JP6920839B2 - Hot water supply system - Google Patents

Description

The present invention relates to a technique of a hot water supply system that heats hot water in a bathtub by a heat medium.

Conventionally, a technique of a hot water supply system for heating hot water in a bathtub by a heat medium has been known. For example, as described in Patent Document 1.

Patent Document 1 describes a water heater that calculates the amount of hot water by a hot water amount calculating means according to the hot water supply amount set by the hot water supply setting device and performs the calculated amount of hot water.

However, in the technique described in Patent Document 1, since the temperature of the hot water in the bathtub is not taken into consideration when the hot water is used, the temperature of the hot water in the bathtub may rise too much even if the hot water is used. In some cases, the temperature of the hot water in the bathtub did not rise.

Japanese Unexamined Patent Publication No. 5-231709

The present invention has been made in view of the above circumstances, and the problem to be solved is to provide a hot water supply system capable of accurately setting the hot water temperature in the bathtub (bathtub hot water temperature) to the target temperature. Is.

The problem to be solved by the present invention is as described above, and next, the means for solving this problem will be described.

That is, in claim 1, a heat storage tank in which a heat medium for heating the hot water in the bathtub is stored, a bathtub hot water temperature detecting means for detecting the bathtub hot water temperature, and a bathtub hot water amount detecting means for detecting the bathtub hot water amount. And the heat medium temperature detecting means for detecting the heat medium temperature of the heat storage tank, and the required heat amount for raising the bath water temperature to the target temperature based on the bath water temperature and the bath water amount are calculated, and the heat storage tank heat is calculated. A calculation means for calculating the required heat medium amount for raising the bath water temperature to the target temperature based on the medium temperature and the calculated required heat amount, and the heat medium in the heat storage tank can be heated. A heat pump unit and a control device that controls the operation of the heat pump unit so as to heat the heat medium in the heat storage tank when the calculated required heat medium amount exceeds a predetermined value. Then, the calculation means calculated the required heat medium based on the heat storage tank heat medium temperature after the heat pump unit was operated because the calculated required heat medium amount exceeded the predetermined value. It corrects the amount .

In claim 2 , the heat medium is hot water, and the hot water supply system includes a drainage means for draining hot water in the bathtub and a hot water means for pouring hot water in the heat storage tank into the bathtub. The calculation means calculates the amount of hot water required to raise the bathtub hot water temperature to the target temperature as the required heat medium amount, and the drainage means calculates the required amount of hot water. The hot water in the bathtub is drained by the same amount as the amount of hot water, and the hot water means is to add hot water to the bathtub by the same amount as the calculated required amount of hot water.

As the effect of the present invention, the following effects are exhibited.

In claim 1, the bathtub water temperature can be accurately set to the target temperature. In addition, the time required to raise the bathtub water temperature to the target temperature can be shortened.

In claim 2 , the required hot water time for raising the bathtub hot water temperature to the target temperature can be shortened.

The schematic diagram which showed the overall structure of the hot water supply system which concerns on one Embodiment of this invention. A block diagram showing a configuration related to control of a hot water supply system. The figure which shows the control flow of a hot water. (A) The figure which shows the table which compared the temperature rise time of the bathtub water temperature. (B) The figure which shows the graph which compared the power consumption.

Hereinafter, the configuration of the hot water supply system 1 according to the first embodiment will be described with reference to FIGS. 1 and 2.

The hot water supply system 1 stores the heat generated by the heat pump and supplies the hot water boiled by using the heat. The hot water supply system 1 is appropriately provided in a house or other building or facility. The hot water supply system 1 mainly includes a bathtub 10, a hot water storage tank 20, a heat pump unit 30, a hot water supply mechanism 40, and a control device 50.

The bathtub 10 is a bathtub for bathing hot water. The bathtub 10 is provided in the bathroom.

The hot water storage tank 20 stores heat through the heat medium stored inside. Specifically, the hot water storage tank 20 is filled with water (hot water) as a heat medium.

The heat pump unit 30 consumes electric power to generate (manufacture) heat. The heat pump unit 30 mainly includes a first pipe 31, a compressor 32, a heat exchanger 33, an expansion valve 34, an evaporator 35, a fan 36, a second pipe 37, and a pump 38.

The first pipe 31 forms a flow path for circulating the heat medium (refrigerant). The first pipe 31 is formed in an annular shape. The inside of the first pipe 31 is filled with a heat medium (refrigerant).

The compressor 32 consumes electric power to compress the heat medium flowing through the first pipe 31. The compressor 32 is arranged in the middle of the first pipe 31.

The heat exchanger 33 exchanges heat (heat energy) between fluids having different temperatures. The heat exchanger 33 is arranged in the middle of the first pipe 31. More specifically, the heat exchanger 33 is arranged on the downstream side of the compressor 32 in the distribution direction of the heat medium flowing through the first pipe 31.

The expansion valve 34 expands the heat medium flowing through the first pipe 31. The expansion valve 34 is arranged in the middle of the first pipe 31. More specifically, the expansion valve 34 is arranged on the downstream side of the heat exchanger 33 in the distribution direction of the heat medium flowing through the first pipe 31.

The evaporator 35 is a heat exchanger for evaporating the heat medium. The evaporator 35 is arranged in the middle of the first pipe 31. More specifically, the evaporator 35 is arranged on the downstream side of the expansion valve 34 in the distribution direction of the heat medium flowing through the first pipe 31.

The fan 36 is for sending wind (outside air) to the evaporator 35.

The second pipe 37 forms a flow path for water to circulate between the heat exchanger 33 and the hot water storage tank 20. One end of the second pipe 37 is connected to the lower part of the hot water storage tank 20. The middle part of the second pipe 37 is arranged so as to pass through the inside of the heat exchanger 33. The other end of the second pipe 37 is connected to the upper part of the hot water storage tank 20.

The pump 38 circulates the water in the second pipe 37. The pump 38 is arranged in the middle of the second pipe 37. When the pump 38 is driven, the water in the second pipe 37 flows from one end (lower side of the hot water storage tank 20) of the second pipe 37 toward the other end (upper side of the hot water storage tank 20).

In the heat pump unit 30 configured in this way, the heat medium compressed by the compressor 32 becomes a high-temperature gas. The high-temperature heat medium circulates in the heat exchanger 33 via the first pipe 31. The heat of the heat medium flowing through the heat exchanger 33 is transferred to the heat medium (water) flowing through the second pipe 37. As a result, the temperature of the heat medium flowing through the heat exchanger 33 is lowered, and the heat medium becomes a liquid. The heat medium in the first pipe 31 through which the heat exchanger 33 has passed expands in the expansion valve 34 to become a low-temperature liquid (or gas). The low-temperature heat medium flowing through the expansion valve 34 receives heat from the outside air in the evaporator 35, evaporates, and becomes a gas again. The heat medium that receives heat from the outside air is supplied to the compressor 32 again.

Further, the water flowing through the second pipe 37 receives the heat generated by the heat pump unit 30 by passing through the heat exchanger 33, and the temperature rises. By returning the water whose temperature has risen to the hot water storage tank 20 in this way, the heat obtained by the heat pump unit 30 can be collected in the hot water storage tank 20.

The hot water supply mechanism 40 supplies the water (high temperature water or medium hot water) stored in the hot water storage tank 20 to the bathtub 10. The hot water supply mechanism 40 mainly includes a water injection pipe 41, a hot water supply pipe 42, a mixing pipe 43, a first return pipe 44, a discharge pipe 46, a pump 47, and a three-way valve 48.

The water injection pipe 41 is a pipe that guides clean water to the hot water storage tank 20. One end of the water injection pipe 41 is connected to the lower part of the hot water storage tank 20.

The hot water supply pipe 42 is a pipe that takes out the water (hot water) stored in the upper part of the hot water storage tank 20 and supplies it to the bathtub 10. One end of the hot water supply pipe 42 is connected to the upper part of the hot water storage tank 20. The other end of the hot water supply pipe 42 is connected to the bathtub 10.

The mixing pipe 43 is a pipe for mixing clean water with the water (hot water) flowing through the hot water supply pipe 42. One end of the mixing pipe 43 is connected to the middle part of the water injection pipe 41. The other end of the mixing pipe 43 is connected to the middle part of the hot water supply pipe 42.

The first return pipe 44 is a pipe through which hot water drained from the bathtub 10 flows. The first return pipe 44 is formed as a part of the repulsion circulation path. The repelling circulation path is a flow path for repelling hot water in the bathtub 10. In addition to the first return pipe 44 and the second return pipe 45, which will be described later, the repelling circulation path is a flow path for heat exchange between the hot water in the bathtub 10 and the hot water in the hot water storage tank 20. It has a flow path (not shown) for supplying the hot water warmed by the heat exchange to the bathtub 10 again (not shown). When the hot water in the bathtub 10 circulates in the circulatory passage, the hot water warmed by heat exchange with the hot water in the hot water storage tank 20 can be supplied to the bathtub 10 again. One end of the first return pipe 44 is connected to the bathtub 10.

The second return pipe 45 is a pipe through which hot water drained from the bathtub 10 flows. The second return pipe 45 is formed as a part of the repulsion circulation path. One end of the second return pipe 45 is connected to the other end of the first return pipe 44.

The discharge pipe 46 is a pipe that guides (discharges) the hot water flowing through the first return pipe 44 to the outside. One end of the discharge pipe 46 is connected to a connection portion between the first return pipe 44 and the second return pipe 45.

The pump 47 circulates the hot water in the first return pipe 44. The pump 47 is arranged in the middle of the first return pipe 44. When the pump 47 is driven, the hot water in the first return pipe 44 flows from one end (bathtub 10 side) of the first return pipe 44 toward the other end.

The three-way valve 48 connects the pipes to each other and switches whether or not water can flow. The three-way valve 48 is provided at the connection portion between the first return pipe 44, the second return pipe 45, and the discharge pipe 46. The three-way valve 48 can appropriately switch whether or not hot water can be distributed from the first return pipe 44 to the second return pipe 45 and the discharge pipe 46. Specifically, the three-way valve 48 guides the hot water supplied from the first return pipe 44 to the second return pipe 45 and the hot water supplied from the first return pipe 44 to the discharge pipe 46. And can be switched.

In the hot water supply mechanism 40 configured in this way, a setting panel (not shown) for the user (bath person) to operate is installed in the bathroom provided with the bathtub 10. The setting panel is provided with various buttons such as an automatic hot water button and a hot water button.

When the automatic hot water filling button is pressed, a pump (not shown) is driven, and the hot water taken out from the hot water storage tank 20 via the hot water supply pipe 42 is mixed with the clean water supplied through the mixing pipe 43. In this way, by appropriately mixing the water (hot water) from the hot water storage tank 20 and the clean water, it is possible to obtain water (hot water) having a temperature corresponding to the demand. The water (hot water) mixed in this way is supplied to the bathtub 10 via the hot water supply pipe 42. In this case, the water (hot water) stored in the hot water storage tank 20 is taken out through the hot water supply pipe 42, and the clean water is supplied to the hot water storage tank 20 through the water injection pipe 41. In this way, the inside of the hot water storage tank 20 is always filled with water.

When the hot water button is pressed, a pump (not shown) is driven, and hot water taken out from the hot water storage tank 20 via the hot water supply pipe 42 is supplied to the bathtub 10 (hot water). The details of the control of the hot water will be described later.

The automatic hot water filling button can be used, for example, when hot water is supplied from scratch when there is no hot water in the bathtub 10. On the other hand, the hot water button can be used, for example, when the bathtub 10 is once filled with hot water and the temperature of the hot water in the bathtub 10 (bathtub hot water temperature) has decreased. When the hot water button is pressed, the hot water in the hot water storage tank 20 having a temperature higher than the bathtub hot water temperature is supplied, so that the bathtub hot water temperature can be raised.

The control device 50 shown in FIG. 2 controls the operation of the hot water supply system 1. The control device 50 is mainly composed of an arithmetic processing unit such as a CPU, a storage device such as a RAM or ROM, an input / output device such as an I / O, and a display device such as a monitor. The control device 50 stores in advance various information, programs, and the like for controlling the operation of the hot water supply system 1. The control device 50 is connected to the upper temperature sensor 51, the lower temperature sensor 52, the incoming water temperature sensor 53, the flow rate sensor 54, and the drainage temperature sensor 55.

The upper temperature sensor 51 detects the temperature of the water (high temperature water) stored in the upper part of the hot water storage tank 20. The upper temperature sensor 51 is arranged at the upper part in the hot water storage tank 20.

The lower temperature sensor 52 detects the temperature of the water (low temperature water) stored in the lower part of the hot water storage tank 20. The lower temperature sensor 52 is arranged at the lower part in the hot water storage tank 20.

The water entry temperature sensor 53 detects the temperature of water supplied from the lower part of the hot water storage tank 20 to the heat exchanger 33 of the heat pump unit 30 via the second pipe 37. The water entry temperature sensor 53 is arranged in the middle of the second pipe 37 (on the upstream side of the heat exchanger 33).

The flow rate sensor 54 detects the flow rate of hot water flowing through the hot water supply pipe 42. The flow rate sensor 54 is arranged in the middle of the hot water supply pipe 42. More specifically, the flow rate sensor 54 is arranged on the downstream side of the connection portion between the hot water supply pipe 42 and the mixing pipe 43 in the distribution direction of the water (hot water) flowing through the hot water supply pipe 42.

The drainage temperature sensor 55 detects the temperature of the hot water flowing through the first return pipe 44. The drainage temperature sensor 55 is arranged in the middle of the first return pipe 44. As a result, the drainage temperature sensor 55 detects the temperature of the hot water drained from the bathtub 10.

Further, the control device 50 is connected to the heat pump unit 30 (compressor 32 or the like) and can control the operation of the heat pump unit 30. Specifically, the control device 50 can operate (operate) or stop the heat pump unit 30.

Further, the control device 50 has a target value of the temperature of water obtained by operating the heat pump unit 30 (specifically, water heated by the heat exchanger 33 by flowing through the second pipe 37) (hereinafter, It is possible to control (referred to as "set hot water storage temperature"). In the present embodiment, the control device 50 can control the set hot water storage temperature step by step. Specifically, the control device 50 according to the present embodiment sets the minimum value of the set hot water storage temperature to 45 ° C., and sets the set hot water storage temperature by 5 ° C. (that is, 50 ° C., 55 ° C., 60 ° C., etc.). It can be changed in stages. The minimum value of the set hot water storage temperature can be set to a value equal to or higher than the hot water supply temperature by the hot water supply mechanism 40.

Further, the control device 50 is connected to the hot water supply mechanism 40 (pump 47 of the hot water supply mechanism 40, etc.) and can control the operation of the hot water supply mechanism 40. Specifically, the control device 50 can operate (operate) or stop the hot water supply mechanism 40.

Further, the control device 50 includes hot water that is poured into the bathtub 10 (specifically, water (hot water) taken out from the hot water storage tank 20 via the hot water supply pipe 42 and clean water supplied via the mixing pipe 43. It is possible to control the target value (hereinafter, referred to as "set hot water filling temperature") of the temperature of the water (hot water) mixed with. In the present embodiment, the control device 50 can control the set hot water temperature in a stepwise manner.

Further, the control device 50 determines the amount of hot water to be poured into the bathtub 10 (hereinafter referred to as "set hot water amount") and the amount of hot water to be added (hereinafter referred to as "set hot water amount"). Can be controlled. The control is performed based on the detection result of the flow rate of the hot water flowing through the hot water supply pipe 42 by the flow rate sensor 54. The control device 50 stops the hot water supply to the bathtub 10 when the flow rate detected by the flow rate sensor 54 reaches the set amount of hot water.

Next, the control related to the hot water will be described with reference to FIG. In the following, the description will be made on the premise that the automatic hot water filling button has already been pressed and the hot water filling has been performed in the bathtub 10.

In step S11, the control device 50 determines whether or not the hot water button on the setting panel has been pressed. The control device 50 makes this determination based on whether or not a signal from the hot water button has been received. When it is determined that the hot water button is pressed (“YES” in step S11), the control device 50 proceeds to step S12. On the other hand, when it is not determined that the hot water button is pressed (“NO” in step S11), the control device 50 returns the process to the first step.

In step S12, the control unit 50 detects the target temperature _{T 1.} The target temperature T ₁ indicates the bathtub hot water temperature (the temperature of the hot water in the bathtub 10) desired by the user. That is, the target temperature T ₁ is a temperature indicating to what temperature the user wants to heat the hot water in the bathtub 10 with the hot water. The target temperature T ₁ is set by operating the setting panel by the user. _{If the user does not set the target temperature T 1} , the target temperature T 1 is set to a predetermined value (for example, 40 ° C.). The control device 50 proceeds to step S13 after performing the process of step S12.

In step S13, the control unit 50 detects the current temperature _{T 2.} The current temperature T ₂ refers to the current hot water temperature in the bathtub 10 (current bathtub hot water temperature). The control device 50 performs a search operation for detecting the _{current temperature T 2.} Specifically, the control device 50 drives the pump 47 to circulate (drain) the hot water in the bathtub 10 to the first return pipe 44. _{Then, the control device 50 can detect the current temperature T 2} by detecting the temperature of the hot water flowing through the first return pipe 44 by the drainage temperature sensor 55. The hot water circulating in the first return pipe 44 is returned to the bathtub 10 as it is through the chasing circulation path. Further, since the purpose of the search operation is _{to detect the current temperature T 2} , it is performed in a very short time. The control device 50 proceeds to step S14 after performing the process of step S13.

In step S14, the control device 50 calculates the required heat quantity Q. Required quantity Q shows the amount of heat required to raise the bath water temperature from the current temperature T ₂ to the target temperature T _1.

Specifically, the required heat quantity Q is calculated using the following equation 1.
Q = (T _1- T ₂ ) x C x V ₁ (number 1)

Here, C is the specific heat of water (hot water). Further, V ₁ is the amount of hot water in the bathtub (the amount of hot water in the bathtub 10). As the bathtub hot water amount V ₁ , the value of the hot water hot water amount set at the time of the first hot water filling is used.

The control device 50 proceeds to step S15 after performing the process of step S14.

In step S15, the control device 50 calculates the required amount of hot water V ₂ based on the required heat amount Q calculated in step S14 and the hot water storage tank hot water temperature T ₃ . _{The hot water temperature T 3} in the hot water storage tank means the temperature of the hot water stored in the hot water storage tank 20. _{More specifically, the hot water storage tank hot water temperature T 3} refers to the temperature of the hot water stored in the upper part of the hot water storage tank 20 (hot water supplied to the bathtub 10 via the hot water supply pipe 42). The required amount of hot water V ₂ refers to the amount of hot water required to raise the bathtub hot water temperature from the current temperature T ₂ to the target temperature T _1.

Specifically, the required amount of hot water V ₂ is calculated using the following equation 2.
V ₂ = Q / {(T _3- T ₁ ) x C} (number 2)

The control device 50 proceeds to step S16 after performing the process of step S15.

In step S16, the control device 50 _{determines whether or not the required amount of hot water V 2} exceeds the threshold value. Here, the threshold value is 50 L. That is, the control device 50 determines whether or not the _{required amount of hot water V 2> 50 L.} The threshold value is set based on the allowable time of the hot water (the time required for the hot water allowed by the user). For example, when the rate of hot water is 10 L / min and the allowable time of hot water is 5 minutes, if the required amount of hot water V ₂ exceeds 50 L, the required time of hot water exceeds 5 minutes, so the threshold value. Is set to 50L. If it is not determined that the required amount of hot water V ₂ > 50 L (“NO” in step S16), the control device 50 proceeds to step S19. On the other hand, when it is determined that the required amount of hot water V ₂ > 50 L (“YES” in step S16), the control device 50 proceeds to step S17.

Here, when YES in step S16, it means that the temperature difference between the hot water storage tank hot water temperature T ₃ and the current temperature T _{2 is small because the hot water storage tank hot water temperature T 3 is relatively low.} Specifically, it is shown that the small temperature difference requires a large amount of hot water V _{2 required to raise the bathtub hot water temperature from the current temperature T 2} to the target temperature T _1.

In step S17, the control device 50 operates the heat pump unit 30. By operating the heat pump unit 30, the water (hot water) in the hot water storage tank 20 is heated. The control device 50 operates the heat pump unit 30 for a predetermined time.

The control device 50 proceeds to step S18 after performing the process of step S17.

In step S18, the controller 50 corrects the required Tashi hot water _{V 2.} Specifically, the modified required amount of hot water V ₂ is calculated using the following equation 3.
V ₂ = Q / {(T _4- T ₁ ) x C} (number 3)

Here, the hot water temperature T ₄ in the hot water storage tank refers to the temperature of the hot water stored in the hot water storage tank 20 after the heat pump unit 30 is operated (step S17). _{Since T 4} > T ₃ when the heat pump unit 30 operates, the required amount of hot water V ₂ after the modification is smaller than the required amount of hot water V _{2 before the modification.} After performing this process, the control device 50 returns the process to step S16. That is, the control device 50 _{repeats the processes from step S16 to step S18 until the required amount of hot water V 2} becomes equal to or less than the threshold value (50 L).

In step S19, the control unit 50, only the calculated required Tashi same amount of hot water V ₂ was, draining hot water bath 10. The control device 50 drains water by driving the pump 47. At this time, the control device 50 switches the three-way valve 48 to a state in which the hot water supplied from the first return pipe 44 is guided to the discharge pipe 46. As a result, the hot water drained from the bathtub 10 is discharged to the outside through the first return pipe 44 and the discharge pipe 46. The control device 50 proceeds to step S20 after performing the process of step S19. When the same amount of drainage as the calculated required amount of hot water V ₂ is completed, the control device 50 switches the three-way valve 48 to a state in which the hot water supplied from the first return pipe 44 is guided to the second return pipe 45.

In step S20, the control unit 50, only calculated the same amount required Tashi hot water V ₂ was to hot plus hot water in the hot water storage tank 20 to the bathtub 10. When the process of step S20 is completed, the control shown in FIG. 2 ends.

As described above, in the hot water supply system 1 according to the present embodiment, the required amount of hot water V _{2 for setting the bathtub hot water temperature to the target temperature T 1 is set each time, instead of adding a predetermined amount of hot water.} calculated, since the hot water to the only the necessary Tashi hot water V _2, or too high a bathtub hot water temperature by plus water, to prevent the tub water temperature conversely or not sufficiently increased to this Can be done.

In the hot-water supply system 1 according to this embodiment, automatically, only necessary Tashi same amount of hot water V ₂ calculated for discharging the hot water bath 10 (step S19). As a result, the amount of cold water in the bathtub 10 is reduced. Then, in order to perform water plus high-temperature hot water after discharge of the cold hot water (step S20), to shorten the time required for raising temperature of the hot water in the bathtub 10 (bath water temperature) up to the target temperature T ₁ of Can be done. Also, if case of no waste water plus for bathtub hot water is increased by the hot water, and many require heat (plus hot water) to raise the bath water temperature to the target temperature T _1. On the other hand, in the hot-water supply system 1 according to this embodiment, since the hot water plus the hot water only bathtub 10 need Tashi same amount of hot water V ₂ calculated from the discharge, before and after the hot water plus a bathtub hot water It does not change. Therefore, the amount of heat (the amount of hot water) for raising the bathtub hot water temperature to the target temperature T _{1 can be reduced as compared with the case where drainage is not performed.}

FIG. 4A shows an actual comparison of the time required to raise the bathtub water temperature by 3 ° C. by each method of chasing, hot water (without drainage) and hot water (with drainage). It was done. In addition, "removal" means that the hot water in the bathtub 10 is circulated in the scavenging circulation path, heat is exchanged between the hot water in the bathtub 10 and the hot water in the hot water storage tank 20, and the hot water is warmed by the heat exchange. This is a method of supplying the hot water to the bathtub 10 again. Incidentally, follow fired, even if the plus hot water of any (Yes drainage) (drainage none) and plus water, was compared to the hot water storage Soyu temperature T ₃ as 50 ° C.. As shown in FIG. 4A, by performing the hot water after discharging the hot water in the bathtub 10, the required time could be shortened from 20 minutes to 4.2 minutes as compared with the chasing. In addition, the required time could be shortened from 5.5 minutes to 4.2 minutes as compared with the case where drainage was not performed.

As described above, especially when the hot water temperature T _{3 of the} hot water storage tank is low, the time required to raise the hot water temperature of the bathtub to the target temperature T _{1 becomes long when the scavenging is performed.} On the other hand, in the hot water supply system 1 according to the present embodiment, the required time can be shortened as compared with the normal chasing.

FIG. 4B shows an actual comparison of the power consumption of each of the methods of chasing, hot water (without drainage) and hot water (with drainage) for each season (winter, intermediate, and summer). Is. _{The hot water temperature T 3} in the hot water storage tank was compared at 65 ° C. for chasing and 50 ° C for other than chasing. As shown in FIG. 4B, by performing the hot water after discharging the hot water in the bathtub 10, the power consumption could be reduced as compared with the case where the hot water was not drained. Further, although not shown in the graph of FIG. 4B, the water consumption can be reduced by performing the hot water after the hot water in the bathtub 10 is discharged, as compared with the case where the hot water is not drained. rice field.

Further, as shown in FIG. 4B, the power consumption of the hot water (with drainage) is substantially the same as the power consumption of the chasing water, and the utility cost merit is not obtained. However, when the amount of repelling is large, a large amount of medium-temperature water due to repelling stays in the hot water storage tank 20, so that the COP (coefficient of performance) during operation of the heat pump unit 30 decreases. Therefore, in this case, there is a possibility that the hot water (with drainage) can obtain the merit of utility cost as compared with the repelling.

Further, in the hot water supply system 1 according to the present embodiment, when the calculated required hot water amount V ₂ exceeds the threshold value, the heat pump unit 30 is operated to operate the hot water temperature in the hot water storage tank 20 (hot water storage tank hot water temperature T). _{Since 3} ) is raised (step S17), the time required to raise _{the bathtub water temperature from the current temperature T 2} to the target temperature T _{1 can be shortened.}

In general, when boiling water in the hot water storage tank 20 using only low-priced midnight electricity, the hot water in the hot water storage tank 20 is stored for a long time from midnight until the time when hot water supply demand occurs (evening to night). There is a need to. When hot water is stored in the hot water storage tank 20 for a long time, the hot water storage loss due to heat dissipation increases. On the other hand, in the hot-water supply system 1 according to this embodiment, as necessary, when hot water demand, since raising the hot water storage Soyu temperature T ₃ by operating the heat pump unit 30 (step S17), the hot water storage Soyu temperature T ₃ The hot water in the bathtub 10 can be warmed without any problem even if it is maintained at a relatively low temperature. Therefore, the hot water storage loss can be reduced, and thus the utility cost can be reduced.

As described above, the hot water supply system 1 according to the present embodiment has a hot water storage tank 20 (heat storage tank) in which hot water (heat medium) for heating the hot water in the bathtub 10 is stored inside, and a current temperature T ₂ (bath water). Drainage temperature sensor 55 (bath water temperature detecting means) for detecting (temperature), flow rate sensor 54 (bath water amount detecting means) for detecting _{bath water amount V 1 , and hot water storage tank hot water temperature T 3} (heat storage tank heat medium temperature) Based on the upper temperature sensor 51 (heat medium temperature detecting means) to detect and the current temperature T ₂ and the bath water amount V ₁ , the required heat amount Q for raising the current temperature T ₂ to the target temperature T _{1 is calculated.} , The required amount of hot water V ₂ (required heat medium amount) _{for raising the current temperature T 2} to the target temperature T _{1 is} calculated based on the hot water storage tank hot water temperature T ₃ and the calculated required heat amount Q. It includes a control device 50 (calculation means).
With this configuration, the current temperature T ₂ (bathtub hot water temperature) can be accurately set to the target temperature T ₁ .

Further, when the heat pump unit 30 formed so as to heat the hot water in the hot water storage tank 20 and the calculated required hot water amount V ₂ exceed a predetermined value, the hot water in the hot water storage tank 20 It includes a control device 50 (calculation means) that controls the operation of the heat pump unit 30 so as to heat hot water.
With this configuration, the time required to raise _{the current temperature T 2} (bathtub hot water temperature) to the target temperature T _{1 can be shortened.}

Further, the control device 50 is calculated based on the _{hot water storage tank hot water temperature T 3} after the heat pump unit 30 operates due to _{the calculated required hot water amount V 2 exceeding the predetermined value.} The required amount of hot water V ₂ is corrected.
With this configuration, the time required to raise _{the current temperature T 2} (bathtub hot water temperature) to the target temperature T _{1 can be shortened.}

Further, the hot water supply system 1 includes a hot water supply mechanism 40 (drainage means) for draining hot water in the hot water storage tank 20, and a hot water supply mechanism 40 (tashi hot water) for pouring hot water in the hot water storage tank 20 into the bathtub 10. comprising a means), the said control device 50, as required heating medium amount, calculates the required Tashi hot water V ₂ for increasing the current temperature T ₂ to the target temperature T _1, the hot water supply mechanism 40 (Draining means) drains the hot water in the bathtub 10 by the same amount as the calculated required hot water amount V _2, and the hot water supply mechanism 40 (hot water means) drains the calculated required hot water amount. The _{same amount as V 2} is added to the bathtub 10.
With this configuration, the time required to raise _{the current temperature T 2} (bathtub hot water temperature) to the target temperature T _{1 can be shortened.}

The hot water storage tank 20 according to this embodiment is an embodiment of the heat storage tank.
Further, the hot water supply mechanism 40 according to the present embodiment is an embodiment of the drainage means.
Further, the hot water supply mechanism 40 according to the present embodiment is an embodiment of the hot water means.
Further, the control device 50 according to the present embodiment is an embodiment of the calculation means.
Further, the upper temperature sensor 51 according to the present embodiment is an embodiment of the heat medium temperature detecting means.
Further, the flow rate sensor 54 according to the present embodiment is an embodiment of the bathtub hot water amount detecting means.
Further, the drainage temperature sensor 55 according to the present embodiment is an embodiment of the bathtub hot water temperature detecting means.
_{Further, the current temperature T 2 according} to the present embodiment is an embodiment of the bathtub hot water temperature.
Also, the hot water storage Soyu temperature T ₃ of the present embodiment is an embodiment of the heat storage tank the heat medium temperature.
Also, hot water V ₂ Tashi required according to the present embodiment is an embodiment of the necessary heat transfer medium volume.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, in the present embodiment, the hot water in the bathtub 10 is drained (step S19), and then the hot water is drained (step S20), but the drainage is not always required.

Further, in the present embodiment, the hot water is added in step S20, but it may be removed. When repelling, the _{repelling time (required repelling time) required to raise the current temperature T 2} to the target temperature T ₁ is calculated in step S15, and the required repelling time is set as the threshold value in step S16. If it exceeds, the heat pump unit 30 is operated. As a result, the bathtub water temperature can be accurately set to the target temperature T _{1 as} in the case of the hot water. Further, in the present embodiment, the hot water storage tank 20 stores water (hot water) as a heat medium, but when it is used for repelling, it stores other fluid as a heat medium. You may.

Further, in the present embodiment, the hot water in the bathtub 10 is discharged to the outside through the discharge pipe 46, but the water stored in the lower part of the hot water storage tank 20 is warmed by heat exchange and then discharged to the outside. It may be what is done. As a result, the heat of the wastewater can be effectively used without being wasted.

Further, in the present embodiment, _{the set hot water amount at the time of the first hot water filling is used as the bathtub hot water amount V 1} , but a water pressure sensor is provided in the bathtub 10 and the bathtub hot water amount V ₁ is detected by the water pressure sensor. You may.

Further, in the present embodiment, the heat pump unit 30 is assumed to operate for a predetermined time, but the present invention is not limited to this, and _{until the hot water temperature T 3 of} the hot water storage tank rises by a predetermined temperature (or a predetermined temperature). It may be operated (until the temperature is reached), and the operating time of the heat pump unit 30 _{varies depending on how much the required amount of hot water V 2} is insufficient with respect to the threshold value. You may.

Further, in the present embodiment, in step S16, the control device 50 _{determines whether or not the required amount of hot water V 2} exceeds the threshold value, but determines the magnitude of the utility cost. May be good. Specifically, the control device 50 has a utility cost (utility cost A) when the heat pump unit 30 is operated and then the hot water is applied, and a case where the heat pump unit 30 is not operated and the hot water is applied. If it is determined that the utility cost A is lower than the utility cost B in comparison with the utility cost (utility cost B), the process proceeds to step S17, and the utility cost A is higher than the utility cost B. If it is determined, the process may proceed to step S19. Further, the control device 50 _{may perform both determination of whether the required amount of hot water V 2} exceeds the threshold value and determination of the magnitude of the utility cost. Specifically, when the control device 50 determines that the required amount of hot water V ₂ exceeds the threshold value and / or the utility cost A is lower than the utility cost B, step S17 is performed. The transition may be performed, and in other cases, the transition to step S19 may be performed.

1 Hot water supply system 10 Bathtub 20 Hot water storage tank 30 Heat pump unit 40 Hot water supply mechanism 50 Control device 51 Upper temperature sensor 54 Flow rate sensor 55 Drainage temperature sensor

Claims (2)

A heat storage tank that stores a heat medium for heating the hot water in the bathtub inside,
Bathtub hot water temperature detecting means for detecting bathtub hot water temperature and
Bathtub hot water amount detecting means for detecting bathtub hot water amount and
Heat storage tank A heat medium temperature detecting means for detecting the heat medium temperature and
The required heat amount for raising the bathtub hot water temperature to the target temperature is calculated based on the bathtub hot water temperature and the bathtub hot water amount, and the bathtub hot water temperature is calculated based on the heat storage tank heat medium temperature and the calculated required heat amount. A calculation means for calculating the amount of heat medium required to raise the temperature to the target temperature, and
A heat pump unit formed so as to heat the heat medium in the heat storage tank, and
When the calculated required amount of heat medium exceeds a predetermined value, a control device that controls the operation of the heat pump unit so as to heat the heat medium in the heat storage tank.
Equipped with
The calculation means is
The calculated required heat medium amount is corrected based on the heat storage tank heat medium temperature after the heat pump unit operates because the calculated required heat medium amount exceeds the predetermined value.
Hot water supply system. The heat medium is hot water,
The hot water supply system
A drainage means for draining hot water in the bathtub and
A hot water means for adding hot water in the heat storage tank to the bathtub, and
Equipped with
The calculation means is
As the required heat medium amount, the required amount of hot water for raising the bathtub hot water temperature to the target temperature was calculated.
The drainage means
Drain the hot water in the bathtub by the same amount as the calculated required hot water amount,
The hot water means
Add hot water to the bathtub in the same amount as the calculated amount of hot water required.
The hot water supply system according to claim 1.

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