KR101109505B1 - The remove ice instrument for a heating system - Google Patents

Abstract

The present invention relates to a defrosting structure of an outdoor unit of a heating device. When the temperature is low in winter and the humidity is high during heating, the ice containing the frost on the outdoor evaporator does not freeze smoothly and the heat efficiency decreases or the heating operation is performed for a defrosting operation. It was developed to solve the problem of defrost by stopping and switching cycle to cooling operation;

An outdoor unit defrost structure of a heating cycle for removing ice including frost generated in an outdoor evaporator using a portion of a refrigerant circulating from a heating system to an indoor condenser;

The first heat exchanger, which serves as an outdoor evaporator during heating, is provided with two first hats formed parallel to each other at a predetermined interval, a plurality of heating pipes interconnecting the first and second hats, and mounted outside the heating pipes. A plurality of heat dissipation fins;

A plurality of second hats which are formed to be parallel to the outside of the two first hats and are formed to be parallel to each other, and the second hats are connected to each other so as to be inserted into the center of the heating pipe through the first hats. A third heat exchanger comprising a defrost pipe;

The heating cycle is located outdoors, and the refrigerant discharged from the first heat exchanger having a first blower fan serving as an evaporator passes through an eighth valve, passes through a first valve, and passes through an accumulator and a compressor. 2 is provided with a blowing fan and a second heat exchanger which serves as a condenser, wherein the refrigerant passes through a ninth valve sequentially through a first check valve, a second valve, and a first expansion valve. Drawn into the first heat exchanger;

In the defrost cycle, the high temperature and high pressure refrigerant discharged from the compressor is branched with a heating cycle going to the second heat exchanger through a third valve that is additionally formed by the first branch, so that a part of the refrigerant passes through the auto control valve to the third heat exchanger. Refrigerant, which is condensed and condensed while defrosting in the third heat exchanger, is heat-exchanged in the second heat exchanger of the heating cycle at the eleventh branch of the ninth valve in front of the ninth valve via the tenth valve and the third expansion valve. The first check valve, the second valve and the refrigerant passing through the first expansion valve is connected to the outdoor unit defrost structure of the heating cycle, characterized in that configured to flow into the first heat exchanger through the ninth valve.

Heating, sex

Description

The outdoor unit defrost structure of the heating device {The remove ice instrument for a heating system}

The present invention relates to an outdoor unit defrosting structure of a heating device. More specifically, when the winter temperature is low and the outside air humidity is high in the process of discharging cold heat from the outdoor evaporator during heating, the outdoor evaporator may generate sexual intercourse or other climatic factors. It is related to the outdoor unit defrost structure of the heating device developed to solve the problem that the ice is hindered in the smooth discharge of cold heat when the ice is frozen.

The heating device uses a heat generated in the process of condensing the refrigerant in the heat exchanger, that is, the condenser, as a heating, and discharges cold heat by circulating the condensed liquefied refrigerant in the outdoor heat exchanger, that is, the evaporator.

The refrigerant used in such a heating device generally uses a material having a lower freezing point than general water, and thus, when the refrigerant evaporates in the evaporator, the temperature is often less than 0 degrees.

At this time, the moisture in the surrounding air condenses, which may cause defrost on the evaporator, that is, the outdoor unit, or other climatic factors, causing the ice to freeze. In this case, the ice blocks and insulates the surrounding air from the surrounding air. In this case, the low pressure is lowered because the heat exchange is not performed, and the heating device is not operated smoothly.

In order to prevent this, conventionally, the cooling system circulating the heating system in reverse direction, that is, the outdoor evaporator acts as a condenser so that the high temperature and high pressure refrigerant discharged from the compressor is heated by the condensation heat to remove the defrost and then operate the heating system again or separately. This problem is solved by a method of installing an electric heater in an outdoor unit by connecting a power source of the outdoor unit. However, this consumes a large amount of energy and does not allow continuous heating when the cooling system is operated when necessary.

The present invention was developed to solve the above problems, and an object of the present invention is to provide a system that can easily remove the ice, including the ice generated in the outdoor unit without the supply of additional energy.

The present invention was developed in order to achieve the above object, in the outdoor unit defrost structure of the heating cycle to remove the ice including the frost generated in the outdoor evaporator by using a portion of the refrigerant circulated to the indoor condenser in the heating system;

The first heat exchanger, which serves as an outdoor evaporator during heating, is provided with two first hats formed parallel to each other at a predetermined interval, a plurality of heating pipes interconnecting the first and second hats, and mounted outside the heating pipes. A plurality of heat dissipation fins;

A plurality of second hats which are formed to be parallel to the outside of the two first hats and are formed to be parallel to each other, and the second hats are connected to each other so as to be inserted into the center of the heating pipe through the first hats. A third heat exchanger comprising a defrost pipe;
The heating cycle is located outdoors, and the refrigerant discharged from the first heat exchanger having a first blower fan serving as an evaporator passes through an eighth valve, passes through a first valve, and passes through an accumulator and a compressor. 2 is provided with a blowing fan and a second heat exchanger which serves as a condenser, wherein the refrigerant passes through a ninth valve sequentially through a first check valve, a second valve, and a first expansion valve. Drawn into the first heat exchanger;
In the defrost cycle, the high temperature and high pressure refrigerant discharged from the compressor is branched with the heating cycle going to the second heat exchanger through a third valve which is additionally formed by the first branch, so that a part of the refrigerant passes through the auto control valve. Refrigerant, which is condensed and condensed while defrosting in the third heat exchanger, is heat-exchanged in the second heat exchanger of the heating cycle at the eleventh branch of the ninth valve in front of the ninth valve via the tenth valve and the third expansion valve. The first check valve and the second valve and the refrigerant passing through the first expansion valve is characterized in that it is configured to flow into the first heat exchanger through the ninth valve.

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In addition, the heating cycle is circulated in the reverse direction, the refrigerant of the high temperature and high pressure generated from the compressor in the first heat exchanger provided outdoors through the seventh valve and the eleventh valve condensed in the first heat exchanger 12 through the valve branched by a third branch formed immediately before the first expansion valve through a third check valve through the fourth branch, the fifth branch, the fifth valve through the second expansion valve Low temperature low pressure refrigerant gas is introduced into a second heat exchanger serving as the evaporator;

The low-temperature low-pressure refrigerant evaporated in the second heat exchanger passes through the sixth valve via a seventh branch formed between the third valve and the second heat exchanger, and is formed between the first valve and the accumulator. The compressor flows into the compressor through an eighth branch and an accumulator, and the refrigerant gas of high temperature and high pressure passes through the ninth branch formed between the first branch and the seventh valve, the first valve, and the first heat exchanger. Between the tenth branch formed between the, the eleventh valve is passed through the first heat exchanger characterized in that the cooling cycle is further formed.

As described above, the present invention uses a part of the refrigerant circulated when the heating device is operated while heating the outdoor unit to remove the frost by heating the outdoor unit with a high temperature and high pressure refrigerant to increase the energy efficiency and the continuous heating device. It is possible to drive.

Accordingly, the configuration of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce.

1 is a perspective view according to an embodiment of the present invention, Figure 2 is a front view according to an embodiment of the present invention, the ice containing the frost generated in the outdoor evaporator using a portion of the refrigerant circulating to the indoor condenser in the heating system In the outdoor unit defrost structure of the heating cycle to remove the;

The first heat exchanger 1, which serves as an outdoor evaporator during heating, includes two first hats 11 formed parallel to each other at regular intervals and a plurality of heating pipes interconnecting the first hats 11 on both sides. (12) and a plurality of heat dissipation fins 13 mounted on the outside of the heating pipe 12;

Two second hats 21 are formed to be parallel to the outside of the two first hats 11 slightly and the second hats 21 on both sides of the first hats 11 to penetrate the first hats 11. Characterized in that it is configured to remove the ice and ice of the first heat exchanger (1) by a third heat exchanger (2) consisting of a plurality of defrost pipes 22 connected to be inserted into the center of the heating pipe (12). The outdoor unit defrost structure of the heating cycle is shown.

The feature of the structure is that the heating pipe 12 and the defrost pipe 22 is coupled in the form of a double pipe.

That is, when the refrigerant evaporates in the first heat exchanger 1 serving as an outdoor evaporator, the pressure drops, and when the outdoor air temperature is low and the humidity is high in winter, condensation water condenses in the outdoor unit, and defrost occurs. The lower the humidity of the outside air condensation occurs as a sexual love.

By sending a part of the high temperature and high pressure refrigerant generated in the compressor to the third heat exchanger to reduce the low pressure in the first heat exchanger (1) that is the outdoor unit by using the condensation heat radiation of the third heat exchanger as the cooling load of the evaporation heat in the first heat exchanger. It is a cycle structure that can prevent the occurrence of frost and suppress the occurrence of frost and form a heating cycle indoors, a defrost cycle outdoors, and continuously heating the indoor condenser.

By this action, the present application does not need to stop the operation and remove the process when sexuality occurs, it is possible to continue heating and reduce the energy consumption compared to the method using an electric heater.

3 is a conceptual diagram showing the structure of a system according to an embodiment of the present invention, will be described according to each operation example to perform heating and cooling, and heating and defrosting at the same time.

First, FIG. 4 is a conceptual view showing a heating circulation structure according to an embodiment of the present invention, wherein the heating cycle is located outdoors and has the first heat exchanger 1 having a first blowing fan 14 serving as an evaporator. The refrigerant discharged from the high temperature and high pressure refrigerant passes through the eighth valve 38 through the first valve 31 through the accumulator 4 and the compressor 5 and passes through the third valve 33. The refrigerant having a second blowing fan 61 and drawn into the second heat exchanger 6 serving as a condenser, and the refrigerant condensed in the second heat exchanger 6 may be the first check valve 71 and the second. Passing through the valve 32, the first expansion valve 81 in order to pass through the ninth valve 39 to the first heat exchanger (1).

At this time, other valves not mentioned in the heating cycle of the present application (10. 35. 36. 37. 39a. 39b. 39c) is preferably kept closed so that the refrigerant circulates only in the flow of the heating cycle of the present application.

At this time, the accumulator 4 serves as a normal liquid separator.

This heating cycle is said to be almost the same principle as a conventional heating device, except for the valves added for the defrosting function described later herein.

5 is a conceptual diagram showing a heating and defrost removal circulation structure according to an embodiment of the present invention, the defrost cycle when the heating and defrost removal at the same time is the high-temperature high-pressure refrigerant discharged from the compressor (5) the first branch The third heat exchanger (2) is branched from the heating cycle to the second heat exchanger (6) via the third valve 33, which is further formed by (91), the third heat exchanger (2) via the auto control valve (10) The refrigerant introduced into the third heat exchanger (2) and decondensed in the third heat exchanger (2) passes through the tenth valve (39a) and the third expansion valve (83) to the eleventh branch portion (front end) of the ninth valve (39). Heat exchange in the second heat exchanger 6 of the heating cycle in 101 and joined with the refrigerant passing through the first check valve 71 and the second valve 32 and the first expansion valve 81 to the ninth valve (39). It is characterized in that it is configured to be introduced into the first heat exchanger (1) through.

Defrosting in the present application is a part of the refrigerant supplied to supply heat to the condensation, ie the room is passed through the auto control valve 10 to the third heat exchanger (2) so that the temperature of the first heat exchanger (1) is excessive It is lowered to prevent sexuality from happening.

At this time, the auto control valve 10 is a waste of energy to supply heat to the first heat exchanger (1) in the state that the defrost does not occur, so the appropriate amount of refrigerant is additionally manipulated only when necessary by detecting the degree of defrost. It is to be supplied without.

The auto control valve 10 may be equipped with a sensor for sensing a temperature in the first heat exchanger 1, which serves as an outdoor evaporator, and an air differential pressure valve may be installed so that the first heat exchanger 1 may be loaded. As long as the auto control valve 10 is proportional to the system used.

At this time, the valve closed in the defrost cycle is a valve (35. 36. 37. 39b. 39c).

6 is a conceptual view showing a cooling circulation structure according to an embodiment of the present invention, in the case of the cooling cycle as a whole the refrigerant to reverse circulation so that the condenser during heating the evaporator to function as a condenser to the outdoor Is to exhaust heat.

Its structure includes a structure for effectively connecting with the above-described heating system and defrosting system and the structure is such that the heating cycle is circulated in the reverse direction, the heating cycle is circulated in the reverse direction, the first provided in the outdoor In the heat exchanger 1, the high temperature and high pressure refrigerant generated from the compressor 5 passes through the seventh valve 37, the tenth branch 100, and the eleventh valve 39b to condense in the first heat exchanger 1. And the fourth branch 94 through the third check valve 73 is liquefied and branched by the third branch 93 formed immediately before the first expansion valve 81 after passing through the twelfth valve 39c. The low temperature low pressure refrigerant gas throttled in the second expansion valve 82 via the fifth branch 95 and the fifth valve 35 is introduced into the second heat exchanger 6 serving as the evaporator;

The low temperature low pressure refrigerant evaporated in the second heat exchanger 6 passes through the seventh branch part 97 formed between the third valve 33 and the second heat exchanger 6 to form a sixth valve 36. ), And flows into the compressor (5) via the eighth branch 98 and the accumulator (4) formed between the first valve (31) and the accumulator (4), the compressor ( In 5), the high-temperature, high-pressure refrigerant gas passes through the ninth branch portion 99 formed between the first branch portions 91 to form the seventh valve 37, the first valve 31, and the first heat exchanger. A cooling cycle introduced into the first heat exchanger 1 through the tenth branch part 100 and the eleventh valve 39b formed between 1) is further formed.

At this time, all the valves 10. 31. 32. 33. 38. 39. 39a formed in a path other than the path shown in the drawing are closed.

1 is a perspective view according to an embodiment of the present invention

2 is a front view according to an embodiment of the present invention;

3 is a conceptual diagram showing the structure of a system according to an embodiment of the present invention;

4 is a conceptual diagram showing a heating circulation structure according to an embodiment of the present invention

5 is a conceptual diagram showing a heating and defrosting circulation structure according to an embodiment of the present invention

6 is a conceptual diagram showing a cooling circulation structure according to an embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

1: first heat exchanger

     11: 1st sun 12: heating piping

     13: heat dissipation fin 14: first blowing fan

2: third heat exchanger

     21: the second saw 22: defrost piping

     31: first valve 32: second valve

     33: third valve 34: fourth valve

     35: fifth valve 36: sixth valve

     37: seventh valve 38: eighth valve

     39: ninth valve 39a: tenth valve

     39b: 11th valve 39c: 12th valve

4: accumulator

5: compressor

6: second heat exchanger

     61: second blowing fan

     71: first check valve 72: second check valve

     73: third check valve

     81: first expansion valve 82: second expansion valve

     83: third expansion valve

     91: first branch portion 92: second branch portion

     93: third branch part 94: fourth branch part

     95: fifth branch 96: sixth branch

     97: seventh branch 98: eighth branch

     99: ninth branch 100: tenth branch

     101: the eleventh branch

10: Auto control valve

Claims (3)

delete An outdoor unit defrost structure of a heating cycle for removing ice including frost generated in an outdoor evaporator using a portion of a refrigerant circulating from a heating system to an indoor condenser; The first heat exchanger 1, which serves as an outdoor evaporator during heating, includes two first hats 11 formed parallel to each other at regular intervals and a plurality of heating pipes interconnecting the first hats 11 on both sides. (12) and a plurality of heat dissipation fins 13 mounted on the outside of the heating pipe 12; Two second hats 21 are formed to be parallel to the outside of the two first hats 11 slightly and the second hats 21 on both sides of the first hats 11 to penetrate the first hats 11. A third heat exchanger (2) comprising a plurality of defrost pipes (22) connected to be inserted into a center of the heating pipe (12); The heating cycle is located outdoors, and the refrigerant discharged from the first heat exchanger 1 having the first blower fan 14 serving as an evaporator passes through the eighth valve 38 and passes through the first valve 31. Via an accumulator (4) and a compressor (5), and having a second blower fan (61) located indoors and introduced into a second heat exchanger (6) serving as a condenser, said second heat exchanger (6) In the refrigerant flow through the first check valve 71, the second valve 32, the first expansion valve 81 in order to pass through the ninth valve 39 to the first heat exchanger (1) Done; In the defrost cycle, the high temperature and high pressure refrigerant discharged from the compressor 5 is branched from the heating cycle to the second heat exchanger 6 via the third valve 33 which is further formed by the first branch 91. Part of the refrigerant is introduced into the third heat exchanger (2) via the auto control valve (10), and the third heat exchanger (2) decondenses the refrigerant while defrosting the tenth valve (39a) and the third. Heat exchange in the second heat exchanger 6 of the heating cycle at the eleventh branch 101 in front of the ninth valve 39 via the expansion valve 83 and the first check valve 71 and the second valve 32 And the refrigerant passing through the first expansion valve (81) and introduced into the first heat exchanger (1) through the ninth valve (39). 3. The high temperature and high pressure refrigerant generated from the compressor (5) in the first heat exchanger (1) provided outdoors is configured to allow the heating cycle to circulate in the reverse direction so that the seventh valve (37) and the tenth branch portion (3). The third branch 93 formed through the eleventh valve 39b and condensed in the first heat exchanger 1 to pass through the twelfth valve 39c and immediately before the first expansion valve 81. The low temperature branched by the second expansion valve 82 through the third branch valve 94, the fifth branch portion 95, and the fifth valve 35 through the third check valve 73; Low-pressure refrigerant gas is introduced into a second heat exchanger (6) serving as the evaporator; The low temperature low pressure refrigerant evaporated in the second heat exchanger 6 passes through the seventh branch part 97 formed between the third valve 33 and the second heat exchanger 6 to form a sixth valve 36. ), And flows into the compressor (5) via the eighth branch 98 and the accumulator (4) formed between the first valve (31) and the accumulator (4), the compressor ( In 5), the high-temperature, high-pressure refrigerant gas passes through the ninth branch portion 99 formed between the first branch portions 91 to form the seventh valve 37, the first valve 31, and the first heat exchanger. The air conditioner defrost structure of the heating cycle of the heating cycle, characterized in that the cooling cycle to be introduced into the first heat exchanger (1) through the tenth branch (100), the eleventh valve (39b) formed between the 1).

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