JP6384320B2 - Temperature control system - Google Patents

Description

  The present invention relates to a temperature control system, and more particularly, to a temperature control system that performs a cooling operation using cold water.

  Conventionally, a temperature control system includes a thermoelectric valve header having a valve body, a plurality of nozzles, and an actuator for operating a valve provided in each nozzle. The thermoelectric valve header is composed of a plurality of thermal valves provided in parallel (see, for example, Japanese Patent Application Laid-Open No. 2003-329254 (Patent Document 1)). In the said temperature control system, warm water is distributed to the heating equipment connected to the some nozzle of the thermoelectric valve header.

JP 2003-329254 A

  By the way, in the said temperature control system, since a heat source is a heat exchanger of a water heater, it cannot perform a cooling operation by supplying cold water to a heat exchange terminal such as a floor panel.

  Therefore, a temperature control system that performs cooling operation using cold water supplied from a cold water supply unit has been considered.

  In such a temperature control system that performs the cooling operation, the thermal valve that opens and closes the flow path for supplying cold water to the heat exchange terminal has a configuration as shown in FIG. In FIG. 11, 600 is a spring, 601 is a valve body, 602 is a valve rod, 603 is a wax element, 604 is a heater, 605 is a valve seat, 606 is a port, 607 is a port, and 608 is an electric wire. The vicinity of the valve seat 605 is sealed with an O-ring 611, and the drawing port of the electric wire 608 is sealed with a seal member 612.

  However, in the thermal valve having the configuration shown in FIG. 11, moisture enters from the outside through the O-ring 611 and the seal member 612, and the heater 604 and the electric wire 608 in the thermal valve are connected by the cold heat of cold water. There is a problem in that dew condensation occurs on the connection electrodes and the like, causing the thermal valve to deteriorate or break.

  Accordingly, an object of the present invention is to provide a temperature control system capable of preventing deterioration or breakage of a thermal valve due to condensation during cooling operation.

In order to solve the above problems, the temperature control system of the present invention is:
A cold water supply unit;
A heat exchange terminal to which cold water from the cold water supply unit is supplied;
A thermal valve that opens and closes a flow path for supplying the cold water to the heat exchange terminal;
A controller for controlling the cold water supply unit and the thermal valve,
The control device is preset with anti-condensation energization after the cooling operation is stopped for the thermal valve that is not energized at least in the cooling operation for supplying the cold water from the cold water supply unit to the heat exchange terminal. It is characterized by being performed for a long time.

  According to the above configuration, in the cooling operation in which the cold water from the cold water supply unit is supplied to the heat exchange terminal, the control device preliminarily sets the condensation prevention energization for the thermal valve that was not energized during the cooling operation. By performing for a long time, the inside of the thermal valve can be heated and dried by the heater of the thermal valve, and deterioration and breakage of the thermal valve due to condensation can be prevented.

In the temperature control system of one embodiment,
The control device performs the dew condensation prevention energization for a preset time after the cooling operation is stopped even for the thermal valve that has been energized in the cooling operation.

  According to the above-described embodiment, after stopping the cooling operation for supplying cold water from the cold water supply unit to the heat exchange terminal, the control device preliminarily sets dew condensation prevention energization for the thermal valve that was energized in the cooling operation. Therefore, the inside of the thermal valve can be heated and dried by the heater of the thermal valve, and deterioration and breakage of all the thermal valves can be reliably prevented.

In the temperature control system of one embodiment,
A pump for supplying the cold water from the cold water supply unit to the heat exchange terminal via the flow path;
The control device performs the dew condensation prevention energization for the thermal valve that is not energized at least in the cooling operation after stopping the pump by stopping the cooling operation.

  According to the above embodiment, after the pump is stopped by stopping the cooling operation, dew condensation prevention energization is performed on the thermal valve, so that the cold valve no longer flows through the flow path near the thermal valve, and the heater of the thermal valve Is turned on, the inside of the thermal valve can be heated without being affected by cold water, and the temperature inside the thermal valve can be reliably raised and dried.

In the temperature control system of one embodiment,
When the cooling operation continues for a preset operation time, the control device performs the dew condensation prevention energization for the thermal valve that is not energized at least in the cooling operation.

  According to the above embodiment, when the cooling operation continues for a preset operation time, the control device performs dew condensation prevention energization on the thermal valve that is not energized at least in the cooling operation. Even in the case of cooling operation, the inside of the thermal valve can be dried by heating the inside of the thermal valve with the heater of the thermal valve every operating time.

In the temperature control system of one embodiment,
When the cooling operation continues for the preset operation time, the control device temporarily stops the cooling operation, and prevents the dew condensation on the thermal valve that is not energized at least in the cooling operation. Energize.

  According to the above-described embodiment, when the cooling operation continues for a preset operation time, the control device temporarily stops the cooling operation, and at the same time, the condensation prevention is performed on the thermal valve that is not energized in the cooling operation. Since electricity is applied, for example, even in the case of cooling operation continuously for 24 hours, since the cooling operation is temporarily stopped, it is necessary to energize the heaters of the thermal valve without chilled water flowing through all the thermal valves. Thus, the inside of the thermal valve can be heated without being affected by cold water, and the temperature inside the thermal valve can be reliably increased and dried.

  As is apparent from the above, according to the present invention, it is possible to realize a temperature control system that can prevent deterioration or breakage of a thermal valve due to condensation during cooling operation.

FIG. 1 is a schematic configuration diagram of a temperature control system according to a first embodiment of the present invention. FIG. 2 is a timing chart for explaining the operation of the temperature control system. FIG. 3 is a timing diagram for explaining the operation of the temperature control system of the first comparative example. FIG. 4 is a timing chart for explaining the operation of the temperature control system of the second comparative example. FIG. 5 is a schematic configuration diagram of a modified example of the temperature control system. FIG. 6 is a timing chart for explaining the operation of the temperature control system according to the second embodiment of the present invention. FIG. 7 is a timing chart for explaining the operation of the temperature control system according to the third embodiment of the present invention. FIG. 8 is a timing chart for explaining the operation of the temperature control system according to the fourth embodiment of the present invention. FIG. 9 is a timing chart for explaining the operation of the temperature control system according to the fifth embodiment of the present invention. FIG. 10 is a schematic configuration diagram of a temperature control system according to a sixth embodiment of the present invention. FIG. 11 is a cross-sectional view of the thermal valve.

  Hereinafter, the temperature control system of the present invention will be described in detail with reference to the illustrated embodiments.

[First Embodiment]
FIG. 1 shows a schematic configuration diagram of a temperature control system according to a first embodiment of the present invention.

[Overall configuration of temperature control system]
The temperature control system includes an outdoor unit 100, a cold / hot water supply unit 200 connected to the outdoor unit 100, and first to eighth floor air-conditioning / cooling units as an example of a heat exchange terminal connected to the cold / hot water supply unit 200. Panels P1-P8 are provided.

[Configuration of outdoor unit 100]
The outdoor unit 100 includes a compressor 101, a four-way switching valve 102, an outdoor heat exchanger 103, an electric expansion valve 104, and an accumulator 105. One end of the outdoor expansion heat exchanger 103 is connected to one end of the electric expansion valve 104, and the other end of the water heat exchanger 201 of the cold / hot water supply unit 200 is connected to the other end of the electric expansion valve 104. . Further, the first port 102 a of the four-way switching valve 102 is connected to the discharge side of the compressor 101. Further, the second port 102 b of the four-way switching valve 102 is connected to the other end of the outdoor heat exchanger 103. The third port 102 c of the four-way switching valve 102 is connected to the suction side of the compressor 101 via the accumulator 105. The fourth port 102d of the four-way switching valve 102 is connected to one end of the water heat exchanger 201 on the cold / hot water supply unit 200 side. The water heat exchanger 201 is a plate type water heat exchanger.

  The outdoor unit 100 and the water heat exchanger 201 of the cold / hot water supply unit 200 constitute a cold water supply unit.

  During the heating operation, the four-way switching valve 102 is switched to the solid line switching position so that the first port 102a and the fourth port 102d communicate with each other, and the second port 102b and the third port 102c communicate with each other. .

  On the other hand, during the cooling operation, the four-way switching valve 102 is switched to the dotted line switching position so that the first port 102a and the second port 102b communicate with each other and the third port 102c and the fourth port 102d are connected to each other. Communicate.

  The outdoor unit 100 is detected by the first to fourth temperature sensors 106 to 109, the outdoor temperature sensor 110, and the refrigerant temperature and the outdoor temperature sensor 110 detected by the first to fourth temperature sensors 106 to 109. And an outdoor unit control device 120 that receives a signal representing the outdoor temperature. The first to fourth temperature sensors 106 to 109 and the outdoor temperature sensor 110 are, for example, thermistors.

  The first temperature sensor 106 detects the temperature of the refrigerant between the electric expansion valve 104 and the water heat exchanger 201. The second temperature sensor 107 detects the temperature of the refrigerant between the fourth port 102 d of the four-way switching valve 102 and the water heat exchanger 201. The third temperature sensor 108 detects the temperature of the refrigerant between the compressor 101 and the first port 102a of the four-way switching valve 102. The fourth temperature sensor 109 is attached to the outdoor heat exchanger 103 in order to detect the temperature of the refrigerant in the outdoor heat exchanger 103. The outdoor temperature sensor 110 is disposed in the vicinity of the outdoor heat exchanger 103 in order to detect the outdoor temperature.

  The outdoor unit controller 120 controls the operating frequency of the compressor 101 through an inverter (not shown). The outdoor unit control device 120 also controls the opening degree of the electric expansion valve 104 so that the heat exchange efficiency of the water heat exchanger 201 and the outdoor heat exchanger 103 is optimized.

  Moreover, the refrigerant circuit is comprised by connecting the said outdoor heat exchanger 103, the compressor 101, the water heat exchanger 201, and the electric expansion valve 104 cyclically | annularly.

  Although not shown, an outdoor fan is disposed in the vicinity of the outdoor heat exchanger 103. This outdoor fan blows air to the outdoor heat exchanger 103.

  When the compressor 101 is operated with the four-way switching valve 102 set to the dotted line switching position during the cooling operation by the outdoor unit controller 120, the high-temperature and high-pressure refrigerant discharged from the compressor 101 is transferred to the outdoor heat exchanger 103. After condensation, the pressure is reduced by the electric expansion valve 104, condensed by the water heat exchanger 201, and returned to the suction side of the compressor 101 via the accumulator 105. At this time, heat exchange between the refrigerant and water is performed in the water heat exchanger 201 functioning as an evaporator, and cold water having a desired temperature is generated.

  On the other hand, when the compressor 101 is operated with the four-way switching valve 102 in the solid line switching position during the heating operation, the high-temperature and high-pressure refrigerant discharged from the compressor 101 is condensed in the water heat exchanger 201 and then the electric expansion valve. The pressure is reduced at 104 and evaporated by the outdoor heat exchanger 103, and returns to the suction side of the compressor 101 via the accumulator 105. At this time, heat exchange between the refrigerant and water is performed in the water heat exchanger 201 functioning as a condenser, and hot water having a desired temperature is generated.

[Configuration of Cold / Hot Water Supply Unit 200]
The cold / hot water supply unit 200 includes a water heat exchanger 201, an expansion tank 202, a circulation pump 203, a forward header 204, and a return header 205.

  The water heat exchanger 201 functions as an evaporator during cooling operation and functions as a condenser during heating operation. Further, the water heat exchanger 201 is provided with a flow path through which a refrigerant from the outdoor unit 100 flows and a flow path through which return water from the first to eighth floor cooling / heating panels P1 to P8 flows.

  The expansion tank 202 has a positive / negative pressure valve, and cold water (or hot water) from the water heat exchanger 201 is accumulated therein. In addition, a water supply port 202a is provided in the upper portion of the expansion tank 202, and water is replenished into the expansion tank 202 from the water supply port 202a when necessary.

  The circulation pump 203 is connected to the expansion tank 202 on the suction side and connected to the forward header 204 on the discharge side. Thereby, the circulation pump 203 can send the cold water (or hot water) heat-exchanged with the refrigerant | coolant which passes the water heat exchanger 201 to the 1st-8th floor air conditioning panel P1-P8.

  The forward header 204 is connected to one end of the first to eighth thermal valves V1 to V8 and one end of the drain plug V9. Water inlets of the first to eighth floor cooling / heating panels P1 to P8 are connected to the other ends of the first to eighth thermal valves V1 to V8. The first to eighth thermal valves V1 to V8 open and close flow paths for supplying cold water (or hot water) to the first to eighth floor cooling and heating panels P1 to P8.

  The first to eighth thermal valves V1 to V8 control the flow of cold water (or hot water). More specifically, the first to eighth thermal valves V1 to V8 are controlled by the controller for cold / hot water supply unit 220 and perform opening / closing operations corresponding to the cooling / heating capacity settings of the first to eighth floor cooling / heating panels P1 to P8. Do.

  The return header 205 is connected to water outlets of the first to eighth floor cooling / heating panels P1 to P8. Thereby, the cold water (or hot water) of the 1st-8th floor air conditioning panel P1-P8 returns to the cold / hot water supply unit 200, and can circulate through the water circuit 211 now.

  In the first embodiment, the first to eighth thermal valves V1 to V8 may be individually attached to the forward header 204, or the header and a plurality of thermal valves may be integrated. However, the cold water flowing through the flow path through the open thermal valve has a great influence on other closed thermal valves.

  The cold / hot water supply unit 200 includes first and second water temperature sensors 212 and 213, a refrigerant temperature sensor 214, a refrigerant pressure sensor 215, and a cold / hot water supply unit controller 220. The first and second water temperature sensors 212 and 213 and the refrigerant temperature sensor 214 are, for example, thermistors.

  The first water temperature sensor 212 detects the temperature of the cold water (or hot water) flowing from the expansion tank 202 toward the forward header 204 and sends a signal representing this temperature to the cold / hot water supply unit controller 220.

  The second water temperature sensor 213 detects the temperature of cold water (or hot water) flowing from the return header 205 toward the water heat exchanger 201 and sends a signal representing this temperature to the cold / hot water supply unit controller 220.

  The refrigerant temperature sensor 214 is disposed in the vicinity of the refrigerant pipe and the water heat exchanger 201 that connect the electric expansion valve 104 and the other end of the water heat exchanger 201. The refrigerant temperature sensor 214 detects the temperature of the refrigerant between the electric expansion valve 104 and the water heat exchanger 201, and sends a signal representing this temperature to the controller for cold / hot water supply unit 220.

  The refrigerant pressure sensor 215 is disposed in the vicinity of the refrigerant pipe and the water heat exchanger 201 that connect the four-way switching valve 102 and one end of the water heat exchanger 201. The refrigerant pressure sensor 215 detects the pressure of the refrigerant between the fourth port 102d of the four-way switching valve 102 and the water heat exchanger 201, and sends a signal indicating this pressure to the controller for cold / hot water supply unit 220. Send it out.

  The controller for cold / hot water supply unit 220 receives a signal representing the cooling / heating capacity setting of the first to eighth floor cooling / heating panels P1 to P8 from a remote controller (not shown). Moreover, the control apparatus 220 for cold / hot water supply units controls the circulation pump 203, the 1st-8th thermal valve V1-V8, etc. based on the signal from a remote controller, etc.

  The cold / hot water supply unit controller 220 is connected to the outdoor unit controller 120 via a signal line (not shown), and the outdoor unit controller 120 and the cold / hot water supply unit controller 220 are connected to each other. Operate cooperatively. The cold / hot water supply unit controller 220 controls the cold water supply unit (the outdoor unit 100 and the water heat exchanger 201) and the first to eighth thermal valves V1 to V8. It is an example.

  The communication between the outdoor unit control device 120 and the cold / hot water supply unit control device 220 may be wired or wireless.

[Configuration of first to eighth floor cooling / heating panels P1 to P8]
The first to eighth floor cooling / heating panels P1 to P8 receive the supply of cold water (or hot water) via the first to eighth thermal valves V1 to V8 and perform cooling and heating of the temperature control zone. More specifically, the first to eighth floor cooling / heating panels P1 to P8 have first to eighth water circulation pipes 301 to 308 formed in a meandering shape. Cold water (or hot water) from the water heat exchanger 201 flows in the first to eighth water circulation pipes 301 to 308. Moreover, the edge part of the upstream of the 1st-8th water circulation pipes 301-308 forms the water inlet of the 1st-8th floor air conditioning panel P1-P8. Moreover, the downstream edge part of the 1st-8th water circulation pipes 301-308 forms the water outlet of the 1st-8th floor air conditioning panel P1-P8.

  Here, the said temperature control zone points out the space where cold heat or warm heat is supplied from the 1st-8th water circulation pipes 301-308.

  The cold / hot water supply unit controller 220 includes a microcomputer and an input / output circuit. As shown in FIG. 1, the cold / hot water supply unit controller 220 includes a water temperature control unit 220a that controls the temperature of cold water or hot water supplied to the first to eighth floor cooling / heating panels P1 to P8, A thermal valve control unit 220b that controls opening and closing of the eighth thermal valves V1 to V8 and a circulation pump control unit 220c that controls the circulation pump 203 are provided.

  The water temperature control unit 220a, the thermal valve control unit 220b, and the circulation pump control unit 220c are configured by software.

  FIG. 2 is a timing diagram for explaining the operation of the temperature control system, FIG. 3 is a timing diagram for explaining the operation of the temperature control system of the first comparative example, and FIG. 4 is a diagram of the second comparative example. The timing diagram for demonstrating operation | movement of a temperature control system is shown. In FIG. 2 to FIG. 4, for the sake of simplicity, the thermal valves V1 and V2 are systems that perform cooling operation, the thermal valve V3 is a system that does not perform cooling operation, and the other thermal valves V4 to V8 are omitted. doing.

  As shown in FIG. 2, in the cooling operation, when the operation signal is turned on, the thermal valves V1 and V2 of the system that performs the cooling operation are turned on, and the thermal valve V3 is kept in the off state.

  Next, after a predetermined time T1 (1 to 2 minutes in this embodiment) after the operation signal is turned on, the outdoor unit controller 120 turns on the compressor 101 (shown in FIG. 1) and the circulation pump controller 220c. As a result, the circulation pump 203 (shown in FIG. 1) is turned on. Here, the reason why the compressor 101 and the circulation pump 203 are delayed by the predetermined time T1 is to correct the delay until the thermal valves V1 and V2 are opened.

  Next, when the cooling operation is stopped and the operation signal is turned off, the outdoor unit control device 120 turns off the compressor 101 and the circulation pump 203, and turns off the thermal valves V1 and V2.

  Then, from the time when the compressor 101 and the circulation pump 203 are turned off, the thermal valve V3 of the system that is not in the cooling operation is turned on for a predetermined time T2 (5 to 10 minutes in this embodiment).

  According to the temperature control system having the above-described configuration, in the cooling operation of supplying the cold water generated by the water heat exchanger 201 of the cold / hot water supply unit 200 to the first to eighth floor cooling / heating panels P1 to P8 (heat exchange terminals), The heat valve control unit 220b performs dew condensation prevention energization for a predetermined time T2 on the heat valve V3 that is not energized during the cooling operation, so that heat is generated by a heater (not shown) of the heat valve V3. The inside of the valve operating valve V3 can be heated and dried, and deterioration and breakage of the heat operating valve V3 due to condensation can be prevented.

  In the first embodiment, dew condensation prevention energization is applied to the thermal valve V3 immediately after the compressor 101 and the circulation pump 203 are turned off. However, there is a time interval after the circulation pump 203 is turned off after the cooling operation is stopped. To prevent condensation.

  For the temperature control system of the first embodiment, as shown in FIG. 3, the heat valve V3 that is not energized in the cooling operation is not subjected to dew condensation prevention energization after the cooling operation is stopped. In one comparative example, the heat operated valve V3 of the system that is not in the cooling operation is cooled by the cold heat of the cold water flowing through the adjacent heat operated valves V1 and V2, the temperature of the heat operated valve V3 is decreased, and condensation is generated. The valve train V3 is deteriorated or damaged. This first comparative example is not the present invention.

  Further, as shown in FIG. 4, a second comparative example in which dew condensation prevention energization after the cooling operation is stopped is not applied to the thermal valve V3 that is not energized in the cooling operation (the circulation pump 203 and the thermal valve V1, In an example in which V2 is turned off by delay time T3), the thermal valve V3 of the system not performing the cooling operation is cooled by the cold heat of the cold water flowing through the adjacent thermal valves V1 and V2, and the temperature of the thermal valve V3 decreases. Condensation occurs and the thermal valve V3 deteriorates or is damaged. This second comparative example is not the present invention.

  In the first embodiment, the thermal valve V3 that is a system that does not perform the cooling operation may be one in which a heat exchange terminal such as a floor cooling / heating panel is not connected to the thermal valve that is not energized in the cooling operation.

  For example, as shown in FIG. 5, in the temperature control system in which the eighth floor cooling / heating panel P8 is not connected to the cold / hot water supply unit 200, the connection portion of the thermal valve V8 is closed by the stop cock 231, The connection portion of the return header 205 corresponding to V8 is closed by a stop cock 232.

[Second Embodiment]
FIG. 6 is a timing chart for explaining the operation of the temperature control system according to the second embodiment of the present invention. In addition, the temperature control system of this 2nd Embodiment has the structure same as the temperature control system of 1st Embodiment except the operation | movement of thermal valve V1, V2, and uses FIG.

  As shown in FIG. 6, in the cooling operation, when the operation signal is turned on, the thermal valves V1 and V2 of the system that performs the cooling operation are turned on, and the thermal valve V3 is kept in the off state.

  Next, after a predetermined time T1 (1 to 2 minutes in this embodiment) after the operation signal is turned on, the outdoor unit controller 120 turns on the compressor 101 (shown in FIG. 1) and the circulation pump controller 220c. As a result, the circulation pump 203 (shown in FIG. 1) is turned on. Here, the reason why the compressor 101 and the circulation pump 203 are delayed by the predetermined time T1 is to correct the delay until the thermal valves V1 and V2 are opened.

  Next, when the cooling operation is stopped and the operation signal is turned off, the outdoor unit control device 120 turns off the compressor 101 and the circulation pump 203.

  Then, from the time when the circulation pump 203 is turned off, the thermal valves V1 and V2 of the system that performs the cooling operation and the thermal valve V3 of the system that does not perform the cooling operation are turned on for a predetermined time T2 (in this embodiment, 5 to 10 minutes). .

  In the temperature control system having the above configuration, after stopping the cooling operation for supplying the cold water generated by the water heat exchanger 201 of the cold / hot water supply unit 200 to the thermal valves V1 and V2, the thermal valve controller 220b performs the cooling operation. Condensation prevention energization is performed for a predetermined period of time T2 with respect to the thermally operated valves V1 and V2 that are energized and the thermally operated valve V3 that is not energized. As in the case of the thermal valve V3, this allows the inside of the thermal valves V1 and V2 to be heated and dried by the heaters of the thermal valves V1 and V2, thereby reliably preventing deterioration and breakage of all the thermal valves. can do.

  In the second embodiment, the condensation prevention energization time of the thermal valves V1, V2, V3 is set to the same predetermined time T2, but the condensation prevention energization of the thermal valves V1, V2 energized in the cooling operation is performed. The time and the dew condensation prevention energization time of the thermally operated valve V3 that is not energized may be different.

[Third Embodiment]
FIG. 7 is a timing chart for explaining the operation of the temperature control system according to the third embodiment of the present invention. In addition, the temperature control system of this 3rd Embodiment has the same structure as the temperature control system of 1st Embodiment except operation | movement of the thermal valve control part 220b, and uses FIG.

  As shown in FIG. 7, in the cooling operation, when the operation signal is turned on, the thermal valves V1 and V2 of the system that performs the cooling operation are turned on, and the thermal valve V3 remains off.

  Next, after a predetermined time T1 (1 to 2 minutes in this embodiment) after the operation signal is turned on, the outdoor unit controller 120 turns on the compressor 101 (shown in FIG. 1) and the circulation pump controller 220c. As a result, the circulation pump 203 (shown in FIG. 1) is turned on. Here, the reason why the compressor 101 and the circulation pump 203 are delayed by the predetermined time T1 is to correct the delay until the thermal valves V1 and V2 are opened.

  Next, when the cooling operation is stopped and the operation signal is turned off, the compressor 101 is turned off by the outdoor unit controller 120, and then the circulation pump 203 is turned off by the circulation pump control unit 220c after a predetermined time T3 from the turning off of the operation signal. To do.

  Then, from the time when the circulation pump 203 is turned off, the thermal valves V1 and V2 of the system that performs the cooling operation and the thermal valve V3 of the system that does not perform the cooling operation are turned on for a predetermined time T2 (in this embodiment, 5 to 10 minutes). . It should be noted that the thermal valve V3 may be turned on slightly before the circulation pump 203 is turned off (after the operation signal is turned off).

  In the temperature control system configured as described above, the compressor 101 and the circulation pump 203 are stopped by stopping the cooling operation, and then the T2 energization is performed for a predetermined period of time to the thermal valve V3. Since the heater of the thermal valve V3 is turned on after no longer flows, the interior of the thermal valve V3 can be heated without being affected by cold water, and the temperature in the thermal valve V3 can be reliably increased and dried. .

[Fourth Embodiment]
FIG. 8 is a timing chart for explaining the operation of the temperature control system according to the fourth embodiment of the present invention. In addition, the temperature control system of this 4th Embodiment is carrying out the structure same as the temperature control system of 1st Embodiment except operation | movement of the thermal valve control part 220b, and uses FIG.

  As shown in FIG. 8, in the cooling operation, when the operation signal is turned on, the heat valves V1 and V2 of the system performing the cooling operation are turned on, and the heat valve V3 is kept off.

  Next, after a predetermined time T1 (1 to 2 minutes in this embodiment) after the operation signal is turned on, the outdoor unit controller 120 turns on the compressor 101 (shown in FIG. 1) and the circulation pump controller 220c. As a result, the circulation pump 203 (shown in FIG. 1) is turned on. Here, the reason why the compressor 101 and the circulation pump 203 are delayed by the predetermined time T1 is to correct the delay until the thermal valves V1 and V2 are opened.

  Next, when the cooling operation is continued for a predetermined operation time T4 (for example, 6 hours), the thermal valve V3 of the system not performing the cooling operation is turned on for a predetermined time T2 (in this embodiment, 5 minutes to 10 minutes).

  Next, when the cooling operation is stopped and the operation signal is turned off, the compressor 101 is turned off by the outdoor unit controller 120, and then the circulation pump 203 is turned off by the circulation pump control unit 220c after a predetermined time T3 from the turning off of the operation signal. To do.

  Then, from the time point when the circulation pump 203 is turned off, the thermal valves V1 and V2 of the system that performs the cooling operation and the thermal valve V3 of the system that does not perform the cooling operation are turned on for a predetermined time T2 (5 to 10 minutes in this embodiment). . The thermal valve V3 may be turned on before the circulation pump 203 is turned off (after the operation signal is turned off).

  In the temperature control system having the above-described configuration, when the cooling operation continues for a predetermined operation time T4 (for example, 6 hours), the thermal valve control unit 220b performs dew condensation prevention energization for the thermal valve V3 that is not energized in the cooling operation. Is performed for a preset time. Thereby, for example, even in the case of cooling operation continuously for 24 hours, the inside of the thermal valve V3 can be dried by heating the inside of the thermal valve V3 by the heater of the thermal valve V3.

  In this 4th Embodiment, since cold water will flow with respect to thermal valve V3 by dew condensation prevention electricity supply during air_conditionaing | cooling operation, it is preferable to apply when a little cold water may flow during dew condensation prevention electricity supply.

  Note that dew condensation prevention energization may also be performed on the thermal valve that has been energized in the cooling operation.

[Fifth Embodiment]
FIG. 9 is a timing chart for explaining the operation of the temperature control system according to the fifth embodiment of the present invention. In addition, the temperature control system of this 5th Embodiment is carrying out the structure same as the temperature control system of 1st Embodiment except the operation | movement of the thermal valve control part 220b, and uses FIG.

  As shown in FIG. 9, in the cooling operation, when the operation signal is turned on, the heat valves V1 and V2 of the system performing the cooling operation are turned on, and the heat valve V3 is kept off.

  Next, after a predetermined time T1 (1 to 2 minutes in this embodiment) after the operation signal is turned on, the outdoor unit controller 120 turns on the compressor 101 (shown in FIG. 1) and the circulation pump controller 220c. As a result, the circulation pump 203 (shown in FIG. 1) is turned on. Here, the reason why the compressor 101 and the circulation pump 203 are delayed by the predetermined time T1 is to correct the delay until the thermal valves V1 and V2 are opened.

  Next, when the cooling operation is continued for a predetermined operation time T4 (for example, 6 hours), the thermal valve V3 of the system not performing the cooling operation is turned on for a predetermined time T2 (in this embodiment, 5 minutes to 10 minutes). Here, the compressor 101 and the circulation pump 203 are turned off while the thermal valve V3 is turned on. Note that the heat valve V3 may be turned on slightly before the time when the compressor 101 and the circulation pump 203 are turned off.

  Next, when the cooling operation is stopped and the operation signal is turned off, the compressor 101 is turned off by the outdoor unit controller 120, and then the circulation pump 203 is turned off by the circulation pump control unit 220c after a predetermined time T3 from the turning off of the operation signal. To do.

  Then, from the time when the circulation pump 203 is turned off, the thermal valves V1 and V2 of the system that performs the cooling operation and the thermal valve V3 of the system that does not perform the cooling operation are turned on for a predetermined time T2 (in this embodiment, 5 to 10 minutes). . The thermal valve V3 may be turned on before the circulation pump 203 is turned off (after the operation signal is turned off).

  In the temperature control system configured as described above, when the cooling operation continues for a predetermined operation time, the thermal valve control unit 220b temporarily stops the cooling operation, and the thermal valve V3 that has not been energized in the cooling operation is temporarily stopped. For a predetermined operating time (for example, 6 hours). Thus, for example, in the case of cooling operation continuously for 24 hours, the cooling operation is temporarily stopped every predetermined operation time (for example, 6 hours) for preventing condensation, and the thermal valve V3 in a state in which no cold water flows. By applying dew condensation prevention energization, the inside of the thermal valve V3 can be heated without being affected by cold water, and the temperature inside the thermal valve V3 can be reliably increased and dried.

In addition, you may perform dew condensation prevention electricity supply also with respect to the thermally operated valves V1 and V2 which were supplied with electricity in the cooling operation.
[Sixth Embodiment]
FIG. 10 shows a schematic configuration diagram of a temperature control system according to a sixth embodiment of the present invention. The temperature control system of the sixth embodiment has the same configuration as the temperature control system of the first embodiment except for the cold / hot water supply unit 400 and the thermal valve unit 500, and the same components are the same. A reference number is attached.

[Overall configuration of temperature control system]
As shown in FIG. 10, the temperature control system includes an outdoor unit 100, a cold / hot water supply unit 400 connected to the outdoor unit 100, a thermal valve unit 500 connected to the cold / hot water supply unit 400, 1st-8th floor air conditioning panel P1-P8 as an example of the heat exchange terminal connected to the thermal valve unit 500 is provided.

  The temperature control system of the sixth embodiment is different from the temperature control system of the first embodiment in that it is separated into a cold / hot water supply unit 400 and a thermal valve unit 500.

[Configuration of cold / hot water supply unit 400]
The cold / hot water supply unit 400 has the same configuration as the cold / hot water supply unit 200 except that the first to eighth thermal valves V1 to V8, the forward header 204, and the return header 205 are not provided.

[Configuration of thermal valve unit 500]
The thermal valve unit 500 includes a thermal valve controller 240 that controls the first to eighth thermal valves V1 to V8, a forward header 204, and a return header 205. The thermal valve control device 240 performs transmission / reception with the cold / hot water supply unit controller 220 of the cold / hot water supply unit 400 via a communication line.

  In the first to sixth embodiments, the temperature control system that performs the heating operation and the cooling operation has been described. However, the present invention may be applied to a temperature control system that performs only the cooling operation. Moreover, you may apply this invention to the temperature control system provided with the indoor unit for air conditioning.

  Moreover, in the said 1st-6th embodiment, although the water temperature control part 220a, the thermal valve control part 220b, and the circulation pump control part 220c were comprised by software, the water temperature control part, the thermal valve control part, and the circulation At least one of the pump control units may be configured by hardware.

  Moreover, in the said 1st-6th embodiment, although the plate type water heat exchanger was used for the water heat exchanger 201 of the cold / hot water supply unit 200, other water heat exchanges, such as a double pipe type water heat exchanger, are used. A vessel may be used.

  In the first to sixth embodiments, a pressure switch may be provided instead of the refrigerant pressure sensor 215.

  In the first to sixth embodiments, the electric expansion valve 104 as the expansion mechanism is provided in the refrigerant circuit of the outdoor unit 100. However, for example, a capillary tube as an example of the expansion mechanism may be provided.

  In the first to sixth embodiments, at least one of the first to eighth floor cooling / heating panels P1 to P8 serving as a heat exchange terminal is used as a ceiling cooling / heating panel, a ceiling cooling panel, a ceiling heating panel, and a wall cooling / heating. You may replace with a heat exchange terminal, such as a panel, a wall cooling panel, a wall heating panel, or an indoor installation type radiator.

  Although specific embodiments of the present invention have been described, the present invention is not limited to the first to sixth embodiments, and can be implemented with various modifications within the scope of the present invention. For example, what combined suitably the content described in the said 1st-6th embodiment is good also as one Embodiment of this invention.

DESCRIPTION OF SYMBOLS 100 ... Outdoor unit 101 ... Compressor 102 ... Four-way selector valve 103 ... Outdoor heat exchanger 104 ... Electric expansion valve 105 ... Accumulator 106 ... First temperature sensor 107 ... Second temperature sensor 108 ... Third temperature sensor 109 ... Fourth Temperature sensor 110 ... Outdoor temperature sensor 120 ... Outdoor unit controller 200 ... Cold / hot water supply unit 201 ... Water heat exchanger 202 ... Expansion tank 203 ... Circulating pump 204 ... Outgoing header 205 ... Return header 211 ... Water circuit 212 ... First Water temperature sensor 213 ... second water temperature sensor 214 ... refrigerant temperature sensor 215 ... refrigerant pressure sensor 220 ... cold / warm water supply unit controller 220a ... water temperature control unit 220b ... thermal valve control unit 220c ... circulation pump control unit 240 ... thermal valve Control devices 301 to 308... 1st to 8th water circulation pipe 400... 00 ... Thermal valve unit V1 ... First thermal valve V2 ... Second thermal valve V3 ... Third thermal valve V4 ... Fourth thermal valve V5 ... Fifth thermal valve V6 ... Sixth thermal valve V7 ... 7th thermal valve V8 ... 8th thermal valve V9 ... Drain plug P1 ... 1st floor cooling / heating panel P2 ... 2nd floor cooling / heating panel P3 ... 3rd floor cooling / heating panel P4 ... 4th floor cooling / heating panel P5 ... 5th floor Air conditioning panel P6 ... 6th floor air conditioning panel P7 ... 7th floor air conditioning panel P8 ... 8th floor air conditioning panel

Claims (5)

A cold water supply section (100, 201);
Heat exchange terminals (P1 to P8) to which cold water from the cold water supply unit (100, 201) is supplied;
Thermal valves (V1 to V8) for opening and closing flow paths for supplying the cold water to the heat exchange terminals (P1 to P8);
The cold water supply unit (100, 201) and the control device (120, 220) for controlling the thermal valve (V1-V8),
The control device (120, 220) is the thermal valve (V1) that is not energized at least in the cooling operation for supplying the cold water from the cold water supply unit (100, 201) to the heat exchange terminals (P1 to P8). To V8), the dew condensation prevention energization is performed for a preset time after the cooling operation is stopped. In the temperature control system according to claim 1,
The control device (120, 220) performs the dew condensation prevention energization for a preset time after the cooling operation is stopped even for the thermal valves (V1 to V8) energized in the cooling operation. Temperature control system characterized by In the temperature control system according to claim 1 or 2,
A pump (203) for supplying the cold water to the heat exchange terminals (P1 to P8) through the flow path;
The controller (120, 220) stops the pump (203) by stopping the cooling operation, and then condenses the condensation on the thermal valves (V1 to V8) that are not energized at least in the cooling operation. A temperature control system characterized by preventing energization. In the temperature control system according to any one of claims 1 to 3,
When the cooling operation continues for a preset operation time, the control device (120, 220) is configured to prevent the dew condensation energization with respect to the thermal valves (V1 to V8) that are not energized at least in the cooling operation. Temperature control system characterized by performing. In the temperature control system according to claim 4,
When the cooling operation continues for the preset operation time, the control device (120, 220) temporarily stops the cooling operation, and at least the energized valve is not energized in the cooling operation ( A temperature control system characterized in that the dew condensation prevention energization is performed on V1 to V8).

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