KR100224592B1 - Outdoor side heat exchanger - Google Patents

Abstract

The present invention relates to a multi air conditioner (Multi Air Conditioner), in the outdoor heat exchanger of the multi-air conditioner for cooling and heating mixed respectively connected to the indoor heat exchanger in the room A, B rooms, the refrigerant flow path of each room And divided into the lower part and configured to circulate the upper and lower parts of the refrigerant in each chamber, thereby eliminating the performance imbalance between the two chambers during the cooling or heating operation of the two chambers, and the outdoor heat exchanger during the mixed operation of the two cooling chambers. By eliminating the heat exchange effect due to each refrigerant passage of the two chambers, the two chambers are each capable of mixing operation of cooling and heating.

Description

Heat Exchanger on the Outdoor Side of a Multi-Air Conditioner

The present invention relates to an outdoor heat exchanger of a multi air conditioner, and more particularly, to prevent unbalanced performance between rooms in a two-room operation, and to allow a mixed operation of cooling and heating operations in each room. An outdoor unit heat exchanger of a multi air conditioner.

In general, air conditioning means to maintain indoor air at optimal conditions according to the purpose of the room, and the air temperature, humidity, flow, and purification are the four major factors. The air conditioner is a device that processes intake air and supplies it to the room in order to keep indoor air in a comfortable condition for the four elements. A general home air conditioner that makes a home's room comfortable is a room air conditioner. It is called.

The air conditioner as described above is known in various forms depending on the function, the configuration of the unit, the cooling capacity of the condenser and the rating of the power supply, etc., in order to further improve the performance of the air conditioner, the air conditioner having two or more indoor units, Multi Airconditioner), a typical embodiment of which will be described below with reference to the accompanying drawings.

1 is a refrigerant circuit diagram for explaining a refrigerant flow of a general multi-air conditioner, it can be seen that the cooling and cooling combined use due to the flow characteristics of the refrigerant.

In more detail, the outdoor unit 10 and the two indoor units A and B rooms 30 and 40 are structured. The outdoor unit 10 includes a first compressor 11 and a first compressor. A compressor 12, an outdoor side heat exchanger (also referred to as a 'condensor' and, in some cases, an evaporator) 13, a first heating capillary tube 14, First Cooling Capillary Tube Capillary Tube 15 and Second Heating Capillary Tube 16, 2-B Cooling Capillary Tube 17, First Check Valve 18 and Second Check to Prevent Backflow of Refrigerant The valve 19, the outdoor blower fan 20, the 1st 4-way valve 21 and the 2nd 4-way valve 22 which change the flow path of a refrigerant | coolant are included.

The indoor unit A and B rooms 30 and 40 are independent first indoor side heat exchangers (also referred to as 'evaporators' and, in some cases, also serve as condensers) 31 and second indoor side heat exchangers. 41 and the 1st indoor blowing fan 32 are included, respectively.

The first and second compressors 11 and 12 are connected to the outdoor heat exchanger 13 and the refrigerant lines L11 and L21, and the outdoor heat exchanger 13 and the first and second indoor heat exchanger. Groups 31 and 41 are connected to refrigerant lines L12 and L22, and the first and second indoor side heat exchangers 31 and 41 and the first and second compressors 11 and 12 are refrigerants. It is connected by lines L13 and L23.

The refrigerant lines L12 and L22 are provided with a first heating capillary tube 14 and a first cooling capillary tube 15, a second heating capillary tube 16, and a second cooling capillary tube 17, respectively. The 1st heating capillary 14 and the 2nd heating capillary 16 are comprised so that it may be controlled by the 1st check valve 18 and the 2nd check valve 19, respectively.

The first four-way valve 21 and the second four-way valve 22 are provided at portions where the refrigerant lines L11, L21, and the refrigerant lines L13, L23 meet.

The pass-line of the outdoor heat exchanger 13 will be described in detail. As shown in FIG. 2, one side (upper side in the drawing) and the middle side of the outdoor heat exchanger 13 are up-in. Refrigerant lines L21 and L22 constituting a pass of UP IN and LOW IN and forming a path of TOTAL OUT are connected to the other side (the lower side in the drawing).

In addition, the outdoor heat exchanger 13 is divided into three stages of the upper part 13a, the middle part 13b, and the lower part 13c, and the refrigerant flowed into the upper part 13a and the middle part 13b in each chamber. Is again configured to recondense at the lower portion 13c.

The heat exchange method of each chamber employs an independent refrigerant distribution system that constitutes a refrigerant passage of right and left crossings.

The arrows in the solid lines in FIG. 1 show the refrigerant flow during cooling, and the arrows in the dashed lines show the refrigerant flow during heating.

In the drawings, reference numerals 51, 52, 53, and 54 show packed valves.

The multi-air conditioner as described above may be divided into a cooling operation and a heating operation. First, in the case of the cooling operation, the refrigerant moves in the same path as a conventional multi-air conditioner dedicated to cooling.

That is, the coolant discharged from the first and second compressors 11 and 12 of the outdoor unit 10 in the state of high temperature and high pressure is the first four-way valve 21 and the second four-way valve as shown by the solid arrows. After passing through the 22 and moving along the refrigerant lines L11 and L21 to pass through the outdoor heat exchanger 13, the refrigerant passing through the inside of the outdoor heat exchanger 13 is transferred to the outdoor blower fan 20. Condensation at room temperature and high pressure by heat exchange with air.

As such, the condensed refrigerant having passed through the outdoor heat exchanger 13 moves along the refrigerant lines L12 and L22 and passes through the first and second check valves 18 and 19 to the first cooling capillary tube 15 and While passing through the second cooling capillary tube 17, the refrigerant is converted into a low temperature and low pressure refrigerant.

Thereafter, the air blown by the first and second indoor blowing fans 32 and 42 while passing through the first and second indoor side heat exchangers 31 and 41 in the indoor units A and B chambers 30 and 40. Through the process of heat exchange with the refrigerant evaporates the ambient heat is taken away to lower the air temperature in the room, the low-temperature, low-pressure refrigerant passing through the first and second indoor heat exchangers (31, 41) is a refrigerant The lines L13 and L23 are sucked into the first and second compressors 11 and 12 to be repeatedly compressed to high temperature and high pressure.

In the independent refrigerant distribution system as described above, each capillary tube is required to lower each indoor air.

On the other hand, in the case of heating operation, the flow of the refrigerant is reversed from the case of cooling, and the room is heated by the action of the heat pump. In this case, it should be noted that the concept of the outdoor unit and the indoor unit is changed.

That is, as shown by the dotted line in Fig. 1, the high-temperature, high-pressure refrigerant discharged from the first and second compressors 51 and 52 is the first four-way valve 21 and the second four-way valve 22 While passing through the indoor heat exchanger (condenser) 31, 41 to supply hot air to the room, the refrigerant passing through the indoor heat exchanger (31) (41) and the first cooling capillary (15) and After passing through the first heating capillary tube 14, the second cooling capillary tube 17, and the second heating capillary tube 16, evaporate in the outdoor heat exchanger (evaporator) 13, and then again the first 4 The process of flowing into the first and second compressors 51 and 52 through the way valve 21 and the second four-way valve 22 is repeated.

However, in the outdoor side heat exchanger of the general multi-air conditioner as described above, each chamber has a refrigerant passage of right and left crossings, and the performance decrease in two-room operation compared to one-room operation always follows. There was a disadvantage that the performance imbalance of the liver occurs.

In addition, since the heat exchange effect between the chambers is large because the refrigerant flow paths of the left and right crosses are large, when the indoor unit A chamber 30 is cooled and the indoor unit B chamber 40 performs the mixed operation of heating operation, the outdoor unit heat exchanger 13 A The heat of condensation on the measurement side causes the evaporation temperature of the room B side to be excessively high, resulting in the increase of both cycle temperatures on the B side. Therefore, by mixing both low and high pressures excessively, the mixed operation of each chamber is impossible. there was.

The main object of the present invention is to provide an outdoor side heat exchanger of a multi-air conditioner so as to prevent the performance imbalance between the two chambers during operation.

Another object of the present invention is to provide an outdoor unit heat exchanger of a multi-air conditioner to enable a mixed operation of cooling operation and heating operation of each chamber.

1 is a refrigerant circuit diagram of a general multi-air conditioner.

2 is a configuration diagram for explaining an example of an outdoor side heat exchanger applied to a general multi-air conditioner.

Figure 3 is a refrigerant circuit diagram of a multi-air conditioner with an outdoor side heat exchanger of the present invention.

Figure 4 is a block diagram for explaining an embodiment of an outdoor side heat exchanger according to the present invention.

Explanation of symbols for the main parts of the drawings

60; Outdoor units 61,62; 1st, 2nd compressor

63; Outdoor side heat exchangers 63a and 63b; Top, bottom

64; Outdoor blower fan 65,69; 1st, 2nd heating capillary

66,70; First and second cooling capillaries 67,71; Fact valve

68,72; First and second check valves 73,74; 1, 2 4-way valve

80,90; Indoor units A and B rooms 81,91; First and second indoor side heat exchanger

In order to achieve the above object of the present invention, in the outdoor side heat exchanger of the multi-air conditioner for cooling and heating mixed respectively connected to the indoor side heat exchanger of the indoor units A and B rooms, the refrigerant flow path of each chamber is divided into upper and lower portions. Thus, the outdoor heat exchanger of the multi-air conditioner is provided so as to circulate the upper and lower portions of the refrigerant in each chamber, respectively.

It is comprised so that it may have one place of refrigerant | coolant flow path intersections in the middle of upper part and lower part of the said outdoor side heat exchanger, respectively.

Hereinafter, the outdoor heat exchanger of the multi-air conditioner according to the present invention will be described according to the embodiment shown in the accompanying drawings.

3 is a refrigerant circuit diagram of a multi-air conditioner with an outdoor side heat exchanger of the present invention, and FIG. 4 is a block diagram for explaining an embodiment of an outdoor side heat exchanger according to the present invention.

As shown in the drawing, the multi-air conditioner according to the present invention comprises an outdoor unit 60 and indoor units A and B rooms 80 and 90.

The indoor units A and B chambers 80 and 90 each include a first indoor side heat exchanger 81 and a second indoor side heat exchanger 91.

Meanwhile, the outdoor unit 60 includes two first and second compressors 61 and 62, one outdoor side heat exchanger 63, and an outdoor blower fan 64, and the first compressor 61. ) Is for the indoor unit A chamber 80, and the second compressor 62 is for the indoor unit B chamber 90.

In more detail, the first and second compressors 61 and 62 and the outdoor side heat exchanger 63 are connected to the refrigerant lines L31 and L41 and are connected to the outdoor side heat exchanger 63. The first and second indoor side heat exchangers 81 and 91 are connected to the refrigerant lines L32 and L42.

The refrigerant line L32 is provided with a first heating capillary tube 65, a first cooling capillary tube 66, and a fact valve 67, and the first heating capillary tube 65 is connected to the first check valve 68. And a second heating capillary tube 69, a second cooling capillary tube 70, and a fact valve 71 are provided in the refrigerant line L42, and the second heating capillary tube 69 is formed of a second heating capillary tube 69. It is comprised so that it may be controlled by the 2 check valve 72.

The first and second indoor side heat exchangers 81 and 91 and the first and second compressors 61 and 62 are connected to refrigerant lines L33 and L43, and the refrigerant lines L33 and L43. And a first four-way valve 73 and a second four-way valve 74 are provided at portions where the refrigerant lines L31 and L41 meet.

In addition, referring to the configuration of the outdoor side heat exchanger 63, as shown in FIG. 4, the outdoor side heat exchanger 63 is divided into an upper portion 63a and a lower portion 63b, and the indoor units A and B rooms. Refrigerant flow paths of the 30 and 40 are set in the upper part 63a and the lower part 63b, respectively, and have one intersecting part in the upper part 63a and the lower part 63b, respectively.

As an embodiment of the present invention, a case of the two-stage 30-row outdoor side heat exchanger 63 will be described. A pass line for cooling and heating the indoor unit A chamber 30 has a refrigerant at both left and right sides of the upper portion 63a. It is introduced and passes through three hair pins (H1) and crosses, and after crossing, passes through three hair pins (H1), and then gathers again and is discharged to the refrigerant line (L32), the indoor unit B The pass line for cooling and heating the chamber 40 also has the same refrigerant distribution system as the upper portion 63a.

That is, the refrigerant flows from two left and right sides of the lower portion 63b, passes through the three hair pins H2, and crosses. After crossing, the refrigerant passes through the three hair pins H2. Discharged to line L42.

Therefore, in the outdoor side heat exchanger 63 according to the present invention, the refrigerant passages of the indoor units A and B chambers 30 and 40 are divided into the upper part 63a and the lower part 63b to be used for two-room cooling or heating operation. In this case, the performance imbalance between the rooms can be eliminated, and there is no heat exchange effect due to each refrigerant path of the outdoor heat exchanger 63 during the two-room air-conditioning mixed operation, so that the two rooms perform different operations. .

In the drawings, reference numerals 101, 102, 103 and 104 show fact valves, respectively.

The multi-air conditioner according to the present invention constituted as described above can be divided into the case of the cooling operation and the case of the heating operation, and the case of the cooling operation will be described first.

In the cooling operation, since the first four-way valves 73 and 74 are in an OFF state, the first four-way valves 73 and 74 are discharged at high temperature and high pressure from the first and second compressors 61 as shown by solid arrows in FIG. 3. The refrigerant moves along the refrigerant lines L31 and L41 and flows into the outdoor side heat exchanger (condenser) 63 to condense at room temperature and high pressure by heat exchange with air by the outdoor blower fan 64. .

At this time, since the indoor units A and B chambers 30 and 40 are divided into upper and lower portions 63a and 63b, performance imbalance between the chambers is prevented and the upper and lower portions of the upper and lower portions 63a and 63b are separated. The refrigerant flows along the independent refrigerant passages, respectively.

The condensed refrigerant circulated inside the outdoor heat exchanger 63 and discharged to the refrigerant lines L32 and L42 may include first and second check valves 68 and 69 and first and second cooling capillaries 66 ( Condensed at room temperature and high pressure while passing through 70).

Thereafter, while passing through the first and second indoor side heat exchangers 81 and 91 in the indoor units A and B chambers 80 and 90, the refrigerant is evaporated by a heat exchange action with air to take away the surrounding heat. The air temperature of the indoor units A and B chambers 80 and 90 is lowered, and the low temperature and low pressure refrigerant passing through the first and second indoor side heat exchangers (evaporators) 81 and 91 is a refrigerant line L33. After passing through the L43 and passing through the first and second four-way valves 73 and 74, the first and second compressors 61 and 62 are sucked into the first and second four-way valves 73 and 74, and are compressed to high temperature and high pressure again.

On the other hand, during the heating operation, the high-temperature, high-pressure refrigerant gas compressed by the first and second compressors 61 and 62 is supplied to the indoor unit A, by the refrigerant flow path switching function of the first and second four-way valves 73 and 74. It is introduced into the B room 80, 90 to move the cold air of the indoor side to the outdoor side to increase the indoor temperature.

Thereafter, the refrigerant passing through the indoor side heat exchanger (condenser) 81 and 91 passes through the first cooling capillary tube 66 and the first heating capillary tube 65, and at the same time, the second cooling capillary tube 70 and 2, passing through the heating capillary 69, evaporating in the outdoor side heat exchanger (evaporator) 63, and then again through the first and second four-way valves 73 and 74, the first and second compressors 61 Repeat the flow into (62).

In addition, as in the case of the two-room air-conditioning mixed operation, similarly to the case of cooling and heating, the heat exchange effect due to the refrigerant flow path can be excluded, and the moving path of the refrigerant has been described in the case of the cooling and heating operation, and thus the detailed description thereof will be omitted. Shall be.

As described above, the outdoor heat exchanger of the multi-air conditioner according to the present invention divides the refrigerant flow path of each chamber into an upper portion and a lower portion, and configures the refrigerant in each chamber to circulate the upper and lower portions, respectively. Alternatively, the two chambers can be used in different mixed operation by eliminating the performance imbalance between the two chambers during the heating operation and by eliminating the heat exchange effect due to the refrigerant flow path of the outdoor heat exchanger during the two-room air-conditioning mixed operation. It works.

Claims (2)

In the outdoor heat exchanger of the cooling and heating multi-air conditioner combined with the indoor heat exchanger of the indoor unit A, B rooms, An outdoor side heat exchanger of a multi-air conditioner, wherein a refrigerant flow path of each chamber is divided into upper and lower portions, and the refrigerant of each chamber is circulated through the upper and lower portions, respectively. The outdoor side heat exchanger of the multi-air conditioner according to claim 1, wherein the outdoor side heat exchanger is configured to have one coolant flow path intersecting portion between the upper and lower portions of the outdoor side heat exchanger.

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