KR101621168B1 - Hot water supply system - Google Patents

Abstract

[PROBLEMS] To provide a technology capable of appropriately responding to a desire to operate a hot water supply system so as to suppress a light / heat ratio and a desire to operate a hot water supply system by energy saving.
[MEANS FOR SOLVING PROBLEMS] A hot water supply system disclosed in this specification includes a heat pump for heating water and a tank for storing water. The hot water supply system can operate in the nighttime boiling mode and the learning cost mode for the boiling operation in which the water of the tank is boiled by the heat pump. The hot water supply system performs boiling operation so that the required amount of heat is stored in the tank during the night time zone in which the nighttime power charge is applied in the nighttime boiling mode. In the learning cost mode, the hot water supply system executes the boiling operation so as to store the required heat amount in the tank until the start time of the hot water supply expected based on the past hot water supply performance.

Description

Hot Water Supply System {HOT WATER SUPPLY SYSTEM}

The technique disclosed herein relates to a hot water supply system.

Patent Document 1 discloses a hot water supply system. The hot water supply system includes a heat pump for heating water and a tank for storing water. In the hot water supply system, the water in the tank is boiled by a heat pump so as to store the required heat amount in the tank during the night time zone when the late night power charge is applied. In the hot water supply system, since the heat pump is driven using low-cost nighttime power, the light and heat ratio can be suppressed to a low level.

Patent Document 1: JP-A-2008-157509

In the configuration in which all of the heat quantity necessary for one day is stored in the tank during the night time zone, energy loss due to heat radiation from the tank is large because there is a time difference between the heat storage in the tank and the actual hot water supply. Further, in a configuration in which all of the heat required for one day is stored in the tank during the night time zone, the amount of heat to be stored in the tank is large, and the boiling temperature in the heat pump is set to be high Needs to be. When the boiling temperature of the heat pump is increased, the COP of the heat pump is lowered, thereby lowering the energy efficiency. As described above, in the configuration in which all of the heat amount necessary for one day is stored in the tank during the night time zone, it is advantageous in view of the light / heat ratio, but there is a disadvantage in terms of energy saving.

In general, there is a demand for the user of the hot water supply system to operate the hot water supply system so as to suppress the light / heat ratio. On the other hand, there is a desire for the user of the hot water supply system to operate the hot water supply system by energy saving, in view of the social upsurge of the recent energy saving consciousness. There is a need for a technique capable of appropriately responding to these demands.

In this specification, techniques for solving the above problems are disclosed. In this specification, a demand for operating the hot water supply system to suppress the light and heat ratio and a technology capable of appropriately responding to the desire to operate the hot water supply system by energy saving are provided.

The hot water supply system disclosed in this specification includes a heat pump for heating water and a tank for storing water. The hot water supply system is operable in the nighttime boiling mode and the learning cost mode for boiling operation in which water in the tank is boiled by a heat pump. The hot water supply system performs the boiling operation so as to store the required heat amount in the tank during the night time zone in which the nighttime power charge is applied in the nighttime boiling mode. In the learning cost mode, the hot water supply system performs boiling operation so as to store the required heat amount in the tank up to the start time of the hot water supply expected based on the past hot water supply performance.

When the hot water supply system operates in the nighttime boiling mode, the water of the tank is boiled so as to secure the required amount of heat in the nighttime when a low-cost night-time electricity charge is applied. On the other hand, when the hot water supply system operates in the learning cost mode, the water in the tank is boiled until the start time of the expected hot water supply, so that the time until the hot water is supplied after being stored in the tank can be shortened , Energy loss due to heat radiation from the tank can be suppressed. In addition, when the hot water supply system operates in the learning cost mode, the amount of heat to be stored in the tank is reduced at a time, so that the water temperature of the tank at the time of storage can be lowered. Therefore, the COP of the heat pump can be improved by lowering the boiling temperature by the heat pump. That is, the hot water supply system operates in the learning cost mode, thereby realizing energy saving. According to the hot water supply system described above, it is possible to cope with a desire to operate the hot water supply system so as to suppress the light / heat ratio and a desire to operate the hot water supply system by energy saving.

The hot water supply system includes means for calculating at least one selected from a light / heat ratio, a primary energy consumption amount and a CO ₂ emission amount when operating in the late night boiling mode, a light / heat ratio when operating in a learning cost mode, An energy consumption amount, and a CO ₂ emission amount.

According to the hot water supply system described above, it is possible to quantitatively evaluate the light / heat ratio and the energy saving for each of the night-time boiling mode and the learning cost mode.

The hot water supply system includes means for presenting to the user a comparison between the case of operating in the late night boiling mode and the case of operating in the learning cost mode with respect to at least one selected from the light / heat ratio, primary energy consumption amount and CO ₂ emission amount As shown in FIG.

According to the hot water supply system described above, it is possible to present useful information to the user when selecting either of the night-time boiling mode and the learning cost mode.

The hot water supply system may further comprise a burner heating device for heating the water.

According to the hot water supply system described above, the actual hot water supply condition is different from the assumed one, and hot water can be supplied using the burner heating device without waiting for another boiling operation even when the heat storage of the tank is used up .

1 is a view schematically showing a configuration of a hot water supply system 2;
2 is a flow chart of a process for setting the boiling temperature and the boiling start time when the hot water supply system 2 executes the boiling operation in the late night boiling mode.
Fig. 3 is a diagram showing the relationship between the amount of heat supplied during one day and the amount of heat of the tank 10 when the hot water supply system 2 performs the boiling operation in the late night boiling mode. Fig.
4 is a flowchart of processing for setting the boiling temperature and the boiling start time when the water heating system 2 executes the boiling operation in the learning cost mode.
5 is a diagram showing the relationship between the amount of heat supplied during one day and the amount of heat of the tank 10 when the hot water supply system 2 executes the boiling operation in the learning cost mode.

(Example)

1, the hot water supply system 2 according to the present embodiment includes a tank 10, a tank water circulation path 20, a tap water introduction path 30, a supply path 40, (50), a burner heating device (60), and a controller (100).

The heat pump 50 is a heat source that absorbs heat from the outside air and heats water in the tank water circulation path 20. The heat pump 50 includes a heat medium circulation path for circulating a heating medium (alternate freon such as R410A or CO ₂ ) not shown, an evaporator for performing heat exchange between the outside air and the heat medium, (Condenser) for performing heat exchange between water in the tank water circuit 20 and the heat medium having a high temperature and a high pressure, and an expansion valve for reducing the pressure of the heat medium after the completion of the heat exchange to make the temperature and pressure low .

The tank 10 stores the hot water heated by the heat pump 50. The tank 10 is of a closed type and is covered on the outside by a heat insulating material. In the tank 10, water is stored up to full water. In this embodiment, the capacity of the tank 10 is 200 liters. Thermistors 12, 14, 16 and 18 are mounted on the tank 10 at predetermined intervals in the height direction of the tank 10. [ Each thermistor 12, 14, 16, 18 measures the temperature of the water at its mounting location.

The tank water circulation passage 20 has an upstream end connected to the lower portion of the tank 10 and a downstream end connected to the upper portion of the tank 10. A circulation pump (22) is fitted in the tank water circulation passage (20). The circulation pump 22 delivers water in the tank water circuit 20 from the upstream side to the downstream side. In addition, the tank water circuit 20 passes through a heat exchanger (not shown) of the heat pump 50. When the circulation pump 22 and the heat pump 50 are operated, the water in the lower part of the tank 10 is heated by the heat pump 50 and the heated water is returned to the upper part of the tank 10. That is, the tank water circuit (20) is a circulating water path for storing water in the tank (10) by boiling the water in the tank (10). A thermistor 24 is fitted on the upstream side of the heat pump 50 of the tank water circuit 20. The thermistor 24 measures the temperature of the water sent from the bottom of the tank 10 to the heat pump 50.

The tap conduit 30 is connected at its upstream end to the tap water supply source 31. A thermistor (32) and a water quantity sensor (33) are fitted to the tap water introduction path (30). The thermistor 32 measures the temperature of tap water. The quantity sensor 33 measures the quantity of tap water supplied to the hot water supply system 2 (that is, the quantity of hot water supplied by the hot water supply system 2). The downstream side of the tap water introduction path 30 branches into the first introduction path 30a and the second introduction path 30b. The downstream end of the first introduction path 30a is connected to the lower portion of the tank 10. The downstream end of the second introduction path 30b is connected in the middle of the supply path 40 to be described later. A mixing valve 42 is provided at a connecting portion between the downstream end of the second introduction passage 30b and the supply passage 40. [ The mixing valve 42 adjusts the amount by which the water in the second introduction path 30b is mixed with the hot water flowing in the supply path 40. [

The supply passage 40 has an upstream end connected to the upper portion of the tank 10. As described above, the second introduction path 30b of the tap water introduction path 30 is connected to the middle of the supply path 40, and the mixing valve 42 is provided at the connection portion. A quantity sensor 41 for measuring the quantity of hot water discharged from the tank 10 is fitted to the supply passage 40 on the upstream side of the connecting portion with the second introduction passage 30b. A burner heating device 60 is fitted to the supply path 40, which is on the downstream side of the connection with the second introduction path 30b. The downstream end of the supply path 40 is connected to a hot water utilization site (e.g., kitchen, bathtub, etc.). A thermistor (44) is fitted to the supply path (40) on the downstream side of the burner heating device (60). The thermistor 44 measures the temperature of the hot water supplied to the hot water usage site. The burner heating device 60 heats the water in the supply path 40 so that the temperature of the hot water measured by the thermistor 44 coincides with the set temperature of the hot water supply.

The controller 100 is electrically connected to each component and controls the operation of each component. Although not shown in Fig. 1, the controller 100 is connected to a remote control unit having an operation unit capable of inputting various instructions by the user and a display unit capable of displaying various kinds of information. In addition, the controller 100 has a timer for acquiring the current time and a memory for storing various data. The memory of the controller 100 stores the number and temperature of the hot water supplied to the hot water usage site, the quantity of hot water sent to the hot water usage site in the tank 10, The change over time such as the amount of heat supplied to the use site is stored as the hot water supply performance. The amount of heat supplied to the hot water use site can be calculated from the amount of hot water supplied to hot water use sites and the temperature difference between hot water and tap water supplied to hot water use sites. In addition, the memory of the controller 100, there are a variety of factors required for the utilities, the calculation of the primary energy consumption and C0 ₂ emission, which will be described later are stored in advance.

Next, the operation of the hot water supply system 2 of the present embodiment will be described. The hot water supply system 2 can mainly perform the boiling operation and the hot water supply operation.

(Boiling operation)

The boiling operation is an operation in which water in the tank 10 is circulated and heated by the heat pump 50. The boiling operation may be referred to as a heat storage operation or a low temperature operation. In the boiling operation, the heat pump 50 is driven and the circulation pump 22 is operated. When the circulation pump 22 operates, water in the tank 10 circulates in the tank water circulation passage 20. That is, water present in the lower portion of the tank 10 is introduced into the tank water circulation passage 20, and the introduced water is heated in the heat exchanger in the heat pump 50 and returned to the upper portion of the tank 10. At this time, the operation of the heat pump 50 and the circulation pump 22 is controlled so that the temperature of the water returned from the heat pump 50 to the tank 10 becomes a predetermined boiling temperature. During the boiling operation, a high-temperature water layer is formed in the upper part of the tank 10, and a low-temperature water layer is formed in the lower part. When boiling operation is continued and all the water in the tank 10 is heated up to the boiling temperature, the boiling operation is terminated.

(Hot water operation)

The hot water supply operation is an operation for supplying water in the tank 10 to hot water use sites. Tap water flows into the lower portion of the tank 10 from the tap water introduction path 30 and the first introduction path 30a by the water pressure from the tap water supply source 31 when the hot water supply passage of the hot water use portion is opened. At the same time, the hot water in the upper part of the tank 10 is supplied to the hot water use place through the supply path 40.

The controller 100 opens the mixing valve 42 when the temperature of the water supplied from the tank 10 to the supply path 40 (i.e., the measured temperature of the thermistor 12) is higher than the hot water setting temperature, The tap water is introduced into the supply path 40 from the line 30b. In this case, the water supplied from the tank 10 and the tap water supplied from the second introduction path 30b are mixed in the supply path 40. The controller 100 adjusts the opening degree of the mixing valve 42 so that the temperature of the water supplied to the hot water use position coincides with the hot water setting temperature. On the other hand, the controller 100 operates the burner heating device 60 when the temperature of the water supplied from the tank 10 to the supply path 40 is lower than the hot water setting temperature. In this case, the water passing through the supply path 40 is heated by the burner heating device 60. The controller 100 controls the output of the burner heating device 60 so that the temperature of the water supplied to the hot water usage point coincides with the hot water setting temperature.

In the hot water supply operation, the COP is high when only the heat storage of the tank 10 is used, without heating by the burner heating device 60, compared with the case of heating by the burner heating device 60. [ Therefore, it is preferable to secure a sufficient amount of heat in the tank 10 in performing the boiling operation prior to the hot water supply operation. The hot water supply system 2 of the present embodiment has the night-time boiling mode and the learning ratio mode in relation to the timing of executing the boiling operation. The user can select a mode such as a late night boiling mode or learning cost mode through a remote controller. The controller 100 automatically performs the boiling operation in accordance with the selected mode. Hereinafter, the modes such as the late night boiling mode and the learning cost will be described.

(Late night boiling mode)

In the nighttime boiling mode, the water in the tank 10 is boiled in the middle of the night time zone (for example, from 23:00 to 7:00) to which a low-priced night-time electricity charge is applied, . When the nighttime boiling mode is selected, the controller 100 executes the processing shown in Fig. 2 every day at a predetermined time (for example, 2:00).

In step S102, the necessary axial heat quantity of the tank 10 is calculated. The required amount of heat of the tank 10 is calculated on the basis of the hot water supply performance in the past predetermined period (for example, 7 days). In the present embodiment, the average value of the total heat amount used in one day in the past seven days is calculated as the necessary heat amount of the tank 10.

In step S104, the boiling temperature of the heat pump 50 is set. The boiling temperature is specified from the required amount of heat of the shaft and the capacity of the tank 10 calculated in step S102. Since the COP of the heat pump 50 is improved as the boiling temperature of the heat pump 50 is lower, in this embodiment, the lowest water temperature required for accumulating the necessary amount of heat by the capacity of the tank 10, (50). In this embodiment, the boiling temperature is set in the range of 35 占 폚 to 90 占 폚.

In step S106, it is determined whether the boiling temperature set in step S104 is equal to or higher than 60 占 폚. When the boiling temperature is 60 DEG C or higher (YES in step S106), the water in the tank 10 is sterilized surely by the subsequent boiling operation, and the process proceeds to step S114. If the boiling temperature is less than 60 占 폚 (NO in step S106), the process proceeds to step S108 to determine whether it is necessary to sterilize the water in the tank 10 or not.

In step S108, it is determined whether or not a quantity equal to or more than the capacity of the tank 10 has been dispatched from the tank 10 to the hot water use site within the past predetermined period (for example, 72 hours). In the case where a quantity of water equal to or more than the capacity of the tank 10 has been dispatched from the tank 10 (YES in step S108), since there is no water staying in the tank 10 for a long period of time, It is not necessary to change the boiling temperature. In this case, the process proceeds to step S114. When the quantity of the capacity equal to or more than the capacity of the tank 10 is not dispatched from the tank 10 (NO in step S108), the process proceeds to step S110.

In step S110, it is determined whether boiling operation has been performed at a boiling temperature of 60 占 폚 or higher within a predetermined period of time (for example, 72 hours). When the boiling operation has been performed at a boiling temperature of 60 deg. C or more (YES in step S110), the water in the tank 10 has just been sterilized and it is not necessary to change the boiling temperature for re-sterilization. In this case, the process proceeds to step S114. When the boiling operation is not performed at the boiling temperature of 60 deg. C or more (NO in step S110), the process proceeds to step S112.

In step S112, the boiling temperature is set to 60 DEG C in order to sterilize the water in the tank 10 in the subsequent boiling operation.

In step S114, the boiling completion time is set. The boil completion time may be, for example, 7:00 at the end of the night time zone during which the nighttime power charge is applied. Alternatively, the boiling completion time may be determined based on an average value (for example, 6:00) of the time when the hot water demand first occurs and a time when the late night time period when the late night power rate is applied ends (for example, For example, 7:00), whichever is faster.

In step S116, the boiling start time is set. The boiling start time is a time at which boiling operation should be started to boil the water in the tank 10 to the boiling temperature by the boiling completion time. The boiling start time can be calculated from the boiling completion time set in step S114, the capacity of the tank 10, and the boiling temperature of the heat pump 50. When the boiling start time is set, the process of Fig. 2 is terminated.

After the execution of the process of Fig. 2, when the boiling start time is reached at which the present time is set, the hot water supply system 2 executes the boiling operation at the set boiling temperature. As a result, the hot water heated to the boiling temperature is stored in the tank 10 until the boiling completion time.

Fig. 3 shows the relationship between the amount of heat supplied to hot water use points during one day and the amount of heat accumulated in the tank 10 when the hot water supply system 2 operates in the nighttime boiling mode. In the nighttime boiling mode, the water of the tank 10 is boiled so as to secure the necessary amount of heat in the daytime in the nighttime when the low-priced night-time electricity charge is applied, so that the light / heat ratio can be suppressed.

(Learning expenses mode, etc.)

In the learning cost mode and the like, the start time of the hot water supply is predicted based on the past hot water supply record, and the water in the tank 10 is boiled just before the start time, and the required heat amount is stored in the tank 10 every time. When the mode such as the learning cost is selected, the controller 100 executes the processing shown in Fig. 4 every day at a predetermined time (for example, 2:00).

In step S202, the time zone in which hot water demand occurs is extracted based on the hot water supply performance in the past predetermined period (for example, 7 days). For example, a time zone in which hot water demand occurs due to washing in the morning, cooking, washing, etc., a time zone in which hot water demand occurs due to the supply of hot water in the bathtub, a shower in bathing, etc. is extracted . In each of the time zones in which the hot water demand occurs, the processes in and after step S204 are executed.

In step S204, the required axial heat quantity of the tank 10 is calculated. The required amount of heat of the tank 10 is calculated as the average value of the amount of heat supplied to the hot water use spot in the past with respect to the hot water demand extracted in step S202.

In step S206, the boiling temperature of the heat pump 50 is set. The boiling temperature is set to a temperature obtained by adding a predetermined value (for example, 5 DEG C) to the hot water supply set temperature. In this embodiment, the boiling temperature is set in the range of 35 占 폚 to 65 占 폚.

In step S208, it is determined whether or not the boiling temperature set in step S206 is 60 DEG C or more. If the boiling temperature is 60 DEG C or higher (YES in step S208), the water in the tank 10 is surely sterilized by the subsequent boiling operation, and the process proceeds to step S216. If the boiling temperature is less than 60 占 폚 (NO in step S208), the process proceeds to step S210 to determine whether it is necessary to sterilize the water in the tank 10 or not.

In step S210, it is determined whether or not the quantity of the quantity exceeding the capacity of the tank 10 has been dispatched from the tank 10 to the hot water use site within the past predetermined period (for example, 72 hours). In the case where the amount of water exceeding the capacity of the tank 10 has been dispensed from the tank 10 (YES in step S210), since there is no water staying in the tank 10 for a long period of time, It is not necessary to change the boiling temperature. In this case, the process proceeds to step S216. In a case where the quantity exceeding the capacity of the tank 10 is not sent out from the tank 10 (NO in step S210), the process proceeds to step S212.

In step S212, it is determined whether boiling operation has been performed at a boiling temperature of 60 占 폚 or higher within a predetermined period (for example, 72 hours) in the past. When the boiling operation has been performed at the boiling temperature of 60 deg. C or higher (YES in step S212), the water in the tank 10 has just been sterilized and it is not necessary to change the boiling temperature for re-sterilization. In this case, the process proceeds to step 216. When the boiling operation is not performed at the boiling temperature of 60 deg. C or more (NO in step 212), the process proceeds to step 214. [

In step 214, the boiling temperature is set to 60 DEG C in order to sterilize the water in the tank 10 in the subsequent boiling operation.

In step 216, the boiling completion time is set. The boiling completion time is set to a time immediately before the time zone in which the hot water demand extracted in Step 202 is generated.

In step 218, the boiling start time is set. The boiling start time is a time at which the boiling operation should be started to boil the water in the tank 10 to the boiling temperature until the boiling completion time. The boiling start time can be calculated from the boiling completion time set in step S216, the capacity of the tank 10, and the boiling temperature of the heat pump 50. [

When the boiling temperature and the boiling start time are set for each of the hot water demand extracted in step 202, the processing of FIG. 4 is terminated.

After executing the process of Fig. 4, the hot water supply system 2 performs the boiling operation at the set boiling temperature every time the present time becomes the set boiling start time. As a result, the hot water heated to the boiling temperature is stored in the tank 10 until the boiling completion time.

Fig. 5 shows the relationship between the amount of heat supplied to the hot water utilization site during one day and the amount of heat of the tank 10 when the hot water supply system 2 operates in the learning cost mode. In the learning cost mode, the amount of heat stored in the tank 10 can be reduced as compared with the late night boiling mode because the water in the tank 10 is boiled every time it is expected that the hot water demand is expected to occur. Therefore, the heat pump 50 can be operated at a low boiling temperature, and a high COP can be realized. In addition, energy saving can be realized by reducing the amount of heat radiation from the tank 10.

(Contrast display of each mode)

In the hot water supply system 2 of the present embodiment, after calculating the actual light / heat ratio, the primary energy consumption and the CO ₂ emission amount while operating in the nighttime boiling mode, the light / Primary energy consumption and CO ₂ emissions can be calculated. Also, when operating in hakseupbi such mode, the calculated actual utilities, primary energy consumption and C0 ₂ emissions Next, addition, utilities in the case of operating in the middle of the night boiling mode temporarily, primary energy consumption and C0 ₂ Emissions can be calculated.

The controller 100 calculates the light / heat ratio, the primary energy consumption amount, and the CO ₂ emission amount in each mode as follows.

The controller 100 first calculates the gas consumption amount and the power consumption amount, respectively. The gas consumption amount and the electric power consumption amount can use the actual gas consumption amount in the burner heating device 60 and the actual electric power consumption amount in the heat pump 50 as they are. The amount of heat supplied to the burner heating device 60 and the amount of heat supplied to the heat pump 50 from the ratio of use of the burner heating device 60 and the heat pump 50 assumed based on the actual amount of heat supplied to the hot- And the gas consumption amount and the power consumption amount may be calculated from the respective supplied heat amounts. In the latter case, the COP of the burner heating device 60 is taken into account when calculating the gas consumption amount, and the COP of the heat pump 50 and the heat dissipation loss from the tank 10 are taken into consideration in calculating the power consumption.

Regarding the light / heat ratio, the controller 100 calculates the gas rate from the gas consumption amount and the gas amount rate, calculates the electric charges from the electric power consumption amount and the electric power amount rate, and sums them. The gas amount charge and the electric charge amount charge are stored in the controller 100 in advance. In calculating the light / heat ratio, it is also possible to consider the influence of electric power generation of a power generation device (not shown).

Regarding the primary energy consumption, the controller 100 calculates the primary energy consumption of the gas from the gas consumption amount and the primary energy conversion coefficient of the gas, and calculates the primary energy consumption of the power from the primary energy conversion coefficient of the power consumption and the power , And summing them. The primary energy conversion coefficient of the gas and the primary energy conversion coefficient of the electric power are stored in the controller 100 in advance.

For the C0 ₂ emission, the sum them to the controller 100 calculates the gas consumption and C0 ₂ emission power from the output of C0 ₂ emission of the gas, electric power consumption and the power of the C0 ₂ emission factors from the C0 ₂ emission factor for gas . C0 ₂ emission factors and C0 ₂ emission factor of the power of the gas is stored in advance in the controller 100.

The controller 100 displays at least one selected from the light / heat ratio, the primary energy consumption, and the CO ₂ emission amount calculated for each mode on the display unit of the remote controller, thereby providing useful information when the user selects the mode .

Although the embodiments have been described in detail above, they are merely illustrative and do not limit the claims. The techniques described in the claims include various modifications and changes to the specific examples described above.

For example, in the above embodiment, the capacity of the tank 10 is set to 200 liters, and the amount of heat for one day is stored in the tank 10 during the night time zone in the late night boiling mode. The capacity of the tank 10 may be 50 liters or 100 liters so as to store the amount of heat for half a day during the night time zone in the late night boiling mode.

The technical elements described in this specification or the drawings exert their technical usefulness alone or in various combinations, and are not limited to combinations of claim descriptions at the time of filing. In addition, the techniques exemplified in the present specification or drawings are intended to achieve a plurality of objectives at the same time, and achieving one of them is technically useful.

2: hot water supply system 10: tank
12, 14, 16, 18: thermistor 20: tank number circulation loop
22: circulation pump 24: thermistor
30: tap water introduction path 30a: first introduction path
30b: second introduction passage 31: tap water supply source
32: thermistor 33: quantity sensor
40: supply path 41: quantity sensor
42: mixing valve 44: thermistor
50: heat pump 60: burner heating device
100: controller

Claims (4)

As a hot water supply system,
A heat pump for heating the water,
And a tank for storing water,
It is possible to operate in boiling operation mode in which the water of the tank is boiled by the heat pump,
In the late night boiling mode, the boiling operation is performed so as to store the necessary heat quantity in the tank during the night time zone when the late night power charge is applied,
In the learning cost mode and the like, the boiling operation is performed so as to store the required amount of heat in the tank up to the start time of the hot water supply expected based on the past hot water supply performance,
Means for calculating at least one selected from a light / heat ratio, a primary energy consumption amount and a CO ₂ emission amount when operating in a nighttime boiling mode or a learning cost mode,
A comparison between the case of operating in the late night boiling mode and the case of operating in the learning cost mode is presented to the user with respect to at least one selected from the light / heat ratio, the primary energy consumption amount, and the CO ₂ emission amount, And the boiling operation is performed only in the selected one mode.
delete delete The method according to claim 1,
Further comprising a burner heating device for heating the water.

Images