The condition is set to be a timing at which the amount is expected to exceed the set power amount. In this embodiment, for example, the ice thermal storage system 100 is provided in a large facility 200 such as a commercial facility having a plurality of stores, and the surrounding area R1 including the large facility 200 and houses and facilities around the large facility 200 is provided. It is considered as one specific area R2. About how large the area is set as the specific area R2, for example, it can be set based on what area is supplied from the power company as one supply range. In addition, the specific area R2 may be an area including the facility 200, and the facility 200 and an area away from the facility 200 may be set as the specific area R2, and the facility 200 and an area adjacent to the facility 200. It is not limited to

  Here, the set power amount can be set on the basis of the amount of power that can be supplied to the specific area R2 as the demand response to the specific area R2. In addition, when the target reduction amount of power consumption is set as the demand response corresponding to the specific area R2, the current power consumption amount such as the power amount obtained by subtracting the target reduction amount from the current power consumption amount And can be set based on the target reduction amount.

  The ice heat storage system 100 is provided with a receiving unit 41 that receives from the external company G such as a power company a stress request T for which the power consumption in the specific area R2 is predicted to exceed the set power, and the receiving unit 41 Whether or not the first operation switching condition is satisfied is determined based on the stress request T received.

  When it is predicted that the power consumption in the specific area R2 exceeds the set power, a stress request T is transmitted from the outside G such as a power company to the ice storage system 100. The tightness demand T includes, for example, various kinds of information such as a tightness time zone in which the power consumption in the specific area R2 is predicted to exceed the set power, and a reduction target amount of the power consumption. In the ice heat storage system 100, when the stress request T is received by the receiving unit 41, it is determined that the first operation switching condition is satisfied when the stress time zone included in the stress request T is reached. And the heat dissipation operation in both the first operation mode and the second operation mode by the heat dissipation unit 3 is performed. Then, during the pressing time zone, as shown in FIG. 4, the heat radiating operation in both the first and second driving modes by the heat radiating portion 3 is performed, and when it is out of the pressing time zone, as shown in FIG. As shown in FIG. 4, the operation is switched to a state in which the heat dissipation operation in the second operation mode by the heat dissipation unit 3 and the additional heat dissipation operation by the additional heat dissipation unit 4 are performed.

  In addition, even if the tightness request T does not include the tightness time zone, for example, based on the time when the tightness request T is received by the receiving unit 41, the time interval from the time of reception is set as the tightness time zone. Thus, it can be determined whether or not the first operation switching condition is satisfied.

  Here, it is determined whether or not the first operation switching condition is satisfied, and the operation switching to a state in which the heat dissipation operation is performed in both the first operation mode and the second operation mode by the heat dissipation unit 3 accordingly For example, when the tightness request T is received by the reception unit 41, the operation control unit 40 automatically determines whether the first operation switching condition is satisfied, and the operation switching is also performed accordingly. The control unit 40 can do this automatically. In addition to or instead of this, when the stress request T is received by the reception unit 41, the administrator of the ice heat storage system 100 determines whether the first operation switching condition is satisfied, and the operation associated therewith Also for the switching, an operation switching instruction can be given to the operation control unit 40 for the administrator or the like to perform the operation switching.

  In this manner, in the ice heat storage system 100, the additional heat dissipation operation by the additional heat dissipation unit 4 is stopped in response to the stress request T from the outside G such as a power company, and the first operation mode and the second By switching the operation to a state in which the heat release operation is performed in both operation modes of the operation mode, it is possible to reduce power consumption while performing cooling corresponding to the air conditioning load of the air conditioner 31. The stress request T from the external G is transmitted when the power consumption in the specific area R2 is predicted to exceed the set power, and therefore, it is optimal as an area demand response response for the specific area R2 Power consumption can be reduced at timing. For example, when the ice storage system 100 is provided in a large facility 200 such as a commercial facility having a plurality of stores, the ratio of the power consumption of the ice storage system 100 to the power consumption of the entire specific area R2 By reducing the power consumption of the ice heat storage system 100 at an appropriate timing, it is possible to effectively realize area demand response response for the specific area R2.

  In addition, in the ice heat storage system 100, the additional heat dissipation operation by the additional heat dissipation unit 4 is stopped in response to the stress request T from the outside G of the electric power company or the like, and the first operation mode and the second operation mode by the heat dissipation unit 3 are When performing operation switching to the state which performs the thermal radiation operation in both operation modes, the visit promotion information which urges visit to the facility 200 can be transmitted with respect to surrounding area R1. By making such a transmission and residents of the surrounding area R1 visiting the facility 200, it is possible to reduce the power consumption in the residences and facilities of the surrounding area R1, and it is useful for realizing area demand response. It becomes.

[Another embodiment]
(1) In the above embodiment, the first heat exchange unit 5 is disposed in front of the ice heat storage tank 2 in the flow direction of the second heat transfer fluid in the second circulation circuit 20, and the first heat transfer fluid and ice are The second heat transfer fluid before being supplied to the heat storage tank 2 is subjected to heat exchange. Instead of this, as shown in FIG. 6, the first heat exchange unit 5 is disposed in front of the second heat exchange unit 6 in the flow direction of the fluid H to be dissipated in the air conditioning side circuit 30, and the first heat transfer It is also possible to heat exchange the fluid and the second heat transfer fluid before being supplied to the second heat exchange unit 6.

(2) In the above embodiment, in order to determine whether the first operation switching condition is satisfied, in addition to the additional heat dissipation operation by the additional heat dissipation unit 4, the heat dissipation operation in the second operation mode by the heat dissipation unit 3 is Although it has been performed, the heat radiation operation by the heat radiation unit 3 is not limited to the second operation mode, and may be the first operation mode. That is, to determine whether or not the first operation switching condition is satisfied, in addition to the additional heat dissipation operation by the additional heat dissipation unit 4, the heat dissipation unit 3 in one of the first operation mode and the second operation mode As long as the heat release operation is performed.

  The present invention is applicable to various ice heat storage systems capable of realizing demand response handling for an area including a facility having an ice heat storage system.

DESCRIPTION OF SYMBOLS 1 cold heat source 2 ice thermal storage tank 2a heat transfer tube 3 heat radiating part 4 additional heat radiating part 5 1st heat exchange part 6 2nd heat exchange part 10 1st circulation circuit 20 2nd circulation circuit 41 2nd circulation circuit 41 ice thermal storage system 200 facility N1 1st 1 heat transfer fluid N 2 second heat transfer fluid H heat dissipation target fluid R 1 peripheral area R 2 specific area G outside

Claims (4)

An ice storage tank that produces ice around a heat transfer tube and stores cold heat from a cold heat source,
A heat dissipation unit that performs a heat dissipation operation to dissipate the cold heat stored in the ice heat storage tank to the fluid to be dissipated;
And an additional heat radiation unit for performing an additional heat release operation to release the cold heat from the cold heat source to the heat radiation target fluid,
The heat dissipation unit may perform the heat dissipation operation as follows:
A first operation mode in which a first heat transfer fluid is supplied to the inside of the heat transfer tube in the ice heat storage tank, ice is melted from the inside of the heat transfer tube, and cold heat taken out is dissipated to the fluid to be dissipated;
A second heat transfer fluid is supplied to the outside of the heat transfer tube in the ice heat storage tank, and ice is melted from the outside and the cold heat taken out is dissipated to the fluid to be dissipated Is feasible and
When the heat dissipation unit is performing a heat dissipation operation in one of the first operation mode and the second operation mode, and the additional heat dissipation unit is performing the additional heat dissipation operation, When the operation switching condition is satisfied, the additional heat dissipation unit is stopped, and the heat dissipation unit is configured to perform the heat dissipation operation in both the first operation mode and the second operation mode,
In the first operation switching condition, the power consumption in a specific area including the facility having the ice storage system is expected to exceed the set power which is set as the demand response corresponding to the specific area. It is set to the condition that becomes the timing ,
A first heat exchange unit that exchanges heat between the first heat transfer fluid and the second heat transfer fluid before being supplied to the ice heat storage tank;
A second heat exchange unit for exchanging heat between the second heat transfer fluid and the heat radiation target fluid;
The heat dissipation unit performs a heat dissipation operation in the first operation mode by heat exchange in the first heat exchange unit and heat exchange in the second heat exchange unit, and heat exchange in the second heat exchange unit. It is comprised so that the thermal radiation driving | operation in said 2nd driving | running mode may be performed,
The said ice addition thermal storage part is an ice thermal storage system comprised so that the said additional heat dissipation operation | movement may be performed by the heat exchange in a said 1st heat exchange part, and the heat exchange in a said 2nd heat exchange part .   The receiving unit is provided to receive from the outside a stress request predicted that the power consumption in the specific area exceeds the set power amount, and the first operation switching condition is satisfied based on the stress request received by the receiving unit. The ice heat storage system according to claim 1, wherein it is determined whether or not it is stored. A first circulation circuit that circulates the first heat transfer fluid by selecting one of the cold heat source, the ice heat storage tank, and the first heat exchange unit that allows the first heat transfer fluid to flow therethrough;
A second circulation circuit that circulates the second heat transfer fluid by selecting one of the ice heat storage tank, the first heat exchange unit, and the second heat exchange unit that allows the second heat transfer fluid to flow; Is equipped with
The heat dissipation unit switches the first circulation circuit to a state in which the first heat transfer fluid is circulated between the ice heat storage tank and the first heat exchange unit, and the heat storage tank and the first heat exchange Switching the second circulation circuit to a state in which the second heat transfer fluid is circulated between the second heat exchange unit and the second heat exchange unit, and performing the heat release operation in the first operation mode;
The heat transfer operation is performed in the second operation mode by switching the second circulation circuit to a state in which the second heat transfer fluid is circulated between the ice heat storage tank and the second heat exchange unit.
The additional heat radiation unit switches the first circulation circuit to a state in which the first heat transfer fluid is circulated between the cold heat source and the first heat exchange unit, and the ice heat storage tank and the first heat exchange parts and switches the second circulation circuit in a state for circulating the second heat-carrying fluid between said second heat exchanger, according to claim 1 or 2 is configured to perform the additional radiating operation Ice storage system. Equipped in a commercial facility,
Since the heat dissipation unit performs the heat dissipation operation in one of the first operation mode and the second operation mode, and the additional heat dissipation unit is executing the additional heat dissipation operation, the additional heat dissipation unit When the operation of the heat release unit is switched to a state in which the heat release unit performs the heat release operation in both the first operation mode and the second operation mode, the store visits to the commercial facility with respect to the surrounding area is performed. The ice heat storage system according to any one of claims 1 to 3, which sends out store promotion information to promote .

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