JP2018091613A - Hot water supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance availability of a heat storage amount of heat medium heated due to heat exchange with waste heat of a fuel cell, and stabilize hot water supply.SOLUTION: A hot water supply system includes: a first heat exchanger 12-4 configured to perform heat exchange between waste heat and first heat medium HM1 to heat the first heat medium; a heat medium circulation passage 8-1 configured to flow first heat medium extracted from a tank (heat medium tank 6) for accumulating the first heat medium, to the first heat exchanger, and then return it to the tank; a temperature sensor 10-1 configured to detect an upper layer temperature of the tank; a first hot water supply unit 4-1 configured to perform heat exchange with the first heat medium by a second heat exchanger 12-1; a second hot water supply unit 4-2 configured to receive water supplied from the first hot water supply unit, and then perform heat exchange between the supplied water and second heat medium HM2 heated by a heat source (burner 19) by a third heat exchanger 12-2; and a control unit 32 configured to, when a detection temperature of the temperature sensor goes below a temperature (T+β) higher than a setting temperature T by a predetermined temperature β, operate the heat source prior to heat exchange of the third heat exchanger.SELECTED DRAWING: Figure 8

Description

The present invention relates to a heat utilization technique that utilizes heat energy generated in a gas engine or a fuel cell for hot water heating.

2. Description of the Related Art Hot water supply systems that use thermal energy such as thermal energy generated by engine generators or fuel cells that use gas as fuel, solar heat, etc., for hot water heating are known.
In such a hot water supply system, when the amount of stored heat is insufficient for the amount of heat necessary for hot water supply or the like, auxiliary heating is performed. When the combustion heat of gas is used as an auxiliary heat source, the lower limit capacity by the combustion heat is guaranteed by the necessary water supply.
With regard to such a hot water supply system, when the hot water temperature of the hot water storage tank is lower than the set temperature at the start of hot water supply, the auxiliary heat source is adjusted to a low level that does not exceed the lower limit capacity of the auxiliary heat source from the start of hot water supply until the hot water supply is stopped. It is known to perform additional heating by (Patent Document 1). As for the efficient use of the auxiliary heat source, it is known that the auxiliary heat source is operated at the time of hot water supply, and the heat dissipation to the atmosphere and the reduction of fuel consumption are achieved as compared with keeping the hot water in the hot water storage tank ( For example, Patent Document 2).

JP 2003-148804 A JP 2007-311036 A

By the way, about the utilization form of an auxiliary | assistant heat source, when shifting from an unused state to a utilization state, in order to guarantee a minimum capability, the mixing amount of the water supply with respect to warm water increases. That is, increasing the amount of water supply means that the heat utilization from the heat storage tank is reduced accordingly. In such a state, the use of the heat storage amount is insufficient, and there is a possibility that the hot water supply temperature is fluctuated.
In order to solve such problems, the object of the present invention is to increase the utilization rate of the heat storage amount of the heat medium heated by exchanging heat with exhaust heat from a fuel cell or the like and to stabilize hot water supply. is there.

  In order to achieve the above object, according to one aspect of the hot water supply system of the present invention, the first heat exchanger heats the first heat medium by exchanging heat between the exhaust heat from the heat source and the first heat medium. A tank for accumulating the first heat medium, and a heat medium circulation path for flowing the first heat medium taken out from the lower layer of the tank to the first heat exchanger and returning it to the upper layer side of the tank A temperature sensor that detects an upper layer temperature of the first heat medium in the tank; a first hot water supply unit that heats water by exchanging heat with the first heat medium by a second heat exchanger; The second heat medium that receives water from the first hot water supply unit and heats it with a heat source, the second hot water unit that supplies hot water by exchanging heat of the water with a third heat exchanger, and the detected temperature of the temperature sensor If the temperature falls below a temperature (T + β) higher than the set temperature T by a predetermined temperature β, the third heat exchange A controller that operates the heat source prior to heat exchange of the exchanger.

In this hot water supply system, the second hot water supply unit is a combustion heat source in which the heat source burns fuel gas, and a fourth heat exchanger that exchanges heat generated by the combustion heat source with the second heat medium. May be provided.
In this hot water supply system, when the temperature detected by the temperature sensor exceeds a temperature (T + β) higher than the set temperature T by a predetermined temperature β, the operation of the heat source may be stopped.

According to the present invention, any of the following effects can be obtained.
(1) The waste heat from the fuel cell can be stored, and this heat can be effectively used for hot water heating, so that the waste heat can be used efficiently.
(2) The fluctuation of the hot water temperature can be suppressed and the hot water can be stabilized.
(3) Hot water supply capacity can be improved by using waste heat as a heat source.

It is a figure which shows the hot water supply system which concerns on one embodiment. It is a flowchart which shows the hot water supply control of the hot water supply unit 4-1. It is a flowchart which shows the hot water supply control of the hot water supply unit 4-2. It is a figure which shows the operation | movement pattern in case of T2> = T. It is a figure which shows the operation | movement pattern in case of T2 <T. It is a figure which shows the operation | movement pattern in case of T2 <T. It is a figure which shows an operation timing. 1 is a diagram illustrating a cogeneration system according to a first embodiment. It is a figure which shows the position of the temperature sensor of a heat-medium tank. It is a figure which shows a control part. It is a flowchart which shows cooperation control. It is a flowchart which shows control of a fuel cell unit. It is a flowchart which shows the hot water supply control of the hot water supply unit 4-1. It is a flowchart which shows the hot water supply control of the hot water supply unit 4-1. It is a flowchart which shows the hot water supply control of the hot water supply unit 4-2. It is a flowchart which shows the hot water supply control of the hot water supply unit 4-2. It is a flowchart which shows the sequence of communication control. FIG. 10 is a diagram for explaining control according to the second embodiment. FIG. 6 is a diagram illustrating a fuel cell and a hot water supply unit according to a third embodiment. It is a figure which shows the hot water supply apparatus which concerns on Example 4. FIG.

FIG. 1 shows a hot water supply system according to an embodiment. The configuration shown in FIG. 1 is an example and is not limited to the configuration according to the present invention.
The hot water supply system 2 includes a first hot water supply unit 4-1 and a second hot water supply unit 4-2. The hot water supply unit 4-1 has a heat storage function and a hot water supply function. The hot water supply unit 4-1 is provided with a heat medium tank 6 in which the first heat medium HM1 is stored. The heat medium HM1 flows from the lower layer side of the heat medium tank 6 to the heat medium circulation path 8-1, for example, The high-temperature heat medium HM1 circulated to the exhaust heat source and heated is returned to the upper layer portion of the heat medium tank 6. Thereby, heat storage in a hierarchical state is performed. For example, an open heat storage tank is used as the heat medium tank 6. The heat medium HM1 is a cooling heat medium on the exhaust heat source side, collects heat from the exhaust heat source, and stores the heat in the heat medium tank 6. The heating medium tank 6 is provided with a plurality of temperature sensors that detect the temperature of the heating medium in the upper layer, the middle layer, and the lower layer, and the detection temperature T1 of the temperature sensor 10-1 represents the heating medium temperature in the upper layer. With this heat storage function, in the hot water supply function, the heat of the heat medium HM1 is exchanged with the water supply W to supply hot water HW.

  At the time of hot water supply, the water supply W supplied to the water supply path 8-2 flows into the heat exchanger 12-1. At this time, by driving the circulation pump 14-1, the heat medium HM1 flows from the upper layer side of the heat medium tank 6 to the heat exchanger 12-1 through the heat medium circulation path 8-3. The heat exchanger 12-1 is an example of a second heat exchange unit. In the heat exchanger 12-1, the heat of the heat medium HM1 is exchanged with the feed water W, and the hot water HW is generated from the feed water W by the heat of the heat medium HM1. This hot water HW is supplied with hot water from the first hot water supply path 8-4.

  In this hot water supply unit 4-1, when the set temperature of the hot water HW is T, the heat exchange between the feed water W and the heat medium HM 1 is a temperature (T + α) higher than the set temperature T by α (for example, α = 5 [° C.]). ) To perform heat exchange. The feed water temperature T2 is detected by a temperature sensor 10-2 installed on the inlet side of the feed water channel 8-2. The temperature T3 of the hot water HW on the outlet side is detected by the temperature sensor 10-3. The hot water HW in the hot water supply path 8-4 flows to the mixing valve 16-1 which is an example of the mixing means in the hot water supply path 8-4. The mixing valve 16-1 is connected to the bypass passage 8-5 on the water supply passage 8-2 side, and the opening ratio between the hot water supply passage 8-4 side and the bypass passage 8-5 side of the mixing valve 16-1 is increased. It is possible to mix the feed water W with the hot water HW at a suitable mixing ratio. Accordingly, if the amount of heat of the heat medium HM1 in the heat medium tank 6 is equal to or greater than the amount of heat necessary to obtain the hot water HW having the set temperature T, the hot water HW having the set temperature T can be obtained using only the hot water HW or the mixed water of the hot water HW and the feed water W. However, if the amount of heat is insufficient, the temperature of the hot water HW is lower than the set temperature T.

  The hot water supply path 8-4 of the hot water supply unit 4-2 is connected to the hot water supply path 8-4 of the hot water supply unit 4-1, and the hot water supply path 8-6 forms a continuous water passage with the hot water supply path 8-4. Thereby, the hot water HW discharged from the hot water supply unit 4-1 is supplied to the hot water supply path 8-6 of the hot water supply unit 4-2. If the temperature of the hot water HW flowing through the hot water supply passage 8-6 is the set temperature T, the heat treatment of the hot water supply unit 4-2 is not necessary, and the hot water supply unit 4-2 may be used as it is. That is, hot water can be discharged from the bypass passage 8-7 branching from the hot water supply passage 8-6 through the second mixing valve 16-2. The mixing valve 16-2 is an example of hot water switching means.

  When the detected temperature T1 of the temperature sensor 10-1 for detecting the upper layer temperature of the heat medium tank 6 falls below the temperature (T + β) higher than the set temperature T by β (β> α) degrees, {T1 <(T + β)} The shortage of heat is predicted, and the auxiliary heat source 18 is operated. For example, the auxiliary heat source 18 uses a burner 19 that burns fuel gas as a heat source. In this case, the auxiliary heat amount is combustion heat, but it may be electric heat or solar heat. When the auxiliary heat source 18 is operated, the circulation pump 14-2 is operated to circulate the second heat medium HM2 in the heat medium circulation path 8-8, and the combustion heat of the burner 19 is an example of the fourth heat exchange unit. The heat exchanger 12-3 is to exchange heat with the heat medium HM2. At this time, the combustion heat amount of the burner 19 is adjusted so that the heat medium HM2 after heat exchange becomes a predetermined temperature (for example, 80 [° C.]). Thereby, the shortage of heat quantity of the heating medium HM1 is compensated by heating the heating medium HM2 by the burner 19.

  When the detected temperature T4 of the temperature sensor 10-4 is lower than the set temperature T (T4 <T), the hot water HW is supplied from the hot water supply path 8-6 to the heat exchanger 12-2 as an example of the third heat exchange unit. And heat exchange between the heat medium HM2 and the hot water HW is performed. Thereby, the warm water HW is heated. The temperature T5 of the hot water HW on the exit side of the heat exchanger 12-2 is detected by the temperature sensor 10-5. The hot water HW after heat exchange of the heat exchanger 12-2 flows to the mixing valve 16-2. The mixing valve 16-2 is connected to a bypass path 8-7 on the hot water supply path 8-6 side, and corresponds to the opening ratio between the hot water supply path 8-6 side and the bypass path 8-7 side of the mixing valve 16-2. It is possible to mix the warm water HW before the heat exchange with the warm water HW after the heat exchange at the mixing ratio. If the detected temperature T5 of the hot water HW after the heat exchange is higher than the set temperature T, the hot water HW before the heat exchange and the hot water hHW after the heat exchange are mixed at a mixing ratio corresponding to the opening ratio from the bypass 8-8. Then, the mixed water mHW (= HW + hHW) at the set temperature T is discharged. The temperature of the mixed water mHW is detected by a temperature sensor 10-6 in the hot water supply path 8-6, and the detected temperature T6 is used for adjusting the opening of the mixing valve 16-2 that adjusts the mixed water mHW to the set temperature T. .

<Control of hot water supply units 4-1 and 4-2>
The control during hot water supply is as follows.
(1) The heat of the heating medium HM1 is exchanged with the feed water W to generate hot water HW that is higher by α degrees than the set temperature T, and the hot water temperature of the hot water HW is controlled to the set temperature T by the mixing valve 16-1.
(2) When T1 <(T + β), the operation of the auxiliary heat source 18 of the hot water supply unit 4-2 is started.
(3) If the temperature of the hot water HW provided from the hot water supply unit 4-1 to the hot water supply unit 4-2 is the set temperature T, the hot water HW is discharged from the bypass passage 8-7 through the mixing valve 16-2.
(4) When T4 <T, the heat of the heating medium HM2 is exchanged with the hot water HW, thereby adjusting the opening ratio of the mixing valve 16-2 and discharging the mixed water mHW having the set temperature T.

<Hot water supply control of hot water supply unit 4-1>
FIG. 2 shows a processing procedure of hot water supply control of the hot water supply unit 4-1. In the hot water supply unit 4-1, it is determined whether or not the hot water supply is used by starting the operation (S <b> 11). If hot water is not used (NO in S11), circulation pump 14-1 is stopped (S12), and this hot water supply process is terminated. If hot water is used (YES in S11), it is determined whether the detected temperature T1 in the upper layer of the heat medium tank 6 exceeds the detected temperature T2 of the feed water W (T1> T2) (S13). If T1> T2 (YES in S13), the rotational speed of the circulation pump 14-1 is controlled so that the detected temperature T3 of the hot water HW on the outlet side of the heat exchanger 12-1 becomes the temperature (T + α) (S14). If T1> T2, that is, if T2 ≧ T1 (NO in S13), the circulation pump 14-1 is stopped (S15).

Through S14 or S15, it is determined whether the detected temperature T1 is T1 <(T + β) (S16). If T1 <(T + β) (YES in S16), it is determined that there is no heat storage in the heat medium tank 6 (S17). If T1 <(T + β) is not satisfied (NO in S16), that is, T1 ≧ (T + β ), It is determined that there is heat storage in the heat medium tank 6 (S18).
And the mixing ratio of the warm water HW and the feed water W is adjusted with the opening ratio of the mixing valve 16-1, and the warm water HW discharged is controlled to the set temperature T (S19).

<Hot-water supply control of hot-water supply unit 4-2>
FIG. 3 shows a processing procedure of hot water supply control of the hot water supply unit 4-2. It is determined whether or not the hot water supply unit 4-2 also uses hot water (S21). If hot water is not used (NO in S21), the circulation of the heating medium HM2 is stopped by stopping the circulation pump 14-2 (S22), and this hot water supply process is terminated. If hot water is used (YES in S21), it is determined whether or not the heat medium tank 6 of the hot water supply unit 4-1 has stored heat (S23).

  If there is no heat storage (YES in S23), circulation of the heat medium HM2 is started and the auxiliary heat source 18 is operated (S24). If there is no heat storage (NO in S23), it is determined whether the detected temperature T4 of the hot water HW flowing into the hot water supply unit 4-2 from the hot water supply unit 4-1 is lower than the set temperature T (T4 <T) (S25). . If T4 <T (YES in S25), the circulation of the heating medium HM2 is started (S24). If T4 <T, that is, if T4 ≧ T (NO in S25), the circulation of the heating medium HM2 is started. The auxiliary heat source 18 is stopped and stopped (S26).

After the circulation of the heating medium HM2 is started (S24), it is determined whether the detected temperature T4 of the hot water HW is less than the set temperature T (T4 <T) (S27). If T4 <T (YES in S27), the hot water HW flowing from the hot water supply unit 4-1 into the hot water supply unit 4-2 is heated by the heat exchanger 12-2 by changing the opening ratio of the mixing valve 16-2. By using the hot water hHW after replacement, the temperature of the hot water HW discharged is controlled to the set temperature T (S28). In this case, the mixed water mHW (= HW + hHW) of the warm water hHW after heat exchange and the warm water HW before heat exchange is discharged.
If T4 <T, that is, if the detected temperature T4 is the set temperature T (NO in S27), the opening degree of the mixing valve 16-2 is switched to the bypass path 8-7 side, and hot water is supplied from the hot water supply unit 4-1. The hot water HW flowing into the unit 4-2, that is, the hot water HW before heat exchange flowing on the bypass path 6-7 side is discharged (S29).

<Operation pattern>
In the case of T4 ≧ T, the heat storage amount of the heat medium tank 6 is sufficient for the tapping water at the set temperature T. Therefore, as shown in FIG. The hot water HW controlled to T is discharged from the bypass passage 8-7 through the mixing valve 16-2.
In this way, when T4 ≧ T starts tapping, and during T1 <(T + β) during tapping, as shown in FIG. 5, the operation of the auxiliary heat source 18 is started, and the heating medium HM2 is used as the heating medium. Circulate to circuit 8-8.

  In the case of T4 <T, since the amount of heat stored in the heat medium tank 6 is insufficient for the tapping water at the set temperature T, the heat of the heat medium HM2 heated by the auxiliary heat source 18 is exchanged with the warm water HW, and the warm water Auxiliary heating of HW is performed. As shown in FIG. 6, when the hot water HW is discharged (FIG. 4), when T4 <T, the bypass path 8-5 of the mixing valve 16-1 is closed and the hot water supply path 8-4 side is opened. And Thereby, only warm water HW passes through the mixing valve 16-1. At this time, the temperature sensor 10-4 detects the temperature of the hot water HW.

  Heat of the heat medium HM2 is exchanged with the hot water HW, and the hot water hHW is obtained from the heat exchanger 12-2. In the mixing valve 16-2, the hot water HW before heat exchange and the hot water hHW after heat exchange of the heat exchanger 12-2 are mixed from the bypass path 8-7 to obtain mixed water mHW. The tapping temperature of the mixed water mHW is detected by the temperature sensor 10-6, the opening ratio of the opening on the bypass path 8-7 side and the opening on the hot water hHW side of the mixing valve 16-2 is controlled, and the set temperature T The mixed water mHW tapping water is controlled.

A, B, C, D, E, and F in FIG. 7 indicate the operation timing of hot water supply control.
7A shows the temperature drop of the heating medium HM1 in the heating medium tank 6. FIG. T is the set temperature of the hot water HW, T1 is the change in the detected temperature of the temperature sensor 10-1, T4 is the change in the detected temperature of the temperature sensor 10-4, and Tx is the change in the temperature of the hot water HW entering the mixing valve 16-1. Show. Thus, even if the temperature (T1) of the heating medium HM1 changes, the temperature (T4) of the hot water HW is controlled to the set temperature T. The reason why the temperature Tx is higher than the detected temperature T1 is that the hot water HW heat-exchanged with the high-temperature heat medium HM1 flows from the upper layer side of the heat medium tank 6 to the mixing valve 16-1. This temperature is detected by the temperature sensor 10-3.
The operation of the auxiliary heat source 18 is started at a time point t1 when the transition is made from T1 ≧ T + β to T1 <T + β. If the auxiliary heat source 18 is a burner, combustion starts at this time t1. That is, the auxiliary heat source 18 is operated in advance before the detection temperature T4 of the temperature sensor 10-4 decreases. As a result, as shown in FIG. 7B, the heat medium temperature Tm rises from the operation start time t1 of the auxiliary heat source 18 by the heating of the burner 19, and is maintained at a constant temperature.

  At time t2 when the detected temperature T4 falls below the set temperature T, as shown in FIG. 7C, the control area C1 of the mixing valve 16-1 is switched to the control area C2 of the mixing valve 16-2. A time Δt exists between the time point t1 and the time point t2. That is, this means that the operation of the auxiliary heat source 18 precedes the time t2 by the time Δt. Thereby, before switching to the control area C2 of the mixing valve 16-2, the operation of the auxiliary heat source 18 is started, and the heat medium temperature Tm is maintained at a constant temperature.

  FIG. 7D shows the case where the heat storage temperature of the heat medium tank 6 rises during the hot water with the mixed water mHW. T is a set temperature of the hot water, T1 is a temperature detected by the temperature sensor 10-1 (= heat medium temperature), T4 is a temperature detected by the temperature sensor 10-4 (= hot water temperature), and Tx is hot water entering the mixing valve 16-1. An example of the transition of the HW temperature is shown. The time point t3 is a time point when the detected temperature T4 rises from the set temperature T, and the time point t4 is a time point when the detected temperature T1 exceeds the set temperature T + β, which is a time point when the operation of the auxiliary heat source 18 is stopped.

As shown in E of FIG. 7, the heat medium temperature Tm is maintained at a constant temperature by the heating of the burner 19 in the auxiliary heat source 18, and is gradually lowered due to the operation of the auxiliary heat source 18 being stopped at time t <b> 4.
Then, as shown in FIG. 7F, at the time t3 when the transition from T4 <T to T4 ≧ T is made, the control region C2 of the mixing valve 16-2 is switched to the control region C1 of the mixing valve 16-1. As a result, the hot water HW and the feed water W are mixed, or the hot water at the set temperature T is obtained only with the hot water HW.

<Effect of one embodiment>
According to this embodiment, the following effects can be obtained.
(1) When T4 ≧ T, hot water is discharged at the set temperature T using the hot water HW and the hot water W obtained on the hot water supply unit 4-1 side. Since hot water supply at the set temperature T is realized without operating the auxiliary heat source 18, it is economical.
(2) When T4 <T, the hot water HW heated by the auxiliary heat source 18 is exchanged with the hot water HW together with the hot water HW on the hot water supply unit 4-1 side. Since the hot water HW is used entirely, the utilization rate of the heat storage amount of the heat medium HM1 in the heat medium tank 6 is high and efficient hot water supply can be performed.
(3) When transition from T1 ≧ T + β to T1 <T + β during hot water supply, the auxiliary heat source 18 can be operated in advance at that time, and the heat of the heat medium HM2 can be quickly exchanged with the hot water HW. Therefore, undershoot due to insufficient heat storage in the heat medium tank 6 can be suppressed, and stable hot water supply at the set temperature T can be performed.
(4) When the detected temperature T1 in the upper layer of the heating medium tank 6 is equal to or higher than the predetermined set temperature T + β, hot water at the set temperature T is supplied, and when it falls below, hot water HW at the same temperature is supplied as hot water. The heat source 18 can be controlled to the set temperature T whatever the temperature difference between the set temperature T and the hot water HW.

FIG. 8 shows a cogeneration system according to the first embodiment. The configuration shown in FIG. 8 shows one aspect of the present invention, and the present invention is not limited to such configuration. In FIG. 8, the same parts as those in FIG.
This cogeneration system 20 is an application example of the hot water supply system 2 described above, and this cogeneration system 20 is provided with a fuel cell unit 22 as an exhaust heat source in addition to the hot water supply units 4-1 and 4-2. That is, the cogeneration system 20 is an example of a hot water supply system including the fuel cell unit 22.
The fuel cell unit 22 includes a fuel cell 24 as an example of a heat source unit, and an exhaust HM3 of the fuel cell 24 is an example of a first heat exchange unit through an exhaust path 8-9. Flowing into. The heat of the exhaust HM3 is heat-exchanged to the heat medium HM1 that circulates in the heat exchanger 12-4, and the heat medium HM1 heats the heat medium HM1 by the exhaust heat of the fuel cell 24. The heat medium HM1 circulates in the heat medium circulation path 8-1 by driving the circulation pump 14-3. The inlet temperature of the heat exchanger 12-4 that circulates the heating medium HM1 is detected by the temperature sensor 10-7, and the outlet temperature thereof is detected by the temperature sensor 10-8.

The heat medium HM1 in the heat medium tank 6 of the hot water supply unit 4-1 circulates from the lower layer side of the hot water supply unit 4-1 to the heat medium circulation path 8-1, and after heat exchange with exhaust heat in the heat exchanger 12-4. The heat medium tank 6 is returned to the upper layer side. Thereby, the hierarchical heat storage of the heat medium HM1 is performed. In the heating medium tank 6, the upper layer temperature of the heating medium HM1 is detected by the temperature sensor 10-1, the middle layer temperature is detected by the temperature sensors 10-9 and 10-10, and the lower layer temperature is detected by the temperature sensor 10-11. The
At the time of heat exchange between the heat medium HM1 of the hot water supply unit 4-1 and the water supply W, the flow rate of the water supply W flowing through the water supply path 8-2 is detected by the flow sensor 26-1. The temperature of the hot water HW discharged from the hot water supply unit 4-1 is detected by the temperature sensor 10-12.

  During hot water supply, the flow rate of the hot water HW flowing from the hot water supply unit 4-1 to the hot water supply path 8-6 is detected by the flow rate sensor 26-2. The heat medium circulation path 8-8 is provided with an accumulator 28, and the pressure of the heat medium HM2 is controlled. The outlet side temperature of the heat exchanger 12-3 through which the heat medium HM2 circulates is detected by the temperature sensor 10-13, and the inlet side temperature of the circulation pump 14-2 through which the heat medium HM2 is circulated is detected by the temperature sensor 10-14. The The auxiliary heat source 18 that heats the heat medium HM2 by the heat exchanger 12-3 is provided with a burner 19 that generates combustion heat by combustion of gas fuel.

<Temperature sensor 10-1 of heating medium tank 6>
FIG. 9 shows the IX portion of FIG. 8 in an enlarged manner. As shown in FIG. 9, the temperature sensor 10-1 of the heat medium tank 6 is installed in the upper layer of the heat medium tank 6. The position of the temperature sensor 10-1 may be determined from the heating capacity and heating speed of the auxiliary heat source 18 of the burner 19. The position of the temperature sensor 10-1 is a position at which the temperature of the heat medium HM1 is detected at least at a volume level where it is possible to secure time for completing the start-up of the burner 19 before the amount of heat of the heat medium HM1 is used for hot water supply. If it is. For example, when the regulated flow rate 24 [liter / min] can be heated at 10 [seconds], the heat medium amount is set to a volume level position corresponding to 4 [liter] or more, and the heat medium temperature at that position is set. To detect. In the figure, a broken line 34 indicates a virtual line of a water divide between the upper layer side heat medium HM1 and the lower layer side low temperature heat medium LHM1.

<Control part of cogeneration system 20>
FIG. 10 shows an example of the control unit of the cogeneration system 20. The control unit 32 includes hot water supply unit control units 36-1 and 36-2, a fuel cell unit control unit 36-3, and a remote control unit 36-4 configured by a computer having a communication function.
The hot water supply unit control unit 36-1 is a control unit of the hot water supply unit 4-1, and includes a processor 38-1, a memory unit 40-1, a system communication unit 42-1, and an input / output unit (I / O) 44-1. The hot water supply unit 4-1 performs hot water supply control. The processor 38-1 executes an OS (Operating System) and a hot water supply control program in the memory unit 40-1, and supplies a hot water supply unit control unit 36-2 and a fuel cell unit control unit 36- via the system communication unit 42-1. 3 and the remote control controller 36-4, information processing necessary for hot water supply control is executed. The memory unit 40-1 includes a ROM (Read-Only Memory) and a RAM (Random-Access Memory). The memory unit 40-1 uses a storage element such as a hard disk device or a nonvolatile memory for storing data. The RAM constitutes a work area for information processing. The system communication unit 42-1 performs wired or wireless communication with the system communication unit on the hot water supply unit control unit 36-2, the fuel cell unit control unit 36-3, and the remote control control unit 36-4, and information necessary for control Send and receive. The I / O 44-1 receives detection signals from various temperature sensors such as the temperature sensor 10-1 in the hot water supply unit 4-1 and the flow rate sensor 26-1, and control signals for the mixing valve 16-1 and the circulation pump 14-1. Is output.

  The hot water supply unit control unit 36-2 is a control unit for the hot water supply unit 4-2, and includes a processor 38-2, a memory unit 40-2, a system communication unit 42-2, and an I / O 44-2. 2 hot water supply control is performed. The processor 38-2 executes the OS and the hot water supply control program in the memory unit 40-2, and controls the hot water supply unit control unit 36-1, the fuel cell unit control unit 36-3, and the remote controller via the system communication unit 42-2. In cooperation with the unit 36-4, information processing necessary for hot water supply control is executed. The memory unit 40-2 includes a ROM and a RAM. The memory unit 40-2 uses a storage element such as a hard disk device or a nonvolatile memory for storing data. The RAM constitutes a work area for information processing. The system communication unit 42-2 performs wired or wireless communication with the system communication unit on the hot water supply unit control unit 36-1, the fuel cell unit control unit 36-3, and the remote control control unit 36-4, and information necessary for control Send and receive. The I / O 44-2 receives detection signals from various temperature sensors such as the temperature sensor 10-4 in the hot water supply unit 4-2 and the flow rate sensor 26-2, and receives the mixing valve 16-2, the circulation pump 14-2, the burner 19 The control signal of the combustion control unit 46 is output.

  The fuel cell unit control unit 36-3 is a control unit for the fuel cell unit 22, and includes a processor 38-3, a memory unit 40-3, a system communication unit 42-3, and an I / O 44-3. The drive control is performed. The processor 38-3 executes the OS and the hot water supply control program in the memory unit 40-3, and with the hot water supply unit control units 36-1 and 36-2 and the remote control control unit 36-4 via the system communication unit 42-3. It cooperates and executes information processing necessary for hot water supply control. The memory unit 40-3 includes a ROM and a RAM. For the memory unit 40-3, a storage element such as a hard disk device or a nonvolatile memory for storing data is used. The RAM constitutes a work area for information processing. The system communication unit 42-3 communicates with the system communication units on the hot water supply unit control units 36-1 and 36-2 and the remote control control unit 36-4 in a wired or wireless manner, and transmits and receives information necessary for control. The I / O 44-3 receives detection signals from the temperature sensors 10-7 and 10-8 in the fuel cell unit 22, and outputs control signals for the circulation pump 14-3 and the fuel cell control unit 48.

  The remote controller control unit 36-4 is provided in the remote controller 50 independent of the hot water supply units 4-1, 4-2 and the fuel cell unit 22, and includes the hot water supply unit control units 36-1, 36-2, the fuel cell unit control unit 36-. 3 and computer communication.

<Cooperation control processing procedure>
FIG. 11 shows a main flow of cooperative control including hot water supply control of the control unit 32. In this processing procedure, the remote control device 50 executes initialization at startup (S41), and performs input reception processing (S42) and display output processing (S43). In the input reception process, initial setting is performed by the user. This initial setting includes the input of the set temperature T of hot water supply to the hot water supply units 4-1 and 4-2 and the switching of ON / OFF of the operation for the fuel cell unit 22. In the display output process, input information and output information are presented on the display unit of the remote control device 50.

  The fuel cell unit 22 performs initialization (S51), heat recovery processing (S52), and other management processing (S53). The heat recovery process is instructed to start or end the process by switching operation ON / OFF from the remote controller 50. Management processing includes processing such as maintenance.

  In the hot water supply unit 4-1, initialization is executed (S61), hot water supply processing (S62), and other management processing (S63). The hot water supply process receives the set temperature T of hot water supplied from the remote control device 50 and controls the temperature of the hot water HW to the set temperature T. In this hot water supply process, “with heat storage” or “without heat storage” is reported to the hot water supply unit 4-2 as the heat storage state of the heat medium tank 6. Other management includes processing such as maintenance.

  In the hot water supply unit 4-2, initialization is executed (S71), hot water supply processing (S72), and other management processing (S73). In this hot water supply process, the set temperature T of hot water supplied from the remote control device 50 is received, the temperature of the hot water HW is controlled to the set temperature T, and a notification of “with heat storage” or “without heat storage” is sent from the hot water supply unit 4-1. The temperature adjustment including the heating control of the hot water HW by the combustion control of the burner 19 is performed. For other management, processing such as maintenance is reduced as in the hot water supply unit 4-1.

<Heat recovery process>
FIG. 12 shows a processing procedure for heat recovery processing of the fuel cell unit 22.
In the control of the fuel cell unit 22, it is determined whether the operation is ON (S81). If the operation is ON (YES in S81), the fuel cell 24 is driven (S82). In driving the fuel cell 24, the rotation of the circulation pump 14-3 is controlled so that the detected temperature T8 of the temperature sensor 10-8 becomes a constant temperature, for example, 75 [° C.] (S83).
If the operation is not ON (NO in S81), the driving of the fuel cell 24 is stopped (S84). When the drive of the fuel cell 24 is stopped, the rotation of the circulation pump 14-3 is stopped (S85).

<Hot-water supply process [1-1]>
FIG. 13 shows the procedure of the hot water supply process [1-1] of the hot water supply unit 4-1.
It is determined whether hot water is used (S91). If not hot water (NO in S91), circulation pump 14-1 is stopped (S92), and this hot water supply process is terminated.
If hot water is used (YES in S91), it is determined whether T1> T2 (S93), and if T1> T2 (YES in S93), the detected temperature T3 is a temperature higher than the set temperature T by α [° C.]. The rotational speed of the circulation pump 14-1 is controlled so as to be (T + α) (or approach) (S94). If T1> T2 is not satisfied (NO in S93), the circulation pump 14-1 is stopped (S95).
After S94 or S95, it is determined whether or not T1 <T + β (S96). If T1 <T + β (YES in S96), the hot water supply unit control unit 36-1 notifies the hot water supply unit control unit 36-2 that there is no heat storage. Is transmitted (S97), and if T1 <T + β is not satisfied (NO in S96), “with heat storage” is transmitted (S98). After these transmissions, the hot water supply unit 4-1 controls the temperature of the hot water HW to be discharged to the set temperature T (or so as to approach T) and discharges hot water (S99).

<Hot water supply treatment [1-2]>
FIG. 14 shows the procedure of the hot water supply process [1-2] of the hot water supply unit 4-1.
It is determined whether hot water is used (S101). If not hot water (NO in S101), circulation pump 14-1 is stopped (S102), and this hot water supply process is terminated.
If hot water is used (YES in S101), it is determined whether T1> T2 (S103). If T1> T2 (YES in S103), the detected temperature T3 is a temperature higher by α [° C.] than the set temperature T. The rotational speed of the circulation pump 14-1 is controlled so as to be (T + α) (or approach) (S104). If T1> T2 is not satisfied (NO in S103), the circulation pump 14-1 is stopped (S105).
After S104 or S105, it is determined whether or not T1 <T + β (S106). If T1 <T + β (YES in S106), the hot water supply unit control unit 36-1 notifies the hot water supply unit control unit 36-2 that “no heat is stored. Is transmitted (S107), and if T1 <T + β is not satisfied (NO in S106), “with heat storage” is transmitted (S108).

  In this control, it is determined whether T3 <T (S109), and if T3 <T (YES in S109), the mixing valve 16-1 controls the hot water supply channel 8-4 side to a fully open state (S110). If T3 <T (NO in S109), the opening ratio of the mixing valve 16-1 is controlled based on the detected temperature T12 so that the hot water HW becomes the set temperature T (S111).

<Hot-water treatment [2-1]>
FIG. 15 shows the procedure of the hot water supply process [2-1] of the hot water supply unit 4-2.
It is determined whether hot water is used (S121). If not hot water (NO in S121), the circulation of the heating medium HM2 is stopped and the hot water supply process is terminated.
If hot water is being used (YES in S121), it is determined whether “no heat storage” has been received (S123). If “no heat storage” is received (YES in S123), the heat medium HM2 is circulated (S124). If “no heat storage” is not received (NO in S123), it is determined whether T4 <T (S125). If T4 <T (YES in S125), the process proceeds to S124. If T4 <T (NO in S125), the circulation of the heating medium HM2 is stopped (S126).
When the process shifts to the circulation drive of the heating medium HM2 in S124, it is determined whether T4 <T (S127). If T4 <T (YES in S127), the temperature of the mixed water mHW is set by the mixing valve 16-2. The temperature is controlled to T (S128). If T4 <T is not satisfied (NO in S127), the mixing valve 16-2 is fully opened to the bypass circuit 8-7 side, and only the hot water HW from the hot water supply unit 4-1 is discharged (S129).

<Hot water supply treatment [2-2]>
FIG. 16 shows a processing procedure of hot water supply processing [2-2] of the hot water supply unit 4-2.
It is determined whether hot water is used (S131), and if hot water is used (YES in S131), it is determined whether "no heat storage" is received (S132). If “no heat storage” is received (YES in S132), the circulation pump 14-2 is driven (S133), and the heat medium HM2 is circulated. Based on the detected temperature T13 of the temperature sensor 10-13, the combustion amount of the burner 19 is controlled so that the temperature of the heating medium HM2 becomes a constant temperature. This control is executed by the combustion control unit 46 of the burner 19. If “no heat storage” is not received (NO in S132), the circulation pump 14-2 is stopped (S136), and the combustion of the burner 19 is stopped (S137).
After S134 and S137, it is determined whether T4 <T (S138). If T4 <T (YES in S138), the mixed water mHW becomes the set temperature T based on the detected temperature T4 of the temperature sensor 10-4. Thus, the opening ratio of the mixing valve 16-2 is controlled (S139). If T4 <T (NO in S138), hot water HW controlled to the set temperature T is supplied from the hot water supply unit 4-1 to the hot water supply path 8-6, so that the bypass path 8-7 side is fully opened. Then, the mixing valve 16-2 is controlled to discharge hot water HW having a set temperature T (S140).
If hot water supply is not used in S131 (NO in S131), the circulation of the heat medium HM2 is stopped by stopping the circulation pump 14-2 (S141), the combustion of the burner 19 is stopped (S142), and the mixing valve 16- 2 controls the bypass path 8-7 to a fully closed state (S143), and ends this control. In the case of “with heat storage”, the bypass path 8-7 may be controlled to be fully opened.

<Cooperative communication processing>
FIG. 17 shows a sequence of cooperative communication processing of hot water supply units 4-1 and 4-2, fuel cell unit 22 and remote control device 50.
Regarding the power generation-related process F1, the remote controller 50 instructs the fuel cell ON (S201), the fuel cell 24 operation display (S202), the fuel cell 24 OFF instruction (S203), the fuel cell 24 OFF display (S204), and the like. This process is included.

  Regarding the power generation-related process F1, the fuel cell unit 22 drives the circulation pump 14-3 according to the fuel cell ON instruction (S201) (S211), and notifies the start of the fuel cell 24 in response to the operation display (S202) of the fuel cell 24 ( S212), control of circulation pump 14-3 for target hot water temperature: 75 [° C.] (S213), stop operation of fuel cell 24 by OFF instruction of fuel cell 24 (S203), circulation pump until heat quantity is reduced Processes such as exhaust heat recovery by 14-3 (S215), driving stop of fuel cell 24 (S216), and the like are included.

  As the power generation-related process F1, the hot water supply unit 4-1 includes exhaust heat recovery (no control or communication) (S221), and as the process F2 in the case of "with heat storage" related to the hot water supply, the hot water supply flow rate ON ( S222), “with heat storage” transmission (S223), heat storage hot water supply start (S224), heat storage decrease (warm-up instruction) (S225), hot water flow rate OFF (S226), and heat storage hot water supply stop (S227). Further, as processing F3 of “no heat storage” in relation to hot water supply, “no heat storage” transmission (S228), hot water supply flow rate ON (S229), when there is a heat quantity, hot water supply hot water start (S230), hot water supply flow rate OFF (S231) ), Heating hot water supply stop (S232) and the like are included.

  In the hot water supply unit 4-2, the hot water supply flow rate is turned on (S241), the hot water supply mode is determined (heat storage hot water supply) (S242), the warm-up operation (S243), and the mixing control based on the hot water temperature as the process F2 of “with heat storage” in relation to hot water supply. (S244) and hot water flow rate OFF (S245) are included. In addition, as processing F3 in the case of “no heat storage” in relation to hot water supply, a “hot storage” transmission from the hot water supply unit 4-1 is received and a hot water supply mode determination (water supply / heated gas hot water or gas hot water) (S246), hot water supply Flow rate ON (S247), Hot water supply use transmission (S248), Gas combustion hot water supply (S249), Hot water flow rate OFF (S250), Hot water supply stop transmission (S251) for hot water supply hot water supply stop (S232) of hot water supply unit 4-1, etc. This process is included.

<Effect of Example 1>
According to the first embodiment, the following effects can be obtained.
(1) The hot water HW stored in the heat medium tank 6 can be effectively used, and the hot water supply capacity can be improved.
(2) Exhaust heat obtained from the gas engine or fuel cell is exchanged with the heating medium HM1 of the heating medium tank 6, and the heat of the heating medium HM1 is exchanged with hot water HW to store hot water, and the hot water HW is used as hot water supply. Available.
(3) In the hot water supply unit 4-1, the hot water HW discharged from the hot water supply path 8-4 is heat-exchanged so that the water supply W becomes a temperature (T + α) higher than the set temperature T by, for example, α = 5 [° C.] Hot water HW (temperature = T + α) after heat exchange and feed water W before heat exchange can be mixed and adjusted to a set temperature T to supply hot water using the mixing valve 16-1.
(4) When the detected temperature T1 of the temperature sensor 10-1 in the heating medium tank 6 becomes lower than the temperature (T + β), the temperature of the hot water HW after the heat exchange is expected to be lower than the above-described temperature (T + α). Therefore, combustion of the burner 19 of the auxiliary heat source 18 is started at the time when the detected temperature T1 shifts below the temperature (T + β), and a decrease in the hot water HW hot water temperature can be prevented in advance.
(5) Even if the temperature of the heating medium HM1 in the heating medium tank 6 decreases, if the temperature of the heating medium HM1 is higher than the detection temperature T2 of the feed water W, the heat of the heating medium HM1 is used by exchanging heat with the feeding water W. The heat storage amount of 6 can be used effectively.
(6) Since the hot water is not directly used for heat exchange of the heating medium HM1 in the heating medium tank 6, it is not necessary to secure the water quality of the heating medium HM1 in the heating medium tank 6 (measures against Legionella bacteria), and the heating of the heating medium tank 6 Processing such as sterilization is unnecessary and economical.
(7) The heat medium tank 6 may be open to the atmosphere, and it is not necessary to consider the pressure resistance function of the heat medium tank 6 and a pressure reducing valve on the water supply W side is not required. The configuration of 8-3 can be simplified.
(8) The combustion heat of the burner 19 of the auxiliary heat source 18 is used, the combustion heat is exchanged with the heat medium HM2, and the heat of the heat medium HM2 is used for heating the hot water hHW. The temperature is raised.
(9) Using the mixing valve 16-1 of the hot water supply unit 4-1, if the temperature of the hot water HW from the heat exchanger 12-1 is equal to or higher than the set temperature T, the hot water HW and the feed water W are mixed, The temperature of the hot water HW is adjusted to the set temperature T. In this case, when the hot water supply unit 4-1 can discharge hot water at the set temperature T, the mixing valve 16-2 of the hot water supply unit 4-2 fully opens the bypass path 8-7, and the heating medium HM2 by the burner 19 is opened. No heating is performed.
(10) When the heat medium temperature on the upper layer side of the heat medium tank 6 becomes lower than the set temperature T + β, the drive of the burner 19 is started. In the burner 19, a heat medium circulation path 8-8 and a heat exchanger 12-2 are provided, and heat of the heat medium HM2 is exchanged with the hot water HW. That is, the warm water HW is indirectly heated by the burner 19 to obtain the warm water hHW.
(11) When the temperature of the upper layer of the heat medium tank 6 falls below the set temperature T + β during the hot water supply, the burner 19 is driven in advance to heat the heat medium HM2, and the heat medium of the hot water supply unit 4-1. Prepare for hot water shortage due to insufficient heat of HM1.
(12) When the detected temperature T4 becomes less than the set temperature T due to running out of hot water in the hot water supply unit 4-1, the heat of combustion of the burner 19 is exchanged with the heat medium HM2, and the heat of the heat medium HM2 is exchanged with the hot water HW. The mixed water mHW discharged from the hot water is adjusted to the set temperature T by the mixing valve 16-2 using the hot water HW having a high temperature and the hot water HW before heat exchange.
(13) Even if the temperature of the hot water HW obtained from the mixing valve 16-1 of the hot water supply unit 4-1 is drastically lowered, the heating medium HM2 on the burner 19 side is preheated. The mixed water mHW can be controlled to the set temperature T by the mixing ratio of the hot water HW and the heated hot water HW, and the tapping temperature can be stabilized.
(14) When the amount of heat in the heat medium tank 6 is insufficient, the mixing valve 16-1 is fully open on the hot water HW side, and when the hot water HW is discharged, the heat amount of the heat medium HM1 in the heat medium tank 6 can be fully utilized.
(15) The hot water supply units 4-1 and 4-2 may be integrated or separated. If such hot water supply units 4-1 and 4-2 can be separated, the degree of freedom of installation and the ease of maintenance can be achieved.
(16) When the hot water is not discharged, the mixing valve 16-2 is fully opened to the heat exchanger 12-2 side under the condition that the detected temperature T5 of the temperature sensor 10-5 is lower than the set temperature T (T5 <T). Since the bypass path 8-7 side is fully closed, even when the bypass path 8-7 side is fully opened at the start of hot water, switching requires a certain amount of time, and the mixing valve 16-2 is subjected to heat exchange. Since the heated hot water HW on the side of the vessel 12-2 flows out, the hot water HW can be prevented from staying.
(17) For example, when a maximum water flow rate of 24 [liter / min] is passed as the feed water flow rate, a grace period of about 10 seconds is required until the hot water HW exchanged with the heat medium HM1 of the temperature sensor 10-1 flows out. Yes, even when the detected temperature T1 of the temperature sensor 10-1 is lower than the set temperature T + β (T1 <T + β), the heating medium HM2 in the heat exchanger 12-2 can be sufficiently heated during such a grace period. Therefore, even if the circulation delay of the heat medium HM1 occurs, the temperature of the hot water discharged can be stabilized.

FIG. 18 shows the relationship between the hot water supply temperature on the hot water supply unit 4-2 side and the heat medium HM2 according to the second embodiment.
The second embodiment shows an example of the hot water supply capacity of the hot water supply unit 4-2 alone. The horizontal axis indicates the temperature of the hot water supply, and the vertical axis indicates the transition of the temperature of the heating medium HM2. As is apparent from this result, in the hot water supply unit 4-2, the set temperatures Ta, Tb, and Tc (for example, Ta = 35 [° C.], Tb = 40 [° C.], Tc = 45 [T] of the hot water HW and the hot water HW are set. Temperature control of the heating medium HM2 is performed.

FIG. 19 shows a hot water supply system 52 according to the third embodiment. 19, the same parts as those in the hot water supply system 2 shown in FIG. 1 or the cogeneration system 20 shown in FIG. 8 are denoted by the same reference numerals.
The hot water supply system 52 includes the hot water supply unit 4-1 and the fuel cell unit 22 described above, and is configured independently of the hot water supply unit 4-2. That is, the hot water supply system 52 can be configured as a hot water source that provides hot water not only to the hot water supply unit 4-2 but also to other hot water supply systems and hot water supply apparatuses. About each part, since it is as stated above, the same code | symbol is attached | subjected and the description is omitted.

FIG. 20 shows a hot water supply system according to the fourth embodiment. 20, the same parts as those in FIG. 1 or FIG.
This hot-water supply system 52 shows an example of the hot-water supply unit 4-2 separated from the hot-water supply unit 4-1, and is connected to the hot-water supply unit 4-1 by a pipe line and is set to the set temperature T by cooperative control with the hot-water supply unit 4-1. The hot water HW to be controlled can be discharged.
The hot water supply system 52 has a hot water supply function, a heating function, and a bathtub water replenishment function. Hot water HW is supplied to the hot water supply path 8-6 from the hot water supply unit 4-1 side, and hot water HW or mixed water mHW is discharged. In this embodiment, heat exchangers 12-31, 12-32 and 12-33 for exchanging heat of combustion of the burner 19 are provided. The heat exchanger 12-31 heat-exchanges mainly sensible heat of combustion heat to the heat medium HM2, and the heat exchanger 12-32 heat-exchanges mainly latent heat of combustion heat to the heat medium HM2, and the heat exchanger 12-33. Exchanges mainly latent heat of combustion heat into hot water HW in the hot water supply passage 8-6. Therefore, in this embodiment, the heat of the heating medium HM2 is exchanged with the hot water HW by the heat exchanger 12-2, and mainly the latent heat of the combustion heat is exchanged by the heat exchanger 12-33.

In the burner 19, the amount of gas combustion is controlled by the combustion control unit 46, and the control of the combustion control unit 46 includes air supply control by a fan, proportional valve control for a hot water supply request of the fuel gas G, and combustion switching control of the burner 19. It is.
A remote control device 50 is connected to the control unit 32 via a communication line 56, and the remote control device 50 includes the remote control control unit 36-4 described above. The communication line 56 may be connected to the hot water supply system 52 to acquire the detected temperature T1 information of the temperature sensor 10-1, notify the hot water supply set temperature T, and the like.
During heating, the heating medium HM2 is circulated to heat dissipation devices such as the heating panel 58-1 and the convector 58-2 by the heating circuit 8-10 branched from the heating medium circulation path 8-8.
A heat exchanger 12-5 that exchanges heat of the heat medium HM2 with the bath water BW is installed in the heat medium circulation path 8-8. A bathtub 60 is connected to the heat exchanger 12-5 via a memorial circuit 8-11. Therefore, when the bath water BW is replenished, the bath water BW is circulated to the heat exchanger 12-5 through the recirculation circulation path 8-11 by driving the circulation pump 14-4, and the heat of the heat medium HM2 is transferred to the bath water BW. Is heat exchanged.

The hot water supply system 52 may use the control unit 32 (FIG. 10) described above. In the fourth embodiment, the control of the mixing valve 16-2 and the combustion control of the burner 19 are performed based on the determination of no remaining hot water in the control unit 32. The determination that there is no remaining hot water may be made by comparing the detection temperature T1 of the temperature sensor 10-1 with the set temperature T. For example, when the transition is made to T1 <T, only the hot water HW is set, that is, without using auxiliary heating. What is necessary is just to have no remaining hot water when the hot water supply at the temperature T is impossible.
According to such a hot water supply system 52, the hot water HW can be heated by the heating medium HM2 and controlled by the hot water adjustment function similar to the hot water supply unit 4-2.

<Effects of Examples 1 to 4>
According to Examples 1 to 4, the following effects can be obtained.
(1) According to such a configuration, the hot water supply function of the hot water supply system 52 can be utilized for the temperature adjustment function of the hot water supply unit 4-2. Therefore, the existing hot water supply apparatus can be used when installing the hot water supply unit 4-2.
(2) If such a system is used, since the heating medium HM1 of the heating medium tank 6 is used in advance as described above, the utilization efficiency of the heating medium HM1 of the heating medium tank 6 can be increased. Moreover, stable hot water at the set temperature T of the hot water HW can be performed.
(3) In the above embodiment, the heating medium HM2 performs a combustion operation in advance and is heated to 75 [° C.] or higher, so the hot water HW that has passed through the heat exchanger 12-2 is heated to 75 [° C.] or higher, Heated hot water HW is obtained and is very hygienic.

[Other Embodiments]
a) In the above-described embodiment, the hot water supply system 52 is not provided with a hot water storage tank, but may be configured with a hot water storage tank.
b) Although the accumulator 28 is provided in the heat medium circulation path 8-8 in the first embodiment, the accumulator 28 may be omitted.

As described above, the most preferable embodiment of the present invention has been described. The present invention is not limited to the above description. Various modifications and changes can be made by those skilled in the art based on the gist of the invention described in the claims or disclosed in the embodiments for carrying out the invention. It goes without saying that such modifications and changes are included in the scope of the present invention.

In the hot water supply system of the present invention, heat is stored by the heat medium in the heat medium tank. The heat of the heat medium can be used efficiently for hot water heating, and stabilization of the hot water temperature during hot water supply can be achieved.

2 Hot-water supply system 4-1 First hot-water supply unit 4-2 Second hot-water supply unit 6 Heat medium tank 8-1 Heat medium circulation path 8-2 Water supply path 8-3 Heat medium circulation path 8-4 Hot water supply path 8-5 Bypass path 8-6 Hot water supply path 8-7 Bypass path 8-8 Heat medium circulation path 8-9 Heat medium path 10-1, 10-2, 10-3, 10-4, 10-5, 10-6, 10 -7, 10-8, 10-9, 10-10, 10-11, 10-12, 10-13, 10-14 Temperature sensor 12-1, 12-2, 12-3, 12-4, 12- 31, 12-32, 12-33 Heat exchanger 14-1 Circulation pump 14-2 Circulation pump 14-3 Circulation pump 16-1, 16-2 Mixing valve 18 Auxiliary heat source 19 Burner 20 Cogeneration system 22 Fuel cell unit 24 Fuel cell 26-1, 26-2 Flow rate sensor Sensor 28 accumulator 32 control unit 34 broken line 36-1, 36-2 hot water supply unit control unit 36-3 fuel cell unit control unit 36-4 remote control control unit 38-1, 38-2, 38-3 processor 40-1, 40 -2, 40-3 Memory unit 42-1, 42-2, 42-3 System communication unit 44-1, 44-2, 44-3 Input / output unit (I / O)
46 Combustion control unit 48 Fuel cell control unit 50 Remote control device 52 Hot water supply system 56 Communication line 58-1 Heating panel 58-2 Convector 60 Bathtub

Claims (3)

A first heat exchanger for exchanging heat between the exhaust heat of the exhaust heat source and the first heat medium to heat the first heat medium;
A tank for storing the first heat medium;
A heating medium circulation path for flowing the first heating medium taken out from the lower layer of the tank through the first heat exchanger and returning the first heating medium to the upper layer side of the tank;
A temperature sensor for detecting an upper layer temperature of the first heating medium of the tank;
A first hot water supply unit that heats feed water by exchanging heat with the first heat medium by a second heat exchanger;
A second hot water supply unit that receives hot water from the first hot water supply unit and heats it with a heat source, and a second hot water supply unit that exchanges heat with the third heat exchanger to supply hot water;
A control unit that operates the heat source prior to heat exchange of the third heat exchanger, when the temperature detected by the temperature sensor falls below a temperature (T + β) that is higher than a set temperature T by a predetermined temperature β;
Hot water supply system with   2. The second hot water supply unit includes a fourth heat exchanger for exchanging heat generated by the combustion heat source with the second heat medium, wherein the heat source is a combustion heat source for burning fuel gas. Hot water supply system as described in. The hot water supply system according to claim 1, wherein when the temperature detected by the temperature sensor exceeds a temperature (T + β) higher than a set temperature T by a predetermined temperature β, the operation of the heat source is stopped.

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