JPH08265988A - Hot water supply - Google Patents

Abstract

PURPOSE: To enhance the reliability by connecting an inverter through a switch with a heat pump type hot water supply system thereby sharing the inverter between a solar power generation system and the heat pump type hot water supply system. CONSTITUTION: The EMI.DC filter 3 of a heat pump type hot water supply system is connected through a first switch 4 with an inverter 5 which is connected through a second switch 6, an AC-EMI filter 7 and a system interconnection protective switch 8 with an insulation unit 9 thus constituting a solar power generation system. Furthermore, the inverter 5 is connected through a DC filter 10, a rectifier 11 and a third switch 12 with an EMI filter 13, and through a fourth switch 14 with a compressor drive motor 15 thus constituting the compressor drive section in the heat pump type hot water supply system.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot water supply device for solar power generation, which is equipped with a solar power generation system and a heat pump type electric hot water supply system.

[0002]

2. Description of the Related Art The structure of a conventional solar water-capable electric water heater equipped with a solar power generation system and a heat pump type electric water heater incorporating an inverter will be described below with reference to FIG.

The solar power generation system includes a solar cell array 5
1 is connected to a solar power generation control device 52, and this solar cell array 51 is connected to an inverter 55 via an EMI filter 53 and a DC filter 54 in the solar power generation control device 52.
It is connected to a system linkage protection switch 58 via a filter 56 and an EMI filter 57. Note that the inverter 5
A system linkage protection control device 59 is connected to 5.

The heat pump type electric hot water supply system includes a compressor drive unit 60.
In the above, the EMI filter 61 is connected to the inverter 64 via the rectifier 62 and the DC filter 63, and the inverter 64 is connected to the compressor driving motor 65. A heat pump controller 66 is connected to the inverter 64.

The system linkage protection switch 58 in the photovoltaic power generation control device 52 and the EMI filter 61 in the compressor drive unit 60 are connected to a distribution board 67, respectively.

When the solar cell array 51 is irradiated with sunlight, the direct current generated by the power generation is supplied to the inverter 55 via the EMI filter 53 and the DC filter 54 of the solar power generation control device 52, and the grid connection is performed. The protection control device 59 converts the AC current into a sinusoidal waveform without distortion. The converted alternating current is supplied to the AC filters 56 and E.
System linkage protection switch 58 via MI filter 57
To the distribution board 67.

Further, in the heat pump type electric hot water supply system, the EMI filter 6 of the compressor drive unit 60.
1 is supplied with AC commercial power, and is converted into DC current by the rectifier 62. The converted direct current is supplied to the inverter 64 via the DC filter 63, adjusted to an appropriate frequency by the heat pump controller 66, and then supplied to the compressor driving motor 65.

[0008]

In the conventional electric hot water supply apparatus for photovoltaic power generation, a plurality of inverters such as the inverter 55 in the solar power generation system and the inverter 64 in the heat pump type electric hot water supply system are required. There is a problem that the configuration becomes complicated, and if there is a difference in the reliability of the respective inverters, failure is likely to occur and it becomes very uneconomical.

The present invention provides a hot water supply apparatus in which the inverter used in the solar power generation system and the heat pump type electric hot water supply system can be commonly used to improve reliability, and moreover, the apparatus configuration can be simplified. It is an object.

[0010]

In order to achieve the above object, in a hot water supply apparatus of the present invention, a solar power generation system having a solar cell array and an inverter and a heat pump hot water supply system are provided, and the inverter is The compressor drive unit of the heat pump hot water supply system is connected via a switch.

Further, the inverter may be connected to the compressor drive section of the heat pump hot water supply system via an open / close switch.

Further, power generation detecting means may be inserted in the solar power generation system, and the inverter may be connected to the compressor drive section of the heat pump hot water supply system via a changeover switch.

In addition, an EMI-connected solar cell array
A sunlight formed by connecting an inverter to the DC filter via the first opening / closing switch, and connecting an insulating device to the inverter via the second opening / closing switch, the AC / EMI filter, and the grid connection protection switch. A power generation system, and a compressor drive unit formed by connecting the inverter to a EMI filter via a DC filter and a rectifier and a third opening / closing switch and a compressor driving motor via a fourth opening / closing switch. And is effective.

Further, in the above, power generation detecting means is inserted between the solar cell array and the EMI / DC filter,
The third open / close switch is replaced with the first changeover switch, the fourth open / close switch is replaced with the second changeover switch to form one path, and the other of the first changeover switch and the second changeover switch is formed. A heat pump control device can be inserted in the path.

[0015]

In the hot water supply device configured as described above,
During operation of the solar power generation system, the direct current generated by irradiating the solar array with sunlight is converted into an AC current with a sinusoidal waveform without distortion and supplied to the insulation device. When the compressor drive section of the system is in operation, the electric power supplied from the commercial system is supplied to the inverter and adjusted to an appropriate frequency to operate the compressor of the heat pump type electric hot water supply system.

Further, when the solar cell array is irradiated with sunlight and the power generation detecting means detects the power generation during the operation of the solar power generation system, the DC current generated by the power generation has a sinusoidal waveform without distortion. When the compressor drive part of the heat pump type electric hot water supply system is operated, the electric power supplied from the commercial system is supplied to the heat pump control device, which is converted into an alternating current and supplied to the insulation device. When the compressor is driven by the power supply motor and the compressor drive section of the heat pump type electric hot water supply system is operated by an inverter at midnight, the power generation detecting means does not detect the power generation. Is converted to DC current by the converter and supplied to the inverter. It is supplied to the compressor driving section after being adjusted to an appropriate frequency by the control device, the compressor of the heat pump type electric water system to inverter operation.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The structure and operation of the embodiment of the present invention will be described below with reference to FIGS.

In FIGS. 1 and 2, an electric water heater for photovoltaic power generation comprises a solar cell array 1 and a heat pump type electric water heating system control device 2, and the solar cell array 1 is a heat pump type electric water heating system control device 2. Is connected to the EMI / DC filter 3 in FIG. This EMI / DC filter 3 has a first opening / closing switch 4
Is connected to the inverter 5 via the second opening / closing switch 6, the AC / EMI filter 7 and the grid connection protection switch 8 to form a solar power generation system. ing.

Further, the inverter 5 includes the DC filter 1
0 and the rectifier 11 and the third opening / closing switch 12 are connected to the EMI filter 13, while the fourth opening / closing switch 14 is connected to the compressor driving motor 15 to form a compressor driving unit in the heat pump electric hot water supply system. are doing.

An inverter / system linkage protection control device 16 is connected to the inverter 5, and the insulating device 9 in the photovoltaic power generation system and the EMI filter 13 in the compressor drive section are connected to the terminal unit 17, respectively.

During operation of the solar power generation system, the first opening / closing switch 4 and the second opening / closing switch 6 are closed, and the third opening / closing switch 12 and the fourth opening / closing switch 14 are open (see FIG. 1). 1 is exposed to sunlight, the direct current generated by power generation is EMID
A sinusoidal waveform without distortion in the inverter 5 which is supplied to the inverter 5 via the C filter 3 and the first open / close switch 4 and is controlled by the inverter / system linkage protection control device 16 to control the current waveform and the constant power factor. Is converted to AC current. The converted alternating current is supplied to the insulating device 9 via the second opening / closing switch 6, the AC / EMI filter 7 and the system linkage protection switch 8, and then supplied from the terminal unit 17 to the system.

When the compressor drive section of the heat pump type electric hot water supply system is in operation, the first opening / closing switch 4
And the second opening / closing switch 6 is opened, the third opening / closing switch 12 and the fourth opening / closing switch 14 are closed (see FIG. 2), and the electric power supplied from the commercial system is the terminal unit 1
7 to EMI filter 13 and third open / close switch 12
Is supplied to the rectifier 11 and is converted into a direct current by the rectifier 11. The converted DC current is supplied to the inverter 5 via the DC filter 10 and adjusted to an appropriate frequency by the inverter / system linkage protection control device 16 and then for driving the compressor via the fourth opening / closing switch 14. It is supplied to the motor 15 and operates the compressor of the heat pump type electric hot water supply system.

Therefore, with one inverter 5,
It is possible to perform grid-connected operation of the solar power generation system and compressor operation of the heat pump electric hot water supply system by simple switching.

Further, as shown in FIGS. 3 and 4, the power generation detecting means 18 is inserted between the solar cell array 1 and the EMI / DC filter 3, and the third opening / closing switch 12 is replaced by the first changeover switch 19. , 4th open / close switch 1
4 is replaced by a second changeover switch 20 to form one path, and the first changeover switch 19 and the second changeover switch 20 are connected to each other.
The heat pump control device 21 may be inserted in the other path of the changeover switch 20.

During operation of the solar power generation system, when the solar cell array 1 is irradiated with sunlight and the power generation detecting means 18 detects power generation, the first opening / closing switch 4 and the second opening / closing switch 4
The open / close switch 6 is closed, and the first changeover switch 19
The second changeover switch 20 is changed over to the path side of the heat pump control device 21 (see FIG. 3), and the direct current generated and generated is passed through the EMI / DC filter 3 and the first open / close switch 4 to the inverter 5 And is converted into an AC current having a sinusoidal waveform without distortion in the inverter 5 whose current waveform is controlled and whose power factor is constant by the inverter / system linkage protection control device 16. The converted alternating current is supplied to the insulating device 9 via the second opening / closing switch 6, the AC / EMI filter 7 and the system linkage protection switch 8, and then supplied from the terminal unit 17 to the system.

When the compressor drive section of the heat pump type hot water supply system is in operation, the electric power supplied from the commercial system is supplied to the heat pump controller 21 via the terminal unit 17, the EMI filter 13 and the first changeover switch 19. After being supplied and controlled here, it is supplied to the compressor driving motor 15 via the second changeover switch 20 to operate the compressor.

Further, when the compressor drive section of the heat pump type electric hot water supply system is operated by the inverter at midnight, the power generation detecting means 18 does not detect the power generation.
The first open / close switch 4 and the second open / close switch 6 are opened, and the first changeover switch 19 and the second changeover switch 20 are changed over to the path side of the inverter 5 (see FIG. 4).
The electric power supplied from the commercial system is supplied from the terminal unit 17 to the rectifier 11 via the EMI filter 13 and the first changeover switch 19, and is converted into a direct current by the rectifier 11. The converted direct current is D
The heat is supplied to the inverter 5 via the C filter 10, adjusted to an appropriate frequency by the inverter / system linkage protection control device 16, and then supplied to the compressor driving motor 15 via the second changeover switch 20. Inverter operates the compressor of the electric hot water supply system.

Therefore, with one inverter 5,
The grid linked operation of the solar power generation system and the compressor operation of the heat pump type electric hot water supply system can be performed by simple switching, and when the solar power generation is not performed, the heat pump type electric hot water supply system can be operated by an inverter.

[0029]

EFFECTS OF THE INVENTION Since the present invention is configured as described above, it is possible to perform the grid-linked operation of the solar power generation system and the operation of the heat pump hot water supply system with one inverter, and the device configuration is also The effect is simplified, the reliability of the inverter is improved, and the occurrence of failures is reduced.

[Brief description of drawings]

FIG. 1 is a block diagram of a solar power generation hot water supply apparatus according to an embodiment of the present invention when the solar power generation system is operating.

FIG. 2 is a block diagram during operation of the heat pump hot water supply system in the hot water supply device for solar power generation.

FIG. 3 is a block diagram of a solar power generation hot water supply apparatus according to another embodiment of the present invention when the solar power generation system is operating.

FIG. 4 is a block diagram of the heat pump hot water supply system in the solar power hot water supply device when the inverter is operating.

FIG. 5 is a block diagram of a conventional hot water supply device for photovoltaic power generation.

[Explanation of symbols]

 1 Solar Cell Array 3 EMI / DC Filter 4 First Open / Close Switch 5 Inverter 6 Second Open / Close Switch 7 AC / EMI Filter 8 Grid Link Protection Switch 9 Insulator 10 DC Filter 11 Rectifier 12 Third Open / Close Switch 13 EMI Filter 14 4th Open / close switch 15 Compressor driving motor 18 Power generation detecting means 19 First changeover switch 20 Second changeover switch 21 Heat pump control device

Claims (5)

[Claims] 1. A hot water supply apparatus comprising a solar power generation system having a solar cell array and an inverter, and a heat pump hot water supply system, wherein the inverter is connected to a compressor drive unit of the heat pump hot water supply system via a switch. 2. The hot water supply apparatus according to claim 1, wherein the inverter is connected to the compressor drive section of the heat pump hot water supply system via an open / close switch. 3. The hot water supply apparatus according to claim 1, wherein power generation detection means is inserted into the solar power generation system, and the inverter is connected to the compressor drive section of the heat pump hot water supply system via a changeover switch. 4. An EMI / DC connected with a solar cell array.
A solar power generation system in which an inverter is connected to the filter via a first opening / closing switch, and an insulating device is connected to the inverter via a second opening / closing switch, an AC / EMI filter, and a grid connection protection switch, and A hot water supply device comprising: a DC filter, a rectifier, and a compressor drive section that is connected to an EMI filter via a third opening / closing switch and is connected to a compressor driving motor via a fourth opening / closing switch. 5. An EMI / DC filter connected to a solar cell array via a power generation detecting means is connected to an inverter via a first opening / closing switch, and this inverter is connected to a second opening / closing switch and AC / EMI. A photovoltaic power generation system in which an insulating device is connected via a filter and a grid connection protection switch, and the inverter is connected to a DC filter, a rectifier, and an EMI filter via a first changeover switch, and via a second changeover switch. A hot water supply apparatus comprising: a compressor drive unit connected to a compressor drive motor; and a heat pump control device inserted between the other paths of the first changeover switch and the second changeover switch.