JP7699072B2 - Storage tank type hot water supply device - Google Patents

Description

The present invention relates to a storage-type hot water supply device that boils water using electricity generated by a solar power generation system.

Conventionally, there is known a technology that uses a HEMS (Home Energy Management System) to centrally manage energy used in a home. For example, there is known a technology that predicts a time period when the generated power value is sufficient for the HEMS to perform boiling operation so that a storage-type hot water heater linked to a solar power generation system can efficiently boil water using the privately generated power generated by the solar power generation system.

JP 2018-115826 A

The amount of power generated by a solar power generation system varies depending on the weather. For example, the decision as to whether or not to generate power during a specific time period is based on acquired weather forecast information, such as sunny, cloudy, or rainy. Therefore, if the weather during a specific time period is in line with the weather forecast information, the predicted amount of power generation will be obtained, but if the weather forecast information changes, the predicted amount of power generation will not be obtained.

If privately generated electricity is not available, the water will be boiled using commercial electricity supplied from a commercial power source, but the unit price of commercial electricity may vary depending on the time of day. For example, the unit price of electricity may be relatively high during the day. For these reasons, users typically wish to boil water using commercial electricity during times when the unit price of electricity is low, and using privately generated electricity at other times.

The present invention was made in consideration of these circumstances, and aims to provide a storage-type hot water supply device that can heat water using both privately generated electricity and commercial electricity, while reflecting the user's wishes.

In order to solve the above-mentioned problems, the storage type hot water supply device of the present invention comprises a hot water storage tank for storing hot water, a heat pump unit that operates on privately generated power generated by a solar power generation system and commercial power supplied from a commercial power source and boils the hot water, a weather forecast information acquisition unit that acquires weather forecast information for a specified time period at a primary judgment time and a secondary judgment time that arrives after the primary judgment time, an execution determination unit that determines whether or not to execute boiling using the privately generated power by operating the heat pump unit with the privately generated power during the specified time period to boil the hot water by determining whether or not a predicted power generation amount of the privately generated power calculated based on the weather forecast information acquired by the weather forecast information acquisition unit is equal to or greater than a required power generation amount, and The system includes an instruction acceptance unit that causes a display means to display an instruction acceptance screen that accepts instructions to perform or cancel boiling during the specified time period, and an instruction acceptance unit that accepts the instruction to perform or cancel input by a user via an input means of the external terminal, wherein when the execution determination unit determines to perform the boiling based on the weather forecast information acquired at the primary determination time, it determines whether a secondary predicted power generation amount of the self-generated power calculated based on the weather forecast information acquired at the secondary determination time is equal to or greater than the required power generation amount, and when the execution determination unit determines that the secondary predicted power generation amount is less than the required power generation amount, the instruction acceptance unit causes the display means to display the instruction acceptance screen and accepts the instruction to perform or cancel.

The storage-type hot water supply device of the present invention can heat water using both privately generated electricity and commercial electricity, reflecting the user's wishes.

1 is a system configuration diagram of a hot water supply system including a storage type hot water supply device in this embodiment. Functional block diagram of the control unit, remote control, and server. 11 is a flowchart illustrating a daytime boiling determination process executed by the control unit. A conceptual diagram of the processing executed in the water heating device when it is determined in the daytime heating determination process that daytime heating is impossible. 13 is a conceptual diagram of the process executed in the water heating device when it is determined in the daytime boiling determination process that daytime boiling is possible. FIG. FIG. 13 is an explanatory diagram conceptually showing information required to execute the daytime boiling determination process when the standard mode is selected. FIG. 13 is an explanatory diagram conceptually showing information required to execute the daytime boiling determination process when the active mode is selected. A figure showing an example of a display screen when information necessary to perform the daytime boiling judgment process is received from a user on a user terminal. 11 is a flowchart illustrating a daytime boiling instruction acceptance process executed by the control unit.

An embodiment of the hot water storage type hot water supply device according to the present invention will be described with reference to the attached drawings.

Figure 1 is a system configuration diagram of a hot water supply system 100 including a hot water storage type hot water supply device 1 in this embodiment.

The hot water supply system 100 includes a distribution board 2, a solar power generation system 3, a server 6, and a storage-type hot water supply device 1 (hereinafter simply referred to as "hot water supply device 1").

The distribution board 2 is installed in a building such as a house (hereinafter simply referred to as "house") together with the solar power generation system 3 and the hot water supply device 1. The distribution board 2 is connected to a commercial power source 2a and the solar power generation system 3. The distribution board 2 supplies commercial power supplied from the commercial power source 2a and privately generated power generated by the solar power generation system 3 to the hot water supply device 1 used in the house and to electrical load devices in the house other than the hot water supply device 1, such as an air conditioner (hereinafter simply referred to as "air conditioner, etc. 7" in the following explanation and in FIG. 1).

The solar power generation system 3 has a solar power generation panel 4 and an inverter 5. The solar power generation panel 4 is installed on the roof of a house, for example. The inverter 5 converts the power generated by the solar power generation panel 4 into AC power.

The server 6 is connected to the water heating apparatus 1 and the user terminal 9 via the network 8. The server 6 transmits and receives information (details of which will be described later) necessary for various processes executed by the water heating apparatus 1 to and from the water heating apparatus 1 and the user terminal 9. The user terminal 9 is a device owned by the user of the water heating apparatus 1 that can communicate with the server 6 via the network 8, such as a smartphone, tablet, or personal computer.

The hot water supply device 1 has a hot water storage tank 10, a heat pump unit 19, a circulation circuit 27, a remote control 32, and a control unit 31.

The hot water tank 10 stores hot water to be supplied to hot water supply terminals such as baths and kitchens. The hot water tank 10 has a water supply pipe 11, a hot water outlet pipe 12, a water supply bypass pipe 13, a hot water supply pipe 15, and a hot water temperature sensor 18.

The water supply pipe 11 is connected to the bottom of the hot water storage tank 10 and supplies water to the hot water storage tank 10. The hot water outlet pipe 12 is connected to the top of the hot water storage tank 10 and supplies hot water from the hot water storage tank 10. The water supply bypass pipe 13 is a pipe branched off from the water supply pipe 11 and is connected to the hot water outlet pipe 12 via a mixing valve 14. The mixing valve 14 mixes the hot water from the hot water outlet pipe 12 and the water from the water supply bypass pipe 13 to the hot water supply temperature set by the remote control 32.

The hot water supply pipe 15 supplies hot water supplied through the mixing valve 14 to the hot water supply terminal. The hot water supply pipe 15 has a hot water supply flow rate sensor 16 and a hot water supply temperature sensor 17. The hot water supply flow rate sensor 16 detects the hot water supply flow rate and outputs a corresponding detection signal to the control unit 31. The hot water supply temperature sensor 17 detects the hot water supply temperature and outputs a corresponding detection signal to the control unit 31.

The hot water temperature sensor 18 detects the temperature of the hot water in the hot water tank 10 and outputs a corresponding detection signal to the control unit 31. A plurality of hot water temperature sensors 18 are provided at different height positions on the side of the hot water tank 10. Each of the plurality of hot water temperature sensors 18 outputs a corresponding detection signal to the control unit 31 when it detects a hot water temperature equal to or higher than a predetermined threshold value, which is preset in advance to correspond to the temperature of hot water in a sufficiently heated state. The control unit 31 detects the amount of hot water in the hot water tank 10 that is in a sufficiently heated state (i.e., the amount of hot water stored) based on the number of hot water temperature sensors 18 that output detection signals.

The heat pump unit 19 operates on privately generated electricity and commercial electricity, and exchanges heat with hot water to boil the water. The heat pump unit 19 has a compressor 20, a water-refrigerant heat exchanger 21, an expansion valve 22, an air heat exchanger 23, a refrigerant pipe 26, and a blower 24.

The compressor 20 compresses and transports the refrigerant to a high temperature and high pressure. The water-refrigerant heat exchanger 21 exchanges heat between the high temperature, high pressure refrigerant and the water from the hot water storage tank 10. The expansion valve 22 reduces the pressure and expands the refrigerant that has been heat exchanged in the water-refrigerant heat exchanger 21. The air heat exchanger 23 exchanges heat between outside air and the low pressure refrigerant, evaporating the low pressure refrigerant. The refrigerant pipe 26 circulates the refrigerant through the compressor 20, the water-refrigerant heat exchanger 21, the expansion valve 22, and the air heat exchanger 23. The blower 24 blows outside air to the air heat exchanger 23.

The heat pump unit 19 also has a discharge temperature sensor 25 and an outside air temperature sensor 30. The discharge temperature sensor 25 detects the temperature of the refrigerant discharged from the compressor 20 and outputs a corresponding detection signal to the control unit 31. The outside air temperature sensor 30 detects the outside air temperature and outputs a corresponding detection signal to the control unit 31.

The circulation circuit 27 circulates the hot water in the hot water storage tank 10 between the hot water storage tank 10 and the water-refrigerant heat exchanger 21. The circulation circuit 27 has a heating forward pipe 27a, a heating return pipe 27b, a heating circulation pump 28, and a boiling temperature sensor 29.

The heating forward pipe 27a connects the lower part of the hot water storage tank 10 to the water side inlet of the water-refrigerant heat exchanger 21. The heating return pipe 27b connects the water side outlet of the water-refrigerant heat exchanger 21 to the upper part of the hot water storage tank 10. The heating circulation pump 28 is disposed on the heating forward pipe 27a and circulates hot water. The boiling temperature sensor 29 is disposed on the heating return pipe 27b and outputs a detection signal to the control unit 31.

The remote control 32 has an input unit 33 and a display unit 34. The input unit 33 accepts instructions from the user regarding the water heating device 1, such as the set temperature of hot water supplied to the hot water terminal. The display unit 34 displays the required information to be presented to the user.

The control unit 31 has a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), etc., and stores various programs and data necessary for the control of the control unit 31. The control unit 31 controls the operation of the entire hot water supply device 1 in accordance with the various programs. The control unit 31 is connected to a remote control 32 and communicates with the remote control 32 in both directions.

The control unit 31 has functions in particular for executing the daytime boiling determination process and the daytime boiling instruction acceptance process (both described below). Here, FIG. 2 is a functional block diagram of the control unit 31, the remote control 32, and the server 6. In FIG. 2, only the functions particularly necessary for the daytime boiling determination process and the daytime boiling instruction acceptance process are illustrated, and other functions are omitted. The control unit 31 has a memory unit 50, a weather forecast information acquisition unit 41, an execution determination unit 42, a mode acquisition unit 43, an instruction acceptance unit 44, and a boiling execution unit 45.

The memory unit 50 stores information acquired from the user terminal 9 for the daytime boiling determination process, such as selected mode information 51, system capacity information 52, boiling time period information 53, in-house power consumption information 54, and area information 55, which will be described later.

The weather forecast information acquisition unit 41 acquires weather forecast information 61 for a specified time period from the server 6 at the primary judgment time and at a secondary judgment time that arrives after the primary judgment time. The weather forecast information 61 is weather defined by cloud cover, for example, three types: sunny, cloudy, and rainy. Sunny is weather with the least cloud cover and the highest power generation efficiency of the solar power generation system 3. Cloudy is weather with more cloud cover than sunny and with a lower power generation efficiency of the solar power generation system 3 than sunny. Rainy is weather in which the solar power generation system 3 does not generate power, or even if it does generate power, the power generation efficiency is lower than sunny and may be lower than cloudy.

The specified time period is a time period included in the daytime when the solar power generation system 3 is capable of generating power (hereinafter referred to as the "power generation time period"), for example, from 9:00 to 15:00. The weather forecast information acquisition unit 41 acquires weather forecast information 61 for each specified hour (for example, every hour) during the power generation time period from the server 6.

The execution determination unit 42 determines whether or not to perform boiling water using the self-generated power at any time during the power generation time zone based on the predicted power generation amount of the self-generated power. The predicted power generation amount is calculated based on the weather forecast information 61 acquired by the weather forecast information acquisition unit 41 (described later). Boiling water using self-generated power is an operation in which the heat pump unit 19 is operated using the self-generated power at any time during the power generation time zone to boil the hot water circulating through the circulation circuit 27. The execution determination unit 42 refers to the selected mode information 51 stored in the memory unit 50 and makes a determination based on the selected determination mode.

The mode acquisition unit 43 acquires information on the judgment mode selected by the user from the user terminal 9. The mode acquisition unit 43 stores the acquired judgment mode in the storage unit 50 as selected mode information 51. The judgment mode is a mode related to the judgment of the execution judgment unit 42, and is provided for the user to select. The judgment modes consist of a standard mode and an aggressive mode.

The standard mode is a mode in which the execution determination unit 42 determines that boiling will be performed using self-generated electricity during the day only when there is a high degree of certainty that the self-generated electricity required for boiling can be obtained (for example, when the weather forecast information 61 is sunny). The proactive mode is a mode in which the execution determination unit 42 determines that daytime boiling will be performed even when there is a lower degree of certainty that the self-generated electricity required for boiling can be obtained than is assumed in the standard mode (for example, when the weather forecast information 61 is cloudy).

That is, the proactive mode makes it easier for the execution determination unit 42 to determine that daytime boiling using self-generated power is to be performed than the standard mode. For example, the standard mode is a mode in which it is determined that daytime boiling using self-generated power is to be performed only when it is sunny, whereas the proactive mode is a mode in which it is determined that daytime boiling using self-generated power is to be performed when it is sunny or cloudy. "Cloudy" has a range of cloud cover, and the same "cloudy" includes cases where the cloud cover allows the required amount of power to be obtained and cases where the cloud cover does not allow the required amount of power to be obtained. Therefore, even if it is determined that daytime boiling using self-generated power is to be performed when the proactive mode is selected, the certainty of obtaining the amount of power generated is lower than in the standard mode. That is, on cloudy days with a lot of cloud cover, there is a risk that sufficient self-generated power cannot be secured, and daytime boiling must be performed using commercial power, which has a relatively high unit price for electricity, in order to boil the required amount of water.

The instruction receiving unit 44 performs the necessary display on the display unit 34 and the user terminal 9 during the daytime boiling instruction receiving process described below, and receives instructions input from the input unit 33 and the user terminal 9.

The boiling execution unit 45 boils water using commercial power or privately generated power at the required timing.

Next, the daytime boiling determination process executed by the control unit 31 of the water heater 1 in this embodiment will be described in detail. First, as a premise for the daytime boiling determination process, the issues that the water heater 1 has will be described.

The water heater 1 boils hot water using commercial electricity or privately generated electricity. The electricity rate for commercial electricity is set higher during the day (specified time period) than at night (time periods other than the specified time period). For this reason, when using commercial electricity, it is preferable for the water heater 1 to boil hot water at night (night boiling operation) rather than during the day (daytime boiling operation) in order to reduce the burden on the user's electricity bill.

At the same time, if a solar power generation system 3 is installed in a house together with the hot water heater 1, it is preferable to boil hot water using self-generated electricity rather than commercial electricity. Here, the power generation efficiency of the solar power generation system 3 varies depending on the hours of sunlight and the amount of solar radiation. Therefore, in order for the hot water heater 1 to boil hot water using self-generated electricity, it is necessary for the solar power generation system 3 to obtain the amount of electricity required by the user during the daytime.

For example, if the HEMS centrally manages the energy used in the home, the water heater 1 can obtain the actual amount of power generated by the solar power generation system 3 and a predicted amount of power consumed in the home, and can determine whether or not to use self-generated power to boil water depending on the amount of power generated. However, this is currently difficult in homes that do not have a HEMS installed.

In other words, the hot water supply device 1 determines based on the weather forecast information 61 that it can obtain the amount of self-generated power required for daytime heating the next day, and by reducing the amount of heating at night, it is possible to reduce the amount of commercial electricity used and increase the amount of self-generated power used.

When the actual amount of power generated and the actual amount of power consumed by electrical load devices other than the hot water heater 1 can be grasped by the HEMS, this actual amount of power generated and the actual amount of power consumed can be used to predict the amount of surplus power available for water heating using self-generated power during the day. However, in homes that do not have a HEMS installed, the accuracy of predicting the amount of surplus power is relatively low because the actual amount of power generated cannot be used. For this reason, even if it is decided to perform daytime water heating the next day, there is a risk that the amount of power will not actually be obtained and water will be heated using daytime commercial power, which has a higher unit price for electricity.

In order to ensure that surplus electricity from the solar power generation system 3 is available for use in heating the hot water heater 1, it is preferable to decide to perform daytime heating only when the weather forecast information 61 indicates sunny weather, which is highly efficient at generating electricity, and to perform nighttime heating to heat the entire required amount of hot water when it is cloudy or rainy, and not to perform daytime heating.

However, if the system capacity of the solar power generation system 3 is large, a certain amount of power can be generated even on cloudy days, so some users may wish to actively perform daytime heating. Therefore, the water heating device 1 executes a daytime heating determination process to perform daytime heating using self-generated power while reflecting the wishes of each user.

Figure 3 is a flowchart explaining the daytime boiling determination process executed by the control unit 31.

Figure 4 is a conceptual diagram of the process executed by the water heater 1 when it is determined in the daytime boiling determination process that daytime boiling is not possible.

Figure 5 is a conceptual diagram of the process executed by the water heater 1 when it is determined in the daytime boiling determination process that daytime boiling is possible.

This daytime boiling determination process is executed repeatedly, for example, while the water heater 1 is running.

In step S1, the weather forecast information acquisition unit 41 determines whether the primary judgment time has arrived. The primary judgment time is a preset time at which weather forecast information 61 for the power generation time period of the next day is acquired from the server 6. The primary judgment time is, for example, the timing at which night boiling can be completed after it is determined in step S4 described below that the entire amount of hot water that needs to be boiled can be boiled in the night boiling. In addition, from the viewpoint of the accuracy of the weather forecast, it is preferable that the primary judgment time be a time as close as possible to the power generation time period (for example, 11 p.m.).

When the weather forecast information acquisition unit 41 determines that the primary judgment time has not yet arrived (NO in step S1), it waits until the primary judgment time arrives. On the other hand, when the weather forecast information acquisition unit 41 determines that the primary judgment time has arrived (YES in step S1), it acquires weather forecast information 61 from the server 6 in step S2. Here, FIG. 6 is an explanatory diagram conceptually showing information required to execute the daytime boiling judgment process when the standard mode is selected. FIG. 7 is an explanatory diagram conceptually showing information required to execute the daytime boiling judgment process when the aggressive mode is selected. In FIG. 6, the weather forecast information 61 acquired at the primary judgment time and the weather forecast information 61 acquired at the secondary judgment time are shown. In FIG. 7, the weather forecast information 61 acquired at the primary judgment time is shown.

The weather forecast information acquisition unit 41 acquires weather forecast information 61 for the corresponding region from the server 6 based on the regional information 55 relating to the region of the house in which the hot water supply device 1 is installed. Here, FIG. 8 shows an example of a display screen when the user terminal 9 receives information required for the daytime boiling determination process from the user.

The user terminal 9 can be used by, for example, downloading and installing an application program (app) created and provided exclusively by the water heating apparatus 1 from a specified server. The user terminal 9 sends instructions for operating the water heating apparatus 1 to the water heating apparatus 1 via this app, and receives and views the current usage status and past usage history of the water heating apparatus 1. The control unit 31 provides the user terminal 9 with the necessary information required for these processes, and executes the instructions obtained from the user terminal 9 in the water heating apparatus 1. In this embodiment, the control unit 31 accepts the necessary information from the user terminal 9 on the display screen 9a of Figure 8 as the initial setting for executing the daytime boiling determination process.

The control unit 31 acquires the regional information 55 by accepting information about prefectures and municipalities from the user terminal 9 via the app. The memory unit 50 stores the acquired regional information 55.

The server 6 stores in advance weather forecast information 61 for multiple locations across the country, provided, for example, by a weather information provider. Alternatively, when the water heating device 1 requests weather forecast information 61, the server 6 acquires the weather forecast information 61 from a specified data server. The weather forecast information acquisition unit 41 requests and acquires the corresponding weather forecast information 61 from the server 6 based on the regional information 55. The weather forecast information acquisition unit 41 acquires hourly weather forecast information 61 for the power generation time period from 9:00 to 15:00, as shown in, for example, Figures 6 and 7. Note that in Figures 6 and 7, the weather forecast information 61 for the time "9:00" indicates weather forecast information for one hour from 9:00 to 10:00.

In step S3, the execution determination unit 42 determines whether or not to perform daytime boiling of water using privately generated power during the power generation time period by operating the heat pump unit 19 with privately generated power to boil water. That is, the execution determination unit 42 determines whether or not to perform boiling of water using privately generated power instead of commercial power during the power generation time period by determining whether or not the predicted power generation amount (primary predicted power generation amount) of privately generated power calculated based on the weather forecast information 61 acquired at the primary determination time is equal to or greater than the required power generation amount.

Specifically, the execution determination unit 42 calculates the predicted power generation amount based on the contents of the obtained weather forecast information 61, i.e., the power generation rates assigned to sunny, cloudy, and rainy days. The execution determination unit 42 also compares the surplus power amount obtained by subtracting the amount of power consumed by the air conditioner etc. 7 (hereinafter simply referred to as "household power consumption") from the predicted power generation amount with the amount of power consumed by the heat pump unit 19 when boiling water. The execution determination unit 42 compares the surplus power amount with the amount consumed by the heat pump unit 19 (hereinafter simply referred to as heat pump power consumption), and if the surplus power amount is greater than the heat pump power consumption, determines to boil water using self-generated power.

As described above, the judgment mode is set by the user when the mode acquisition unit 43 accepts the selection via the user terminal 9. On the display screen 9a of the user terminal 9 in FIG. 8, the judgment mode is set by selecting the "aggressive" button or the "standard" button. The mode acquisition unit 43 stores information related to the judgment mode accepted by the user as selected mode information 51.

When the standard mode is selected, the execution determination unit 42 sets the power generation rate to 0.6 if the weather forecast information 61 is sunny. Also, if it is cloudy or raining, the power generation rate is set to 0. When the aggressive mode is selected, the power generation rate is set to 0.6 if the weather forecast information 61 is sunny. Also, if it is cloudy, the power generation rate is set to 0.4. Also, if it is raining, the power generation rate is set to 0.

When the aggressive mode is selected, the power generation rate is set so that it is higher when it is cloudy than when the standard mode is selected. In other words, the execution determination unit 42 uses different methods for calculating the predicted power generation amount when the standard mode is selected and when the aggressive mode is selected. This makes it easier to determine that water boiling should be performed using self-generated electricity when the aggressive mode is selected by the user than when the standard mode is selected.

The predicted power generation amount is calculated by multiplying the system capacity of the solar power generation system 3 by the power generation rate assigned to the obtained weather forecast information 61. The system capacity is the amount of power generated per unit time (per hour) of the solar power generation system 3, and is a value that represents the power generation capability, and is a value unique to the solar power generation system 3. As shown in FIG. 8, the control unit 31 receives the system capacity from the user terminal 9 on the display screen 9a of the app, and stores it in the memory unit 50 as system capacity information 52.

When the standard mode is selected and weather forecast information 61 such as that shown in FIG. 6 is obtained, the execution determination unit 42 calculates the predicted power generation amount for each hour by multiplying the system capacity and the power generation rate.

The home power consumption is, for example, the average home power consumption per unit time (per hour), and is a value set by the user. The control unit 31 stores the home power consumption received from the user terminal 9 via the display screen 9a in the memory unit 50 as home power consumption information 54.

The execution determination unit 42 calculates the amount of surplus power by subtracting this in-house power consumption from the predicted power generation amount. In other words, the amount of surplus power is defined as the system capacity x power generation rate - in-house power consumption.

The heat pump power consumption is a value obtained by multiplying the amount of power consumed by the heat pump unit 19 during boiling water, which is preset and stored in the control unit 31, by a small additional coefficient. The heat pump power consumption is a value that can vary depending on the season, day of the week, etc. For example, the heat pump power consumption is normally set to a value of 1 kW multiplied by a coefficient of 1.2. Also, in winter, when the heat pump unit 19 is used more frequently, it is set to a value of 1.5 kW multiplied by a coefficient of 1.2.

In step S4, the execution determination unit 42 determines whether daytime boiling of hot water is possible with the surplus amount of self-generated power by determining whether the calculated surplus amount of power is greater than the amount of power consumed by the heat pump. The execution determination unit 42 determines that daytime boiling is possible when the surplus amount of power consumed by the heat pump is greater for a continuous period of time required for boiling (e.g., three hours). For example, in the examples of Figures 6 and 7, the surplus amount of power consumed by the heat pump is greater for three consecutive hours in both determination modes, and the operation determination is O, so the execution determination unit 42 determines that daytime boiling is possible.

If the execution determination unit 42 determines that daytime boiling is not possible (NO in step S4), then in step S5, nighttime boiling is performed to boil the entire amount of hot water that needs to be boiled (see FIG. 4). That is, because the required hours of sunlight or amount of solar radiation are not available during the daytime of the following day and daytime boiling cannot be performed, or because the amount of surplus electricity is less than the amount of power consumed by the heat pump, the entire amount of hot water is boiled using commercial electricity during the night when the electricity rate is low. The control unit 31 then returns to step S1 and repeats the subsequent processes.

On the other hand, if the execution determination unit 42 determines that daytime boiling is possible (YES in step S4), then in step S6 it determines the start time of daytime boiling. The execution determination unit 42 determines the start time of daytime boiling to be the earliest time period among the times obtained consecutively for the time required for boiling. This is because weather forecast information 61 for a time close to the timing at which the weather forecast information 61 was acquired is said to have a high degree of accuracy. For example, in the examples of Figures 5 to 7, 9:00, the earliest time period among the times during which daytime boiling can be performed for three consecutive hours, is determined to be the start time.

The execution determination unit 42 may also receive from the user the setting of the time period for performing daytime boiling. On the display screen 9a of the user terminal 9 in FIG. 8, the time period setting is received by selecting the "Early" button, the "Standard" button, or the "Late" button. The control unit 31 stores the information on the boiling time period received from the user terminal 9 in the memory unit 50 as boiling time period information 53. The peak power generation of the solar power generation system 3 differs for each user depending on the installation angle of the solar power generation panel 4, etc. For this reason, the water heating device 1 allows the user to select the time period for performing daytime boiling using self-generated electricity, thereby performing boiling that is suited to each user's environment.

In step S7, the boiling execution unit 45 boils a portion of the amount of hot water that needs to be boiled using commercial power at night (see FIG. 5). That is, since it is predicted that the required hours of sunshine and amount of solar radiation will be available during the daytime the next day, a portion of the hot water that needs to be boiled (e.g., 20 to 60% of the total amount) is boiled using commercial power at night when the electricity rate is low.

In step S8, the weather forecast information acquisition unit 41 determines whether the secondary judgment time has arrived. The secondary judgment time is a preset time (e.g., 7:00) at which weather forecast information 61 for the power generation time period on the day when daytime boiling is performed is acquired from the server 6. The secondary judgment time is a time before the start time of daytime boiling, which is performed in step S13 described later.

If the weather forecast information acquisition unit 41 determines that the secondary judgment time has not yet arrived (NO in step S8), it waits until the secondary judgment time arrives. On the other hand, if the weather forecast information acquisition unit 41 determines that the secondary judgment time has arrived (YES in step S8), in step S9, it acquires the weather forecast information 61 from the server 6 in the same manner as in step S2.

The weather forecast information acquisition unit 41 acquires hourly weather forecast information 61 for the power generation time period from 9:00 to 15:00, as shown in FIG. 6, for example.

In step S10, the execution determination unit 42 determines whether there has been a change in the weather forecast information 61 acquired at the secondary determination time relative to the weather forecast information 61 acquired at the primary determination time. If the execution determination unit 42 determines that there has been a change (YES in step S10), in step S11, the start time of daytime boiling is determined based on the changed weather forecast information 61 acquired at the secondary determination time. The execution determination unit 42 determines the earliest time period among the times at which the time required for boiling is continuously obtained as the start time of daytime boiling. The execution determination unit 42 may also determine the start time so that daytime boiling is performed during the time period when the total amount of surplus electricity over three consecutive hours is the largest.

For example, in the example of FIG. 6, the weather forecast information 61 from 10:00 to 11:00 changed from sunny to cloudy, so the surplus power amount was smaller than the heat pump power consumption, and the operation judgment was changed to ×. Therefore, the execution judgment unit 42 judges that daytime boiling with a start time of 9:00 is not possible. The execution judgment unit 42 determines that 11:00, which is the time when daytime boiling can be performed for three consecutive hours, is the start time. Note that in step S11, if the surplus power amount is smaller than the heat pump power consumption and there is no time when the time required for boiling is continuously available, the control unit 31 proceeds to the daytime boiling instruction acceptance process in FIG. 9 described later.

If it is determined that there is no change in the weather forecast information 61 (NO in step S10) and after step S11, in step S12, the control unit 31 determines whether the start time determined in the start time determination step S6 or S11 has arrived. If the control unit 31 determines that the start time has not yet arrived (NO in step S12), it waits until the start time arrives. On the other hand, if it determines that the start time has arrived (YES in step S12), in step S13, the boiling execution unit 45 boils the remaining amount of hot water that needs to be boiled using self-generated electricity (see Figure 5). The control unit 31 then returns to step S1 and repeats the subsequent processes.

In the daytime boiling determination process described above, by acquiring the required information from the user and weather forecast information 61, it is possible to easily realize the link between the solar power generation system 3 and the water heater 1. Therefore, the water heater 1 can use the self-generated electricity by the solar power generation system 3 for boiling water while reflecting the wishes of each user.

Here, even if it is determined that daytime heating is possible based on the weather forecast information 61 acquired at the primary judgment time (YES in step S4), the weather forecast information 61 acquired at the secondary judgment time may change (YES in step S10), making it difficult to heat up daytime water using self-generated power. For example, even if the weather forecast information 61 acquired at the primary judgment time is sunny, the weather forecast information 61 acquired at the secondary judgment time may be rain. In this case, the primary predicted power generation amount of the self-generated power calculated at the primary judgment time may be greater than the required power generation amount (surplus power amount > heat pump power consumption), but the secondary predicted power generation amount of the self-generated power calculated at the secondary judgment time may not meet the required power generation amount. In this case, the remaining amount of hot water that needs to be boiled and is allocated for daytime heating cannot be boiled by the self-generated power, so there is a risk of a shortage of hot water storage. Therefore, the remaining required amount of hot water can be obtained by using commercial electricity to heat water during the day, but as mentioned above, the electricity rate is higher during the day, which places a greater financial burden on users than at night. In other words, users run the risk of having to use commercial electricity during the day, when the electricity rate is relatively high, to heat water during the day.

In this embodiment, the water heater 1 determines at the primary determination time that daytime heating using self-generated electricity should be performed, and if the secondary predicted power generation amount calculated at the secondary determination time does not meet the required power generation amount, the water heater 1 determines whether or not to perform daytime heating, reflecting the user's judgment.

Figure 9 is a flowchart explaining the daytime boiling instruction acceptance process executed by the control unit 31.

The daytime boiling instruction acceptance process may be started when the secondary predicted power generation amount is calculated based on the weather forecast information 61 obtained at the secondary judgment time and does not meet the required power generation amount, or may be started simply when the weather forecast information 61 at the secondary judgment time changes to information that results in a lower power generation efficiency than the weather forecast information 61 at the primary judgment time. For example, the daytime boiling instruction acceptance process is started when the time during which the surplus power amount is equal to or greater than the heat pump power consumption amount is not obtained continuously for the time required for boiling (e.g., 3 hours) in step S11 of FIG. 3, or when the weather was sunny or cloudy at the primary judgment time but changed to cloudy or rainy at the secondary judgment time.

In step S21, the instruction receiving unit 44 of the control unit 31 displays an instruction receiving screen on the display unit 34 of the remote control 32 to receive an instruction to perform or stop boiling during the power generation time period. Alternatively, the instruction receiving unit 44 displays it on the user terminal 9 via an app. The instruction receiving screen is composed of information for selecting whether to perform or stop daytime boiling, for example. At this time, the instruction receiving unit 44 notifies the user that when daytime boiling is performed, the amount of power generated by the private power generation may be insufficient, and daytime boiling using commercial power may be performed, and that the electricity fee will increase accordingly. The instruction receiving unit 44 notifies the user, for example, "The weather forecast has changed. Electricity fees may increase due to daytime boiling operation. Do you want to continue boiling operation?" The remote control 32 and the user terminal 9 output the instruction received via the input unit 33 or the like to the control unit 31.

In step S22, the instruction receiving unit 44 determines whether or not an instruction to cancel daytime boiling has been received. If the instruction receiving unit 44 determines that an instruction to cancel has been received (YES in step S22), in step S23, the control unit 31 displays on the display unit 34 or the user terminal 9 that the scheduled boiling will not be performed and the amount of stored hot water will decrease due to the cancellation of daytime boiling. The control unit 31 also displays a message that the amount of stored hot water is decreasing, a warning to encourage water conservation, and a message to encourage the user to manually increase the amount of stored hot water (add to the amount of stored hot water). The control unit 31 notifies the user, for example, "The amount of stored hot water is less than usual. If the amount of stored hot water is insufficient, please add more hot water."

In step S24, the boiling execution unit 45 cancels the scheduled daytime boiling based on the user's instructions.

On the other hand, if the instruction receiving unit 44 determines that it has not received an instruction to cancel (NO in step S22), in step S25, the boiling execution unit 45 performs daytime boiling as scheduled. When the instruction receiving unit 44 does not receive an instruction to cancel, this includes when it receives an instruction to perform and when it does not receive either an instruction to perform or to cancel because the user does not notice the notification. In other words, when the user's instructions are not received and the user's wishes cannot be understood, the instructions received on the setting screen in FIG. 8 described above are given priority, and daytime boiling is performed. The boiling execution unit 45 performs boiling using privately generated electricity, and when the required privately generated electricity cannot be obtained, performs boiling using commercial electricity. Alternatively, when the weather is rainy, for example, the boiling execution unit 45 may not perform boiling using privately generated electricity, and may only perform boiling using commercial electricity.

After steps S24 and S25, the process ends.

In the water heating device 1 of this embodiment, by executing such a daytime boiling instruction reception process, the control unit 31 can automatically determine whether or not to perform daytime boiling based on the weather forecast information 61, and at the same time, when there is a possibility that commercial power will be used for daytime boiling, the water heating device 1 can have the user decide whether or not to perform daytime boiling even if it means using commercial power. In other words, when the user desires daytime boiling in the hope of boiling water using self-generated power, but there is a possibility that daytime boiling will be performed against the user's will using commercial power, which is a relatively large economic burden, the water heating device 1 can decide whether or not to perform it at the user's discretion. Therefore, the water heating device 1 can perform boiling using self-generated power and commercial power while reflecting the user's wishes.

When the water heater 1 receives an instruction to perform or stop daytime heating, it notifies the user that electricity charges may be high, allowing the user to decide whether to perform or stop the operation appropriately depending on the situation. Furthermore, when the water heater 1 receives an instruction to stop daytime heating, it notifies the user that the amount of hot water storage is decreasing, allowing the user to be made aware of this and to be encouraged to add more hot water or conserve water as appropriate.

Although several embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be embodied in various other forms, and various omissions, substitutions, and modifications can be made without departing from the gist of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are included in the scope of the invention and its equivalents described in the claims.

For example, in step S3 of the daytime boiling determination process, an example was described in which the conditions for the determination are different for standard mode and aggressive mode, but there is no need to have multiple modes, and the determination may be made under certain conditions.

Also, an example of executing the daytime boiling determination process in FIG. 3 and the daytime boiling instruction acceptance process in FIG. 9 has been described using an example in which the water heating device 1 is not connected to a HEMS, but the same processes can be executed even if the water heating device 1 is connected to a HEMS.

The server 6 obtains and stores the information required for the daytime boiling determination process from the user, but the control unit 31 may obtain the information directly from the user.

1. Storage tank type hot water supply system (hot water supply system)
3 Photovoltaic power generation system 6 Server 7 Air conditioner, etc. 8 Network 9 User terminal 10 Hot water storage tank 19 Heat pump unit 27 Circulation circuit 31 Control unit 32 Remote control 33 Input unit 34 Display unit 41 Weather forecast information acquisition unit 42 Execution determination unit 43 Mode acquisition unit 44 Instruction reception unit 45 Boiling execution unit 50 Memory unit 51 Selected mode information 52 System capacity information 53 Boiling time zone information 54 In-house power consumption information 55 Area information 61 Weather forecast information 100 Hot water supply system

Claims (6)

A hot water storage tank for storing hot water;
a heat pump unit that operates using privately generated power generated by a solar power generation system and commercial power supplied from a commercial power source to heat the hot water;
a weather forecast information acquisition unit that acquires weather forecast information for a predetermined time period at a primary determination time and a secondary determination time that arrives after the primary determination time;
an execution determination unit that determines whether or not to operate the heat pump unit with the self-generated power during the specified time period to boil the hot water by determining whether or not a predicted power generation amount of the self-generated power calculated based on the weather forecast information acquired by the weather forecast information acquisition unit is equal to or greater than a required power generation amount; and
an instruction receiving unit that displays an instruction receiving screen for receiving an instruction to start or stop boiling during the predetermined time period on a display means of the external terminal and receives the instruction to start or stop boiling input by a user via an input means of the external terminal;
Equipped with
when it is determined to execute the boiling based on the weather forecast information acquired at the primary determination time, the execution determination unit determines whether or not a secondary predicted power generation amount of the self-generated power calculated based on the weather forecast information acquired at the secondary determination time is equal to or greater than the required power generation amount,
The instruction receiving unit, when it is determined by the execution determining unit that the secondary predicted power generation amount is less than the required power generation amount, causes the display means to display the instruction receiving screen and receives an instruction to execute or cancel.
A storage type hot water supply device characterized by the above . The hot water storage type hot water supply device according to claim 1, further comprising a boiling execution unit that executes boiling using the privately generated power during the specified time period when the instruction reception unit receives an instruction to execute or when neither the instruction to execute nor the instruction to cancel is received, and executes boiling using the commercial power when the required privately generated power is not available. The hot water storage type hot water supply device according to claim 1 or 2, wherein the predetermined time period is a time period during which the electric power rate unit price of the commercial electric power is higher than time periods other than the predetermined time period. The hot water storage type hot water supply device according to claim 3, wherein the instruction receiving unit notifies the user that the commercial electricity rate will increase if the water heating is performed during the specified time period, and receives an instruction to perform or cancel the water heating. The hot water storage type hot water supply device according to any one of claims 1 to 4, wherein the instruction receiving unit, when receiving the instruction to stop, issues a notification that the amount of hot water stored in the hot water storage tank is decreasing or a notification to encourage the user to increase the amount of hot water stored. The hot water storage type hot water supply device according to any one of claims 1 to 5, wherein the instruction receiving unit receives an instruction to perform or stop boiling water during the specified time period when the weather forecast information acquired at the first determination time is sunny or cloudy and the weather forecast information acquired at the second determination time is rain.

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