JPS5813948A - Room-cooling, heating and hot water supplying device - Google Patents

Abstract

PURPOSE:To dispense with other heat source such as a combustor at the time of heating when outside temperature is low, by supplying heat from solar heat collected by a collector in a device which utilizes a heat pump and solar heat collector. CONSTITUTION:The device 1 comprises a heat pump 4 having the first and second heat exchangers 2, 3, the first heat medium circulating circuit 5 which exchanges heat with a heat pump 4, a heat storage circuit 6 which exchanges heat individually with the heat exchanger 2 and 3, a hot water storage circuit 7 which exchanges heat with the heat storage circuit 6 and the second heat medium circulation circuit 8 which supplies solar heat to both circuits 6 and 7. At the time of heating when outside temperature is low, hot water heated by solar heat collected by a collector 32 is supplid by means of hot water pump 38 to a heat storage tank 15 which is supplied to the heat pump 4 as an axuiliary heat source via the heat exchanger 2, facilitating heating operation.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an air-conditioning/heating/water heating system using a toto pump and a solar collector.

BACKGROUND ART In the past, indoor heating and cooling and hot water supply into a room were performed by separately providing an air conditioning device for heating and cooling and a hot water supply device for supplying hot water, and operating them individually.

However, according to such conventional methods.

This is because the ability of the air conditioning system, especially during heating operation in an environment where the outside air temperature is extremely low, decreases due to the occurrence of frost.

It is necessary to supply auxiliary heat using an electric heater or the like to the heating and cooling equipment that is in heating mode. This requires a new device for auxiliary heat supply and new electric power to operate it, resulting in an increase in operating costs. Furthermore, since the hot water supply system is also operated in addition to the operation of the air conditioning system, this contributes to an increase in operating costs.

In addition, in order to suppress the increase in costs mentioned above, there is a known water heater that uses solar heat as its heat source and introduces a solar system that uses this solar heat to obtain hot water. Since it is operated separately, it is not possible to reduce the cost of heating and cooling equipment.This invention was made in view of these conventional circumstances.It has a pair of heat exchange parts. A first heat medium circulation circuit that exchanges heat with the heat pump and one of the heat exchange sections of the heat pump, a heat storage circuit that exchanges heat with each of the pair of heat exchange sections, and the heat storage circuit. By configuring an air conditioning/hot water supply system with a hot water storage circuit that performs exchange, and a second heat medium circulation circuit that supplies solar heat to the heat storage circuit and the hot water storage circuit, conventional problems can be solved. The object of the present invention is to provide an air-conditioning/heating/water heating device that does not reduce heating capacity during heating operation in an environment where the temperature has significantly decreased, can suppress an increase in operating costs, and can also supply hot water. Hereinafter, this invention will be explained in detail based on an embodiment shown in FIGS. 1 to .mu.. - What is indicated by the reference numeral 1 in the drawing is an air-conditioning/heating/hot-water supply device, and this air-conditioning/heating/hot-water supply device 1 includes a heat pump 4 having a first heat exchange section 2 and a third heat exchange section 3.

A seventh heat medium circulation circuit 5 that performs heat exchange with the heat pump 4; and a heat storage circuit 6 that performs individual heat exchange between the seventh heat exchange section 2 and the third heat exchange section 3 of the heat pump 4. , a hot water storage circuit 7 that exchanges heat with the heat storage circuit 6, and a second heat medium circulation circuit 8 that supplies solar heat to the heat storage circuit 6 and the hot water storage circuit 7.

The seventh heat medium circulation circuit 5 includes a heat exchanger 9 that exchanges heat with the first heat exchange section 2 of the heat pump 4, and an indoor (
The terminal heat exchangers 10 and 10 disposed on the side (not shown) are communicated with each other through pipes 11 and 12.

The heat storage circuit 6 includes a heat exchanger 13 and a latent heat storage material 1 inside.
The heat exchanger 13 has a heat storage tank 15 in which 4, 14, . . . By communicating with the exchanger 9tC, the heat storage tank 15 is also communicated with the heat exchanger 20, which exchanges heat with the second heat exchange section 3 of the heat pump 4, by pipes 21 and 22tC. has been done.

The hot water storage circuit 7 has a hot water storage tank 24 in which a heat exchanger 23 is disposed, and the heat exchanger 23 is connected to the three-way valve 2.
The hot water tank 24 has a faucet 29 located on the indoor side. connected.

In the second heat medium circulation circuit 8, the solar collector 32 is communicated with the heat storage tank 15 and the hot water storage tank 24 through pipes 35 and 36 connected to the pipes 21 and 22 via three-way valves 33 and 34ft. It is made up of.

Further, among the circuits configured in the same manner, the seventh heat medium circulation circuit 5 has a space between the heat exchanger 9 and one three-way valve 17, and the heat storage circuit 6 has a space between the three-way valve 33 and the third heat medium circulation circuit 5.

Pumps 37 and 38 for heat medium circulation are arranged in each of them.

(K　ICb) The operation of this invention will be explained.

First, the operation for performing normal heating operation will be explained. For this purpose, by switching the three-way valve 17, communication between the terminal heat exchanger 10.lO and the heat exchanger 9 is established.
All that is required is to drive the pump 37 together with the heat pump 37 to circulate the heat medium in the first heat medium circulation circuit 5 as shown by the solid arrow in FIG. The heat generated by the heat pump 4 is transferred to the circulating heat medium through heat exchange between the seventh heat exchange section 2 and the heat exchanger 9, and the heat transferred to the heat medium is converted into terminal heat. Since the heat is transmitted to the indoor air by the exchangers 10, the indoor air is heated and space heating is performed. The heat transfer at this time is shown by the dashed-dotted arrow in Figure 1.

Next, a description will be given of the operation when performing heating operation in an environment where the outside air temperature has significantly decreased. In order to perform heating operation in an environment where the temperature of the outside air has significantly decreased, in addition to the normal heating operation described above, in order to prevent a decrease in % heating capacity.

Although it is necessary to supply auxiliary heat to the heat pump 4,
As this auxiliary heat, heat stored in the heat storage tank 15 of the heat storage circuit 6 may be used. Therefore, the operation for storing heat in the heat storage tank 15 will be explained. There are two types of this operation: One book uses the solar heat obtained from daytime sunlight, and the other uses the heat generated by the heat pump 4 when solar heat cannot be obtained. The former connects the solar collector 32 and the heat storage tank 15 by switching the three-way valves 25 and 26 and the three-way valves 33 and 34, and then drives the pump 38 to connect the heat storage circuit 6 and the first heat medium circulation. , the circulation of the heat medium between the first path and the third
This is done by performing the steps shown by the solid line arrows in the figure. As a result, the solar heat collected by the solar collector 32 is transmitted to the heat storage tank 15 and stored therein, as shown by the dashed-dotted arrow in FIG. The latter is performed during the day when the outside air temperature is relatively high, and the three-way valves 16 and 17 are switched to connect the heat exchanger 9 and the heat storage tank 1.
5 - and cut off the communication between the terminal heat exchangers 10, 10 and the heat exchanger 9, the pump 37 is driven to transfer the heat medium between the first heat medium circulation circuit 5 and the heat storage circuit 6. The third cycle of
This is done by performing the steps shown by the solid line arrows in the figure. Through this circulation of the heat medium, the heat generated by the heat pump 4 is transferred to the second heat exchange section 2% heat exchanger 9. The heat is transferred to the heat storage tank 15 by the heat exchanger 13 and is stored therein. The heat transfer at this time is shown by the dashed-dotted arrow in FIG. The heat stored in advance in this way can be used in heating operations under the above-mentioned environment.
The heat is supplied to the first heat exchange section 3 of the heat pump 4 as auxiliary heat. To do this, the three-way valves 33 and 34 and the three-way valves 25 and 26 are switched to establish communication between the heat exchanger 20 and the heat storage tank 15. After that, the pump 3B may be driven to circulate the heat medium between the heat storage tank 15 and the heat exchanger 20.

As a result, the heat stored in the heat storage tank 15 is transferred to the heat exchanger 20.
By the operations described above, auxiliary heat is supplied to the first heat exchange section 3, and even during heating operation in an environment where the temperature of the outside air is extremely low, the generation of frost is prevented by supplying auxiliary heat, and the heating capacity is improved. prevent a decline in

Next, the operation for obtaining hot water for hot water supply will be explained.

Hot water for hot water supply is obtained by heating water supplied from piping 31 into the hot water storage tank 24 by a heat exchanger 23IF- in the hot water storage tank 24.
3 is supplied with heat through three-way valves 33 and 34 and three-way valves 25 and 3.
This can be done by switching the switch 26 to establish communication between the solar collector 32 and the heat exchanger 23, and driving the pump 38 to circulate the heat medium. This and the circulation of the heat medium are $v! % is also indicated by a solid arrow in J. Heat transfer is shown in the same figure by the dashed-dotted arrow. Of course, if the heat exchanger 23 and the heat storage tank 15 are connected through a circulation circuit, it is also possible to perform the above-described heating using the stored heat. The hot water thus obtained is supplied from the hot water storage tank 24 into the room by opening the 29ft faucet located in the room.

Next, the operation for performing cooling operation will be explained.

The operation in this case is to switch the operation of the heat pump 4 to the cooling operation in the operation for normal heating shown in FIG. Since the heat medium is absorbed from the heat medium circulating in the first heat medium circulation circuit 5 via the converter 9, the heat medium is cooled as it passes through the heat exchanger 9, and , the terminal heat exchanger lO·10t- absorbs heat from the indoor air as it passes through, thereby cooling the indoor air. This cools the room.

In addition, in the above embodiment, the three-way valve 1 connects the communication t-1 pipes 18 and 19 between the heat storage tank 15 and the heat exchanger 9 to the pipes 11 and 12.
An example was explained in which the connection is made by connecting the heat storage tank 15t and the heat exchanger 9;! Alternatively, the heat exchanger 20 that exchanges heat with the first heat exchange section 3 of the heat pump 4 may be connected to the heat storage tank 1.
It is also possible to communicate directly with 5. Furthermore, the third
As shown in the figure, a pipe 31 connected to the water supply is connected to the pipe 12 of the seventh heat medium circulation circuit 5 by a pipe 39.

Further, by connecting the faucet 29 to the pipe 11 of the circuit 5 through the pipe 40Wc, water may be supplied twice as shown by the solid arrow in the figure. This circulation WIK
Therefore, it is also possible to heat and supply hot water using the heat pump 4, which is heated by t% of the water supplied from the water supply. However, in this case, on-off valves 41 and 42 are installed between the connecting part of the pipe 12 and the pipe 39 of the pipe 12 and the terminal heat exchanger 10 and on the pipe 40. By switching, it is necessary to switch between the hot water supply circuit and the cooling/heating circuit described above.

As explained above, there is a heat pump having a pair of heat exchange parts, and an M/heat medium circulation circuit that exchanges heat with one of the heat exchange parts of the heat pump.

A heat storage circuit that performs heat exchange with each of the pair of heat exchange units, a hot water storage circuit that performs heat exchange with the heat storage circuit, and a first heat medium circulation that supplies solar heat to the heat storage circuit and the hot water storage circuit. According to the air-conditioning/heating/hot-water supply apparatus of the present invention, which is comprised of a circuit and a V-, it is possible to perform normal air-conditioning and hot water supply using solar heat.

The heat obtained from the pump and the solar heat obtained from the solar collector are temporarily stored in a heat storage tank, and this stored heat can be operated easily when the outside air temperature is relatively high. When operating a heating system in an environment where the outside air temperature is extremely low.

It can be supplied as auxiliary heat to a heat pump, or as heat for heating a hot water tank when supplying hot water when solar heat is not available, making it easy to store heat, and 2. It can be done cheaply, and
There is no need for electrical equipment or combustion equipment to obtain heat for auxiliary heat or hot water supply, reducing equipment costs and operating costs.

Therefore, during heating operation under the above-mentioned environment, it is possible to easily prevent a decrease in heating capacity at low operating costs.

As described above, according to the present invention, it is possible to provide an air-conditioning/heating/hot water supply device that can achieve various effects.

[Brief explanation of drawings]

In the drawings, Fig. 1 to Fig. μ show an embodiment of the present invention, Fig. 7 shows the overall device, and Fig. 1 to Fig. μ show operation explanatory views. FIG. 3 is a diagram showing another embodiment. 1...Air conditioning/heating/water heating equipment, 2...7th
Heat exchange m%3...Second heat exchange section, 4...
... heat pump, 5 ... seventh heat medium circulation circuit, 6 ... heat storage circuit, 7 ... hot water storage circuit, 8 ... second heat medium circulation circuit Heat medium circulation circuit%9...
Heat exchanger%13...Heat exchanger, 15...
・Heat storage tank, 20...Heat exchange section, 23...
・Heat exchanger, 32... Solar Yorefta 1, 2
4...Hot water tank.

Claims (1)

[Claims] A heat pump having a pair of heat exchange parts, a seventh heat medium circulation circuit having a terminal heat exchanger and exchanging heat with one of the heat exchange parts of the heat pump, and a heat storage tank having the pair of heat exchange parts. a heat storage circuit that performs heat exchange with each of the heat storage tanks; a hot water storage circuit that has a hot water storage tank and performs heat exchange with the heat storage tank; and a second hot water storage circuit that has a solar collector and supplies heat to the heat storage tank or the hot water storage tank. An air-conditioning/heating/water heating system comprising a heat medium circulation circuit and valve bodies arranged in each of the circuits to individually open and close the circuits.