KR100598216B1 - The pipe arrangement structure of air conditioner outdoor unit - Google Patents

Abstract

The present invention relates to a pipe arrangement structure of an outdoor unit of an air conditioner, and relates to an arrangement angle between a suction pipe, a counterflow heat exchanger, and an electronic expansion valve of a compressor for vibration reduction and compact pipe structure of a compressor.

The piping arrangement structure of the air conditioner outdoor unit according to the present invention includes a suction pipe of the compressor, a counter-flow heat exchanger having one end connected to the suction pipe, and an electronic expansion valve pipe parallel to the counter-flow heat exchanger. In order to reduce the vibration of the suction pipe during start-up, the angle between the suction pipe and the electromagnetic expansion valve pipe portion is disposed within the range of 90 degrees with the counterflow heat exchanger as a point.

Air conditioner, outdoor unit, compressor, suction pipe, counterflow heat exchanger, LEV

Description

Pipe arrangement structure of air conditioner outdoor unit

1 is a cycle diagram showing a cooling process of the conventional air conditioner.

2 is a cycle diagram showing a heating process of the conventional air conditioner.

Figure 3 is a perspective view showing a piping arrangement structure of the outdoor air conditioner according to the embodiment of the present invention.

4 is a plan view of the present invention Figure 3;

5 is a schematic configuration diagram of a counterflow heat exchanger employed in the present invention.

Figure 6 is a graph showing the outdoor unit compact rate for the arrangement angle of the electromagnetic expansion valve, dryer, counter flow heat exchanger, compressor suction pipe of the mechanical components of the outdoor unit according to the present invention.

Explanation of symbols on the main parts of the drawings

110 Compressor 115 Expansion valve

120 ... dryer 130 ... counterflow heat exchanger.

132 ... suction line

The present invention relates to an air conditioner, and more particularly, in order to achieve an optimum arrangement angle of the counterflow heat exchanger between the suction side of the compressor and the electromagnetic expansion valve (LEV) and the dryer piping for high efficiency of the air conditioner. It relates to the piping arrangement of an air conditioner outdoor unit.

In general, an air conditioner is a device that lowers indoor temperature by discharging cold air generated through a process of compressing, condensing, expanding, and evaporating a refrigerant into an interior, and is classified into an outdoor unit installed in an outdoor side and an indoor unit installed in an indoor side. The outdoor unit includes a compressor 10 and four sides 20, an outdoor heat exchanger 22, an outdoor fan 24, and an expansion valve 26. The indoor unit includes an indoor heat exchanger 28 and an indoor fan ( 30).

In addition, in the case of the air conditioner, a plurality of indoor units may be configured in a multi-shape to be used to cool or heat a plurality of indoor spaces.

Looking at the cooling process of the air conditioner configured as described above, as shown in Figure 1, the low-temperature low-pressure gas phase refrigerant introduced into the compressor 10 from the indoor heat exchanger 28 is a high temperature and high pressure through the pressure action of the compressor (10). At the same time as being pressurized to a gaseous state of the, and is discharged to the outdoor heat exchanger 22 through the four sides 20 switched to achieve a cooling cycle, the refrigerant discharged to the outdoor heat exchanger 22 is the outdoor heat exchanger ( 22) while performing the internal exchange of heat with the outside air sucked into the outdoor unit through the driving of the outdoor fan 24, the phase changes to a liquid state of room temperature and high pressure.

The refrigerant changed in phase as described above is discharged to the expansion valve 26 and decompressed to a low-temperature low-pressure liquid state so as to easily evaporate while flowing inside the expansion valve 26 to the indoor heat exchanger 28. The refrigerant discharged to the indoor heat exchanger 28 undergoes heat exchange with the ambient air of the indoor heat exchanger 28 to form a phase change to a low temperature low pressure gas phase state, and then again through the four sides 20. It is introduced into the compressor (10).

As described above, the ambient air heat-exchanged with the refrigerant decompressed through the expansion valve 26 in the indoor heat exchanger 28 is changed into cold cold while losing heat to the refrigerant, and the cold air is indoors through the indoor fan 30. Cooling is achieved while being discharged to.

In addition, the heating process of the air conditioner, which forms a cycle opposite to the above-described cooling process, as shown in Figure 2, the low-temperature low-pressure gas phase refrigerant introduced into the compressor 10 from the outdoor heat exchanger 22 is a compressor (10). Pressurized to a gaseous state of high temperature and high pressure through the pressurizing action of), discharged to the indoor heat exchanger 28 through the four sides 20 switched to achieve a heating cycle to exchange heat with the ambient air of the indoor heat exchanger 28 After the phase change to the liquid phase of the room temperature and high pressure through the discharge valve 26, the ambient air heat-exchanged with the gaseous refrigerant of high temperature and high pressure is changed to hot air by the heat of the refrigerant, and the indoor fan ( It is discharged to the room through the 30) is made to the heating to increase the temperature of the room.

In addition, the refrigerant discharged to the expansion valve 26 is decompressed to a low-temperature low-pressure liquid state so that the evaporation can be performed smoothly in the outdoor heat exchanger 22 and then discharged to the outdoor heat exchanger 22, the outdoor heat exchanger The refrigerant discharged to 22 is phase-changed to a low-temperature low-pressure gas phase state through heat exchange with external air introduced into the outdoor unit, and then flows back into the compressor 10 through the four sides 20.

However, in the outdoor unit configured as described above, a counter-flow heat exchanger (Liquid to Suction Hex) for high efficiency of the air conditioner is installed in the suction pipe of the compressor 10 among the components of the outdoor unit. In the case of such a counterflow heat exchanger, since it is arbitrarily disposed in the mechanical part when installed around the compressor 10 without considering its proper position, the size of the mechanical part is increased while the space efficiency in the mechanical part is greatly reduced. In addition to the big problem, there is a big problem that the overall outdoor unit size is also increased by the increase of the mechanical portion of the outdoor unit.

In addition, there is a problem that the application of the sound absorbing sound material (not shown) according to the increase of the overall size of the mechanical part and the outdoor unit or the mass productivity of the product is also greatly reduced, and the manufacturing cost and the product cost according to the increase of the size of the entire mechanical part and the outdoor unit There was a huge problem going up.

In order to solve the above problems, the present invention is to provide a counterflow heat exchanger immediately before the suction pipe connecting the suction side and the four sides of the compressor among the components of the outdoor unit, and the counterflow heat exchanger The electromagnetic expansion valve piping is connected in parallel, but the suction tube, the counterflow heat exchanger, and the electromagnetic expansion valve piping are arranged at an optimal placement angle which allows the electronic expansion valve piping to be compact. The purpose of the present invention is to allow the outdoor unit to be compactly configured while reducing vibrations of the suction pipe due to the compressor starting by the optimum arrangement angle of the suction pipe, the counter flow heat exchanger, the electromagnetic expansion valve, and the dryer.

In order to achieve the above object, the piping arrangement structure of the air conditioner outdoor unit according to the present invention,

In the air conditioner outdoor unit,

A suction pipe of the compressor, a vertical counter flow heat exchanger connected at one end to the suction pipe, and an electromagnetic expansion valve pipe part parallel to the counter flow heat exchanger are disposed, and the vibration of the suction pipe due to the start of the compressor is reduced. The counterflow heat exchanger is characterized in that the angle between the suction pipe and the electromagnetic expansion valve is arranged within a 90 degree range.

Preferably, the upper portion of the counter-flow heat exchanger is characterized in that the suction pipe, the electromagnetic expansion valve and the dryer piping are in the range of about 15 to 90 degrees.

Preferably, the electromagnetic expansion valve pipe portion is characterized in that the dryer is installed in parallel to the counter-flow heat exchanger vertically below the electromagnetic expansion valve.

According to the present invention, the counter flow heat exchanger is disposed immediately before the suction pipe of the compressor, and the counter flow heat exchanger and the electromagnetic expansion valve pipe are connected in parallel, but the suction pipe of the compressor, the counter flow heat exchanger, The expansion valve and the dryer can be arranged at the optimum placement angle.

Hereinafter, with reference to the accompanying drawings will be described in detail.

3 and 4 are a perspective view and a plan view showing a pipe arrangement structure of the air conditioner outdoor unit according to the present invention.

3 and 4, the piping structure of the air conditioner outdoor unit of the present invention is an air conditioner outdoor unit including a compressor 110, a counterflow heat exchanger 130, an electronic expansion valve (LEV) 115, and a dryer 120. To;

One end of the counter flow heat exchanger 130 is disposed immediately before the suction pipe 132 of the compressor 110, and the counter flow heat exchanger 130, the electronic expansion valve 115, and the dryer 120 are disposed. Parallel to each other, but the arrangement angle of the pipe connecting the compressor suction pipe 132 and the electromagnetic expansion valve 115 and the dryer 120 based on the point of the counter flow heat exchanger 130 is 15 ~ 90 degrees Configured to be placed in range.

That is, the optimum arrangement angle (A-A ') formed by the suction pipe 132, the counterflow heat exchanger 130, the electromagnetic expansion valve 115 and the dryer 120 is the suction pipe according to the start of the compressor 130 It is characterized in that it is in the range of about 15 to 90 degrees which can be compacted while reducing vibration of 132.

In addition, the electromagnetic expansion valve 115 and the dryer 120 are vertically connected to each other for the advantage of space use and vibration through the optimal placement angle.

Hereinafter, the pipe structure of the air conditioner outdoor unit of the present invention will be described in detail with reference to Figs. 3 and 4, the counter-flow heat exchanger 130 as a double tube heat exchanger for the high efficiency of the air conditioner, the inner tube is a compressor 110 One end is connected to the suction pipe 132 of, and the other end 131 is connected to the evaporator outlet 131, the refrigerant flows from the evaporator outlet toward the compressor. Appearance is one end is connected to the electronic expansion valve 115 and the other end 134 is connected to the condenser outlet.

In detail, the double tube heat exchanger, referring to FIG. 5, in the counterflow heat exchanger 130, the inner tube 130a and the outer tube 130b are combined in a double tube form, and the inner tube 130a has one side of the evaporator outlet pipe 131. The other side is connected to the compressor inlet side pipe 132 and sucks the gas of low temperature low pressure and exchanges heat by the fluid flowing to the exterior (130b) to be delivered to the compressor.

That is, the inner tube (130a) is connected to the evaporator outlet side pipe 131 and the compressor inlet side pipe (suction pipe) 132 is a tube through which low-temperature low-pressure gas flows, the exterior (130b) is the expansion valve inlet side pipe 133 And it is connected to the condenser outlet side pipe 134 and the liquid of the high temperature and high pressure flows in a counterflow manner with the refrigerant flowing in the inner tube (130a), thereby conducting the gas flowing in the inner tube (130a) at a high temperature.

The counterflow heat exchanger 130 is disposed vertically just before the suction pipe 132, and the pipe portion connecting the electromagnetic expansion valve 115 and the dryer 120 is disposed in parallel with the counterflow heat exchanger 130. do.

Here, with the counter flow type heat exchanger 130 as the point B, the arrangement angles Θ: BA and B-A 'between the suction pipe 132 and the pipe portion (electromagnetic expansion valve-dryer) are predetermined. Angled.

Here, the arrangement angle Θ is an angle with the suction piping of the suction pipe 132, and connects the suction pipe 132 of the compressor 110 when the counterflow heat exchanger 130 is a vertical axis B. The angle between one point BA, the point B-A 'connected between the electronic expansion valve 115, which is a pipe, and the dryer 120, is shown.

In particular, the pipes arranged around the compressor 110 to vibrate the rotation torsion generated by the rotation of the compressor 110, that is, the rotation torsion generated by the rotor (not shown) in the compressor 110 rotating along the central axis. In order to withstand (not shown), the suction pipe 132 is a center of the compressor (132) in order to withstand the compressor 110 vibration due to the rotational torsion of the compressor 110, the stiffness of the pipe and severe vibration eccentricity Placed within 90 ° from the center of the compressor 110 in a state coincided with the center 110 supports the vibration transmitted from the compressor 10 so that the vibration is transferred to other pipes (not shown) through the suction pipe 132. It is the most ideal layout structure such as not to be transmitted.

In this case, since the suction pipe 132 is disposed at 90 ° perpendicular to the center of the compressor 110 even if the vibration force due to the rotational torsion at the start of the compressor 110 acts on the suction pipe 132. The vibration of the torsion is supported by the vertical portion of the suction pipe 132 corresponding to the center of the compressor 110, that is, the vertical length of the suction pipe 132 disposed to coincide with the center of the compressor 110. The counterflow heat exchanger 130, the electromagnetic expansion valve 115, and the dryer 120, which are connected to the suction pipe 132 at a predetermined angle, may be freed from vibration of the compressor 10. do.

In addition, the vibration generated when the compressor 110 is started is prevented from being transmitted to the counterflow heat exchanger 130, the electromagnetic expansion valve 115, and the dryer 120 through the suction pipe 132. The suction pipe 132 is an arrangement angle for supporting the vibration transmitted from the compressor 110, and is disposed within 90 ° perpendicular to the center of the compressor 110.

Specifically, the optimum arrangement angle of the suction pipe 132, the counterflow heat exchanger 130, the electromagnetic expansion valve 115 and the dryer 120 is as described above, according to the start of the compressor 110 The vibration range of the suction pipe 132 is about 15 to 90 degrees, which can be compact.

In addition, the electromagnetic expansion valve 115 and the dryer 120 are vertically connected to each other for space use and vibration reduction through the optimal placement angle.

Figure 6 shows the compactness of the outdoor unit with respect to the arrangement angle of the electromagnetic expansion valve 115, the dryer 120, the counter-flow heat exchanger 130, the compressor suction tube 132, which is a mechanical component of the outdoor unit according to the present invention It is a graph.

As described above, the counter flow type heat exchanger 130 is connected to and disposed immediately before the suction pipe 132 of the compressor 110, and the counter flow type heat exchanger 130 is parallel to the electromagnetic expansion valve 115 and the dryer 120. And the counterflow heat exchanger 130, the electromagnetic expansion valve 115, and the dryer 120 are arranged around the compressor 110 at an optimum arrangement angle (about 15 to 90 °). When the vibration from the compressor 110 according to the start of the compressor 110 acts on the suction pipe 132, the suction pipe 132 is the most ideal for supporting the vibration transmitted from the compressor 110 as described above The vibration transmitted from the compressor 110 is connected to the suction side of the compressor 110 within a range of the arrangement angle, from the placement angle to the placement angle such as to support the vibration of the compressor 110 to some extent. Support through the suction pipe 132 Can be achieved the characteristic effect is prevented from being transmitted to the-flow heat exchanger 130, the electric expansion valve 115 and the dryer 120. The

Furthermore, in arranging the counter flow heat exchanger 130, the electromagnetic expansion valve 115, and the dryer 120 around the compressor 110, the suction pipe 132 of the compressor 10 and the counter flow heat exchanger. Machine 130, electromagnetic expansion valve 115, and dryer 120 are arranged at an optimal placement angle in the range of about 15 to 90 °, so that the suction pipe 132 and the counterflow heat exchanger 130 When the electronic expansion valve 115 and the dryer 120 are arranged in the optimum arrangement angle range as described above, while the vibration of the suction pipe 132 according to the operation of the compressor 110 is reduced, that is, the compressor 110 inside the outdoor unit. It is possible to reduce the use space of the mechanical unit 5 is installed as shown in Figure 3, it is possible to compactly configure the outdoor unit.

In the case of the piping structure of the air conditioner outdoor unit as described above, it can be applied to the outdoor unit of the air conditioner for cooling operation, the outdoor unit of the multi-type air conditioner, the air conditioner outdoor unit equipped with the accumulator, in addition to the outdoor unit of the heat pump which is a general air conditioning system. Make sure you know.

The piping structure of the air conditioner outdoor unit of this invention arranges a counterflow heat exchanger immediately before the suction pipe which connects the suction side and the four sides of a compressor among the components of an outdoor unit, and parallels the said counterflow heat exchanger, an electromagnetic expansion valve, and a dryer. In order to achieve a high efficiency of the air conditioner by the counter-flow heat exchanger, by arranging the compressor at an optimal placement angle to compact the suction pipe, the counter-flow heat exchanger, the electromagnetic expansion valve and the dryer, The optimum arrangement angle of the suction pipe, the counter flow heat exchanger, the electromagnetic expansion valve, and the dryer arranged as described above has an excellent effect of compactly configuring the outdoor unit while reducing vibration of the suction pipe due to the compressor startup.

Claims (3)

In the air conditioner outdoor unit, A suction pipe of the compressor, a vertical counter flow heat exchanger connected at one end to the suction pipe, and an electromagnetic expansion valve pipe part parallel to the counter flow heat exchanger are disposed, and the vibration of the suction pipe due to the start of the compressor is reduced. And a counterflow heat exchanger at a point such that an angle between the suction pipe and the electromagnetic expansion valve is within a 90 degree range. The piping arrangement of the air conditioner outdoor unit according to claim 1, wherein a suction pipe, an electromagnetic expansion valve, and a dryer pipe portion at an upper point of the counterflow heat exchanger are in a range of about 15 to 90 degrees. The method of claim 1, The electromagnetic expansion valve pipe portion is a pipe arrangement structure of the air conditioner outdoor unit, characterized in that the dryer is installed in the lower portion of the electromagnetic expansion valve in parallel to the counterflow heat exchanger.

Images