JP2014163641A - Hot water storage type water heater and solar system including hot water storage type water heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hot water storage type water heater capable of improving efficiency of power selling when combined with a photovoltaic power generation device.SOLUTION: A hot water storage type water heater 1 includes a heat pump unit, a hot water storage tank, a control device and the like, and it configures a solar system together with a photovoltaic power generation device 40, a distribution board 42, an HEMS controller 43 and the like. The distribution board 42 includes a function of: distributing power supplied from an electric power company 50 and the photovoltaic power generation device 40 to an electric apparatus such as the hot water storage type water heater 1; and selling power generated by the photovoltaic power generation device 40. The control device makes a correction in such a manner that an execution time zone of a boiling operation does not overlap with a time zone in which photovoltaic power generation is possible, on the basis of at least one piece of information of: electricity charge information including information regarding power selling charge and power buying charge for each time zone; meteorological information including information regarding weather and a sunshine time zone; and hot water supply information including information regarding presence/absence of hot water supply.

Description

  The present invention relates to a hot water storage water heater that heats and stores hot water, and a solar system that can link the operation of a solar power generation device and a hot water storage water heater.

  As a conventional technique, for example, as described in Patent Document 1, a hot water storage type hot water heater capable of performing hot water storage, hot water supply, hot water filling of a bathtub, and the like by heating hot water is known. Further, in the conventional technology, for example, a power control device called a HEMS (Home Energy Management System) is used to manage a supply and demand of energy in the entire house and to construct a system that promotes efficient use of power. In addition, as an example of such a system, a system for reducing the power generation load of the power company by supplying (selling) power generated by solar power generation to the power company is known.

JP 2012-163238 A

  In the conventional technology, for example, a boiling operation for heating (boiling) hot water in a hot water storage tank is performed in the late-night time period when the electricity rate is low, and the boiling operation is not performed during the daytime. However, in a cycle in which hot water boiled in the middle of the night is used in the daytime, the temperature is lowered, that is, energy loss is likely to occur due to heat radiation, so that there is a possibility that the APF (year-round energy consumption efficiency) is lowered. For this reason, in the system of the prior art, the start time of the boiling operation is controlled so that the boiling operation is completed immediately before the end of the midnight time period, and the control for suppressing the heat radiation and increasing the APF is adopted. There are many.

  On the other hand, in a solar power generation and sale system using HEMS, if power is consumed by some devices such as a water heater, surplus power obtained by solar power generation cannot be sold. There are limitations. For this reason, in the prior art, even when the day is different, for example, when the sunrise time arrives before the end of the midnight time zone, power is sold until the midnight time zone (that is, the heating operation) ends. There is a problem that can not be.

  The present invention has been made to solve the above-described problems, and provides a hot water storage type water heater capable of improving the efficiency of power selling when combined with a solar power generation device. Objective. Moreover, an object of this invention is to provide the solar system which can make a solar power generation device and a hot water storage type hot water heater cooperate efficiently.

  The hot water storage type hot water heater according to the present invention includes a solar power generation device that performs solar power generation, a heating device that can heat hot water by being fed from another external power source, and hot water heated by the heating device. Hot water storage tank that stores hot water, a hot water supply circuit that supplies hot water stored in the hot water storage tank to the outside, and a boiling operation that stores hot water heated by the heating device in the hot water storage tank during the electricity discount period when the electricity purchase fee is low The control device calculates the length of time for which the boiling operation should be performed based on the hot water storage state of the hot water storage tank, and reduces the heating operation based on the calculation result of the time length. Boiling control means starting and ending during the time zone, and means for correcting the execution time zone of the heating operation set by the boiling control means, the information regarding the power purchase fee and the power sale fee for each time zone Based on at least one of the electricity price information including the weather information including information on the weather and sunshine hours, and the hot water information including information on the presence or absence of hot water by the hot water circuit, the heating operation execution time zone is determined. Boiling time zone correction means for correction.

  ADVANTAGE OF THE INVENTION According to this invention, the electric power generation time of a solar power generation device is fully ensured, and the generated electric power can be efficiently sold to an electric power company etc. Therefore, when combined with a solar power generation device, a hot water storage type hot water heater capable of improving power selling efficiency can be provided. Moreover, the solar system which can make a solar power generation device and a hot water storage type hot water heater cooperate efficiently can be provided.

It is a block diagram which shows the system configuration | structure of the hot water storage type water heater by Embodiment 1 of this invention. It is a block diagram which shows the solar system by Embodiment 1 of this invention. 5 is a flowchart illustrating an example of control executed by a control device in Embodiment 1 of the present invention.

Embodiment 1 FIG.
The first embodiment of the present invention will be described below with reference to FIGS. FIG. 1 is a configuration diagram showing a system configuration of a hot water storage type hot water heater according to Embodiment 1 of the present invention. As shown in this figure, the hot water storage type hot water heater 1 includes a heat pump unit 2 as a heating device and a tank unit 3. The heat pump unit 2 includes a compressor, a water-refrigerant heat exchanger, an expansion valve, and an air heat exchanger that are annularly connected by a refrigerant circulation pipe, and is supplied with power from a solar power generation device 40 and a power company 50 described later. It operates by. The heat pump unit 2 heats the low-temperature water to generate high-temperature water by performing heat exchange between the low-temperature water introduced from the tank unit 3 and the high-temperature refrigerant flowing through the refrigerant circulation pipe.

  The tank unit 3 includes a hot water storage tank 4, a circulation pump 5, a flow path switching valve 8, a hot water supply mixing valve 12, a bath mixing valve 13, and the like. The hot water storage tank 4 stores hot water heated by the heat pump unit 2, and is constituted by a sealed tank. An outlet 4A, an inlet 4B, and a return port 4C are provided in the lower part of the hot water storage tank 4, and an inlet / outlet 4D is provided in the upper part of the hot water storage tank 4. When hot water flows into the hot water storage tank 4 from the top and low temperature water flows from the bottom, a temperature stratification is formed in which the high temperature water stays on the upper side and the low temperature water stays on the lower side. In the present specification, “hot water” means hot water or water, and “high temperature water” means hot water staying in the upper part of the hot water storage tank 4 or hot water isothermal with this. Further, “low temperature water” means water staying in the lower part of the hot water storage tank 4 or water having the same temperature as this, or tap water, well water, etc. supplied from a water supply pipe 10 described later, and has a temperature lower than that of high temperature water. have.

  The circulation pump 5 circulates hot water between the heat pump unit 2 and the hot water storage tank 4, and is provided in the middle of the heat pump outgoing pipe 6. The heat pump outgoing pipe 6 connects the outlet 4 </ b> A of the hot water storage tank 4 and the inflow side of the heat pump unit 2. The outflow side of the heat pump unit 2 is connected to the inflow port of the flow path switching valve 8 via the heat pump return pipe 7. The flow path switching valve 8 switches the flow path of hot water, and is constituted by, for example, an electromagnetically driven three-way valve having one inflow port and two outflow ports. One outflow port of the flow path switching valve 8 is connected to an inlet / outlet port 4D of the hot water storage tank 4 via a tank upper return pipe 9. Further, the other outflow port of the flow path switching valve 8 is connected to the return port 4C of the hot water storage tank 4 through other piping or the like.

  On the other hand, a water supply pipe 10 is connected to the inlet 4 </ b> B of the hot water storage tank 4. The water supply pipe 10 supplies low-temperature water whose water pressure is adjusted via the pressure reducing valve 11 to the hot water storage tank 4, the hot water supply mixing valve 12 and the bath mixing valve 13. The hot water supply mixing valve 12 and the bath mixing valve 13 are each constituted by an electromagnetically driven three-way valve or the like, and have two inflow ports and two outflow ports. One inflow port of these mixing valves 12 and 13 is connected to an inlet / outlet port 4 </ b> D of the hot water storage tank 4 via a hot water supply pipe 14. The other inflow port of the mixing valves 12 and 13 is connected to the water supply pipe 10. Furthermore, the outflow port of the hot water mixing valve 12 is connected to a hot water supply target such as a hot water tap and a shower via an external hot water supply pipe 15, and the outflow port of the bath mixing valve 13 is connected to a bathtub ( (Not shown).

  The hot water supply mixing valve 12 mixes high temperature water supplied from the heat pump unit 2 and the hot water storage tank 4 via the hot water supply pipe 14 and low temperature water supplied from the water supply pipe 10, and supplies hot water at a desired temperature to the external hot water supply pipe 15. Supply to hot water supply target. The bath mixing valve 13 supplies hot water having a desired temperature, which is a mixture of high-temperature water and low-temperature water, from the bath hot water supply pipe 16 to the bathtub. In the present embodiment, hot water supply mixing valve 12, bath mixing valve 13, hot water supply pipe 14, external hot water supply pipe 15 and bath hot water supply pipe 16 are examples of a hot water supply circuit for supplying hot water stored in hot water storage tank 4 to the outside. Is configured.

  Next, the control system of the hot water storage type hot water heater 1 will be described. The hot water storage type water heater 1 includes a plurality of tank temperature sensors 20 that detect the temperature of the hot water storage tank 4. In FIG. 1, three tank temperature sensors 20 are illustrated. The plurality of tank temperature sensors 20 are attached to the hot water storage tank 4 at different positions in the vertical direction, and the temperature distribution in the hot water storage tank 4 can be detected. The hot water storage type hot water heater 1 detects an inflow temperature sensor 21 that detects the temperature of hot water flowing into the heat pump unit 2, an outflow temperature sensor 22 that detects the temperature of hot water flowing out of the heat pump unit 2, and an outside air temperature. The outside air temperature sensor 23 is provided. Further, although not shown in the figure, the hot water storage type water heater 1 detects the temperature of hot water flowing through the external hot water supply pipe 15, a hot water temperature sensor detecting the flow rate, a hot water flow rate sensor detecting the flow rate, and the temperature of hot water flowing through the bath hot water supply pipe 16. A bath hot water temperature sensor, a bath hot water flow sensor for detecting the flow rate, and the like.

  The tank unit 3 is equipped with a control device 30 that controls the operating state of the hot water storage type hot water heater 1. The control device 30 includes, for example, a storage circuit including a ROM, a RAM, a nonvolatile memory, and the like, an arithmetic processing device (CPU) that executes predetermined arithmetic processing based on a program stored in the storage circuit, and the arithmetic processing device. An input / output port for inputting / outputting external signals is provided. The various sensors described above are connected to the input side of the control device 30. Various actuators including the compressor of the heat pump unit 2, the flow path switching valve 8, the hot water supply mixing valve 12, and the bath mixing valve 13 are connected to the output side of the control device 30.

  Moreover, the control apparatus 30 is comprised so that communication with the remote control 31 with which the hot water storage type water heater 1 was equipped is possible. The remote controller 31 is operated by a user or the like of the hot water storage type hot water heater 1 and switches the operation mode of the hot water storage type hot water heater 1 or sets a target hot water supply temperature or the like. The control device 30 controls the operating state of the hot water storage hot water heater 1 by driving each actuator based on operations and settings performed by the remote controller 31 and the output of each sensor, and switches its operation mode. . A specific example of the operation mode will be described later.

  Next, a solar system including the hot water storage type hot water heater 1 will be described with reference to FIG. FIG. 2 is a configuration diagram illustrating the solar system according to the first embodiment of the present invention. As shown in this figure, the solar system of the present embodiment includes a hot water storage type hot water heater 1, a solar power generation device 40, a power conditioner 41, a distribution board 42, a HEMS controller 43, and the like. The solar power generation device 40 is equipped with a solar cell or the like that receives sunlight to generate power, and executes solar power generation in a time zone from sunrise to sunset. The electric power generated by the solar power generation device 40 is converted from direct current to alternating current by the power conditioner 41 and transmitted to the distribution board 42.

  The distribution board 42 is supplied with electric power from an external power source such as the electric power company 50 and the solar power generation device 40 and distributes the electric power to a plurality of electric devices arranged in the home. The electric devices fed from the distribution board 42 include not only the hot water storage type hot water heater 1 but also other electric devices 44 such as an air conditioner. In addition, the distribution board 42 has a function of selling the electric power generated by the solar power generation device 40 to the electric power company 50.

  A HEMS (Home Energy Management System) controller 43 comprehensively manages the operating states of a plurality of electric devices arranged in the home. The electric devices include a hot water storage hot water heater 1 and a solar power generation device 40. And other electrical equipment 44 is included. The HEMS controller 43 has a function of performing bidirectional data communication with the plurality of electric devices and the distribution board 42, and controls the distribution board 42 while monitoring the operating state and power consumption of each electric device. To do. Thereby, the HEMS controller 43 controls appropriately the electric power distribution supply with respect to each electric equipment, and the electric power sale by the solar power generation device 40. FIG.

  As an example of the above control, the HEMS controller 43 distributes surplus power generated by solar power generation when the amount of power generated by the solar power generation device 40 is larger than the total power consumption of the electrical devices in the home. The control for selling power to the power company 50 is executed. The distribution board 42 and the HEMS controller 43 constitute a specific example of the power distribution apparatus in the present embodiment. Similarly to the remote controller 31, the HEMS controller 43 has an operation unit operated by a user or the like, and has a function of reflecting the operation and setting contents on the operation unit in power distribution control.

  The HEMS controller 43 has a function of acquiring various information including weather information and electricity rate information from the Internet 51. This weather information includes, for example, the sunrise time, sunset time, weather, outside temperature, etc. at the location where the hot water storage hot water heater 1 is installed. Includes information about charges and electricity sales (electricity billing system). Moreover, the HEMS controller 43 detects the power generation information about whether it is during solar power generation via the distribution board 42, and based on this detection result, the past performance in the execution time zone of solar power generation is recorded as a history. It has a function to store (store) data. The history data includes information related to the start time and end time of solar power generation. The history data may be stored in an external server or the like by the HEMS controller 43.

  And the HEMS controller 43 transmits said weather information, electricity bill information, the power generation information of solar power generation, and historical data to the control apparatus 30 of the hot water storage type hot water heater 1 as needed. Accordingly, the HEMS controller 43 constitutes a specific example of information output means in the present embodiment. The various information and history data described above may be transmitted to the control device 30 by the distribution board 42.

  Next, the operation of the hot water storage type water heater 1 will be described. First, the control device 30 executes a hot water supply operation when a user's hot water supply operation is detected based on, for example, the output of an external hot water supply flow rate sensor or a bath hot water flow rate sensor. In the hot water supply operation, the temperature of the hot water supplied to the outside through the external hot water supply pipe 15 and the bath hot water supply pipe 16 is controlled as the target hot water supply temperature by controlling the corresponding mixing valve among the hot water supply mixing valve 12 and the bath mixing valve 13. Match. Moreover, the control apparatus 30 performs the boiling operation which stores the hot water heated by the heat pump unit 2 in the hot water storage tank 4 as needed.

  The boiling operation is executed, for example, when the amount of hot water stored in the hot water storage tank 4 (the amount of stored hot water) is smaller than the reference hot water storage amount that requires the boiling operation. More specifically, the control device 30 detects the temperature distribution in the hot water storage tank 4 based on the output of each tank temperature sensor 20, and calculates the amount of hot water stored in the hot water storage tank 4 based on the detection result. When the calculated hot water storage amount is smaller than the reference hot water storage amount, the heating operation is executed using a power discount time zone such as a midnight time zone when the power purchase fee is cheap. In the following description, the midnight time zone is an example of a power discount time zone.

  In the boiling operation, first, low temperature water such as tap water decompressed by the pressure reducing valve 11 is supplied from the water supply pipe 10 to the hot water storage tank 4. Then, the circulation pump 5 is operated in a state where the heat pump return pipe 7 and the tank upper return pipe 9 are communicated by the flow path switching valve 8. Thereby, the low temperature water staying in the lower part of the hot water storage tank 4 flows out to the heat pump forward piping 6 and flows into the heat pump unit 2 via the circulation pump 5. This low-temperature water is heated to high-temperature water by exchanging heat with a high-temperature refrigerant in the heat pump unit 2. The hot water flowing out of the heat pump unit 2 flows into the upper part of the hot water storage tank 4 through the heat pump return pipe 7, the flow path switching valve 8 and the tank upper return pipe 9 in order, and is stored in the hot water storage tank 4.

  During the boiling operation, the control device 30 controls the output of the heat pump unit 2 and the rotational speed of the circulation pump 5 based on the outputs of the sensors 21 to 23. This control is executed, for example, so that the boiling operation is performed at a constant speed, and the temperature of the high-temperature water flowing out from the heat pump unit 2 becomes the target boiling temperature. The target boiling temperature is set by the remote controller 31 or the like.

  The boiling operation is started and ended during the midnight time period. That is, the execution time zone of the boiling operation (the time zone from the start time to the end time of the boiling operation) is set to be included in the midnight time zone. Specifically, the control device 30 first calculates the amount of hot water stored in the hot water storage tank 4 based on the output of the tank temperature sensor 20, and based on the difference between this calculation result and the target hot water storage amount for the boiling operation. Then, the time length (execution time) at which the boiling operation should be executed is calculated. The target hot water storage amount is set by the remote controller 31 or the like.

  Next, the control device 30 selects the end time of the midnight time zone (for example, 7:00 am) as the end time of the boiling operation, and then calculates the time obtained by back-calculating the execution time from this end time. Set as start time. In the following description, the time setting process described above is referred to as “normal boiling operation control”. That is, in normal boiling operation control, the boiling operation end time is made coincident with the midnight time zone end time, and the boiling operation start time is set by calculating backward from the end time.

  According to the normal boiling operation control described above, the boiling operation can be completed in the midnight time zone when the power purchase fee is cheap, and the cost of the boiling operation can be reduced. However, in a solar system using HEMS, if electric power is consumed by boiling operation or the like, it is not possible to sell power by solar power generation. Therefore, with only normal boiling operation control, there is a possibility of missing an opportunity to sell electricity, for example, when the sunrise time arrives before the end of the midnight time zone. For this reason, the control device 30 corrects the execution time zone of the heating operation based on at least one information among weather information, electricity rate information, hot water supply information regarding the presence or absence of hot water supply, power generation information of solar power generation, and history data. Execute time zone correction control.

  Hereinafter, a specific example of the time zone correction control will be described with reference to FIG. FIG. 3 is a flowchart showing an example of control executed by the control device in Embodiment 1 of the present invention. Each step of the routine shown in this figure is executed within the range of the midnight time zone. Also, at the start of this routine, it is assumed that the start time and end time of the boiling operation used in normal boiling operation control are set.

  In the routine shown in FIG. 3, first, in step S <b> 1, electricity rate information and weather information are acquired from the HEMS controller 43. In step S2, it is determined whether the sunrise time is earlier than the end time of the midnight time zone based on the acquired information. In step S3, it is determined whether the weather is sunny such as solar power generation. Determine. If either of the determinations in steps S2 and S3 is not established, the solar power generation is executed during the midnight time because the sunrise time is after the end of the midnight time zone or the weather is rainy or cloudy. Judge that it is not. In this case, without performing time zone correction control, the process proceeds to steps S4 and S5, and normal boiling operation control is executed.

  On the other hand, when both steps S2 and S3 are established, it is in a state where solar power generation can be performed during the midnight time zone. In this case, in step S6 and subsequent steps, the control for correcting the start time of the solar power generation and the execution time zone of the heating operation and performing the heating operation while avoiding the time zone in which the solar power generation can be executed (early boiling). Up operation control). More specifically, first, in step S6, the past results of solar power generation, the sunrise time and the weather information are acquired from the HEMS controller 43, and the start time of solar power generation is corrected according to the acquired result based on the acquired results. To do.

  Next, in step S7, the end time of the boiling operation set by the normal boiling operation control is corrected based on the start time of the photovoltaic power generation calculated in step S6. Specifically, in step S7, the end time of the boiling operation is set to a time earlier than the start time of the photovoltaic power generation, and the boiling operation is finished before the start of the photovoltaic power generation. According to the control in step S7, when the start time of solar power generation is changed according to the sunrise time, weather, or the like, the end time of the heating operation can be corrected appropriately in accordance with this change. . Therefore, while avoiding the time zone in which solar power generation can be performed, the boiling operation can be completed in the late night time zone, and solar power generation can be started from the earliest possible time.

  Next, in step S8, a power sale adaptable time zone in which the efficiency of power sale by solar power generation is maximized is calculated based on the electricity rate information, and a heating operation execution time zone is calculated with respect to this power sale adaptable time zone. The end time of the heating operation is corrected so as not to overlap. In addition, about two processes shown to step S7, S8, any process may be performed first. In the present invention, only one of these two processes is executed, and the other process need not be adopted. According to the control in step S8, power sale by solar power generation is preferentially executed during the power sale adaptable time zone, and the boiling operation can be executed while avoiding the power sale adaptable time zone. Thereby, boiling operation can be performed smoothly, realizing high power selling efficiency.

  Next, in step S9, the start time of the boiling operation is set based on the end time of the boiling operation calculated in steps S7 and S8 and the execution time of the above-described boiling operation. This start time is set as a time obtained by calculating back the execution time from the end time of the boiling operation. In addition, in this Embodiment, the case where the process of step S1-S9 was performed based on the information acquired from the HEMS controller 43 by the control apparatus 30 of the hot water storage type water heater 1 was illustrated. However, the present invention is not limited to this, and the HEMS controller 43 may execute the processes of steps S1 to S9. In this case, the start time and end time of the boiling operation may be transmitted from the HEMS controller 43 to the control device 30, and the boiling operation may be executed by the control device 30 based on the transmitted information.

  Next, in step S10, whether or not the amount of hot water stored in the hot water storage tank 4 has decreased, that is, whether or not the hot water supply operation has been performed after the execution time of the boiling operation has been set by the normal boiling operation control. Determine. If the determination in step S10 is established, the amount of hot water stored has decreased due to the hot water supply operation, and the process proceeds to step S11. In step S11, the start time of the boiling operation is corrected to an earlier time as compared with the start time set by the normal boiling operation control, and the execution time of the boiling operation is extended. On the other hand, if the determination in step S10 is not established, the process proceeds to step S12. According to the control in steps S10 and S11, even if the hot water storage amount is reduced by the hot water supply operation after the boiling operation execution time has been set, the boiling operation execution time can be extended by that amount. Therefore, the amount of hot water obtained by the boiling operation can be appropriately corrected according to the amount of hot water used.

  Next, in step S12, the boiling operation is started when the start time set in step S9 comes. In step S13, it is determined whether a hot water supply operation has been executed during the boiling operation. If this determination is satisfied, the process proceeds to step S14. In step S14, for example, in a state where the execution time of the boiling operation is kept constant, the capability of generating hot water by the boiling operation (hereinafter referred to as the boiling capability) is increased compared to when the hot water supply operation is not performed. As a method for increasing the boiling capacity, a method for changing the target heating capacity of the heat pump unit 2 to a high value, and a method for changing the target boiling temperature (target heating temperature) of the hot water by the heat pump unit 2 to a low value, There is a method of increasing the boiling temperature and increasing the amount of heat in boiling.

  Here, the heating capacity (kW) of the hot water by the heat pump unit 2 varies depending on, for example, the rotational speed and discharge amount of the compressor of the heat pump unit 2, and the target heating capacity is set as a target value of the heating capacity. Is done. The control device 30 controls the compressor and the like so that the actual heating capacity by the heat pump unit 2 matches the target heating capacity. When the target heating capacity is increased, the amount of heat added to the hot water increases, so that it is possible to shorten the execution time of the boiling operation on the assumption that the amount of heat secured by boiling is constant.

  On the other hand, the target boiling temperature is set by the remote controller 31 or the like as described above, but is changed by the control device 30 as necessary. When the target boiling temperature is lowered, the amount of hot water to be boiled can be increased on the premise that the heating capability of the heat pump unit 2 is constant, so that the execution time of the boiling operation can be shortened. Moreover, in the heat pump unit 2, since the efficiency of the boiling operation tends to increase as the target boiling temperature is lower, the heating capacity itself can be increased.

  In step S14, the boiling operation is continued with the boiling capacity increased in this manner. On the other hand, if the determination in step S13 is not established, the boiling operation is continued without executing the process in step S14. In step S15, when the end time of the boiling operation comes, the heat pump unit 2 and the circulation pump 5 are stopped, and the boiling operation is ended.

  According to the control in steps S13 and S14, even when hot water is used during the boiling operation, the heating capacity of the heat pump unit 2 or the target boiling temperature can be changed to be high. As a result, it is not necessary to delay the end time of the heating operation and extend the execution time, so that the heating operation is prevented from being executed during a time when solar power generation can be performed, and even when using hot water, The execution time of power generation can be secured stably.

  Next, in step S16, it is determined whether or not hot water has been used after the completion of the boiling operation by the early boiling operation control. If this determination is not satisfied, this routine is terminated. Moreover, when determination of step S16 is materialized, it is good also as a structure which transfers to step S17 and performs additional boiling operation only in the midnight time zone. In the additional boiling operation, it is determined in step S18 whether or not the remaining hot water amount in the hot water storage tank 4 has increased beyond the target hot water storage amount. If this determination is satisfied, the boiling operation is terminated in step S19. To do.

  If the determination in step S18 is not established, the process proceeds to step S20, and it is determined whether or not the end time of the midnight time zone has come. And when determination of step S20 is materialized, boiling operation is complete | finished by step S21 even in the state where the amount of remaining hot water does not exceed the target hot water storage amount. As a result, the above-described steps S1 to S21 are all completed during the midnight time period, and then photovoltaic power generation is started when conditions such as weather and sunshine are met. According to the processing of steps S16 to S21, even after the boiling operation is completed, if the amount of stored hot water is reduced due to the use of hot water, additional boiling operation is performed within a range with a margin in the midnight time zone. In addition, the amount of hot water stored can be increased as much as possible.

  Next, the control in step S8 will be described with a specific example. First of all, as a precondition, the power consumption of the hot water storage type hot water heater 1 is 0.05 kW / min, the power charge (electric power purchase charge) in the midnight hours is 12 yen per kW, and the power selling charge is 42 yen per kW. Suppose that If the amount of photovoltaic power generation per unit time exceeds the electricity rate per unit time in the midnight time zone, considering that it is possible to increase economic efficiency by moving the boiling start time forward, the charges described above If the system is in use, the electricity sales fee for one minute of generated power is higher than the electricity fee for electricity used per minute in the hot water storage hot water heater 1 (12 / (1 / 0.05)) = 0.6 yen / minute The condition is (0.6 / 42) kW / min. Under this precondition, if the amount of electric power exceeding (0.6 / 42) kW per minute is sold by solar power generation, the economic efficiency of the electric power selling exceeds the electric power usage efficiency in the midnight hours. In other words, in order to obtain high power selling efficiency, a time zone in which the amount of power generation exceeds (0.6 / 42) kW per minute is set as a power sale suiting time zone, and solar power generation is started in this power sale suiting time zone. Is preferred. Therefore, for example, in the state where the execution time zone of the heating operation is set to the time zone from 1 am to 7 am (end time of the midnight time zone), the power sale suitable time zone is after 6:30 am In some cases, the end time of the boiling operation is corrected to 6:30 am, and the start time of the boiling operation is corrected to 0:30 am accordingly.

  Next, the control in steps S10 to S14 will be described with a specific example. First, as a precondition, it is assumed that the heat pump unit 2 has a heating capability of boiling 90 ° C. warm water by 1 liter per minute, and the execution time of the boiling operation is set from 3 am to 6:30 am. Under this precondition, for example, when 90 liters of hot water of 90 ° C. is used for hot water supply before the start of the boiling operation, the start time of the boiling operation is shortened by one and a half hours to reduce the amount of hot water due to the hot water supply. Can be supplemented. Therefore, in this case, in step S11, the start time of the boiling operation is advanced by 1 hour and a half from 3 am and is corrected to 1:30 am.

  On the other hand, when the same hot water supply is used during the boiling operation, the end time of the boiling operation cannot be delayed in consideration of the start time of solar power generation. Therefore, in this case, the decrease in the amount of stored hot water is compensated by changing the boiling capacity higher in step S14. Specifically, for example, in the heat pump unit 2 having a heating capacity changing function, when the target heating capacity is changed from 4.5 kW to 6.0 kW, the amount of heat added to the hot water is about 1.3 times. Since it increases, the execution time of the boiling operation can be shortened. Moreover, in the heat pump unit 2 that does not have the function of changing the heating capacity, when the target boiling temperature is lowered, the amount of hot water to be heated can be increased as described above, and the execution time of the boiling operation can be shortened. .

  As described above in detail, according to the present embodiment, it is possible to sufficiently secure the power generation time of the solar power generation device 40 and efficiently sell the generated power to the power company 50. Therefore, when combined with the solar power generation device 40, the hot water storage type hot water heater 1 capable of improving the efficiency of power sale can be provided. Moreover, the solar system which can make the solar power generation device 40 and the hot water storage type water heater 1 cooperate efficiently can be provided.

  In the above embodiment, steps S2, S3, S6, S7, S8, S9, S10, and S11 in FIG. 3 are specific examples of time zone correction means. Steps S2 and S3 show a specific example of the photovoltaic power generation determination means, and steps S13 and S14 show a specific example of the boiling capacity changing means. Steps S16, S17, S18, S19, S20, and S21 show specific examples of the boiling addition means. On the other hand, steps S4 and S5 show a specific example of the boiling control means.

  Moreover, in the said embodiment, in step S6 in FIG. 3, the past performance of solar power generation, the sunrise time, and the information of a weather are acquired from the HEMS controller 43, and the start time of solar power generation is based on this acquisition result. A case where the correction is made according to the current situation is illustrated. In this case, in the present invention, the following correction process may be executed by the HEMS controller 43 and the control device 30 functioning as the estimation means. In this correction process, first, based on the difference between the start time of solar power generation estimated from past historical data of weather information and the actual start time of solar power generation (power generation start time from the solar panel) Estimate the start time of solar power generation (estimated start time) (this difference is, for example, the installation environment of solar panels (direction, influence of shade of other buildings, location conditions, etc.) and standard data of weather information and Resulting from individual differences at the location). And the execution time zone of a boiling operation is correct | amended based on the estimation start time of solar power generation so that boiling operation may not overlap with the time zone which can perform solar power generation.

  According to the above configuration, the estimated start time of solar power generation can be accurately calculated based on the difference between past history data of weather information and the actual start time of solar power generation. Then, the execution time zone of the boiling operation can be corrected based on the estimated start time. Therefore, while avoiding the time zone in which solar power generation can be performed, the boiling operation can be completed in the late night time zone, and solar power generation can be started from the earliest possible time.

  Moreover, in the said embodiment, it was set as the structure which correct | amends the execution time zone of a boiling operation based on the weather information and the past performance of the execution time zone of photovoltaic power generation at least. However, the present invention is not limited to this, and the configuration may be such that the execution time zone of the boiling operation is corrected based only on the past performance of the execution time zone of solar power generation without using the weather information. With this configuration, even in a system that does not have a weather information acquisition function, it is possible to obtain substantially the same effect as the present embodiment, and it is possible to widen the application range of the system.

  Moreover, in the said embodiment, the case where electric bill information and weather information were acquired from the internet 51 by the HEMS controller 43 etc. was illustrated. However, the present invention is not limited to this, and the electricity rate information and weather information may be input by operating the operation unit such as the HEMS controller 43 by the user.

  In the present invention, weather information, electricity bill information, power generation information of solar power generation and history data are acquired by the HEMS controller 43, and only the processing result of information obtained directly or indirectly from these information is stored in the hot water storage hot water supply. It is good also as a structure transmitted to the control apparatus 30 of the machine 1. On the other hand, in this invention, it is good also as a structure which mounts the acquisition function of said each information in the hot water storage type hot water supply machine 1, and the control apparatus 30 can acquire such information independently. As a result, even in a system constituted by a single hot water storage type hot water heater 1, substantially the same effect as in the first embodiment can be obtained.

  Moreover, in the said embodiment, although the hot water storage type water heater 1 provided with the heat pump unit 2 was mentioned as an example and demonstrated, this invention is not limited to such a water heater. That is, the present invention may be applied to a heating device that uses a heating method other than the heat pump method, or may be applied to a hot water heater that does not include the hot water storage tank 4 (a hot water heater other than the hot water storage type).

DESCRIPTION OF SYMBOLS 1 Hot water storage type water heater, 2 Heat pump unit (heating device), 3 Tank unit, 4 Hot water storage tank, 5 Circulation pump, 6 Heat pump forward piping, 7 Heat pump return piping, 8 Flow path switching valve, 9 Tank upper return piping, 10 Water supply Piping, 12 Hot water mixing valve (hot water circuit), 13 Bath mixing valve (hot water circuit), 14 Hot water piping (hot water circuit), 15 External hot water piping (hot water circuit), 16 Bath hot water piping (hot water circuit), 20 Tank temperature sensor , 21 Inflow temperature sensor, 22 Outflow temperature sensor, 23 Outside air temperature sensor, 30 Control device (estimating means), 31 Remote control, 40 Solar power generation device, 41 Power conditioner, 42 Distribution board (power distribution device), 43 HEMS Controller (power distribution device, information output means, estimation means), 50 Electric power company (external power supply)

Claims (9)

A solar power generation device that performs solar power generation and a heating device capable of heating hot water by being fed from another external power source;
A hot water storage tank for storing hot water heated by the heating device;
A hot water supply circuit for supplying hot water stored in the hot water storage tank to the outside;
A control device that executes a boiling operation of storing hot water heated by the heating device in the hot water storage tank during a power discount time zone in which a power purchase fee is low,
The controller is
Based on the hot water storage state of the hot water storage tank, a time length for performing the boiling operation is calculated, and the boiling operation is started and ended during the power discount period based on the calculation result of the time length. Control means;
A means for correcting an execution time zone of the boiling operation set by the boiling control means, including electricity rate information including information on a power purchase fee and a power sale fee for each time zone, and weather and sunshine hours Boiling time zone correction means for correcting an execution time zone of the boiling operation based on at least one information of weather information including information on hot water information including information on presence or absence of hot water supply by the hot water supply circuit;
Hot water storage water heater equipped with. Solar power generation determination means for determining whether or not the solar power generation is possible during the power discount period based on the electricity rate information and the weather information;
When it is determined that the solar power generation is possible during the power saving time zone, the boiling time zone correction means sets the execution time zone of the boiling operation earlier than the start time of the solar power generation. The hot water storage type water heater according to claim 1, wherein the hot water storage type water heater is configured to correct the time zone.   The boiling time zone correction means calculates a power sale compatible time zone in which the efficiency of power sale by solar power generation is maximized based on the electricity rate information, and the boiling time is corrected with respect to the power sale compatible time zone. The hot water storage type hot water supply device according to claim 1 or 2, wherein the execution time zone is corrected so that the execution time zones of the operation do not overlap.   The boiling time zone correction means increases the start time of the boiling operation when the amount of hot water stored in the hot water storage tank is reduced after the execution time zone of the boiling operation is set by the boiling control means. The hot water storage type hot water supply apparatus according to any one of claims 1 to 3, wherein the boiling time is extended.   Any one of claims 1 to 4, further comprising a boiling capacity changing means for changing the generation capacity of hot water by the boiling operation to a high level when the amount of hot water stored in the hot water storage tank decreases during execution of the boiling operation. The hot water storage type water heater according to claim 1.   The boiling addition means for performing an additional boiling operation only during the power saving time period when the amount of hot water stored in the hot water storage tank is reduced after the boiling operation is finished. The hot water storage type hot water supply device according to any one of the above. An estimation means for estimating the start time of the photovoltaic power generation based on the difference between the start time of the solar power generation estimated from the past history data of the weather information and the actual start time of the solar power generation,
The boiling time zone correction means corrects the boiling time execution time period based on the estimation result of the estimation means so that the boiling operation does not overlap with the time period during which solar power generation can be performed. The hot water storage type water heater according to any one of claims 1 to 6, which is configured.   2. The heating time zone correction means is configured to correct the execution time zone of the boiling operation based on the past performance of the execution time zone of the photovoltaic power generation without using the weather information. 7. A hot water storage type water heater according to claim 1. A hot water storage type water heater according to any one of claims 1 to 8,
The solar power generation device;
A power distribution device having a function of supplying power to the hot water storage hot water supply device from the solar power generation device and another external power source, and a function of selling power generated by the solar power generation device to the outside;
Information output means for outputting at least information related to the operation of the solar power generation apparatus to the hot water storage type water heater;
With solar system.

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