JP2006064284A - Sunlight heat compound use system, operation control method therefor, program and recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To further reduce a carbon dioxide emission amount by reducing power consumption while satisfying heat demand in time of operation of a sunlight heat compound use system. <P>SOLUTION: This sunlight heat compound use system has: a solar battery 1; a first heat collection means 2 collecting heat from the solar battery 1; a second heat collection means 20 collecting heat from a heat source except the solar battery 1; heat collection changeover means 21, 22 performing a changeover into the first heat collection means 2 or the second heat collection means 20; and a control part 10 controlling the changeover of the heat collection changeover means 21, 22. The control part 10 subtracts a power generation amount generated by the solar battery 1 when collecting heat of the same heat quantity by use of the second heat collection means 20 from a power generation amount generated by the solar battery 1 when using the first heat collection means 2 to calculate a difference P<SB>sd</SB>between the power generation amounts, subtracts a supply power amount when using the first heat collection means 2 from a supply power amount when using the second heat collection means 20 to calculate a difference P<SB>hd</SB>between the supply power amounts, and controls the changeover of the heat collection changeover means 21, 22 on the basis of the difference P<SB>hd</SB>between the supply power amounts and the difference P<SB>sd</SB>between the power generation amounts. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a solar heat combined utilization system using solar energy and natural energy such as atmospheric heat and an operation control method thereof.

  In general, the power generation efficiency of solar cells decreases with increasing temperature. Therefore, conventionally, many techniques for cooling a solar cell and suppressing a decrease in power generation efficiency have been proposed.

  For example, a method of cooling a solar cell with a cooling device such as a circulating water pump as disclosed in Patent Document 1 and a method of collecting heat from a solar cell using an electric heat collecting device as disclosed in Patent Document 2 are proposed. Has been.

Here, an electric heat collecting device represents a device that collects heat using the outside as a heat source when electricity is input. For example, a heat pump such as a heat pump whose efficiency changes due to changes in the heat source temperature. And an electric water heater equipped with a heat medium circulation device. The heat collected by the electric heat collecting device can be supplied to heat demand such as hot water supply or air conditioning.
JP-A-10-201268 JP-A-5-66065

  However, in the conventional operation control method of Patent Document 1, the case where the efficiency of the electric heat collecting apparatus has temperature dependence is not taken into consideration, and the capacity cannot be utilized to the maximum.

  In addition, even the conventional operation control method of Patent Document 2 does not take into consideration the amount of power consumption reduction due to the combination of a solar cell and an electric heat collecting device, and has not made full use of its ability.

  In addition, in order to use the heat collected by the electric heat collecting device for hot water supply or air conditioning, the heat storage container may be used to store heat once. However, in the case of an electric heat collecting device configured to selectively collect heat from solar cells and heat sources other than solar cells, the amount of power consumed when collecting heat from heat sources other than solar cells and when collecting heat from solar cells. Even when the difference is small, heat is actively collected. As a result, the amount of heat that can be collected is limited due to the capacity of the heat storage container when the difference in the amount of power consumption is expected to be greater because power consumption can be reduced and heat can be collected more efficiently. There was a case.

  Therefore, the amount of power consumption cannot be reduced more than expected, and the carbon dioxide emission amount cannot be reduced.

  Note that the difference in the amount of power consumption described above means that the power generation of the solar cell in a case where heat is collected from the solar cell using an electric heat collector and a heat source other than the solar cell during an arbitrary time. The sum of the difference in the amount and the difference in the amount of electric power supplied to the electric heat collecting device when collecting heat from a heat source other than the solar cell and when collecting heat from the solar cell is shown.

  The present invention solves the above-described conventional problems, and an object thereof is to provide a solar heat combined utilization system and an operation control method thereof that can reduce power consumption and further reduce carbon dioxide emissions. And

In order to solve the above-described problem, the first aspect of the present invention provides:
Solar cells,
A first heat collecting cycle having first heat collecting means for collecting heat from the solar cell;
A second heat collecting cycle having second heat collecting means for collecting heat from a heat source other than the solar cell;
Heat collection switching means for switching to collect heat using either the first heat collection means or the second heat collection means;
A controller that controls switching of the heat collection switching means,
The control unit supplies power for operating the first heat collection cycle from the amount of power generated by the solar battery when collecting a predetermined amount of heat using the first heat collecting means. _Is calculated from the amount of power generated by the solar cell when the second heat collecting means is used to collect the same amount of heat as the predetermined amount of heat. the second calculates the surplus power amount P _r2 obtained by subtracting the amount of power supply for operating the second heat collection cycle, the difference between the first surplus power amount P _r1 and the second surplus power amount P _r2 It is a solar heat combined utilization system which controls switching of the said heat collection switching means based on.

The second aspect of the present invention
Solar cells,
A first heat collecting cycle having first heat collecting means for collecting heat from the solar cell;
A second heat collecting cycle having second heat collecting means for collecting heat from a heat source other than the solar cell;
Heat collection switching means for switching to collect heat using either the first heat collection means or the second heat collection means;
A controller that controls switching of the heat collection switching means,
The control unit uses the second heat collecting unit to calculate the predetermined amount of heat from the amount of power generated by the solar cell when collecting the predetermined amount of heat using the first heat collecting unit. The power generation amount P _sd is calculated by subtracting the amount of power generated by the solar cell when collecting the same amount of heat, and / or the same as the predetermined amount of heat using the second heat collecting means. The first heat collection when collecting the predetermined amount of heat using the first heat collection means from the amount of power supplied for operating the second heat collection cycle when collecting the amount of heat. The difference in power supply P _hd is calculated by subtracting the amount of power supplied for operating the cycle, and based on the difference in power generation P _sd and / or the difference in power supply P _hd , It is a solar heat combined use system that controls switching.

The third aspect of the present invention provides
The control unit adds the power generation amount difference P _sd and the supply power amount difference P _hd, and when the added value becomes larger than a preset switching setting value P _set , It is a solar heat combined utilization system of 2nd this invention which controls the said heat collection switching means so that it heat-collects using one heat collection means.

The fourth invention relates to
The switching setting value P _set is determined based on at least the power generation difference P _sd or the supplied power difference P _hd in a predetermined reference state in the solar heat combined utilization system of the third aspect of the present invention. is there.

The fifth aspect of the present invention relates to
The switching set value P _set is the solar heat combined utilization system according to the third aspect of the present invention, which is controlled based on at least the amount of solar radiation and / or the outside air temperature.

The sixth invention relates to
The switching set value P _set is the solar heat combined utilization system according to the third aspect of the present invention, which is controlled based on at least heat demand such as hot water supply.

The seventh invention relates to
The heat source of the second heat collecting means is the solar heat combined utilization system according to the first or second aspect of the present invention, which is atmospheric heat.

The eighth invention relates to
The first heat collection cycle and the second heat collection cycle are heat pump cycles,
The first heat collecting means and the second heat collecting means are the solar heat combined utilization system according to the first or second aspect of the present invention, which is an evaporator of the heat pump cycle.

The ninth invention relates to
The heat pump cycle is
First evaporator refrigerant temperature detecting means for detecting refrigerant temperature in the first heat collecting means;
Second evaporator refrigerant temperature detecting means for detecting refrigerant temperature in the second heat collecting means;
Expansion valve opening degree adjusting means for adjusting the opening degree of the expansion valve;
The expansion valve opening degree adjusting means is arranged so that the refrigerant temperature detected by the first evaporator refrigerant temperature detecting means or the second evaporator refrigerant temperature detecting means does not exceed the critical temperature of the refrigerant. It is the solar-heat combined utilization system of 8th this invention which adjusts the opening degree of a valve.

The tenth aspect of the present invention is
Solar cell power generation amount detecting means for detecting the power generation amount _Ps0 of the solar cell;
Solar cell temperature detecting means for detecting the temperature T _p0 of the solar cell;
An outside air temperature detection means for detecting the outside air temperature T _a,
A heat source temperature detecting means for detecting the temperature T _h of heat sources other than the solar cell,
The power generation amount P _s0, the solar temperature T _p0 of the battery, based on the outside air temperature T _a, any of the solar cell temperature T _p corresponding to the solar cell power generation amount P _s to calculate the solar cell power generation amount calculating means When,
Supply power amount when collecting the same amount of heat as the predetermined heat amount using the second heat collecting means, and supply power when collecting the predetermined heat amount using the first heat collecting means It is the solar heat combined utilization system of 2nd this invention provided with the supply electric energy difference difference calculating means which calculates the difference with quantity.

The eleventh aspect of the present invention is
A heat source other than the solar cell from a power generation amount generated by the solar cell when a first heat collecting cycle having a first heat collecting means for collecting heat from the solar cell is operated to collect a predetermined amount of heat. The amount of power generated is reduced by reducing the amount of power generated by the solar cell when the second heat collecting cycle having the second heat collecting means for collecting heat is operated to collect the same amount of heat as the predetermined amount of heat. Calculating a difference P _sd between:
Supply power amount when operating the first heat collection cycle to collect the predetermined heat amount from supply power amount when operating the second heat collection cycle to collect the predetermined heat amount To calculate the difference P _hd in the amount of supplied power,
Based on the power generation amount difference P _sd and / or the supplied power amount difference P _hd , it is selectively controlled whether to operate the first heat collection cycle or the second heat collection cycle. And an operation control method for a solar heat combined utilization system.

The twelfth aspect of the present invention is
A program for causing a computer to function as the control unit that controls switching of the heat collection switching unit according to the first or second aspect of the present invention.

The thirteenth aspect of the present invention is
A recording medium carrying the program of the twelfth aspect of the present invention, which is a recording medium usable by a computer.

  According to the present invention, it is possible to provide a solar heat combined utilization system and an operation control method thereof that can reduce power consumption and further reduce carbon dioxide emissions.

  Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1)
1 and 2 are configuration diagrams showing a solar heat combined utilization system according to Embodiment 1 of the present invention. FIG. 1 shows a configuration for collecting heat from the atmosphere, and FIG. 2 shows a configuration for collecting heat from a solar cell.

  The solar heat combined utilization system according to the first embodiment includes a heat pump cycle 13 using the solar cell 1 and the atmosphere as a heat source, the compressor 4 of the heat pump cycle 13 using electric power generated by the solar cell 1, and household electric power. Power supply means for supplying to at least one of the device 11 and the commercial power system 12 is provided.

  The heat pump cycle 13 includes two evaporators, an evaporator 2 and an evaporator 20, and the flow path of the refrigerant is switched by two three-way valves 21 and 22, and either the evaporator 2 or the evaporator 20 is switched. Heat is collected at. As shown in FIG. 1, the evaporator 2 is provided to collect the heat of the solar cell 1. On the other hand, the evaporator 20 collects heat from the atmosphere.

  Note that a crystalline silicon solar cell is used as the solar cell 1, and the heat pump cycle 13 uses carbon dioxide as a refrigerant.

  FIG. 1 shows a configuration for collecting heat using the atmosphere as a heat source. In this case, the refrigerant of the heat pump cycle 13 is the compressor 4, the condenser 3, the expansion valve 5, the three-way valve 21, the evaporator 20, and the three-way. It flows in the order of the valve 22. Note that heat from the atmosphere is an example of a heat source other than the solar battery of the present invention.

  On the other hand, FIG. 2 shows a configuration for collecting heat using the solar cell 1 as a heat source. In this case, the refrigerant of the heat pump cycle 13 is the compressor 4, the condenser 3, the expansion valve 5, the three-way valve 21, and the evaporation. The solar cell 1 is cooled in the order of the vessel 2 and the three-way valve 22.

  The evaporator 2 and the evaporator 20 are examples of the first heat collecting means and the second heat collecting means of the present invention, respectively. Moreover, the cycle of the heat pump cycle 13 via the evaporator 2 shown in FIG. 2 is an example of the first heat collection cycle of the present invention, and the cycle of the heat pump cycle 13 via the evaporator 20 shown in FIG. It is an example of the 2nd heat collection cycle of this invention. The three-way valves 21 and 22 are an example of the heat collection switching means of the present invention.

  In both cases of FIGS. 1 and 2, the collected heat is radiated by the condenser 3 and stored in the heat storage tank 7. The heat stored in the heat storage tank 7 can be used for heat demand 8 such as hot water supply.

On the other hand, the electric power generated by the solar cell 1 is supplied to the inverter 9, and the inverter 9 detects the solar cell power generation amount _Ps0 (kWh). Then, the electric power generated by the solar cell 1 is supplied from the inverter 9 through the controller 10 to the home power device 11, the commercial power system 12, and the compressor 4 of the heat pump cycle 13. The In addition, it is also possible to supply the electric power from the commercial power system 12 to the compressor 4 of the heat pump cycle 13.

Further, the solar cell temperature detection means 15 for detecting the outside air temperature detecting means 14 for detecting the outside air temperature T _a (° C.), and the solar cell temperature T _p0 (° C.) is provided.

The controller 10 includes a solar cell power generation amount calculating means for calculating a power generation amount corresponding to an arbitrary solar cell temperature T _p (° C.), a solar heat collection amount calculating means for calculating a heat amount collected from the solar cell 1, A calculation unit having solar cell heat radiation amount calculation means for calculating the amount of heat radiated from the solar cell 1 is provided. In addition, the controller 10 includes a power supply unit that supplies power to the compressor 4 of the heat pump cycle 13. Then, the controller 10 controls the three-way valves 21 and 22 to switch the refrigerant flow path of the heat pump cycle 13.

  The controller 10 is an example of a control unit according to the present invention, and includes a memory for temporarily storing calculated values.

  Next, the operation control method of the solar heat combined use system of the first embodiment will be described.

First, the inverter 9 detects the solar cell power generation amount P _s0 between the time t ₀ and an arbitrary time Δt. Further, the solar cell temperature detection means 15 and outside air temperature detection means 14, the solar cell temperature T _p0 and the outside air temperature T _a at time t ₀ is detected.

In the controller 10, the solar radiation amount G (kWh / m) is calculated from the detected solar cell power generation amount P _s0 and solar cell temperature T _p0 , the solar cell light receiving area S (m ² ), and the solar cell power generation efficiency η _ps0 (%). ² ) is calculated. Then, the solar heat collection amount Q _s (kWh) to the solar cell 1 is calculated from the solar radiation amount G and the heat collection efficiency η _qs0 (%) of the solar cell 1. Further, the solar cell temperature T _p0, the amount of heat released from the outside air temperature T _a from the solar cell 1 to the atmosphere Q _a (kWh) is calculated.

Further, when collecting heat from the solar cell 1 using the heat pump cycle 13, COPη of the heat pump cycle 13 obtained from the amount of electric power P _h1 (kWh) supplied to the heat pump cycle 13 and the solar cell temperature T _{p0. From h0} , a heat collection amount Q _h (kWh) from the solar cell 1 by the heat pump cycle 13 is calculated.

On the other hand, when the heat pump cycle 13 is used to collect heat using the evaporator 20 using the atmosphere as a heat source, the supplied power amount P _h2 (kWh) required to collect heat by the amount of heat Q _h is also the outside air temperature T. It is calculated from COPita _ha of the heat pump cycle 13 obtained from _a.

Solar heat collection amount Q _s to solar cell 1, heat release amount Q _a from solar cell 1 to the atmosphere, heat collection amount Q _h from solar cell 1 by heat pump cycle 13 when collecting heat from solar cell 1, From the heat capacity C _p (kWh / ° C.), the temperature T _p1 (° C.) of the solar cell 1 after an arbitrary time Δt in the case of collecting heat from the solar cell 1 and the case of collecting heat from atmospheric heat using the heat pump cycle 13. ), T _p2 (° C.), respectively, and solar cell power generation amounts P _s1 (kWh) and P _s2 (kWh) during an arbitrary time Δt are calculated.

As described above, the surplus power amount P _r1 (kWh) when heat is collected from the solar cell 1 using the heat pump cycle 13 and the surplus when heat is collected from the atmosphere between the time t ₀ and the arbitrary time Δt. The amount of power P _r2 (kWh) is calculated as follows.

P _r1 = P _s1 −P _h1
P _r2 = P _s2 −P _h2
Here, the surplus power amount is the amount of power obtained by subtracting the amount of power supplied to the compressor 4 for operating the heat pump cycle 13 from the amount of power generated by the solar cell 1. That is, it can be said that the larger the surplus power amount, the larger the substantial power generation amount, or the smaller the amount of power supplied to the compressor 4 separately.

Since the surplus power amount P _r1 and the surplus power amount P _r2 are values calculated for the same heat collection amount, it can be said that the larger these values, the greater the total energy amount of heat and electricity combined.

The controller 10 determines whether to use the evaporator 2 or the evaporator 20 as the heat collecting means based on the values of the surplus power P _r1 and surplus power P _r2 , and controls the three-way valves 21 and 22. The refrigerant flow path of the heat pump cycle 13 is switched.

For example, if the total energy amount is controlled so as to be most efficient, when P _r1 ≧ P _r2 , the refrigerant is controlled to flow through the evaporator 2 to collect heat from the solar cell 1. In the case of P _r1 <P _r2 , the refrigerant may be controlled to flow through the evaporator 20 to collect heat from the atmosphere.

(Embodiment 2)
The solar heat combined utilization system of the second embodiment of the present invention has the same configuration as that of the first embodiment, and the configuration diagram thereof is as shown in FIGS. 1 and 2.

  The solar heat combined utilization system of the second embodiment is different from the first embodiment only in the calculation method and the control method in the controller 10. Since the configuration is exactly the same as in the first embodiment, description of the configuration is omitted.

  The operation control method of the solar heat combined utilization system of the second embodiment will be described below.

  FIG. 3 is a flowchart showing the operation control method of the solar heat combined utilization system in the second embodiment.

First, the inverter 9 detects the solar cell power generation amount P _s0 (kWh) between the time t ₀ and an arbitrary time Δt. Further, the solar cell temperature detection means 15 and outside air temperature detection means 14, the solar cell temperature T _p0 at time t ₀ (° C.) and the outside air temperature T _a (° C.) is detected.

In the controller 10, the solar radiation amount G (kWh / m) is calculated from the detected solar cell power generation amount P _s0 and solar cell temperature T _p0 , the solar cell light receiving area S (m ² ), and the solar cell power generation efficiency η _ps0 (%). ² ) is calculated. Then, the solar heat collection amount Q _s (kWh) to the solar cell 1 is calculated from the solar radiation amount G and the heat collection efficiency η _qs0 (%) of the solar cell 1. Further, the solar cell temperature T _p0, the amount of heat released from the outside air temperature T _a from the solar cell 1 to the atmosphere Q _a (kWh) is calculated.

Further, when collecting heat from the solar cell 1 using the heat pump cycle 13, COPη of the heat pump cycle 13 obtained from the amount of electric power P _h1 (kWh) supplied to the heat pump cycle 13 and the solar cell temperature T _{p0. From h0} , a heat collection amount Q _h (kWh) from the solar cell 1 by the heat pump cycle 13 is calculated.

On the other hand, when the heat pump cycle 13 is used to collect heat using the evaporator 20 using the atmosphere as a heat source, the supplied power amount P _h2 (kWh) required to collect heat by the amount of heat Q _h is also the outside air temperature T. It is calculated from COPita _ha of the heat pump cycle 13 obtained from _a.

Solar heat collection amount Q _s to solar cell 1, heat release amount Q _a from solar cell 1 to the atmosphere, heat collection amount Q _h from solar cell 1 by heat pump cycle 13 when collecting heat from solar cell 1, From the heat capacity C _p (kWh / ° C.), the temperature T _p1 (° C.) of the solar cell 1 after an arbitrary time Δt in the case of collecting heat from the solar cell 1 and the case of collecting heat from atmospheric heat using the heat pump cycle 13. ), T _p2 (° C.), respectively, and solar cell power generation amounts P _s1 (kWh) and P _s2 (kWh) during an arbitrary time Δt are calculated.

From the above, between the time t ₀ and the arbitrary time Δt, the difference P _sd (kWh) between the solar cell power generation amounts when the heat pump cycle 13 collects heat from the solar cell 1 and when collecting heat from the atmospheric heat, The difference P _hd (kWh) in the amount of power supplied to the heat pump cycle 13 between the case of collecting heat from atmospheric heat and the case of collecting heat from the solar cell 1 is calculated as follows.

P _sd = P _s1 − P _s2
P _hd = P _h2 −P _h1
Here, the set value P _set (kWh) for discriminating between the case of collecting heat from the solar cell 1 and the case of collecting heat from the atmospheric heat is _{set to} P _sset ( kWh), T _pset (° C.), T _aset (° C.) in the reference state, the difference P _sdset (kWh) between the solar cell power generation amount when the heat is collected from the solar cell 1 and the heat collected from the atmospheric heat, and the atmospheric heat It is set as the sum of difference P _hdset (kWh) of the heat pump cycle supply electric energy amount in the case of collecting heat from the solar cell and in the case of collecting heat from the solar cell 1.

  In addition, said reference | standard state may be the state set from the average data of the solar cell electric power generation amount in every season or every area, solar cell temperature, and outside temperature, and is the state set arbitrarily by the user. There may be.

FIG. 4 shows an example of a change with time in the power consumption difference (P _sd + P _hd ) when the control method of the solar heat combined utilization system of the second embodiment is used. For example, in FIG. 4, when (P _sd + P _hd ) ≧ P _set , the three-way valves 21 and 22 are controlled so that heat is collected from the solar cell 1 by the heat pump cycle 13, and (P _sd + P _hd ) <P _In the case of _set , the three-way valves 21 and 22 are controlled so as to collect heat from the atmosphere.

P _set may be at least one value of P _sdset or P _hdset , and P _set may be compared with at least one value of P _sd or P _hdset. .

Incidentally, P _sset, T _pset, the value of T _aset is heat demand 8 and hot water supply, etc., vary depending on the weather conditions, such as amount of sunlight G and the outside air temperature T _a. For example, when a hot water storage method is used as the heat storage means, a heat storage amount detection means for detecting the heat storage amount in the hot water storage container from at least the hot water storage amount and the hot water temperature is provided, and when the heat storage amount in the hot water storage container is small or the heat demand 8 is If it is large, the value of P _set is changed so as to decrease, and heat collection is promoted. Conversely, when the amount of heat stored in the hot water storage container is large or when heat demand 8 is small, the value of P _set increases. To efficiently collect heat with high efficiency. The heat demand 8 is detected by at least one of the hot water storage rate reduction means and the hot water temperature drop speed detection means.

Also, when the amount of change in the amount of solar radiation per time is small, the value of P _set is changed so as to decrease the heat collection, and conversely, when the amount of change in the amount of solar radiation per time is large. It is also possible to selectively collect heat with high efficiency by changing the value of P _set to be large.

Note that the values of the power supply amounts P _h1 and P _h2 supplied to the heat pump cycle 13 are calculated for a range that is less than or equal to the maximum power amount _{Phmax that} can be supplied to the heat pump cycle 13 during an arbitrary time Δt. Is done.

The opening degree of the expansion valve 6 is adjusted by the expansion valve opening degree adjusting means so that the refrigerant temperature T _c in the evaporator 2 and the evaporator 20 of the heat pump cycle 13 does not exceed the critical temperature T _cri (° C.) of the refrigerant. Is automatically adjusted.

  According to the operation control method of the solar heat combined utilization system of the second embodiment, when there is a large power consumption difference between the case where heat is collected from the atmospheric heat using the heat pump cycle 13 and the case where heat is collected from the solar cell 1. In order to selectively collect heat from the solar cell 1, the amount of power generated by the solar cell 1 increases, and the amount of power supplied to operate the heat pump cycle 13 is significantly reduced compared to collecting heat from atmospheric heat. Therefore, the amount of power consumption can be reduced as compared with the conventional solar heat combined use system. As a result, carbon dioxide emissions can be reduced.

In the second embodiment, the control of the amount of power supplied to the heat pump cycle 13 is performed using the difference in power consumption between the case where heat is collected from atmospheric heat and the case where heat is collected from the solar cell 1 in the reference state as a set value. _However , at least one of the solar cell temperature T _pset , the outside air temperature T _aset , and the power generation amount P _{sset in} the reference state can also be used for control of the supplied power amount.

In each embodiment, the detection value by the solar cell temperature detection means 15 is used for the calculation, but it is not always necessary to use the detection value by the solar cell temperature detection means 15, and from the solar cell power generation amount _{Ps0 and the} like. It is also possible to use an estimated solar cell temperature.

  Moreover, in each embodiment, although the compressor 4, the expansion valve 5, and the condenser 3 were used in common and the heat pump cycle 13 of the structure which switches and uses the evaporator 2 and the evaporator 20 was used, the solar cell 1 As long as the heat collecting means from the heat source and the heat collecting means from a heat source other than the solar cell 1 are provided and the heat collecting means can be switched and used, any structure may be used. For example, a configuration in which two completely different heat pump cycles are used by switching may be used.

  Moreover, in each embodiment, it was set as the structure which switches and uses the two evaporators 2 and the evaporator 20, However, This invention is applicable also to the structure which switches and uses three or more evaporators. .

  In each embodiment, atmospheric heat is used as a heat source when heat is collected from other than the solar cell 1 using the heat pump cycle 13, but other heat sources such as geothermal heat and bath exhaust heat are used. You can also.

  In each embodiment, the heat pump cycle 13 is used as the first heat collection cycle and the second heat collection cycle in combination with the solar cell 1, but the electric hot water provided with the circulating water pump is used. The present invention can also be applied in the same manner when other electric heat collecting devices such as a heat exchanger are used as the first heat collecting cycle and the second heat collecting cycle.

  In each embodiment, a crystalline silicon solar cell is used as the solar cell 1, but at least a solar cell having temperature dependency in power generation efficiency, for example, an amorphous silicon solar cell or a CIS solar cell is used. The same applies to the case.

  In each embodiment, a heat pump cycle using carbon dioxide as a refrigerant is used as the heat pump cycle 13. However, the same applies to a heat pump cycle using another refrigerant such as HFC. Can be applied.

  The program of the present invention is a program for causing a computer to execute the function of the control unit of the solar heat combined utilization system of the present invention described above, and is a program that operates in cooperation with the computer.

  The recording medium of the present invention is a recording medium carrying a program for causing a computer to execute the function of the control unit of the solar heat combined utilization system of the present invention described above, and is readable and read by the computer. The recording medium is used in cooperation with the computer.

  Further, one usage form of the program of the present invention may be an aspect in which the program is recorded on a computer-readable recording medium and operates in cooperation with the computer.

  Further, the recording medium includes a ROM and the like.

  The computer of the present invention described above is not limited to pure hardware such as a CPU, and may include firmware, an OS, and peripheral devices.

  As described above, the configuration of the present invention may be realized by software or hardware.

  If the operation control method of the solar heat combined utilization system according to the present invention is used, the solar power is selectively selected when the difference in power consumption between the case of collecting heat from atmospheric heat and the case of collecting heat from a solar cell is larger than a set value. Since heat is collected from the battery, it is useful as a means for further reducing carbon dioxide emissions. It is particularly useful for solar cells whose power generation efficiency greatly decreases with increasing temperature. In addition, it is particularly useful in an electric heat collecting apparatus whose efficiency is greatly improved as the temperature rises.

  This operation control method is also applicable to the case where heat once collected using a circulating water pump or the like is used as a heat source for an electric heat collecting device, or when a plurality of different types of electric heat collecting devices are used in combination. Is possible.

  The collected heat can be used for hot water supply or heating. In addition, when the solar heat combined utilization system of the present invention is combined with an adsorption refrigeration cycle or the like, it is possible to cool with collected heat. This operation control method can be applied not only to a solar battery but also to an operation control method for a system in which a power generation means such as a fuel cell and an electric heat collecting device are combined.

Configuration diagram of solar thermal composite utilization system in Embodiment 1 of the present invention Configuration diagram of solar thermal composite utilization system in Embodiment 1 of the present invention Flowchart of operation control method for heat pump cycle 13 in Embodiment 1 of the present invention The figure which shows the relationship between the difference in power consumption in the case where it collects from atmospheric heat, and the case where it collects from the solar cell 1, and the setting value using the heat pump cycle 13 in Embodiment 1 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Solar cell 2,20 Evaporator 3 Condenser 4 Compressor 5 Expansion valve 6 Refrigerant piping 7 Thermal storage tank 8 Heat demand 9 Inverter 10 Controller 11 Domestic electric power equipment 12 Commercial power system 13 Heat pump cycle 14 Outside air Temperature detection means 15 Solar cell temperature detection means 21, 22 Three-way valve

Claims (13)

Solar cells,
A first heat collecting cycle having first heat collecting means for collecting heat from the solar cell;
A second heat collecting cycle having second heat collecting means for collecting heat from a heat source other than the solar cell;
Heat collection switching means for switching to collect heat using either the first heat collection means or the second heat collection means;
A controller that controls switching of the heat collection switching means,
The control unit supplies power for operating the first heat collection cycle from the amount of power generated by the solar battery when collecting a predetermined amount of heat using the first heat collecting means. _Is calculated from the amount of power generated by the solar cell when the second heat collecting means is used to collect the same amount of heat as the predetermined amount of heat. the second calculates the surplus power amount P _r2 obtained by subtracting the amount of power supply for operating the second heat collection cycle, the difference between the first surplus power amount P _r1 and the second surplus power amount P _r2 A solar heat combined utilization system that controls switching of the heat collection switching means based on the above. Solar cells,
A first heat collecting cycle having first heat collecting means for collecting heat from the solar cell;
A second heat collecting cycle having second heat collecting means for collecting heat from a heat source other than the solar cell;
Heat collection switching means for switching to collect heat using either the first heat collection means or the second heat collection means;
A controller that controls switching of the heat collection switching means,
The control unit uses the second heat collecting unit to calculate the predetermined amount of heat from the amount of power generated by the solar cell when collecting the predetermined amount of heat using the first heat collecting unit. The power generation amount P _sd is calculated by subtracting the amount of power generated by the solar cell when collecting the same amount of heat, and / or the same as the predetermined amount of heat using the second heat collecting means. The first heat collection when collecting the predetermined amount of heat using the first heat collection means from the amount of power supplied for operating the second heat collection cycle when collecting the amount of heat. The difference in power supply P _hd is calculated by subtracting the amount of power supplied for operating the cycle, and based on the difference in power generation P _sd and / or the difference in power supply P _hd , Solar heat combined use system that controls switching. The control unit adds the power generation amount difference P _sd and the supply power amount difference P _hd, and when the added value becomes larger than a preset switching setting value P _set , The solar heat combined utilization system according to claim 2, wherein the heat collection switching means is controlled so as to collect heat using one heat collection means. The solar heat combined utilization system according to claim 3, wherein the switching setting value P _set is determined based on at least the difference P _{sd in} power generation amount or the difference P _hd in power supply amount in a predetermined reference state. The solar heat combined utilization system according to claim 3, wherein the switching set value _Pset is controlled based on at least a solar radiation amount and / or an outside air temperature. The solar heat combined utilization system according to claim 3, wherein the switching set value _Pset is controlled based on at least heat demand such as hot water supply.   The solar heat combined utilization system according to claim 1 or 2, wherein the heat source of the second heat collecting means is atmospheric heat. The first heat collection cycle and the second heat collection cycle are heat pump cycles,
The solar heat combined utilization system according to claim 1 or 2, wherein the first heat collecting means and the second heat collecting means are evaporators of the heat pump cycle. The heat pump cycle is
First evaporator refrigerant temperature detecting means for detecting refrigerant temperature in the first heat collecting means;
Second evaporator refrigerant temperature detecting means for detecting refrigerant temperature in the second heat collecting means;
Expansion valve opening degree adjusting means for adjusting the opening degree of the expansion valve;
The expansion valve opening degree adjusting means is arranged so that the refrigerant temperature detected by the first evaporator refrigerant temperature detecting means or the second evaporator refrigerant temperature detecting means does not exceed the critical temperature of the refrigerant. The solar heat combined utilization system according to claim 8, wherein the opening degree of the valve is adjusted. Solar cell power generation amount detecting means for detecting the power generation amount _Ps0 of the solar cell;
Solar cell temperature detecting means for detecting the temperature T _p0 of the solar cell;
An outside air temperature detection means for detecting the outside air temperature T _a,
A heat source temperature detecting means for detecting the temperature T _h of heat sources other than the solar cell,
The power generation amount P _s0, the solar temperature T _p0 of the battery, based on the outside air temperature T _a, any of the solar cell temperature T _p corresponding to the solar cell power generation amount P _s to calculate the solar cell power generation amount calculating means When,
Supply power amount when collecting the same amount of heat as the predetermined heat amount using the second heat collecting means, and supply power when collecting the predetermined heat amount using the first heat collecting means The solar heat combined utilization system according to claim 2, further comprising a supply power amount difference calculating means for calculating a difference from the amount. A heat source other than the solar cell from a power generation amount generated by the solar cell when a first heat collecting cycle having a first heat collecting means for collecting heat from the solar cell is operated to collect a predetermined amount of heat. The amount of power generated is reduced by reducing the amount of power generated by the solar cell when the second heat collecting cycle having the second heat collecting means for collecting heat is operated to collect the same amount of heat as the predetermined amount of heat. Calculating a difference P _sd between:
Supply power amount when operating the first heat collection cycle to collect the predetermined heat amount from supply power amount when operating the second heat collection cycle to collect the predetermined heat amount To calculate the difference P _hd in the amount of supplied power,
Based on the power generation amount difference P _sd and / or the supplied power amount difference P _hd , it is selectively controlled whether to operate the first heat collection cycle or the second heat collection cycle. An operation control method for a solar heat combined utilization system comprising steps.   The program for functioning a computer as the said control part which controls switching of the said heat collection switching means of Claim 1 or 2. A recording medium carrying the program according to claim 12 and usable by a computer.

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