JP2005236125A - Solar power generating system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce costs for a solar power generating system by making it operable simply and properly. <P>SOLUTION: The converter of the solar power generating system is designated to output voltage signals VIN-L and VIN-H according to generated power. The microcomputer of an outdoor unit confirms the voltage signals VIN-L and VIN-H in the state of outputting an off signal, and outputs an on signal to the converter (step 200 to 206) when both of the voltage signals are turned on. While outputting the on signal, the microcomputer confirms whether the voltage signal VIN-L are turned off (step 208). When the signal is turned off, the microcomputer outputs the off signal (step 200) for stopping power conversion by the converter. Thus, the converter operates properly according to the operation of the air conditioner and the generated power. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a photovoltaic power generation apparatus that converts electric power generated by a solar battery into electric power having a predetermined voltage and outputs the electric power. Specifically, the present invention relates to a solar power generation device that supplies generated power to a preset device.

  In an air conditioner (hereinafter referred to as “air conditioner”) that brings an air-conditioned room into a desired air conditioning state, an outdoor unit provided with a compressor and an indoor unit provided with a heat exchanger that performs heat exchange for air conditioning Between them, a refrigeration cycle for circulating the refrigerant is formed. In this air conditioner, the compressor of the outdoor unit is rotationally driven to circulate the refrigerant, and in the heat exchanger of the indoor unit, the temperature is controlled by exchanging heat between the refrigerant and the air blown to the air-conditioned room. Air is blown from the indoor unit into the air-conditioned room.

  In such an air conditioner, not only the indoor unit but also the outdoor unit is provided with a microcomputer (microcomputer), and the outdoor unit microcomputer performs inverter control based on the air conditioning capacity required by the indoor unit microcomputer and rotates the compressor. The number (operating frequency) is controlled.

  As a result, the air conditioner can be air-conditioned in the air-conditioned room based on the set air condition.

  2. Description of the Related Art In recent years, solar power generation devices that supply power generated using sunlight to various power facilities have become widespread. In such a solar power generation device, in addition to a grid-connected power generation device that regenerates electric power generated by sunlight to a commercial power source and can be supplied to any power facility, the power generation capacity is relatively small, such as an air conditioner. It is proposed to connect to a specific device and supply generated power only to the specific device (see, for example, Patent Document 1 and Patent Document 2).

  As proposed in Patent Literature 1 and Patent Literature 2, when the compressor of an air conditioner is driven, the electric power supplied from the commercial power source is minimized by using the generated electric power of the photovoltaic power generation device. Is possible.

  Moreover, the electric power generated by the photovoltaic power generator varies depending on the amount of solar radiation. For this reason, for example, even when the electric power generated by the photovoltaic power generator is used as standby power for an air conditioner, the generated power may not satisfy the standby power.

  From here, when surplus occurs in the power generated by the solar battery, the surplus power is stored in the storage battery, and when the power stored in the storage battery is insufficient, the power is stored in the storage battery using the power of the commercial power source. Thus, a proposal for securing standby power has been made (see, for example, Patent Document 3).

  The output voltage-output current characteristic of the solar cell used in such a solar power generation device is that the output current is constant until the output voltage reaches a predetermined value (predetermined voltage), and when the output voltage becomes higher than the predetermined value, The output current decreases rapidly. Moreover, the electric power generated by the solar power generator changes under the influence of the amount of solar radiation.

  From here, in the solar power generation device, maximum power tracking control (MPPT (Maximum Power Point Tracking) control) is performed in order to efficiently extract the maximum power corresponding to the generated power from the solar cell.

  At this time, the solar power generation device monitors the power generated by the solar cell. I try to stop.

  For this reason, in the photovoltaic power generation apparatus, a microcomputer is provided in a converter that converts the generated power of the solar cell into predetermined power, and the microcomputer performs start / stop of power conversion and MPPT control.

  By the way, when the solar power generation device is connected to a specific device such as an air conditioner and used exclusively for power supply to the connected device, the solar power generation device performs power conversion / stop in conjunction with operation / stop of the connected device. There is a need. Thereby, it becomes possible to suppress the power consumption of a commercial power supply, without being conscious of using the generated electric power of a solar power generation device.

  Moreover, in order to spread such a solar power generation device, it is necessary to reduce the cost.

However, in the photovoltaic power generation device, in order to perform MPPT control and output the generated power efficiently, components used for detecting the generated voltage, generated power, output voltage, output current, etc. are necessary. It is necessary to perform complicated inverter control based on the detection result, and these configurations hinder cost reduction of the photovoltaic power generation apparatus.
Japanese Patent Laid-Open No. 674522 JP-A-8-75221 JP 2000-217271 A

  The present invention has been made in view of the above-described facts, and it is possible to perform appropriate power conversion / stop in accordance with the operation of a device that supplies the generated power of the solar cell and the generated power, and to reduce the cost. An object of the present invention is to provide a solar power generation device that can be used.

  To achieve the above object, the present invention provides a solar panel that receives sunlight and generates DC power, and a solar power generation that includes a converter that converts the power generated by the solar panel into power of a predetermined voltage and outputs it. An input voltage determination means for determining whether or not the voltage of the generated power input from the solar panel to the converter has reached a voltage corresponding to the generated power set to be capable of power conversion in advance. The power conversion is performed by inputting an operation signal based on the determination result of the input voltage determination means.

  According to this invention, the input power determination means for determining whether or not the amount of power generation capable of power conversion has been reached from the input voltage corresponding to the generated power is provided. Further, the converter starts power conversion when an operation signal is input.

  As a result, if an operation signal is input from a device that supplies power based on the determination result of the input voltage determination means, power conversion / stop is appropriately controlled according to the operating state of the device that supplies power. can do.

  In the present invention, the input voltage determination means stops the power conversion with the first determination result based on whether or not the input voltage determination means has reached a voltage set so as to enable continuous power conversion. It is more preferable to output a second determination result based on whether or not the voltage set to be reached is reached.

  Thereby, more appropriate power conversion / stop control according to the generated power of the solar panel becomes possible.

  In the present invention, the detection result of the input voltage detection means includes the detection result of the protection means when the converter includes a protection means for detecting whether or not the converter has risen above a predetermined temperature. It is preferable that this can protect the converter itself.

  Further, the present invention provides a converter for converting the power input from the solar panel into power of a predetermined voltage in the converter, and an input voltage detection unit for detecting a change in the input voltage input to the converter. Output voltage detection means for detecting a change in output voltage output from the conversion means; conversion control means for controlling the operation of the conversion means based on detection results of the input voltage detection means and the output voltage detection means; , Including.

  According to the present invention, the power conversion is performed so that the input voltage detected by the input voltage detecting means is held at a preset voltage, and the output voltage detected by the output voltage detecting means is held at a preset constant voltage. To control.

  As a result, it is possible to detect the input current and the output current, perform efficient power conversion without performing complicated control based on the detection result, and it is possible to simplify the apparatus and reduce the cost.

  In the present invention, the conversion means generates a switching circuit for switching the switching element and a switching signal for driving the switching element, and the on-duty of the switching signal is set to the input voltage detection means and the output. And an oscillation circuit that is controlled based on the detection result of the voltage detection means.

  As described above, according to the present invention, appropriate control can be performed from a device that supplies power with a simple configuration. Moreover, in this invention, since efficient power conversion can be performed without performing complicated control using a microcomputer etc., the outstanding effect that size reduction and cost reduction are attained is acquired.

  Embodiments of the present invention will be described below with reference to the drawings. 1 and 2 show a schematic configuration of an air conditioner (hereinafter referred to as “air conditioner 10”) applied to the embodiment. The air conditioner 10 includes an indoor unit 12 installed in an air-conditioned room and an outdoor unit 14 installed outdoors.

  As shown in FIG. 2, the indoor unit 12 and the outdoor unit 14 are connected to each other by a thick refrigerant pipe 16A and a thin refrigerant pipe 16B. The indoor unit 12 is provided with a heat exchanger 18, and each of the refrigerant pipes 16 </ b> A and 16 </ b> B is connected to the heat exchanger 18.

  The outdoor unit 14 is provided with valves 20A and 20B, the refrigerant pipe 16A is connected to the valve 20A, and the refrigerant pipe 16B is connected to the valve 20B. A four-way valve 24 is connected to the valve 20A via a muffler 22A.

  The outdoor unit 14 is provided with a compressor 26 and a heat exchanger 28, and each of the accumulator 30 and the muffler 22B connected to the compressor 26 is connected to the four-way valve 24, and the heat exchanger. One end of 28 is connected to the four-way valve 24.

  Furthermore, the other end of the heat exchanger 28 is connected to the valve 20 </ b> B via the capillary tube 32, the strainer 34, the electric expansion valve 36 and the modulator 38.

  Thereby, in the air conditioner 10, a refrigeration cycle for circulating the refrigerant is formed between the indoor unit 12 and the outdoor unit 14. In addition, this refrigeration cycle shows an example and does not limit the structure of an air conditioner.

  The air conditioner 10 can be operated in the heating mode or in the cooling mode including the dry mode (dehumidification mode) by switching the four-way valve 24. In addition, in FIG. 2, the flow of the refrigerant | coolant in air_conditioning | cooling mode and heating mode is shown by the arrow.

  The indoor unit 12 is provided with a cross flow fan (not shown). When the cross flow fan is operated, the air in the air-conditioned room in which the indoor unit 12 is provided is sucked, and the heat exchanger 18. After passing through, blow out into the air-conditioned room. At this time, heat exchange is performed between the air passing through the heat exchanger 18 and the refrigerant circulated in the refrigeration cycle, whereby the air is blown into the air-conditioned room as air-conditioned air.

  The air conditioner 10 can include a ventilation function. At this time, for example, when exhausting, the air in the air-conditioned room sucked by the cross flow fan is discharged to the outside without passing through the heat exchanger 18, and the outdoor air When intake of fresh outside air is performed, the outside air may be sucked and the sucked outside air may be blown out through the heat exchanger 18 into the air-conditioned room.

  FIG. 3 shows a schematic configuration of the control unit 40 provided in the indoor unit 12 and the control unit 42 provided in the outdoor unit 14. The control unit 40 of the indoor unit 12 includes a power supply board 44 and a control board 46.

  The air conditioner 10 can be operated with AC power from a commercial power source (for example, single-phase 100 V), and this AC power is supplied to the power supply substrate 44. The power supply board 44 generates an operation power supply for the control board 46, power for driving a crossflow fan (not shown), a flap motor, and the like from the AC power.

  In the present embodiment, air conditioner 10 is described as being operated with single-phase 100V AC power as an example, but the air conditioner may be operated with single-phase 200V.

  On the control board 46, various drive circuits, display circuits, and the like are formed together with a microcomputer (microcomputer 48), and various sensors (not shown) for detecting the air conditioning state of the air-conditioned room and the operating state of the indoor unit 12 are provided. It is connected.

  The microcomputer 48 provided on the control board 46 controls the operation of the power supply board 44 and the various motors based on the operation signal from the remote control switch 50 (see FIG. 1) and the detection signals of various sensors. I do.

  The control board 46 is provided with a communication circuit such as a serial communication circuit, and the microcomputer 48 controls the operation of the outdoor unit 14 via this communication circuit.

  That is, in the air conditioner 10, the operation / stop, the setting of the operation mode, the air conditioning temperature, the wind direction, and the air volume are set by the switch operation of the remote control switch 50, so that the air conditioning operation based on this setting is possible.

  In addition, as shown in FIG. 3, the air conditioner 10 can be provided with a ventilation function. At this time, the ventilation unit 52 is connected to the control board 46, whereby the microcomputer 48 uses the intake fan 54 provided in the ventilation unit 52 and the power supplied from the power supply board 44 and the like. The exhaust fan 56 is supplied to control the operation of the intake fan 54 and the exhaust fan 56.

  In the air conditioner 10, the power supplied to the indoor unit 12 is supplied to the outdoor unit 14 via a power relay contact 58 (not shown). The microcomputer 48 provided on the control board 46 operates / stops the outdoor unit 14 by controlling the power relay to open / close the contact 58.

  The control unit 42 of the outdoor unit 14 includes a control board 60. The control board 60 is provided with a microcomputer (microcomputer 62) for controlling the operation of the outdoor unit 14. Further, a power supply circuit 64, an inverter circuit 66, and the like are formed on the control board 60.

  The power supply circuit 64 includes a filter circuit, a full-wave rectifier circuit, a smoothing circuit, and the like (all not shown), and generates power used for the operation of the control board 60 from AC power supplied via the indoor unit 12. At the same time, AC power is converted into DC power of a predetermined voltage and supplied to the inverter circuit 66.

  The inverter circuit 66 is provided with a switching element. By driving the switching element, the DC power input from the power supply circuit 64 is converted into AC power and supplied to the compressor 26 (compressor motor). Thereby, the compressor 26 is driven.

  The microcomputer 62 controls the compressor 26 to be driven at a predetermined operating frequency by controlling switching of the switching element.

  The control board 46 of the indoor unit 12 and the control board 60 of the outdoor unit 14 are connected by, for example, a communication line for serial communication, whereby the control board 46 (microcomputer 48) and the control board 60 (microcomputer 62). Serial communication is possible.

  The microcomputer 48 provided in the indoor unit 12 controls the operation of the outdoor unit 14 by this serial communication. That is, the microcomputer 62 performs switching of the four-way valve 24 (see FIG. 2) based on the operation mode, control of the operation frequency of the compressor 26 based on the required air-conditioning capacity, etc. according to the signal input from the microcomputer 48. To do.

  An arbitrary configuration can be applied to the basic configuration of the air conditioner 10 as described above, and a detailed description of the operation control is omitted.

  In the air conditioner 10, not only when the air conditioning operation is performed, but also when only the ventilation unit 52 is operated, the contact 58 is closed to supply power to the control board 60 of the outdoor unit 14, and the microcomputer 62 is activated. It is trying to become.

  By the way, as shown in FIG.1 and FIG.3, the solar power generation device 70 can be connected to the air conditioner 10, and by connecting the solar power generation device 70, it can be used as what is called a solar air conditioner. Yes. That is, an air conditioning operation or a ventilation operation using electric power supplied from the solar power generation device 70 is possible.

  As shown in FIG. 3, the indoor unit 12 of the air conditioner 10 is provided with an input connector 90 on the control board 46. In the control board 46, when the ventilation unit 52 is attached, DC power of a predetermined voltage (for example, DC12V to 14V) is input from the input connector 90, whereby the input power is converted into the intake fan of the ventilation unit 52. 54, used to drive the exhaust fan 56 and the like.

  In the air conditioner 10, the ventilation unit 52 is described as being operated by the electric power input to the control board 46 via the input connector 90, but is not limited thereto, and other types such as a flap motor that operates a flap (not shown). It may be used for driving a load.

  In the outdoor unit 14, an input connector 94 and a control connector 98 are provided on the control board 60. The input connector 94 is connected to the input side of the inverter circuit 66 within the control board 60, whereby DC power of a predetermined voltage (for example, DC 300 V to 330 V) is input to the inverter circuit 66 via the input connector 94. Is done. Thereby, in the outdoor unit 14, this DC power can be used to drive the compressor 26.

  Further, the control board 60 can output DC power (for example, DC 5V) of a predetermined voltage (control signal voltage) via the control connector 98. Further, the microcomputer 62 provided on the control board 60 outputs an operation signal (ON / OFF signal) of a device connected through the control connector 98 based on a signal input through the control connector 98. It has become.

  That is, in the air conditioner 10, the control connector 98 is coupled to the solar power generation device 70 together with the input connectors 90 and 94 when the solar power generation device 70 is connected.

  As a result, in the air conditioner 10, the microcomputer 62 provided in the outdoor unit 14 can control the operation / stop of the photovoltaic power generation apparatus 70, and the microcomputer 62 is input to the control board 60 via the control connector 98. When the voltage signal VIN-L and the voltage signal VIN-H are on, an on signal is output to the photovoltaic power generator 70. Further, the microcomputer 62 outputs an off signal to the solar power generation device 70 when the voltage signal VIN-L is turned off while the on signal is output to the solar power generation device 70.

  On the other hand, as shown in FIGS. 1 and 3, the solar power generation device 70 includes a solar panel 72 that generates direct-current power corresponding to the received sunlight energy by receiving sunlight. As shown in FIG. 3, the solar power generation device 70 includes a power controller 74 that converts the power generated by the solar panel 72 into power of a predetermined voltage.

  As shown in FIG. 1, the solar panel 72 is attached to the upper part of the outdoor unit 14 installed outdoors, for example, via a bracket (not shown). Moreover, the solar panel 72 may be attached to the roof, roof, veranda, etc. of the building. At this time, the solar panel 72 is attached so as to face a predetermined angle and direction so that sunlight is efficiently applied to the light receiving surface (lighting surface) 72A.

  As shown in FIG. 3, the solar panel 72 is provided with a solar cell module 76. This solar cell module 76 is formed by a large number of solar cells that generate electricity by receiving sunlight, and the solar panel 72 is generally formed by providing a large number of solar cell modules 76. It is a typical structure.

  The power controller 74 is provided with a converter board (hereinafter referred to as “converter 78”) having a DC-DC converter function in a housing (not shown). The converter 78 is provided with an input terminal 80, and the solar panel 72 is connected to the input terminal 80 of the converter 78.

  As a result, in the solar power generation device 70, the power (DC power) generated by the solar cell module (solar cell) 76 is input to the converter 78. Converter 78 applied to the present embodiment performs voltage conversion on the DC power and outputs DC power of a preset voltage.

  The casing of the power controller 74 in which the converter 78 is housed is attached to the casing of the outdoor unit 14. At this time, for example, a cooling fan (not shown) of the outdoor unit 14 is activated to When the outside air for cooling is sucked in, any attachment structure such as being attached to the outside air passage and being cooled simultaneously with the compressor 26 of the outdoor unit 14 can be applied.

  The converter 78 is provided with an output connector 82 paired with the input connector 94 provided in the outdoor unit 14 of the air conditioner 10 and an output connector 84 paired with the input connector 90 provided in the indoor unit 12. Two power outputs are possible. Further, the converter 78 is provided with a control connector 86 that is paired with the control connector 98 provided in the outdoor unit 14.

  FIG. 4 shows a schematic configuration of the converter 78 provided in the solar power generation device 70. The converter 78 includes a filter circuit 100, a switching circuit 102, a transformer circuit 104, and a rectifier circuit 106.

  In the air conditioner 10, the control signal voltage is output from the control board 60 via the control connector 98 of the outdoor unit 14, and the converter 78 is connected to the control connector 86 so that the control connector 86 is connected to the control connector 86. It is driven by the control signal voltage input via the terminal.

  In the air conditioner 10, not only during the air conditioning operation but also in the ventilation operation using the ventilation unit 52, the contact 58 is closed to supply power to the outdoor unit 14. It can be operated during air conditioning operation and ventilation operation.

  On the other hand, the generated power of the solar panel 72 is input from the input terminal 80, passes through the filter circuit 100, the noise component is removed, and is input to the switching circuit 102.

  The switching circuit 102 includes a switching element 108 using, for example, an FET (power MOSFET), and an oscillation circuit 110 that generates a switching signal for driving the switching element 108.

  In the switching circuit 102, the switching element 108 is switched and driven (on / off driving), whereby the DC power that has passed through the filter circuit 100 is supplied to the transformer circuit 104 while being turned on / off.

  The transformer circuit 104 includes a transformer 112, and electric power that has passed through the switching circuit 102 is input to the primary side of the transformer 112. At this time, when the switching element 108 is turned on / off, a voltage is generated on the secondary side of the transformer 112. Note that the transformer 112 generates voltages for output to the output connectors 82 and 84 and for output to the oscillation circuit 110.

  The rectifier circuit 106 includes a rectifier circuit 106A and a rectifier circuit 106B. The rectifier circuit 106A is provided between the transformer 112 and the output connector 84, and rectifies and smoothes the output voltage of the transformer 112. As a result, the converter 78 outputs power (for example, DC power of DC 14 V) supplied to the indoor unit 12 (see FIG. 3) of the air conditioner 10.

  The rectifier circuit 106B is provided between the transformer 112 and the output connector 82, and rectifies and smoothes the output voltage of the transformer 112. Thereby, in converter 78, the electric power (for example, direct-current power of DC300V) supplied to outdoor unit 14 of air-conditioner 10 is outputted.

  On the other hand, the converter 78 is provided with an input voltage determination circuit 114 that forms input voltage determination means between the filter circuit 100 and the switching circuit 102. In the converter 78, when generated power is input by the solar panel 72 (see FIG. 3), a voltage corresponding to the generated power is input to the switching circuit 102.

  A voltage input to the switching circuit 102 is applied to the input voltage determination circuit 114.

  The input voltage determination circuit 114 includes a first voltage determination unit 114A and a second voltage determination unit 114B. The first voltage determination unit 114A outputs a voltage signal VIN-L that is turned on when a voltage higher than a preset voltage VL is input. The second voltage determination unit 114B outputs a voltage signal VIN-H that is turned on when a voltage higher than the preset voltage VH is input.

  In the converter 78, power generation in the solar panel 72 is started, and when the generated power reaches a power level sufficient to start power conversion, a voltage input to the switching circuit 102 is set to a voltage VH (for example, VH When the power conversion is performed, the voltage input to the switching circuit 102 that generates the minimum power necessary for the solar panel 72 to continue the power conversion is set to the voltage VL (VH> VL, For example, VL = 10V).

  That is, in the solar power generation device 70, when the generated power of the solar panel 72 reaches the voltage VH input to the switching circuit 102, the power conversion can be started, and when the voltage falls below the voltage VL during the power conversion, the power conversion is started. Is set to stop.

  In converter 78, voltage signal VIN-H of input voltage determination circuit 114 (second voltage determination unit 114B) is output from control connector 86.

  Further, the converter 78 is provided with a protection circuit 116 as a protection means. The protection circuit 116 receives the voltage signal VIN-L from the input voltage determination circuit 114 (first voltage determination unit 114A).

  In the converter 78, when the switching element 108 is driven, heat is generated in the switching element 108 and the transformer 112. The converter 78 is provided with a thermistor 124 for detecting the temperature in the power controller 74 at this time, and the thermistor 124 is connected to the terminal 118 in the protection circuit 116.

  When the temperature of the switching element 108 detected by the thermistor 124 does not reach a preset protection temperature, the protection circuit 116 directly receives the voltage signal VIN-L input from the input voltage determination circuit 114 as the control connector 86. Output to.

  On the other hand, when the temperature rises in the switching element 108 or the like and reaches the protection temperature, the voltage signal VIN-L output to the control connector 86 is turned off. In the converter 78, the power conversion is stopped by this, so that the temperature protection for the switching element 108 and the like is achieved.

  As described above, the voltage signals VIN-L and VIN-H are input from the converter 78 to the microcomputer 62 provided on the control board 60 of the outdoor unit 14 via the control connector 98. Outputs an ON signal via the control connector 98 when the voltage signal VIN-H is turned ON while the voltage signal VIN-L is ON.

  Thereby, converter 78 starts power conversion of the power generated by solar panel 72.

  Further, the microcomputer 62 switches the on signal output from the control connector 98 to the off signal by turning off the voltage signal VIN-L while outputting the on signal.

  The converter 78 stops power conversion, that is, switching driving of the switching element 108 when an OFF signal is input via the control connector 86.

  On the other hand, the converter 78 is provided with a solar cell optimum voltage holding circuit (hereinafter referred to as “input voltage holding circuit 120”) as input voltage detecting means and an output voltage holding circuit 122 as output voltage detecting means.

  The input voltage holding circuit 120 is connected to the input side of the switching circuit 102, and an input voltage to the switching circuit 102 is applied. That is, a voltage (output voltage) corresponding to the generated power of the solar panel 72 is input to the input voltage holding circuit 120.

  In this input voltage holding circuit 120, a reference voltage generator 126 and a comparator 128 are formed. The reference voltage generator 126 outputs the reference voltage Vr to the comparator 128. Further, the comparison unit 128 is supplied with an input voltage Vin corresponding to the voltage input to the switching circuit 102. The comparison unit 128 triggers a comparison result between the reference voltage Vr and the input voltage Vin. Output as signal TG1. That is, the Lo / High signal is output as the trigger signal TG1 according to the magnitude of the input voltage Vin with respect to the reference voltage Vr.

  FIG. 5A shows an outline of the output voltage-output power characteristic of the solar cell (solar cell module 76), and FIG. 5B shows an outline of the output voltage-output current characteristic of the solar cell. Yes. In the solar panel 72, the solar cell (solar cell) forming the solar cell module 76 generates electric power according to the amount of solar radiation. Therefore, the output voltage-output current characteristic of the solar panel 72 becomes the output voltage-output current characteristic of the solar battery cell, and becomes the input voltage-input current characteristic to the switching circuit 102.

  As shown in FIG. 5A, in the solar panel 72, the output power changes according to the amount of solar radiation, the output power decreases when the solar radiation amount is small, and the output power increases when the solar radiation amount is large. This output power is input power to the switching circuit 102 of the converter 78.

  When the amount of solar radiation is constant, as shown in FIG. 5B, the output power rises (with a constant output current) until the output voltage rises to a predetermined value (voltage Vp), but the output voltage is predetermined. When it becomes higher than the value (voltage Vp), the output current decreases rapidly. Therefore, as shown in FIGS. 5A and 5B, in the solar panel 72, when the output voltage is the voltage Vp, the maximum power point Wp is obtained.

  From this point, by holding the input voltage to the switching circuit 102, which is the output voltage of the solar panel 72, at a predetermined value, the output power of the solar panel 72 becomes the highest and the output power of the converter 78 becomes the highest.

  Here, in the converter 78, the reference voltage Vr is set based on the output voltage Vp of the solar panel 72, and when the output voltage Vp becomes the input voltage of the switching circuit 102, the reference voltage Vr corresponds to the input voltage. The reference voltage Vr is set so that the input voltage Vin of the input voltage holding circuit 120 is equal to the reference voltage Vr.

  Thereby, the input voltage holding circuit 120 of the converter 78 can output the trigger signal TG1 so as to hold the output voltage of the solar panel 72 at the output voltage Vp of the optimum operating point.

  On the other hand, as shown in FIG. 4, the output voltage holding circuit 122 is provided in the rectifier circuit 106B. The output voltage holding circuit 122 includes a photocoupler 130 and turns on / off the photocoupler 130 according to the output voltage of the rectifier circuit 106B. That is, when the output voltage Vout from the output connector 82 becomes higher than a set voltage (for example, DC 300 V), the photocoupler 130 is turned on, and when it becomes lower, the photocoupler 130 is turned off.

  The on / off (High / Lo) signal of the photocoupler 130 is input to the oscillation circuit 110 together with the trigger signal TG1 (High / Lo signal) of the input voltage holding circuit 120. That is, the trigger signal TG1 of the input voltage holding circuit 120 and the feedback signal of the output voltage holding circuit 122 are input to the oscillation circuit 110.

  In the oscillation circuit 110, the on-duty of the switching signal for driving the switching element 108 is controlled based on the feedback signal including the trigger signal TG1.

  As a result, the converter 78 can perform power conversion while taking out the generated power of the solar panel 72 at the maximum power point Wp and output it. In other words, the converter 78 feeds back the change in the input voltage to the switching circuit 102 and the change in the output voltage to drive the switching element 108, whereby the optimum operating point (generated current) of the solar panel 72 (solar cell module 76). At the peak), maximum power tracking control (MPPT: Maximum Power Point Tracking) for extracting the generated power and converting it into voltage can be performed.

  In the air conditioner 10 configured as described above, the air-conditioned room is set based on the operation conditions such as the set operation mode and set temperature as well as the operation / stop of the air-conditioning operation by the switch operation of the remote control switch 50. Air-conditioning operation is performed so as to be in a state.

  Further, in the air conditioner 10, the ventilation unit 52 can be operated alone as well as the ventilation unit 52 in conjunction with the air conditioning operation. By operating the ventilation unit 52, air supply and exhaust in the air-conditioned room can be performed. It has become.

  By the way, a solar power generation device 70 is connected to the air conditioner 10, and the compressor 26 and the ventilation unit 52 can be driven using the power generated by the solar power generation device 70.

  The air conditioner 10 supplies power to the outdoor unit 14 not only during the air conditioning operation but also during the single operation of the ventilation unit 52, so that the control board 60 and the microcomputer 62 provided on the control board 60 are in an operating state. It has become.

  On the other hand, the converter 78 of the photovoltaic power generator 70 is operated by a control signal voltage sent from the control board 60 when the control board 60 is in an operating state.

  Further, in the solar power generation device 70, when the generated power of the solar panel 72 is input while the converter 78 is in an operating state, an input voltage corresponding to the generated power is input to the input voltage determination circuit 114 of the converter 78. .

  The input voltage determination circuit 114 determines whether or not the input voltage exceeds the voltage VL and whether or not the voltage VH is exceeded. When the input voltage exceeds the voltage VL, the voltage signal VIN-L is output (ON), and the voltage VH If it exceeds, the voltage signal VIN-H is output (ON).

  The microcomputer 62 provided on the control board 60 of the outdoor unit 14 outputs an on / off signal for performing power conversion based on the voltage signals VIN-L and VIN-H input from the converter 78. Power conversion is started when an on signal is input, and power conversion is stopped when an off signal is input.

  Here, an outline of control based on the voltage signals VIN-L and VIN-H will be described with reference to FIG. This flowchart is executed while the microcomputer 62 of the outdoor unit 14 is operating in a state where the solar power generation device 70 is connected to the air conditioner 10. That is, it is executed while the control signal voltage is being supplied to the converter 78 during the air conditioning operation or the ventilation operation of the air conditioner 10.

  When the microcomputer 62 starts operating, first, in the first step 200, the microcomputer 62 outputs an off signal to the converter 78 of the photovoltaic power generator 70. As a result, converter 78 stops power conversion.

  Thereafter, in step 202, it is confirmed whether or not the voltage signal VIN-L input from the converter 78 is turned on. In step 204, it is confirmed whether or not the voltage signal VIN-H is turned on.

  The converter 78 detects the input voltage corresponding to the generated power of the solar panel 72 by starting the operation, confirms whether or not the input voltage exceeds the voltage VL, and whether or not the voltage VH is exceeded. When the power increases and exceeds the voltage VH, the voltage signal VIN-H is output. At this time, since the voltage signal VIN-L is already on, an affirmative determination is made in step 202 and step 204, and the routine proceeds to step 206.

  The microcomputer 62 outputs an ON signal to the converter 78 by moving to step 206.

  The converter 78 starts switching driving of the switching element 108 when the ON signal is input. That is, converter 78 starts power conversion of the power generated by solar panel 72.

  Thereby, the electric power output from the converter 78 is input to the control board 60 of the outdoor unit 14, and the compressor 26 using this generated electric power can be driven. In the indoor unit 12, the output power of the converter 78 is input to the control board 46, and the ventilation unit 52 (the intake fan 54 and the exhaust fan 56) using the generated power can be driven.

  In the next step 208, it is confirmed whether or not the voltage signal VIN-L is turned off. When the voltage signal VIN-L input from the converter 78 is turned off, an affirmative determination is made in step 208 and the process proceeds to step 200. Returning, an off signal is output and the power conversion of the converter 78 is stopped.

  In the converter 78, when the power generated by the solar panel 72 decreases and the input voltage of the input voltage determination circuit 114 decreases below the voltage VL, the voltage signal VIN-L is turned off. That is, when the generated power of the sorter panel 72 does not reach sufficient power for power conversion, the voltage signal VIN-L is turned off.

  The converter 78 is provided with a protection circuit 116. When the temperature detected by the thermistor 124 reaches the protection temperature, the protection circuit 116 turns off the voltage signal VIN-L.

  As a result, the microcomputer 62 outputs an off signal, so that the converter 78 stops the power conversion when the generated power of the solar panel 72 decreases. Further, when the temperature rises due to heat generation or the like of the switching element 108, the converter 78 is stopped and the switching element 108 or the like can be protected from heat.

  As described above, between the microcomputer 62 and the converter 78, the converter 78 outputs the voltage signals VIN-L and VIN-H in accordance with the generated power of the solar panel 72, and the converter 78 can perform power conversion / stop. It can be controlled accurately. Further, the microcomputer 62 can control the power conversion / stop of the converter 78 by a simple process.

  On the other hand, the converter 78 performs power conversion by driving the switching element 108 with a switching signal output from the oscillation circuit 110. Further, the converter 78 is provided with an input voltage holding circuit 120 and an output voltage holding circuit 122 so that a constant output voltage can be obtained by the output voltage holding circuit 122.

  Thus, converter 78 can supply power of a predetermined voltage to each of control boards 46 and 62 of air conditioner 10.

  The input voltage holding circuit 120 outputs a trigger signal TG1 based on the input voltage Vin and the reference voltage Vr, and the converter 78 sets the on-duty of the switching signal for driving the switching element 108 based on the trigger signal TG1. I have control.

  At this time, the reference voltage Vr is set based on the voltage Vp at the optimum operating point of the solar panel 72, so that the converter 78 can perform efficient power conversion at the optimum operating point of the solar panel 72. It has become.

  As described above, the converter 78 of the photovoltaic power generation apparatus 70 performs power conversion at the optimum operation point of the solar panel 72 with a simple configuration in which the input voltage holding circuit 120 and the output voltage holding circuit 122 are provided. Can be output.

  That is, the converter 78 detects each of the input current, input voltage, output current, and output voltage, and controls driving of the switching element 108 according to changes in the input voltage and output voltage without performing complicated control. Optimal power conversion is possible with a simple configuration.

  Thus, with the air conditioner 10 and the solar power generation device 70 applied to the present embodiment, the solar power generation device 70 can be appropriately operated during the operation of the air conditioner 10. Moreover, in the photovoltaic power generator 70, the microcomputer 62 of the air conditioner 10 has a simple configuration in which the voltage signals VIN-L and VIN-H are output from the converter 78. Thus, the converter 78 can be operated properly without providing a microcomputer or the like in the converter 78.

  Further, the converter 78 can output a constant voltage of power at the optimum operating point (maximum power point Wp) of the solar panel 72 without using a microcomputer or the like.

  Thereby, the compactness and cost reduction of the solar power generation device 70 connected to the air conditioner 10 are possible.

  The present embodiment described above does not limit the present invention. For example, in the present embodiment, the voltage signals VIN-L and VIN-H are output from the converter 78. However, even if the signals that share the voltage signals VIN-L and VIN-H are output. As a result, it is possible to appropriately control the power conversion / stop of the converter by a simple process without using the microcomputer 62 or the like.

  In the present embodiment, the power generated by the solar power generation device 70 can be supplied not only to the outdoor unit 14 but also to the indoor unit 12. However, as an air conditioner, only the outdoor unit is a solar power generation device. The solar power generator may supply power only to the outdoor unit 14.

  In the present embodiment, the ventilation unit 52 is provided in the indoor unit 12 and the generated power of the photovoltaic power generation apparatus is mainly used in the ventilation unit in the indoor unit. However, the present invention is not limited to this. You may make it use for drive of the flap motor which drives, the fan motor which drives a cross flow fan, etc.

  Furthermore, in this embodiment, the solar power generation device 70 connected to the air conditioner 10 has been described as an example. An electric power device may be supplied. At this time, the electric power device only needs to be capable of simple control based on a voltage signal output from the solar power generation device.

It is a schematic block diagram of the air conditioner applied to this Embodiment. It is the schematic which shows an example of the refrigerating cycle of an air conditioner. It is a block diagram which shows the outline of the control system of an air conditioner and a solar power generation device. It is an example of the circuit diagram which shows schematic structure of a converter. (A) is a diagram which shows the outline of the output voltage-output power characteristic of a solar cell module, (B) is a diagram which shows the outline of the output voltage-output current characteristic of a solar cell module. It is a flowchart which shows an example of the process based on the signal input from a converter.

Explanation of symbols

10 Air conditioner (air conditioner)
DESCRIPTION OF SYMBOLS 12 Indoor unit 14 Outdoor unit 26 Compressor 46 Control board 48 Microcomputer 52 Ventilation unit 60 Control board 62 Microcomputer 70 Solar power generation device 72 Solar panel 76 Solar cell module 78 Converter 102 Switching circuit (conversion means)
108 Switching element (conversion means)
110 Oscillation circuit (conversion means, conversion control means)
114 Input voltage judgment circuit (input voltage judgment means)
114A 1st voltage determination part (input voltage determination means)
114B 2nd voltage determination part (input voltage determination means)
116 Protection circuit (protection means)
120 Input voltage holding circuit (input voltage detection means)
122 Output voltage holding circuit (output voltage detection means)

Claims (5)

A solar panel that receives sunlight and generates DC power, and a solar power generation apparatus that includes a converter that converts the power generated by the solar panel into power of a predetermined voltage and outputs the power,
The converter includes an input voltage determination means for determining whether or not the voltage of the generated power input from the solar panel has reached a voltage corresponding to the generated power set to be capable of power conversion in advance.
A photovoltaic power generation apparatus that performs power conversion by receiving an operation signal based on a determination result of the input voltage determination means.   The input voltage determination means is set to stop the power conversion and the first determination result based on whether or not the voltage set to continuously enable power conversion has been reached. The photovoltaic power generation apparatus according to claim 1, wherein a second determination result based on whether or not the voltage has been reached is output.   The detection result of the protection means is included in the detection result of the input voltage detection means when the protection means for detecting whether or not the converter has risen above a predetermined temperature is included. The solar power generation device of Claim 1 or Claim 2. In the converter,
Conversion means for converting electric power input from the solar panel into electric power of a predetermined voltage;
Input voltage detection means for detecting a change in the input voltage input to the conversion means;
Output voltage detection means for detecting a change in the output voltage output from the conversion means;
Conversion control means for controlling the operation of the conversion means based on detection results of the input voltage detection means and the output voltage detection means;
The solar power generation device according to any one of claims 1 to 3, further comprising: The conversion means, a switching circuit for switching driving the switching element;
An oscillation circuit that generates a switching signal for driving the switching element and controls an on-duty of the switching signal based on detection results of the input voltage detection unit and the output voltage detection unit;
The solar power generation device according to claim 4, comprising:

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