JP6214492B2 - Heating system - Google Patents

Description

  The present invention relates to a heating device.

  Patent Document 1 discloses a heat pump, a tank, a heat pump path for circulating a heating medium between the tank and the heat pump, a heater that uses the heat of the heating medium, and a tank and heating. A heating path for circulating the heating medium between the machines, an HP circulation pump for circulating the heating medium in the heat pump path, and a pump different from the HP circulation pump, and heating heat in the heat pump path An anti-freezing pump that circulates the medium, a heating circulation pump that circulates the heating heat medium in the heating path, and a control device are provided. The control device is connected to a first power system that can be used only for a predetermined period and a second power system that can be used at all times. The heat pump and the HP circulation pump are operated by electric power from the first electric power system. The anti-freezing pump is operated by electric power from the second electric power system. The control device is designed to prevent freeze damage of the heat pump path by operating the antifreeze pump when the temperature falls below a predetermined temperature while the power from the first power system is shut off.

JP2013-142492A

  The heating device of Patent Document 1 includes both an HP circulation pump and an antifreezing pump in order to circulate the heating medium in the heat pump path.

  The present specification proposes a heating apparatus that can appropriately suppress freezing and breakage of a path through which a heating heat medium circulates.

  A heating device disclosed in the present specification includes a heat pump, a tank, a heater, a heat pump path, a heating path, a first circulation pump, a bypass path, a flow rate adjustment mechanism, a suppression mechanism, and a control device. And. The heat pump heats the heating medium using heat absorbed from the atmosphere. The tank stores a heating medium heated by a heat pump. The heater uses the heat of the heating medium for heating. The heat pump path is a path for circulating a heating heat medium between the tank and the heat pump. The heating path is a path for circulating a heating heat medium between the tank and the heater. The first circulation pump is provided in the heating path and circulates the heating heat medium. The bypass path connects the upstream side of the heater in the heating path and the upstream side of the heat pump in the heat pump path. The flow rate adjusting mechanism is provided in the bypass path, and changes the ratio of the flow rate of the heating heat medium passing through the heater and the flow rate of the heating heat medium passing through the bypass path by adjusting the opening degree. The suppression mechanism suppresses the heating medium introduced from the bypass path into the heat pump path from flowing into the tank. The control device adjusts the opening degree of the flow rate adjustment mechanism based on one or both of the temperature and the temperature of the heating medium so that at least a part of the heating medium in the heating path passes through the bypass path. A specific operation for operating the first circulation pump is executed.

  According to said structure, the heating apparatus can circulate the heating medium for heating in order of a heat pump path | route, a heating path | route, and a bypass path by performing specific operation. Since the suppression mechanism is provided, the heating medium introduced into the heat pump path from the bypass path does not flow into the tank. Therefore, the heat pump path is performed by performing a specific operation for operating the first circulation pump by adjusting the opening of the flow rate adjusting mechanism so that at least a part of the heating medium in the heating path passes through the bypass path. The heating heat medium in the inside and the heating path can be circulated. Therefore, according to said heating apparatus, the freezing breakage of the path | route through which the heating heat medium circulates can be suppressed appropriately.

The figure which shows the structure of the heating system 2 typically. The flowchart explaining the freezing prevention process which the heating system 2 performs.

  The main features of the embodiments described below are listed. The technical elements described below are independent technical elements and exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. Absent.

(Characteristic 1) It is preferable to further include a second circulation pump that is provided in the heat pump path and circulates the heating medium. The control device preferably performs the specific operation based on one or both of the temperature and the temperature of the heating medium when the second circulation pump cannot be operated.

  According to this configuration, even if the second circulation pump cannot be operated, the heating medium in the heat pump path and the heating path can be circulated by executing the specific operation. Moreover, since it is not necessary to provide a pump for the purpose of circulating the heating heat medium in the heat pump path in addition to the second circulation pump, the configuration of the heating apparatus is relatively simple. Therefore, according to said heating apparatus, the freezing breakage of the path | route through which the heat medium for heating circulates can be suppressed appropriately with a comparatively simple structure.

(Characteristic 2) It is preferable that a suppression mechanism is a check valve provided in the upstream of the connection part with a bypass path among heat pump paths.

  The check valve is a mechanical valve that does not require power supply. Therefore, since the electrical wiring etc. for operating a check valve are unnecessary, the structure of a heating apparatus can be simplified more.

(Characteristic 3) It is preferable that the heating device further includes a heat source device for heating the heating medium in the heating path on the upstream side of the heater by the heat generated by burning the fuel. When performing a specific operation, the control device preferably operates the heat source unit based on one or both of the air temperature and the temperature of the heating medium.

  According to this configuration, when the specific operation is performed, by operating the heat source unit, it is possible to circulate the high-temperature heating heat medium in the heat pump path and the heating path. Freezing breakage of the path through which the heating medium circulates can be more appropriately suppressed.

(Example)
As shown in FIG. 1, the heating system 2 according to this embodiment includes an HP (heat pump) unit 10, a tank unit 20, a heating unit 40, and a control device 70.

  The HP unit 10 includes a heat pump 12, an HP circulation pump 14, an HP forward pipe 16, an HP return pipe 18, and a tank upper pipe 80. In the heating system 2 of the present embodiment, the heat pump 12, the HP circulation pump 14, a part of the HP forward pipe 16, and a part of the HP return pipe 18 of the HP unit 10 are installed outdoors. It is assumed that

  The heat pump 12 includes a heat exchanger (not shown) that exchanges heat between the heating medium supplied from the HP forward pipe 16 and the refrigerant. In this embodiment, an antifreeze containing ethylene glycol or the like is used as the heating medium. In another example, water may be used as the heating medium. The heat exchanger includes a heat medium pipe through which a heating heat medium flows and a refrigerant pipe through which a refrigerant flows (not shown). Both ends of the heat transfer medium pipe are connected to the HP forward pipe 16 and the HP return pipe 18, respectively. A gas such as carbon dioxide or HFC (hydrofluorocarbon) can be used as the refrigerant flowing in the refrigerant pipe. In the present embodiment, the heating heat medium flowing through the HP forward pipe 16 exchanges heat with the refrigerant (high temperature and high pressure) in the refrigerant pipe (receives heat from the refrigerant) while passing through the heat medium pipe of the heat exchanger. ). The high-temperature heating medium after the heat exchange is sent to the HP return pipe 18. For efficient heat exchange, it is preferable that the heating medium in the heating medium pipe and the refrigerant in the refrigerant pipe flow in opposite directions (counter flow). Further, the heat pump 12 includes a temperature sensor 15. The temperature sensor 15 measures the outside air temperature.

  One end of the HP forward pipe 16 is connected to the lower part of the tank 22 (described later), and the other end is connected to the inlet side of the heat medium pipe of the heat pump 12. The HP forward pipe 16 sends the heating heat medium at the bottom of the tank 22 to the heat medium pipe of the heat pump 12. The HP forward pipe 16 includes a temperature sensor 39 that measures the temperature of the heating medium flowing through the HP forward pipe 16. In addition, the heating medium that flows from the first bypass path 90 into the HP forward pipe 16 flows into the tank 22 upstream of the connection portion with the first bypass path 90 (described later) in the HP forward pipe 16. A check valve 30 is provided to prevent this. The check valve 30 is a mechanical valve that does not require power supply.

  One end of the HP return pipe 18 is connected to the outlet side of the heat medium pipe of the heat pump 12, and the other end is connected to one end of the tank upper pipe 80 and one end of the heating forward pipe 42. Further, the HP return pipe 18 includes a temperature sensor 38 that measures the temperature of the heating heat medium flowing through the HP return pipe 18. The other end of the tank upper pipe 80 is connected to the upper part of the tank 22.

  In the example of FIG. 1, the HP circulation pump 14 is provided in the heat pump 12. By operating the HP circulation pump 14, the heating heat medium circulates between the heat pump 12 and the tank 22 through the HP forward pipe 16, the HP return pipe 18, and the tank upper pipe 80.

  The tank unit 20 includes a tank 22 and three temperature sensors 24, 26, and 28. The tank 22 stores the heating medium heated by the heat pump 12. The capacity of the tank 22 is, for example, 30L. The three temperature sensors 24, 26, and 28 are provided in this order from the bottom along the height direction of the tank 22. Each temperature sensor 24, 26, 28 measures the temperature of the heating heat medium in the tank 22.

  The heating unit 40 includes a heating forward pipe 42, a heating return pipe 44, a heating circulation pump 46, a burner 48, a heater 50, a second bypass path 60, and a mixing valve 62.

  One end of the heating forward pipe 42 is connected to the end of the tank upper pipe 80 and the end of the HP return pipe 18, and the other end is connected to the heater 50. The heating forward pipe 42 sends the heating heat medium sent from the upper part of the tank 22 to the heater 50. The heating forward pipe 42 further includes temperature sensors 52, 54, and 56 that measure the temperature of the heating heat medium flowing through the heating forward pipe 42.

  One end of the first bypass 90 is connected to the downstream side of the heating circulation pump 46 of the heating forward pipe 42, and the other end is connected to the downstream side of the check valve 30 and the temperature sensor 39 of the HP forward pipe 16. By providing the first bypass 90, part or all of the heating heat medium flowing through the heating forward pipe 42 can be returned to the HP forward pipe 16 without passing through the heater 50 and the tank 22.

  Further, a first thermal valve 91 for opening and closing the heating forward pipe 42 is provided on the downstream side of the connection portion with the first bypass path 90 in the heating forward pipe 42. The first bypass passage 90 is provided with a second thermal valve 92 for opening and closing the first bypass passage 90. The heating medium can be supplied to the heater 50 by opening the first thermal valve 91. The heating medium for heating can be supplied to the first bypass passage 90 by opening the second thermal valve 92. By adjusting the opening of the first thermal valve 91 and the opening of the second thermal valve 92, the flow rate of the heating medium passing through the heater 50 and the heating heat passing through the first bypass 90 are adjusted. The ratio of the flow rate of the medium can also be changed. In this embodiment, when the first thermal valve 91 is closed and the second thermal valve 92 is opened, the entire amount of the heating heat medium flowing through the heating forward pipe 42 passes through the first bypass 90. Conversely, when the first thermal valve 91 is opened and the second thermal valve 92 is closed, the entire amount of the heating heat medium flowing through the heating forward pipe 42 is supplied to the heater 50.

  The heater 50 performs heating using heat radiation from the heating medium supplied from the heating forward pipe 42. Due to the heat radiation, the temperature of the heating medium is lowered. The heating medium after heat radiation is sent to the heating return pipe 44.

  The burner 48 burns fuel such as city gas or LP gas, and heats the heating heat medium flowing in the heat medium forward pipe 42 by the combustion heat. The burner 48 is an auxiliary heat source that operates when the heating medium in the heating forward pipe 42 does not reach the temperature required by the heater 50.

  The heating return pipe 44 has one end connected to the heater 50 and the other end connected to the lower portion of the tank 22. The heating return pipe 44 sends the heating heat medium after heat radiation sent out from the heater 50 to the tank 22. The heating return pipe 44 further includes a temperature sensor 58 that measures the temperature of the heating medium (after heat radiation) that flows through the heating return pipe 44.

  The heating circulation pump 46 is provided in the middle of the heating forward pipe 42. By operating the heating circulation pump 46, the heating heat medium circulates through the heating forward pipe 42 and the heating return pipe 44.

  The second bypass path 60 is provided between the heating forward pipe 42 and the heating return pipe 44. The second bypass path 60 has one end connected to the upstream side of the heating circulation pump 46 of the heating forward pipe 42 and the other end connected to the heating return pipe 44. By providing the second bypass 60, part or all of the heating heat medium flowing through the heating return pipe 44 can be returned to the heating forward pipe 42 without going through the tank 22.

  A mixing valve 62 is provided at a portion where the heating return pipe 44 and the second bypass path 60 are connected. By adjusting the opening degree of the mixing valve 62, the ratio of the flow rate of the heating heat medium returned to the tank 22 and the flow rate of the heating heat medium passing through the second bypass passage 60 can be changed. In this embodiment, when the mixing valve 62 is fully closed, the entire amount of the heating heat medium flowing through the heating return pipe 44 passes through the second bypass path 60. When the mixing valve 62 is fully opened, the entire amount of the heating heat medium flowing through the heating return pipe 44 is supplied to the tank 22.

  By adjusting the opening degree of the mixing valve 62, for example, when the temperature of the heating heat medium sent to the heater 50 through the heating forward pipe 42 is too high, for heating after heat dissipation in the heating return pipe 44 The heat medium can be joined to the heating heat medium in the heating forward pipe 42 via the second bypass path 60, and the temperature of the heating heat medium sent to the heater 50 can be lowered. Further, for example, when heating operation is performed in a state where the high-temperature heating medium is not sufficiently stored in the tank 22, the heating medium after heat radiation in the heating return pipe 44 is not returned to the tank 22. The temperature of the heating medium in the tank 22 can be suppressed from decreasing by joining the heating medium in the heating forward pipe 42 via the second bypass 60.

  The control device 70 is electrically connected to the HP unit 10, the tank unit 20, and the heating unit 40, and controls the operation of each component of each unit 10, 20, 40. The control device 70 causes the heating system 2 of the present embodiment to perform various operations such as a heat storage operation, a heating operation, and an anti-freezing operation.

  Both the normal power system 72 and the snow melting power system 74 are provided by an electric power company. The normal power system 72 is a power system that can always be used. On the other hand, the snow melting power system 74 is a special power system that can be used mainly in the winter (October to May) in cold regions. Note that the electric power company stops supplying power to the snow melting power system 74 during a period when the snow melting power system 74 cannot be used (June to September). There is a rule that the use of power from the snow melting power system 74 is limited to heating purposes. Furthermore, in a period in which the snow melting power system 74 can be used, there is also a rule that it is necessary to provide a cut-off period for cutting off power during a predetermined time period (for example, from 16:00 to 21:00 every day). Yes. The blocking period needs to be provided for a total of 2 hours every day during a predetermined time period (for example, every day from 16:00 to 21:00). The blocking period is set in advance by the user. Therefore, the user can set, for example, 2 hours from 16:00 to 18:00 every day as the cutoff period. Moreover, in another example, you may provide the interruption | blocking period of 30 minutes intermittently 4 times between 16: 00-21: 00 every day. If a total of 2 hours of blocking period can be provided between 16:00 and 21:00 every day, the setting method of the blocking period can be arbitrary.

  As shown in FIG. 1, the snow melting power system 74 includes a timer 76. The timer 76 operates during a period during which the snow melting power system 74 can be used (October to May in the above example). If the timer 76 indicates that the snow melting power system 74 is available, the power supply is interrupted by a breaker (not shown), and the snow melting power system 74 is temporarily unavailable. Become (blocked).

  In the present embodiment, the heat pump 12, the HP circulation pump 14, and the mixing valve 62 operate by receiving power supply from the snow melting power system 74. Therefore, when the cutoff period of the snow melting power system 74 starts, the heat pump 12, the HP circulation pump 14, and the mixing valve 62 cannot operate. The control device 70, the heating circulation pump 46, the burner 48, the heater 50, the first thermal valve 91, and the second thermal valve 92, which are other elements, receive power supply from the normal power system 72. Operate. Therefore, the control device 70, the heating circulation pump 46, the burner 48, the heater 50, the first thermal valve 91, and the second thermal valve 92 can always operate.

  Next, the operation of the heating system 2 of the present embodiment will be described. The heating system 2 performs different operations in the usable period of the snow melting power system 74 and the interruption period of the snow melting power system 74. Hereinafter, the case where the snowmelt power system 74 is available and the period of interruption will be described separately.

(Operation during the usable period of the snow melting power system 74)
During the period in which the snow melting power system 74 can be used, the control device 70 of the heating system 2 can execute the freeze prevention operation, the heat storage operation, and the heating operation. Moreover, the control apparatus 70 of the heating system 2 performs the process immediately before interruption described later when the interruption period of the snow melting power system 74 starts 5 minutes before.

  In the freezing prevention operation during the usable period of the snow melting power system 74, the heating medium is circulated between the heat pump 12 and the tank 22 to prevent the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 from being frozen. It is driving to prevent. When the freeze prevention operation is instructed during the usable period of the snow melting power system 74, the control device 70 operates the heat pump 12 and the HP circulation pump 14. By operating the HP circulation pump 14, the heating heat medium circulates between the heat pump 12 and the tank 22 through the HP forward pipe 16, the HP return pipe 18, and the tank upper pipe 80. When a relatively high temperature heating medium is stored in the tank 22, a relatively high temperature heating medium is supplied to the heat pump 12, the HP forward pipe 16, and the HP return pipe 18. The freezing breakage of the 12, HP forward pipe 16 and the HP return pipe 18 is appropriately suppressed.

  Note that when the high temperature heating heat medium is not stored in the tank 22 when the freeze prevention operation is instructed, the control device 70 operates the heat pump 12 together with the HP circulation pump 14. That is, the control device 70 performs a heat storage operation. The heat storage operation is an operation in which the heating medium in the tank 22 is heated by the heat generated by the heat pump 12. As a result, the heating medium supplied from the HP forward pipe 16 to the heat pump 12 is heated by the heat generated by the heat pump 12 and returned to the upper part of the tank 22 through the HP return pipe 18 and the tank upper pipe 80. As a result, a high-temperature heating medium is stored in the tank 22. A layer of a high-temperature heating medium is formed in the upper part of the tank 22, and a layer of a low-temperature heating medium is formed in the lower part.

  When this heat storage operation is performed, a relatively high-temperature heating heat medium is stored in the tank 22, and as a result, the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 are heated for a relatively high temperature. Heat medium is supplied. Therefore, the freezing breakage of the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 is appropriately suppressed. In the present embodiment, even when the freeze prevention operation is not instructed, the control device 70 may perform the heat storage operation alone.

  In addition, when the freeze prevention operation is instructed, an operation different from the above freeze prevention operation is performed while the heating operation is being performed. The heating operation is an operation in which the room 50 is heated by operating the heater 50. When the heating operation is executed during the period when the snow melting power system 74 is available, the control device 70 operates the heat pump 12 and the HP circulation pump 14 together with the heating circulation pump 46. At this time, the control device 70 opens the first thermal valve 91 and closes the second thermal valve 92. Thereby, the heating medium circulates in the order of the tank 22, the HP forward pipe 16, the heat pump 12, the HP return pipe 18, the heating forward pipe 42, the heater 50, the heating return pipe 44, and the tank 22. The heating heat medium after being heated by the heat pump 12 is supplied to the heater 50 via the HP return pipe 18 and the heating forward pipe 42. The heater 50 heats the living room using the heat of the heating medium. During the heating operation, the heating medium flows from the heating return pipe 44 to the lower part of the tank 22, so that the heating heat medium flowing through the HP return pipe 18 is returned from the tank upper pipe 80 to the upper part of the tank 22. There is nothing. During the heating operation, the control device 70 controls the heat pump 12 so that the temperature of the heating medium supplied to the heater 50 (that is, the temperature detected by the temperature sensor 56) is maintained at a predetermined set temperature. Is activated. In addition, the control apparatus 70 can operate the burner 48, when the temperature of the heating heat medium supplied to the heater 50 is not enough. Further, when the temperature of the heating medium supplied to the heater 50 is not sufficient, the control device 70 opens at least a part of the heating medium that opens the mixing valve 62 and flows through the heating forward pipe 44. The ratio of the flow rate of the heating heat medium supplied to the tank 22 can also be reduced by passing through the second bypass path 60. In addition, when the temperature of the heating medium supplied to the heater 50 is too high, the control device 70 reduces the opening of the mixing valve 62 and out of the heating medium flowing through the heating forward pipe 44. The ratio of the flow rate of the heating heat medium supplied to the tank 22 can also be increased.

  Even when this heating operation is performed, the heating medium can be sufficiently circulated in the heat pump 12, the HP forward pipe 16, and the HP return pipe 18. Therefore, it is possible to appropriately suppress freezing and breakage of the heat pump 12, the HP forward pipe 16, and the HP return pipe 18. In the present embodiment, even when the freeze prevention operation is not instructed, the control device 70 may perform the heating operation alone.

  The process immediately before shutting off is a process of operating the mixing valve 62 before shutting off the snow melting power system 74 for heating operation and anti-freezing operation after the snow melting power system 74 is shut off. Specifically, the control device 70 constantly monitors that the cut-off period of the snow melting power system 74 is 5 minutes before the start, and when the cut-off period of the snow melting power system 74 is 5 minutes before, all the mixing valves 62 are turned on. Perform the closing process. As a result, the entire amount of the heating medium flowing through the heating return pipe 44 passes through the second bypass path 60. That is, the heating medium is not supplied to the tank 22.

(Operation during the interruption period of the snow melting power system 74)
After the above-described process immediately before the interruption, the interruption period of the snow melting power system 74 is started. As described above, the heat pump 12, the HP circulation pump 14, and the mixing valve 62 cannot be operated during the interruption period of the snow melting power system 74. Therefore, the heating system 2 can execute the heating operation and the freeze prevention process shown in FIG. 2 during the interruption period of the snow melting power system 74.

  When execution of the heating operation is instructed during the shut-off period, the control device 70 operates the heating circulation pump 46 and the burner 48. Further, the control device 70 opens the first thermal valve 91 and closes the second thermal valve 92. Further, the mixing valve 62 is fully closed in the operation immediately before the shut-off described above. In the heating operation during the shut-off period, the heat pump 12 and the HP circulation pump 14 are not operated. Thereby, the heating heat medium circulates in the order of the heating forward pipe 42, the heater 50, the heating return pipe 44, and the second bypass path 60. The heating medium after being heated by the combustion heat of the burner 48 is supplied to the heater 50. The heater 50 heats the living room using the heat of the heating medium.

  The anti-freezing process in FIG. 2 is a process for causing the anti-freezing operation to be executed during the interruption period of the snow melting power system 74. The control device 70 starts the anti-freezing process of FIG. 2 when the cutoff period of the snow melting power system 74 is started. As shown in FIG. 2, at the time when the anti-freezing process is started, the mixing valve 62 is fully closed by the process immediately before the shutoff.

  First, in S10, S12, and S16, the control device 70 determines which temperature range the outside air temperature belongs to. Here, the outside air temperature refers to the air temperature measured by the temperature sensor 15 provided in the heat pump 12.

(I) When the outside air temperature is higher than −9 ° C., the control device 70 determines YES in S10. In this case, the control device 70 does not execute the operation for preventing freezing of the heat pump 12, the HP outgoing pipe 16, and the HP return pipe 18 during the shut-off period (that is, does not execute the anti-freezing operation). This is because when the outside air temperature is higher than −9 ° C., the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 are less likely to be frozen and damaged during the shut-off period. Thereafter, when the interruption period ends (that is, when the usable period of the snow melting power system 74 starts), the process of FIG. 2 ends.

(II) When the outside air temperature is higher than −12 ° C. and lower than −9 ° C., the control device 70 determines YES in S12 and proceeds to S14. When the outside air temperature is higher than −12 ° C. and lower than −9 ° C., the heat pump 12, the HP outgoing pipe 16, and the HP return pipe 18 may be frozen and damaged during the shut-off period. Therefore, in S14, the control device 70 operates the heating circulation pump 46 and the burner 48, and opens and closes the second thermal valve 92 according to the period A in the table of FIG. 2 (that is, performs the freeze prevention operation). ). The operation mode of the heating circulation pump 46 and the burner 48 and the opening / closing cycle A of the second thermal valve 92 are set to determine whether the heating operation is being performed and the set hot water temperature when the heating operation is being performed. It changes depending on the situation.

  When the heating operation is not executed, in S14, the control device 70 operates the heating circulation pump 46 and the burner 48 for 10 minutes and then stops them for 10 minutes. That is, the control device 70 operates the heating circulation pump 46 and the burner 48 intermittently. The set temperature of the heating heat medium at this time is 40 ° C. That is, the control device 70 operates the burner 48 so that the temperature of the heating heat medium after heating becomes 40 ° C. Further, the control device 70 opens the second thermal valve 92 (ON in the figure) during 10 minutes during which the heating circulation pump 46 and the burner 48 are operated, and stops the heating circulation pump 46 and the burner 48. The second thermal valve 92 is closed during 10 minutes (OFF in the figure). During this time, since the heating operation is not executed, the first thermal valve 91 is closed. As a result, during the 10 minutes during which the heating circulation pump 46 and the burner 48 are operated, the high-temperature heating heat medium after being heated by the burner 48 passes through the first bypass passage 90 and passes through the HP outgoing pipe. 16 flows in. Since the high-temperature heating heat medium circulates in the HP outgoing pipe 16 and the HP return pipe 18, freezing damage to the heat pump 12, the HP outgoing pipe 16, and the HP return pipe 18 is suppressed.

  On the other hand, when the heating operation is being performed, in S14, the control device 70 operates the heating circulation pump 46 and the burner 48 continuously. In this case, the first thermal valve 91 is continuously opened. The set temperature of the heating heat medium at this time is set to each value of 40 ° C., 60 ° C., and 80 ° C. according to the required heat amount in the heater 50. That is, the control device 70 operates the burner 48 so that the temperature of the heating heat medium after heating becomes a set temperature (40 ° C., 60 ° C., 80 ° C.). When the set temperature is 40 ° C., in S14, the control device 70 opens the second thermal valve 92 for 15 minutes (ON in the figure) and then closes for 5 minutes (OFF in the figure). As described above, the high-temperature heating heat medium after being heated by the burner 48 flows into the HP forward pipe 16 through the first bypass 90 while the second thermal valve 2 is opened. . Since the high-temperature heating heat medium circulates in the heat pump 12, the HP forward pipe 16, and the HP return pipe 18, freezing damage to the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 is suppressed. When the set temperature is 60 ° C., in S14, the control device 70 opens the second thermal valve 92 for 10 minutes (ON in the figure) and then closes for 10 minutes (OFF in the figure). When the set temperature is 80 ° C., in S14, the controller 70 opens the second thermal valve 92 for 5 minutes (ON in the figure) and then closes for 15 minutes (OFF in the figure). The higher the set temperature is, the shorter the time for opening the second thermal valve 92 (ON in the figure) is that the heating medium supplied to the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 is heated. This is because the higher the temperature, the more effectively the effect of suppressing freezing breakage can be obtained even with a shorter period of circulation.

  After the start of the process of S14, when the interruption period ends (that is, when the usable period of the snow melting power system 74 starts), the process of FIG. 2 ends.

(III) When the outside air temperature is higher than −15 ° C. and lower than −12 ° C., the control device 70 determines YES in S16 and proceeds to S18. When the outside air temperature is higher than −15 ° C. and lower than −12 ° C., there is a high possibility that the heat pump 12, the HP outgoing pipe 16, and the HP return pipe 18 are frozen and damaged during the shut-off period. Therefore, in S18, the control device 70 operates the heating circulation pump 46 and the burner 48, and opens and closes the second thermal valve 92 according to the period B in the table of FIG. 2 (that is, performs the freeze prevention operation). ). The operation modes of the heating circulation pump 46 and the burner 48 and the opening / closing cycle B of the second thermal valve 92 are also set to the set hot water temperature when the heating operation is executed and when the heating operation is executed. It changes depending on the situation.

  When the heating operation is not executed, in S18, the control device 70 operates the heating circulation pump 46 and the burner 48 for 15 minutes and then stops them for 5 minutes. That is, the control device 70 operates the heating circulation pump 46 and the burner 48 intermittently. The set temperature of the heating heat medium at this time is 40 ° C. Further, the control device 70 opens the second thermal valve 92 (ON in the drawing) during 15 minutes during which the heating circulation pump 46 and the burner 48 are operated, and stops the heating circulation pump 46 and the burner 48. The second thermal valve 92 is closed for 5 minutes (OFF in the figure). During this time, the first thermal valve 91 is closed. As a result, during the 15 minutes when the heating circulation pump 46 and the burner 48 are operated, the high-temperature heating heat medium after being heated by the burner 48 passes through the first bypass 90 and passes through the HP forward pipe. 16 flows in. Since the high-temperature heating heat medium circulates in the heat pump 12, the HP forward pipe 16, and the HP return pipe 18, freezing damage to the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 is suppressed.

  On the other hand, when the heating operation is being performed, in S18, the control device 70 operates the heating circulation pump 46 and the burner 48 continuously. Further, the first thermal valve 91 is opened. The set temperature of the heating medium is set to 40 ° C., 60 ° C., and 80 ° C. according to the required heat amount in the heater 50. When the set temperature is 40 ° C., in S18, the control device 70 always opens the second thermal valve 92 (continuous ON). When the set temperature is 60 ° C., in S18, the controller 70 opens the second thermal valve 92 for 15 minutes (ON in the figure) and then closes for 5 minutes (OFF in the figure). When the set temperature is 80 ° C., in S18, the controller 70 opens the second thermal valve 92 for 10 minutes (ON in the figure) and then closes for 10 minutes (OFF in the figure). While the second thermal valve 92 is open, the hot heating medium heated by the burner 48 passes through the first bypass 90 and flows into the HP forward pipe 16. Therefore, freezing and breakage of the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 are suppressed.

  When the interruption period ends after the start of the process of S18 (that is, when the usable period of the snow melting power system 74 starts), the process of FIG. 2 ends.

  (IV) When the outside air temperature is −15 ° C. or lower, the control device 70 determines NO in S16, and proceeds to S20. When the outside air temperature is −15 ° C. or lower, the possibility that the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 are frozen and damaged during the shut-off period becomes very high. Therefore, in S20, the control device 70 operates the heating circulation pump 46 and the burner 48, and opens and closes the second thermal valve 92 according to the period C in the table of FIG. 2 (that is, performs the freeze prevention operation). ). The operation modes of the heating circulation pump 46 and the burner 48 and the opening / closing cycle C of the second thermal valve 92 are also set to whether or not the heating operation is being performed, and the set hot water temperature when the heating operation is being performed. It changes depending on the situation.

  When the heating operation is not executed, in S20, the control device 70 operates the heating circulation pump 46 and the burner 48 continuously. The set temperature of the heating heat medium at this time is 40 ° C. Further, the control device 70 always opens the second thermal valve 92 (continuous ON). The first thermal valve 91 is closed. As a result, while the heating circulation pump 46 and the burner 48 are operating, the high-temperature heating medium heated by the burner 48 passes through the first bypass path 90 and flows into the HP forward pipe 16. . Since the high-temperature heating heat medium circulates in the heat pump 12, the HP forward pipe 16, and the HP return pipe 18, freezing damage to the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 is suppressed.

  On the other hand, when the heating operation is being executed, in S20, the control device 70 operates the heating circulation pump 46 and the burner 48 continuously. The first thermal valve 91 is opened. The set temperature of the heating medium is set to 40 ° C., 60 ° C., and 80 ° C. according to the required heat amount in the heater 50. When the set temperature is 40 ° C., in S20, the control device 70 always opens the second thermal valve 92 (continuous ON). Even when the set temperature is 60 ° C., in S20, the control device 70 always opens the second thermal valve 92 (continuous ON). When the set temperature is 80 ° C., in S20, the controller 70 opens the second thermal valve 92 for 15 minutes (ON in the figure) and then closes for 5 minutes (OFF in the figure). While the second thermal valve 92 is closed, the hot heating medium heated by the burner 48 passes through the first bypass 90 and flows into the HP forward pipe 16. Therefore, freezing and breakage of the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 are suppressed.

  When the interruption period ends after the start of the process of S20 (that is, when the usable period of the snow melting power system 74 starts), the process of FIG. 2 ends.

  Heretofore, the configuration and operation details of the heating system 2 of the present embodiment have been described. In the present embodiment, in the heating system 2, the heating medium for the heating passes through the first bypass 90 based on the outside temperature during the shut-off period of the snow melting power system 74, which is a period in which the heat pump 12 and the HP circulation pump 14 are not available. The opening degree of the second thermal valve 92 is adjusted so as to pass, and the heating circulation pump 46 and the burner 48 are operated to perform the freeze prevention operation (S14, S18, S20 in FIG. 2). The heating system 2 performs the anti-freezing operation so that the heating medium is changed from the heating forward pipe 42, the first bypass 90, the HP forward pipe 16, the heat pump 12, the HP return pipe 18, the heating forward pipe 42, Can be circulated in this order. Therefore, even during the interruption period of the snow melting power system 74, the heating medium is circulated in the path including the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 by performing the freeze prevention operation. be able to. In addition to the HP circulation pump 14, it is not necessary to provide a pump for the purpose of circulating the heating heat medium in the heat pump 12, the HP forward pipe 16, and the HP return pipe 18. Easy. Therefore, according to the heating system 2 of a present Example, the freezing breakage of the path | route through which the heating heat medium circulates can be suppressed appropriately with a comparatively simple configuration.

  Further, in the heating system 2 of the present embodiment, the check valve 30 that prevents the heating heat medium flowing into the HP forward pipe 16 from the first bypass passage 90 from flowing into the tank 22 is provided in the HP forward pipe 16. Is intervening. The check valve 30 is a mechanical valve that does not require power supply. Therefore, since the electrical wiring etc. for operating a check valve are unnecessary, the structure of the heating system 2 can be simplified more.

  In this embodiment, the burner 48 is operated together with the heating circulation pump 46 when the freeze prevention operation is executed during the shut-off period (S14, S18, S20 in FIG. 2). As a result, the circulating heating medium can be heated to a high temperature. Freezing breakage of the path through which the heating medium circulates can be more appropriately suppressed.

  Here, the correspondence between the description of the embodiment and the description of the claims will be described. The HP forward pipe 16 and the HP return pipe 18 are examples of the “heat pump path”. The HP circulation pump 14 is an example of a “second circulation pump”. The heating forward pipe 42 and the heating return pipe 44 are examples of the “heating path”. The heating circulation pump 46 is an example of a “first circulation pump”. The first bypass path 90 is an example of a “bypass path”. The first thermal valve 91 and the second thermal valve 92 are examples of the “flow rate adjusting mechanism”. The check valve 30 is an example of a “suppression mechanism”. The freeze prevention operation performed in S14, S18, and S20 in FIG. 2 is an example of the “specific operation”. The burner 48 is an example of a “heat source machine”.

  Each embodiment has been described in detail above, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above.

(Modification 1) In said Example, when the snowmelt electric power system 74 is interrupted | blocked, the control apparatus 70 opens the 2nd thermal valve 92 based on external temperature (namely, 1st bypass path). 90, at least a part of the heating medium is supplied), and the anti-freezing operation is executed by operating the heating circulation pump 46 and the burner 48 (S14, S18, S20 in FIG. 2). On the other hand, the reason why the heat pump 12 and the HP circulation pump 14 cannot be used is not limited to the interruption of the snow melting power system 74 but may be another cause such as a failure of the heat pump 12 and the HP circulation pump 14. Even in such a case, the control device 70 may open the second thermal valve 92 based on the outside air temperature, operate the heating circulation pump 46 and the burner 48, and execute the freeze prevention operation. This modification is also an example of “when the second circulation pump cannot be operated”.

(Modification 2) In said Example, the control apparatus 70 is operating the burner 48 with the heating circulation pump 46, when performing anti-freezing operation (S14 of FIG. 2, S18, S20). However, the present invention is not limited to this, and the control device may operate only the heating circulation pump 46 without operating the burner 48 when performing the freeze prevention operation. Also in this case, if the heating medium can be supplied into the HP forward pipe 16 and the HP return pipe 18, it is possible to prevent the heat pump 12, the HP forward pipe 16, and the HP return pipe 18 from being frozen and damaged. is there.

(Modification 3) In the above embodiment, the control device 70 determines whether or not to perform the freeze prevention operation based on the outside air temperature, and the operation content when the freeze prevention operation is performed ( (See FIG. 2). Instead of this, the control device 70 may determine whether or not to perform the freeze prevention operation and the operation content when performing the freeze prevention operation based on the temperature of the heating medium. Moreover, the control apparatus 70 may judge these based on both the outside temperature and the temperature of the heating medium.

(Modification 4) In the above embodiment, the end (downstream end) of the HP return pipe 16 is connected to one end of the tank upper pipe 80 and one end (upstream end) of the heating forward pipe 42. Not limited to this, the tank upper pipe 80 may be omitted, and the downstream end of the HP return pipe 16 may be connected to the upper part of the tank 22. Further, the upstream end of the heating forward pipe 42 may also be connected to the upper portion of the tank 22.

(Modification 5) In the above embodiment, the check valve 30 is interposed on the upstream side of the connecting portion with the first bypass passage 90 (described later) in the HP outgoing pipe 16. An electric opening / closing valve may be provided in place of the check valve 30 as long as the heating medium flowing into the HP forward pipe 16 from the first bypass path 90 can be prevented from flowing into the tank 22. Further, instead of the check valve 30, a three-way switching valve (mixing valve) may be provided at the connection portion between the first bypass path 90 and the HP forward pipe 16. Further, in the case where an electric on-off valve is provided instead of the check valve 30, the on-off valve is not located upstream of the connection portion with the first bypass passage 90 (described later) in the HP forward pipe 16, but on the tank. The upper tube 80 may be provided. The on-off valve and the three-way switching valve of these modified examples are also examples of the “suppression mechanism”.

(Modification 6) In the above embodiment, the first thermal valve 91 is provided on the downstream side of the connection portion with the first bypass passage 90 in the heating forward pipe 42, and the second bypass passage 90 has the second A thermal valve 92 is provided. However, the present invention is not limited thereto, and the ratio of the flow rate of the heating medium supplied to the heater 50 is adjusted to the portion where the heating forward pipe 42 and the first bypass 90 are connected, and the first bypass A mixing valve that changes the flow rate of the heating medium supplied to 90 may be provided. The mixing valve in this case is also an example of the “flow rate adjusting mechanism”.

  The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology exemplified in this specification or the drawings can achieve a plurality of objects at the same time, and has technical usefulness by achieving one of the objects.

2: Heating system 10: HP unit 12: Heat pump 14: HP circulation pump 15: Temperature sensor 16: HP forward pipe 18: HP return pipe 20: Tank unit 22: Tanks 24, 26, 28: Temperature sensor 30: Check valve 38, 39: Temperature sensor 40: Heating unit 42: Heating forward pipe 44: Heating return pipe 46: Heating circulation pump 48: Burner 50: Heater 52, 54, 56, 58: Temperature sensor 60: Second bypass 62: Mixing valve 70: Control device 72: Normal power system 74: Snow melting power system 76: Timer 80: Tank upper pipe 90: First bypass 91: First thermal valve 92: Second thermal valve

Claims (4)

A heat pump that heats the heating medium using heat absorbed from the atmosphere;
A tank for storing a heating medium heated by a heat pump;
A heater for heating using the heat of the heating medium;
A heat pump path that is a path for circulating the heating medium between the tank and the heat pump;
A heating path that is a path for circulating a heating medium between the tank and the heater;
A first circulation pump provided in the heating path for circulating the heating medium;
A bypass path connecting the upstream side of the heater in the heating path and the upstream side of the heat pump in the heat pump path;
A flow rate adjusting mechanism that is provided in the bypass path and changes the ratio of the flow rate of the heating heat medium passing through the heater and the flow rate of the heating heat medium passing through the bypass path by adjusting the opening;
A deterrence mechanism that inhibits the heating medium introduced into the heat pump path from the bypass path from flowing into the tank;
A control device;
With
The control device adjusts the opening degree of the flow rate adjustment mechanism based on one or both of the temperature and the temperature of the heating medium so that at least a part of the heating medium in the heating path passes through the bypass path. Executing a specific operation for operating the first circulation pump;
Heating device. A second circulation pump that is provided in the heat pump path and circulates the heating medium;
The control device performs the specific operation based on one or both of the temperature and the temperature of the heating medium when the second circulation pump cannot be operated.
The heating device according to claim 1. The deterrent mechanism is a check valve provided on the upstream side of the connection portion with the bypass path in the heat pump path.
The heating device according to claim 1 or 2. A heat source device for heating the heating medium in the heating path on the upstream side of the heater by the heat of burning the fuel;
The control device operates the heat source unit based on one or both of the temperature and the temperature of the heating heat medium when performing the specific operation.
The heating device according to any one of claims 1 to 3.

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