KR101256876B1 - Hybrid absorption type air conditioning system - Google Patents

Abstract

The present invention relates to a hybrid absorption type heating and cooling system, and in particular, a heat collecting plate for collecting solar heat; A heat exchanger to which a heat medium heated by heat collected from the heat collecting plate is transferred; A heat storage tank storing hot water generated by heat exchange with a heat medium in the heat exchanger; A hybrid absorption cold / hot water generator for producing cold water by using hot water supplied from the heat storage tank as an energy source; Geothermal heat storage means for transferring geothermal heat to the hybrid absorption chiller to remove cooling heat generated during the process of generating cold water from the hybrid absorbent chiller; It is configured to include; air conditioning to cool the air by using the cold water generated by heat exchange with the cold water generated in the hybrid absorption cold water heater during cooling, and to warm the air by receiving hot water supplied from the heat storage tank There is an effect that can lower the installation cost and maintenance costs.

Description

Hybrid absorption type air conditioning system

The present invention relates to a hybrid absorption type heating and cooling system, and more particularly, to a hybrid absorption type heating and cooling system that can reduce the installation cost and operating costs.

The development of eco-friendly energy is being expanded due to the depletion of fossil fuels, global warming, and environmental pollution. Accordingly, many technologies that realize cooling and heating using solar heat and geothermal heat have been widely used.

However, the cooling and heating systems, that is, the air conditioning systems, developed so far have a problem in that their efficiency is low and their installation costs are consumed.

The present invention has been made to solve the above problems of the prior art, it is an object of the present invention to provide a hybrid absorption type heating and cooling system that can not only reduce installation costs and operating costs but also improve efficiency.

Hybrid absorption type air-conditioning system according to the present invention for solving the above problems and the heat collecting plate to collect the solar heat; A heat exchanger to which a heat medium heated by heat collected from the heat collecting plate is transferred; A heat storage tank storing hot water generated by heat exchange with a heat medium in the heat exchanger; A hybrid absorption cold / hot water generator for producing cold water by using hot water supplied from the heat storage tank as an energy source; Geothermal heat storage means for transferring geothermal heat to the absorption chiller to remove the cooling heat generated during the process of generating cold water from the hybrid absorbent chiller; And an air conditioner that cools the air by using cold water generated by heat exchange with cold water generated in the hybrid absorption chiller when cooling, and warms the air by using hot water supplied from the heat storage tank.

In addition, the absorption cold and hot water heater further includes a gas burner.

Hybrid absorption type air-conditioning system of the present invention configured as described above can be cooled and heated using the hot water of the heat storage tank and the absorption type cold and hot water heater, there is an advantage that the installation cost and maintenance cost for air conditioning can be lowered.

In addition, the geothermal heat storage means to remove the cooling heat of the absorption type cold and hot water there is an advantage that can maximize the efficiency during cooling.

1 is a view showing a hybrid absorption type heating and cooling system according to the present invention.
Figure 2a is a view showing a fluid flow when cooling by using the heat storage tank of the hybrid absorption type cooling and heating system according to the present invention.
Figure 2b is a diagram showing the fluid flow when cooling by using a gas burner of the hybrid absorption type air-conditioning system according to the present invention.
Figure 3a is a view showing a fluid flow when heating using the heat storage tank of the hybrid absorption type heating and cooling system according to the present invention.
Figure 3b is a diagram showing the fluid flow when heating by using a gas burner of the hybrid absorption air-conditioning system according to the present invention.

Hereinafter, with reference to the accompanying drawings an embodiment of a hybrid absorption type air-conditioning system according to the present invention will be described in detail.

1 is a view showing a hybrid absorption type heating and cooling system according to the present invention.

And, Figure 2a is a view showing the fluid flow when cooling by using the heat storage tank of the hybrid absorption type cooling and heating system according to the present invention, Figure 2b is a fluid flow when cooling by using a gas burner of the hybrid absorption type heating and cooling system according to the present invention. Is shown.

In addition, Figure 3a is a diagram showing the fluid flow when heating by using the heat storage tank of the hybrid absorption type heating and cooling system according to the present invention, Figure 3b is a fluid flow when heating by using a gas burner of the hybrid absorption type heating and cooling system according to the present invention. Is shown.

The hybrid absorption type air-conditioning system according to the present invention includes a heat collecting plate 10 that collects solar heat, a heat exchanger 20 connected to the heat collecting plate 10, a heat storage tank 30 connected to the heat exchanger 20, and the heat storage tank. A portion of the hot water circulation pipe (P3) connected to 30 is inserted into the hybrid absorption cold and hot water heater 40 to generate cold water, and geothermal heat storage means 50 for removing the cooling heat generated in the hybrid absorption cold and hot water heater 40; It is configured to include an air conditioner (60) for cooling the air by heat exchange with the cold water generated in the hybrid absorption cold and hot water heater (40).

The heat collecting plate 10 is a portion for collecting solar heat to heat the heat medium accommodated therein.

The heat exchanger 20 is a portion to which the heat of the heat medium heated by the heat collected by the heat collecting plate 10 is transferred. In more detail, the heat medium flows inside the heat medium pipe P1, and a portion of the heat medium pipe P1 is inserted into the heat exchanger 20 to transfer heat to the heat exchanger 20. . The heat medium pipe (P1) is provided with a heat medium circulation pump (PP1) to circulate the heat medium. Here, the heat medium pipe (P1) is a pipe having a closed loop (Closed Loop) is connected to one end of the heat collecting plate 10 and the other end is similarly connected to the heat collecting plate (10).

The heat storage tank 30 is a tank in which water is stored, and is connected to the heat exchanger 20 and the water circulation pipe P2. The water circulation pipe (P2) flows in the water stored in the heat storage tank (30).

Here, a part of the water circulation pipe (P2) is inserted into the heat exchanger 20 so that the water in the water circulation pipe (P2) inside the heat medium and the heat exchanger (20) inside the heat medium pipe (P1). Hot water is produced by heat exchange at. That is, the low temperature water flowing through the water circulation pipe P2 is changed to high temperature hot water by heat exchange. The hot water thus changed is transferred to the heat storage tank 30 and stored. The flow of water in the water circulation pipe (P2) is made by the operation of the water circulation pump (PP2) installed on the pipeline of the water circulation pipe (P2). In addition, the water circulation pipe (P2) is a pipe having a closed loop shape, one end of which is connected to the heat storage tank 30 and the other end is connected to the heat storage tank 30 as well.

The hybrid absorption cold / hot water heater 40 is a device that generates cold water using hot water supplied from the heat storage tank 30 as an energy source. In more detail, the heat storage tank 30 has a water circulation pipe (P2) is installed on one side, the hot water circulation pipe (P3) is installed on the other side flows, the hot water installed on the other side of the heat storage tank (30) A portion of the circulation pipe P3 is inserted into the hybrid absorption chiller 40 to provide heat. The hot water supply pump (PP3) is installed on the pipeline of the hot water circulation pipe (P3). Here, the hot water circulation pipe (P3) is a pipe having a closed loop shape, one end is connected to the heat storage tank 30 and the other end is connected to the heat storage tank 30 as well. The hot water supply pump PP3 is installed on the hot water circulation pipe P3 and the first three-way control valve V1 and the second three-way control valve V2 are installed at regular intervals.

The geothermal heat storage means 50 is a device for removing the cooling heat of the hybrid absorption chiller hot water (40). The hybrid absorption cold / hot water generator 40 generates cooling heat during the process of generating cold water, and high efficiency can be obtained only by removing the cooling heat. Therefore, the geothermal heat is transferred to the hybrid absorption chiller and water heater 40 by the geothermal pipe P5 inserted at one side in the ground and inserted into the hybrid absorption chiller and water heater 40 to remove the cooling heat of the hybrid absorption chiller and water heater 40. do. The geothermal circulation pump PP5 and the geothermal control valve V5 are installed on the pipeline of the geothermal pipe P5.

The air conditioner 60 cools the indoor air by using cold water generated by heat exchange with cold water generated in the hybrid absorption cold / hot water heater 40 when cooling, and uses hot water supplied from the heat storage tank 30 when heating. As to warm the indoor air, a portion of the air conditioning pipe (P4) connected to the air conditioner (60) is inserted into the hybrid absorption cold water heater (40), the water flowing in the air conditioning pipe (P4) hybrid absorption cold and hot water heater (40). Heat exchange inside.

An air conditioning pump (PP4) for flowing water in the air conditioning piping (P4) is installed on the air line of the air conditioning pipe (P4), and the first air conditioning valve (V3) and the second on both sides of the air conditioning pump (PP4). An air conditioning valve V4 is installed. Here, the air conditioning pipe (P4) is a pipe having a closed loop shape, one end is connected to the air conditioner 60 and the other end is connected to the air conditioner 60 as well.

On the other hand, the hybrid absorption cold and hot water heater 40 is configured to further include a gas burner (42). Therefore, when the solar heat is not used due to cloudy weather or when the solar heat is insufficient, the gas burner 42 is operated to be used as an auxiliary heat source so as to realize efficient air conditioning.

The hot water circulation pipe P3 and the air conditioning pipe P4 communicate with each other by the first connection pipe P6 and the second connection pipe P7.

One end of the first connection pipe (P6) is connected to the second three-way control valve (V2) and the other end is connected to the air conditioning pipe (P4) adjacent to the first air conditioning valve (V3). That is, the other end of the first connection pipe (P6) is connected to the air conditioning pipe (P4) between the first air conditioning valve (V3) and the air conditioner (60).

One end of the second connection pipe (P7) is connected to the first three-way control valve (V1) and the other end is connected to the air conditioning pipe (P4) adjacent to the second air conditioning valve (V4). That is, the other end of the second connection pipe (P7) is connected to the air conditioning pipe (P4) between the second air conditioning valve (V4) and the air conditioner (60).

Referring to the fluid transfer process of the hybrid absorption type air-conditioning system according to the present invention configured as described above divided into several cases as follows.

First, the cooling process when the solar heat is sufficient will be described with reference to Figure 2a.

When solar heat is sufficient, the heat medium heated in the heat collecting plate 10 is introduced into the heat exchanger 20 along the heat medium pipe P1, and at the same time, the cold water stored in the heat storage tank 30 is heat-exchanged along the water circulation pipe P2. It is introduced into the machine 20.

The heat medium and the cold water are heat-exchanged in the heat exchanger 20 so that the temperature of the cold water is increased to convert it into hot water, and the hot water is introduced into the heat storage tank 30.

The hot water introduced into the heat storage tank 30 is introduced into the hybrid absorption type cold / hot water heater 40 through the first three-way control valve V1 along the hot water circulation pipe P3. At this time, the first three-way control valve (V1) blocks the second connection pipe (P7) side so that hot water does not flow to the second connection pipe (P7). The hot water introduced into the hybrid absorption chiller 40 provides heat to allow the hybrid absorption chiller 40 to generate cold water.

Then, the hot water that provides heat while passing through the hybrid absorption chiller and hot water 40 is recycled to the heat storage tank 30 through the second three-way control valve (V2) along the hot water circulation pipe (P3) after the water temperature is lowered. At this time, the second three-way control valve (V2) blocks the first connection pipe (P6) side so that water does not flow to the first connection pipe (P6).

On the other hand, by the operation of the air conditioning pump (PP4) installed in the air conditioning pipe (P4) the water inside the air conditioning pipe (P4) is introduced into the hybrid absorption type hot and cold water heater (40) via the first air conditioning valve (V3). The water introduced is heat-exchanged with cold water produced in the hybrid absorption chiller 40 and then converted into cold water, and then flows to the air conditioner 60 through the second air conditioning valve V4 to cool the indoor air.

In addition, the geothermal heat is continuously transmitted from the geothermal pipe (P5) of the geothermal heat storage means 50 to the hybrid absorption cold / hot water heater (40) in order to remove the cooling heat generated when the hybrid absorption cold / hot water heater (40) makes cold water.

Second, the cooling process when the solar heat is not sufficient will be described with reference to FIG. 2B.

If the solar heat is not sufficient, since hot water is not generated by the solar heat, the gas burner 42 is operated without operating the hot water supply pump PP3. When the gas burner 42 is operated, high temperature heat is supplied to the hybrid absorption chiller 40, and the hybrid absorption chiller 40 is operated to generate cold water. At this time, the water introduced into the hybrid absorption type cold and hot water heater 40 via the first air conditioning valve V3 through the air conditioning pipe (P4) is converted to cold water after the heat exchanger (V4) through the air conditioner (60) ) To cool the air in the room.

Here, the present invention uses the heat collecting plate 10 for cooling and the gas burner 42 does not use the case of FIG. 2A and the case of FIG. 2B using only the gas burner 42 without using the heat collecting plate 10. As may be used individually, as shown in FIG. 2A and FIG. 2B, that is, the heat collecting plate 10 and the gas burner 42 may be simultaneously cooled. Since such a process can be fully understood by those skilled in the art from the above description, a detailed description of the fluid transfer process will be omitted.

Third, the heating process in the case of sufficient solar heat will be described with reference to FIG. 3A.

When solar heat is sufficient, the heat medium heated in the heat collecting plate 10 is introduced into the heat exchanger 20 along the heat medium pipe P1, and at the same time, the cold water stored in the heat storage tank 30 is heat-exchanged along the water circulation pipe P2. It is introduced into the machine 20.

The heat medium and the cold water are heat-exchanged in the heat exchanger 20 so that the temperature of the cold water is increased to convert it into hot water, and the hot water is introduced into the heat storage tank 30.

The hot water introduced into the heat storage tank 30 flows through the first three-way control valve V1 and the second connection pipe P7 along the hot water circulation pipe P3. At this time, the first three-way control valve (V1) is supplied from the heat storage tank (30) by blocking the pipeline of the hot water circulation pipe (P3) toward the hybrid absorption type cold and hot water heater (40) and the second air conditioning valve (V4). The hot water is blocked from entering the hybrid absorption chiller 40.

The hot water flowing through the first three-way control valve (V1) and the second connection pipe (P7) as described above is introduced into the air conditioner (60) along the air conditioning pipe (P4) to warm the indoor air.

The cold water flowing into the air conditioner 60 and warming the indoor air after the water temperature is lowered flows along the air conditioning pipe P4 and then flows along the first connection pipe P6 and then the hot water circulation pipe P3. As a result, it is introduced into the heat storage tank 30 again. When the cold water flows down the air conditioning pipe P4, the first air valve V3 is blocked and the second three-way control valve V2 is connected to the hot water circulation pipe P3 toward the hybrid absorption type cold / hot water heater 40. Blocking the pipeline blocks cold water from entering the hybrid absorption chiller 40.

Fourth, the heating process when the solar heat is not enough will be described with reference to Figure 3b.

If the solar heat is not sufficient, since hot water is not generated by the solar heat, the gas burner 42 is operated without operating the hot water supply pump PP3. When the gas burner 42 is operated, high temperature heat is supplied to the hybrid absorption chiller 40. At this time, the water introduced into the hybrid absorption type cold and hot water heater 40 through the first air conditioning valve (P4) is heat-exchanged with the heat of the hybrid absorption type cold water heater (40) is converted into hot water, and then the second air conditioning valve (V4). ) Is flowed into the air conditioner (60) to warm the air in the room. On the other hand, when water flows into the hybrid absorption chiller / hot water heater 40 through the first air conditioning valve V3, the second three-way control valve V2 blocks the line of the first connection pipe P6 side, and the hybrid absorption chiller-water heater 40 The first three-way control valve (V1) blocks the line of the second connection pipe (P7) side when the flow to the air conditioner (60) after the heat exchange inside the hot water.

10: heat collecting plate 20: heat exchanger
30: heat storage tank 40: hybrid absorption chiller
42 gas burner 50 geothermal heat storage means 60 air conditioner
P1: heat medium piping P2: water circulation piping
P3: hot water circulation piping P4: air conditioning piping
P5: geothermal pipe P6: first connection piping
P7: second connecting pipe PP1: heat medium circulation pump
PP2: water circulation pump PP3: hot water supply pump
PP4: Air conditioning pump PP5: Geothermal circulation pump
V1: first three-way control valve V2: second three-way control valve
V3: 1st air conditioning valve V4: 2nd air conditioning valve
V5: Geothermal Control Valve

Claims (3)

A heat collecting plate 10 collecting solar heat;
A heat exchanger 20 in which the heat medium heated by the heat collected by the heat collecting plate 10 is transferred through the heat medium pipe P1 by the operation of the heat medium circulation pump PP1;
A heat storage tank 30 in which hot water generated by heat exchange with the heat medium in the heat exchanger 20 is transferred and stored through the water circulation pipe P2 by the operation of the water circulation pump PP2;
The gas burner 42 is operated when the hot water supplied through the hot water circulation pipe P3 is operated as the energy source by the operation of the hot water supply pump PP3 from the heat storage tank 30, and is operated when the solar radiation is insufficient. Is equipped with a hybrid absorption chiller 40;
In order to remove the cooling heat generated during the process of generating cold water from the hybrid absorption chiller 40, a part of the geothermal pipe (P5) buried in the ground is inserted into the hybrid absorption chiller 40, geothermal circulation Geothermal heat storage means (50) for transmitting geothermal heat to the hybrid absorption chiller and hot water (40) by the operation of the pump (PP5); And
Cooling the air by receiving the cold water generated in the hybrid absorption cold water heater 40 through the air conditioning pipe (P4) during cooling, and the hot water supplied from the heat storage tank (30) connected to the hot water circulation pipe (P3) 2 is supplied through the connection pipe (P7) to warm the air, the heat-exchanged water is supplied to the hybrid absorption cold water heater (40) through the air conditioning pipe (P4) circulated, or flows along the air conditioning pipe (P4) And an air conditioner (60) flowing along the first connection pipe (P6) connected to the hot water circulation pipe (P3) and flowing into the heat storage tank (30).
A first three-way control valve (V1) connected to the hot water circulation pipe (P3) and the second connection pipe (P7) to control a flow direction of the fluid; and the hot water circulation pipe (P3) and the first connection pipe ( And a second three-way control valve (V2) connected to P6) to control the flow direction of the fluid.
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