KR101463160B1 - Air conditioner - Google Patents

Abstract

The air conditioner includes a compressor, a condenser, an expander, a drain pan connected to the evaporator through a refrigerant pipe, a drain pan installed to receive the condensed water dropped from the evaporator and having a condensed water discharge portion for discharging condensed water; A cylinder arranged to rise inside the condensed water discharge part or to descend into the condensed water discharge part; And a cylinder elevating mechanism for elevating and lowering the cylinder, so that it is possible to use the condensed water for the improvement of the freezing efficiency or the like and to prevent the discomfort caused by the condensed water.

Air conditioner, evaporator, drain pan, condensate, condensate outlet, cylinder, cylinder lift

Description

Air conditioner

The present invention relates to an air conditioner, and more particularly to an air conditioner in which condensate of a drain pan is not drained from a drain pan and is left in a drain pan or drained from a drain pan.

Generally, an air conditioner is a device for cooling or heating a room by using a refrigeration cycle including a compressor, a condenser, an inflator and an evaporator, and is divided into an integral type and a separate type depending on whether the indoor unit or the outdoor unit is divided.

The integral type and the separate type are functionally the same, but the integral type is a device in which a compressor, a condenser, an expansion mechanism, and an evaporator are built in a single device, the device is installed outdoors and a suction duct / discharge duct is connected to the device, It is to place the device on the wall or window of the building.

On the other hand, the separate type includes an evaporator, an inflator and an indoor fan installed in the indoor unit, a condenser, a compressor and an outdoor fan installed in the outdoor unit, and a refrigerant pipe connected to the compressor, the condenser, the inflator and the evaporator.

The air conditioner is provided with a drain mechanism for receiving the condensed water dropped from the evaporator at the lower part of the evaporator and discharging the condensed water to the outside. The drain mechanism includes a drain pan on which an upper surface is opened and a condensed water discharge part is formed on one side, and a drain hose connected to the condensed water discharge part.

However, according to the related art air conditioner, since the condensed water dropped from the evaporator to the drain pan flows along the drain pan and then drained to the outside of the air conditioner, the condensed water can not be used in the air conditioner and is drained in a low temperature state.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and an object of the present invention is to provide an air conditioner capable of preventing condensation water from being discharged by discharging condensed water, It has its purpose.

It is another object of the present invention to provide an air conditioner having a simple structure capable of containing condensed water in a drain pan or draining condensed water in a drain pan.

It is another object of the present invention to provide an air conditioner in which condensate does not flood in the drain pan and the interior is kept clean.

According to an aspect of the present invention, there is provided an air conditioner including a compressor, a condenser, an inflator, and a drain connected to the evaporator through a refrigerant pipe, configured to receive condensed water dropped from the evaporator, A fan; A cylinder arranged to rise inside the condensed water discharge part or to descend into the condensed water discharge part; And a cylinder elevating mechanism for elevating and lowering the cylinder.

And the cylinder is disposed lower than the upper end of the drain pan at a maximum rise.

And the cylinder is disposed at a lower or equal level than the upper end of the condensed water discharge portion when the cylinder is at the maximum descent.

The condensing portion discharge portion is formed with a latching jaw for receiving the cylinder downward.

The cylinder elevating mechanism includes a drain adjusting motor and a power transmitting mechanism interlocked with the drain adjusting motor to raise and lower the cylinder.

The power transmission mechanism includes a driving gear connected to the drain adjusting motor, and a driven gear formed up and down on the cylinder and engaged with the driving gear.

The refrigerant pipe between the evaporator and the compressor is arranged so that a part thereof passes over the upper side of the drain pan.

The air conditioner is formed with a heat radiating portion arranged in a refrigerant pipe between the condenser and the inflator so as to be heat-exchanged with the condensed water of the drain pan.

And a controller for controlling the air conditioner to control the cylinder rising mechanism in a rising mode during a cooling operation of the air conditioner and controlling the cylinder rising mechanism in a falling mode when the air conditioner is stopped.

The air conditioner according to the present invention includes a compressor, a condenser, an expander, and a drain pan connected to the evaporator through a refrigerant pipe, and configured to receive condensed water dropped from the evaporator and having a condensed water discharge portion for discharging condensed water, And an opening / closing unit for opening and closing the condensed water discharge unit, and a heat radiating unit arranged to heat-exchange the condensed water flowing along the drain pan to a refrigerant pipe between the expansion fan and the expansion fan.

The air conditioner according to the present invention configured as described above can use the remaining condensed water in the drain pan to improve the freezing efficiency or the like as the cylinder is raised and blocks the condensed water discharge portion. When the cylinder is lowered to open the condensed water discharge portion, So that the discomfort that may occur when the condensed water is left in the drain pan for a long time is advantageously prevented.

The air conditioner according to the present invention has a simple structure because the condensed water discharge portion is opened and closed by the cylinder and the condensed water is drained through the cylinder.

In the air conditioner according to the present invention, since the cylinder is disposed lower than the upper end of the drain pan when the cylinder rises to the maximum, and the condensed water filled in the drain pan is discharged through the cylinder, the condensed water does not overflow into the drain pan, There is an advantage that it is not dirty by.

The air conditioner according to the present invention is arranged at a lower or equal level than the upper end of the condensed water discharge portion when the cylinder is at the maximum descent, so that the condensed water at the time of descending the cylinder can be drained without being left in the drain pan.

The air conditioner according to the present invention is advantageous in that the cylinder can be prevented from being released from the cylinder without being inserted into the condensed water discharging portion.

The air conditioner according to the present invention is characterized in that the cylinder elevating mechanism includes a drain adjusting motor and a power transmitting mechanism interlocked with the drain adjusting motor to raise and lower the cylinder, The control unit controls the cylinder rising mechanism in the lowering mode when the air conditioner is stopped, so that the air conditioner itself can control the drainage of the condensed water, and the convenience of the user is more enhanced than when the user manually adjusts the condensed water have.

The air conditioner according to the present invention is characterized in that the power transmission mechanism includes a driving gear connected to the drain adjusting motor and a driven gear formed vertically in the cylinder and meshed with the driving gear so that the structure can be installed in a simple and narrow space .

The air conditioner according to the present invention is arranged such that a part of the refrigerant pipe between the evaporator and the compressor is arranged to pass over the upper side of the drain pan and the condensed water generated in the refrigerant pipe between the evaporator and the compressor is treated together by the drain pan There is an advantage that a sufficient amount of condensed water can be ensured in the drain pan since not only the condensed water dropped from the evaporator to the drain pan but also the condensed water dropped from the refrigerant pipe between the evaporator and the compressor flows.

The air conditioner according to the present invention is characterized in that the refrigerant pipe between the condenser and the inflator is formed with a heat radiating portion arranged to be heat-exchanged with the condensate of the drain pan so that the refrigerant passing through the refrigerant pipe between the condenser and the inflator passes through the heat- It is cooled, and then expanded. Therefore, there is an advantage that the refrigeration efficiency is high.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a schematic configuration diagram of an air conditioner according to the present invention, and FIG. 4 is a P-H diagram of a refrigeration cycle of an air conditioner according to the present invention.

3, the air conditioner according to the present embodiment includes a compressor 2 for compressing refrigerant, a condenser 4 for condensing the refrigerant compressed in the compressor 2, a condenser 4 for condensing the refrigerant in the condenser 4, (6) for expanding the refrigerant, and an evaporator (8) for evaporating the refrigerant expanded in the expander (6).

The compressor 2 and the condenser 4 are connected to a compressor-condenser-connected refrigerant pipe 10, which is a refrigerant pipe between the compressor 2 through which the high-temperature and high-pressure refrigerant compressed in the compressor 2 passes, and the condenser 4 The condenser 4 and the inflator 6 are connected to the condenser-expander-connected refrigerant pipe 20 which is a refrigerant pipe between the condenser 4 and the inflator 6 through which the high-temperature refrigerant condensed in the condenser 4 passes, The inflator 6 and the evaporator 8 are connected to the inflator 6 through which the refrigerant expanded in the inflator 6 passes and the inflator-evaporator connected refrigerant pipe 30 which is the refrigerant pipe between the evaporator 8, 8 and the compressor 2 are connected to the evaporator 8 through which the low temperature refrigerant evaporated in the evaporator 8 passes and the evaporator-compressor connected refrigerant pipe 40 which is the refrigerant pipe between the compressor 2 and the compressor 2.

The air conditioner may be an integrated type air conditioner, a separate type air conditioner, and a separate type air conditioner.

The outdoor unit O is provided with a compressor 2 and a condenser 4 and an outdoor fan including an outdoor fan and a fan motor for passing outdoor air through the outdoor unit O. [

The indoor unit I is provided with an indoor fan having an inflator 6 and an evaporator 8 and an indoor fan and a fan motor for passing indoor air through the indoor unit I.

Here, the inflator 6 may be a capillary tube, or an electronic expansion valve whose opening degree varies depending on the input frequency.

The condenser-expander-connected refrigerant pipe 20 is a kind of high-temperature pipe which passes through the outdoor unit O and the indoor unit I and passes through the high-temperature refrigerant. The high-temperature service valve 21 installed in the outdoor unit O, Temperature indoor unit piping 24 connected to the expansion mechanism 6 and a high temperature installation piping 24 connecting the high-temperature indoor unit piping 24 and the high-temperature service valve 21 to the high-temperature outdoor piping 22 connected to the condenser 4, 26).

The evaporator-compressor connecting refrigerant pipe 40 is a kind of low-temperature pipe which passes through the outdoor unit O and the indoor unit I and passes through the low-temperature refrigerant as a whole. The low-temperature service valve 41 and the low- A low temperature indoor piping 44 connected to the evaporator 6 and a low temperature piping 46 connecting the low temperature indoor piping 42 and the low temperature service valve 41. The low temperature indoor piping 42 is connected to the compressor 2, Lt; / RTI >

That is, the indoor unit I includes an inflator 6, an evaporator 8, a high-temperature indoor unit piping 24, and a low-temperature indoor unit piping 44. The outdoor unit O includes a compressor 2, Temperature service valve 41, a high temperature service valve 21, a high temperature outdoor air pipe 22, a low temperature service valve 41, and a low temperature outdoor air pipe 42.

Here, the high-temperature installation pipe 26 passes through the indoor unit I, a part thereof is located inside the indoor unit I, one end is connected to the high-temperature indoor unit pipe 24 and the other end is connected to the high- .

The low-temperature installation piping 46 passes through the indoor unit I, and a part thereof is located inside the indoor unit I, one end thereof is connected to the low-temperature indoor unit piping 44 and the other end thereof is connected to the low-temperature service valve 41.

On the other hand, the indoor unit I is provided with a drain mechanism 50 for receiving the condensed water W generated on the surface of the evaporator 8 and falling down and draining the condensed water W to the outside of the indoor unit I.

The refrigerant pipe connected to the condenser-expander-refrigerant pipe 20 between the condenser 4 and the inflator 6 is arranged to be heat-exchanged with the condensate water W of the drain mechanism 50 to heat the refrigerant with the condensed water W The heat dissipating portion 70 is formed.

The heat dissipating unit 70 is a kind of intercooler that cools the refrigerant to the condensed water W before the refrigerant that has passed through the condenser 4 flows into the expansion mechanism 6 and is expanded to a low temperature and a low pressure. (I), it is formed in a portion of the condenser-expander-connected refrigerant pipe (20) located inside the indoor unit (I).

The heat dissipating unit 70 is formed on at least one of the high temperature indoor unit pipe 24 and the high temperature installation pipe 26. The refrigerant is discharged from the heat dissipating unit 70 And the condensed water of the drain mechanism 50 is transferred to the outside of the indoor unit I after being heated by receiving the heat of the refrigerant.

It is preferable that the heat dissipating unit 70 is installed in the piping close to the drain mechanism 50 of the high temperature indoor unit piping 24 and the high temperature installation piping 26, particularly the drain pan 52 described later.

The high temperature indoor piping 24 is located closer to the drain pan 52 than the high temperature installation piping 26 and is assembled to the indoor unit I when the indoor unit I is transported, The heat dissipating unit 70 is formed in the high temperature indoor unit pipe 24 in consideration of the fact that it is located farther away from the drain pan 52 than the high temperature indoor unit pipe 24 and is highly likely to be replaced when the air conditioner is installed before. And is hereinafter described as being formed in the high temperature indoor unit piping 24.

The heat dissipating unit 70 may be formed such that a part of the high temperature indoor unit pipe 24 itself or the high temperature indoor unit pipe 24 is in direct contact with the condensate water W and the high temperature indoor unit pipe 24 is connected to the condensate water W And the other side is in contact with the condensate water W so that the heat of the refrigerant can be transferred to the condensate water W through the heat transfer member. 24 are formed to be in direct contact with the condensate water W, the number of components is small and the heat radiation of the refrigerant is efficient, so that a part of the high temperature indoor unit pipe 24 is arranged to be in direct contact with the condensate water W. FIG.

FIG. 5 is a partial perspective view of the air conditioner according to the present invention, FIG. 6 is a longitudinal sectional view of the drain pan shown in FIG. 5, and FIG. 7 is a transverse sectional view of the drain pan shown in FIG.

5 to 7, the drain mechanism 50 includes a drain pan 52 installed in the indoor unit I under the evaporator 8.

The drain pan 52 is formed with a passage 54 through which the condensed water flows and a condensed water discharge portion 56 for discharging the condensed water W flowing along the passage 54 to the outside of the drain pan 52 is formed at one side.

The drain pan 52 is formed in a box shape whose upper surface is opened as a whole and the condensed water discharging portion 56 is formed on one side of the left and right sides of the drain pan 52. The flow path 54 is formed by the condensed water discharging portion 56 toward the condensed water discharging portion 56. As shown in FIG.

That is, when the condensed water discharge portion 56 is formed on the left side of the drain pan 52, the drain pan 52 is formed so that the condensed water flows from right to left, When formed on the right side, condensed water flows from left to right.

The drain pan 52 is provided with a lower plate portion 57 and front, rear, left, and right plate portions 58 forming flow paths of the condensed water W together with the door lower plate portion 57 formed vertically or inclined to the lower plate portion 57 And the condensed water discharge portion 56 is formed to protrude downward from the lower plate portion 57.

The drain mechanism 50 further includes a drain hose 62 connected to the condensed water discharge portion and arranged to penetrate the indoor unit I and to guide the condensed water discharged to the condensed water discharge portion 56 to the outside of the indoor unit I .

On the other hand, each of the high-temperature indoor unit pipe 24 of the refrigerant pipe connected to the condenser-expander 20 and the low-temperature indoor unit pipe 44 of the evaporator-compressor connected refrigerant pipe 40 are connected to each other As shown in Fig. 5, a part thereof is arranged to pass over the upper side of the drain pan 52, and each one side thereof is inserted and fixed in the refrigerant pipe fixing part 64 formed concavely in the drain pan 52. [

   The heat radiating portion 70 is formed by a bent portion where a part of the high temperature indoor unit piping 24 of the condenser-expander connected refrigerant piping 20 is bent to be positioned in the flow path 54, and the air conditioner is part of the high temperature indoor unit piping 24 The cooling efficiency is increased by a simple structure that the cooling fan is bent and positioned in the flow path 54 which is the inside of the drain pan 52.

The heat radiating portion 70 is formed in a portion of the high-temperature indoor unit piping 24 of the condenser-expander connected refrigerant piping 20 that passes over the upper side of the drain pan 52.

The heat dissipating unit 70 is provided with a straight line portion 72 at the bottom so that the refrigerant and the condensed water W are heat-exchanged at a sufficient time and a heat transfer area.

The heat dissipating unit 70 is bent in a U-shape as a whole on a portion passing through the upper side of the drain pan 52 of the high-temperature indoor unit pipe 24.

That is, the heat dissipating unit 70 includes a first bent portion 74 bent downward at a portion passing over the upper side of the drain pan 52 of the high-temperature indoor unit pipe 24 of the condenser-expander connected refrigerant pipe 20, A straight portion 72 bent horizontally at the lower end of the bent portion 74 and a second bent portion 76 bent upward at the straight portion 72.

The heat dissipating portion 70 is formed so that the straight portion 72 is lower than the upper ends of the front, rear, left and right plate portions 58, 59, 60 and 61 of the drain pan 52, (54).

The heat dissipating portion 70 is a substantially heat exchanging portion or cooling portion in which the lower portion of the first bent portion 74, the lower portion of the second bent portion 76, and the straight portion 72 are in contact with the condensed water W, 72 may be provided in a single number, and a plurality of linear portions 72 may be provided in a zigzag shape or a plurality of linear portions 72 may be provided in a lattice form.

The heat dissipating unit 70 is disposed so that the condensed water W flowing along the flow path 54 of the drain mechanism 50, particularly the drain pan 52, and the refrigerant passing through the heat dissipating unit 70 flow in the opposite direction.

That is, when the condensed water W flowing down to the flow path 54 of the drain pan 52 flows from the left side to the right side of the drain pan 52, When the condensed water W flows from the right side to the left side of the drain pan 52, the heat radiating portion 70 is configured such that the refrigerant flows from the left side of the straight portion 72 to the right side Respectively.

 The drain pan (52) is formed with a heat radiating portion fixing portion (66) for fixing the heat radiating portion (70).

The heat dissipating unit fixing unit 66 is configured to make the heat dissipating unit 70 come into contact with the condensed water W in a state where the heat dissipating unit 70 does not move shakenly and is protruded upward from the lower plate 57 of the drain pan 52, And a pair of hooks 67 and 68 for elastically fixing one side of the straight portion 72, in particular.

 The heat dissipating unit fixing unit 66 elastically bends the heat dissipating unit 70 to allow the heat dissipating unit 70 to enter and the heat dissipating unit 70 is mounted on the lower plate 57 of the drain pan 52 And is restored to its original shape to restrict the movement of the heat radiating portion 70 before, after, and upward.

On the other hand, the drain mechanism (50) further includes an opening / closing means (80) for opening / closing the condensed water discharge portion (56).

FIG. 8 is a cross-sectional side view of the drain pan shown in FIG. 5 when the drain pan is closed; FIG. 9 is a sectional side view of the drain pan shown in FIG. 5 when the condensed- Fig.

The opening and closing means 80 temporarily stores the condensed water W in the drain pan 52 so that the condensed water W of the drain pan 52 can be used for other purposes such as raising the efficiency of freezing the air conditioner, And that the condensed water W is not immediately drained to the condensed water discharge portion 56 during the cooling operation of the air conditioner and the heat dissipating portion 70 is continuously cooled.

8, the condensed water W dropped into the drain pan 52 is not immediately discharged through the condensed water discharge portion 56, and is discharged to the drain pan 52 The heat exchange time between the condensed water W and the heat dissipating unit 70 is longer than the case where the condensed water is drained immediately and the rectilinear part 72 of the heat dissipating unit 70 is locked to the condensed water W The heat exchange area between the condensed water W and the heat dissipating unit 70 is increased and the cooling effect of the refrigerant passing through the heat dissipating unit 70 can be maximized.

On the other hand, when the operation of the air conditioner is stopped or the operation of the air conditioner is other than the cooling operation, if the drain pan 52 is left for a long time in the drain pan 52 without draining the condensed water to the outside, The opening and closing means 80 closes the condensed water discharge portion 56 such that the condensed water remains in the drain pan 52 as shown in Fig. 7 during the cooling operation of the air conditioner, and the air When the operation stop of the air conditioner or the operation of the air conditioner is other than the cooling operation, it is explained that the condensed water discharge portion 56 is opened so that the condensed water is drained as shown in Fig.

Here, the opening / closing means 80 comprises a stopper for closing the condensed water discharge portion 56, and a stopper drive mechanism for rotating or lifting the stopper so that the stopper can open and close the condensate discharge portion, When the shuttle is rotated or lowered to the closed position, the closure prevents the condensate discharge 56 from draining through the condensate discharge 56, and the cap drive mechanism rotates or rises the cap to the open position It is also possible to cause the cap to open the condensed water discharge portion 56 and to discharge the condensed water through the condensed water discharge portion 56. [

The opening and closing means 80 is configured as described above and when the stopper driving mechanism drives the stopper irrespective of the water level of the condensed water W, The drain pan 52 is provided with a condensate water level sensor for sensing the water level of the condensate water and the condensate water level sensor sensed by the condensate water level sensor If the level of the condensed water W detected by the condensate water level sensor is lower than the lower limit set value, the cap drive mechanism is closed and the cap drive mechanism is closed Mode so that the stopper seals the condensed water discharge portion 56. [0053]

In addition, instead of providing the water level sensor as described above, the opening / closing means 80 is provided with a separate condensed water passage through which the condensed water can pass, and when the predetermined pressure or more is applied to the condensed water passage, It is of course possible to provide a condensing water passage shielding mechanism which closes the condensing water passage while being opened or closed and when the pressure is less than a predetermined pressure.

The opening and closing means 80 includes a cylinder 82 arranged to rise inside the condensed water discharge portion 56 or to descend into the condensed water discharge portion 56 and a cylinder elevating mechanism 84 for moving the cylinder 82 up and down When the amount of the condensed water W is excessively large while the cylinder 82 closes the condensed water discharge portion 56 when the cylinder elevating mechanism 84 raises the cylinder 82, It is also possible for the cylinder 82 to discharge the condensed water discharging portion 56 when the cylinder elevating mechanism 84 descends the cylinder 82. In this case,

When the opening and closing means 80 includes the cylinder 82 and the cylinder elevating mechanism 84 as described above, there is no need for a separate water level sensor, a condensed water passage and a condensed water passage blocking mechanism as in the case of installing a cap, , And a cylinder 82 and a cylinder elevating mechanism 84 will be described below.

The cylinder 82 is a hollow cylindrical body whose top, bottom, and inside are opened in the vertical direction, and is formed such that its outer diameter is smaller than the inner diameter of the condensed water discharge portion 56.

The upper end of the cylinder 82 is disposed lower than the upper end of the drain pan 52 and the upper end of the cylinder 82 is disposed lower than or equal to the upper end of the condensed water discharge portion 56 when the cylinder 82 is at its maximum.

  The cylinder 82 and the condensed water discharge portion 56 are structured such that the cylinder 82 is not inserted into the condensed water discharge portion 56. The engagement portion 83 is formed in the upper portion of the cylinder 82 in the radial direction And a catching protrusion 56A is formed at an upper portion of the condensed water discharging portion 56 to catch the catching portion 83 of the cylinder 82 downward.

The cylinder elevating mechanism 84 includes a drain adjusting motor 86 and a power transmitting mechanism 88 for interlocking with the drain adjusting motor 86 to raise and lower the cylinder 82.

 The power transmission mechanism 88 includes a drive gear 90 connected to the drain adjustment motor 86 and a driven gear 92 formed on the cylinder 82 up and down and engaged with the drive gear 90.

 In addition, the air conditioner includes an operation unit 100 for inputting various operation commands such as cooling operation and operation stop, and an air conditioner, such as an air conditioner, a compressor 2, an outdoor blower 5, And controls the cylinder elevating mechanism 84, particularly the drain adjusting motor 86, in the ascending mode during the cooling operation of the air conditioner. When the operation of the air conditioner is stopped, the cylinder lifting mechanism 84, And a control unit 110 for controlling the motor 86 in a downward mode.

Reference numeral 94 shown in Figs. 8 and 9 is formed around the condensed water discharging portion 56 of the drain pan 52, and the drain adjustment is provided in which the driving gear 90 is rotatably positioned and the drain adjusting motor 86 is installed. Box.

Reference numeral 96 in Figs. 8 and 9 is a hole-shaped gear penetration formed in the condensed water discharge portion 56 and the drain adjustment box 94 so that at least one of the drive gear 90 and the driven gear 92 is penetrated.

Hereinafter, the operation of the present invention will be described.

11 is a flow chart of an embodiment of a control method of an air conditioner according to the present invention.

First, in the cooling operation of the air conditioner, the control unit 110 drives the compressor 2 and the outdoor blower 5 of the outdoor unit O and drives the indoor blower 9 of the indoor unit I, And controls the elevating mechanism 84, particularly the drain adjusting motor 86, in the elevating mode. (S1) (S2)

The outdoor air is sucked into the outdoor unit O and then exchanged with the condenser 4 and then discharged to the outside of the outdoor unit O. When the indoor air blower 9 is driven, Exchanged with the evaporator 8 after being sucked into the indoor unit I, and then discharged to the outside of the indoor unit I.

The drain adjusting motor 86 rotates the driving gear 90 in the clockwise direction in Figs. 8 and 9 while the driven gear 92 is rotated by the driving gear 92 in the lifting mode of the drain adjusting motor 86 The upper end of the cylinder 82 is raised higher than the upper end of the drainage fan 56 and lower than the upper end of the drainage fan 52 as shown in FIG.

On the other hand, when the compressor (2) is driven, the compressor (2) compresses the gaseous refrigerant of low temperature and low pressure into gaseous refrigerant of high temperature and high pressure, and the refrigerant compressed by the compressor (2) passes through the compressor- Condenser 4 and then condensed while passing through the condenser 4 while releasing heat to the outdoor air sucked into the outdoor unit.

The condensed refrigerant passes through the condenser-expander connecting pipe 20 to the indoor unit I, passes through the heat dissipating unit 70 in the indoor unit I, is moved to the expander 6, (6).

The expanded refrigerant passes through the inflator-evaporator connecting pipe 30 and flows into the evaporator 8 and then evaporates while taking the heat of the room air sucked into the indoor unit I while passing through the evaporator 8 And then flows through the evaporator-compressor connecting pipe 40 to the outdoor unit O and flows into the compressor 2 from the outdoor unit O. [

In the operation of the air conditioner as described above, the moisture in the room air is condensed at the portion of the surface of the evaporator 8 and the upper portion of the drain pan 52 of the evaporator-compressor connecting pipe 40, The condensed water generated on the surface drops to the drain pan 52 along the surface of the evaporator 8 and the condensed water generated in the portion of the evaporator-compressor connecting pipe 40 that passes above the drain pan 52 passes through the drain pan 52 ).

The condensed water W dropped into the drain pan 52 can not be drained through the condensed water discharge portion 56 because the outer wall of the cylinder 82 blocks the condensed water discharge portion 56, And is brought into contact with the heat dissipating portion 70 as its height becomes higher.

At this time, the condensed water W in contact with the heat dissipating unit 70 in the drain pan 52 is lower in temperature than the high-temperature refrigerant passing through the heat dissipating unit 70, and the heat of the refrigerant passing through the heat dissipating unit 70 flows to the heat- The refrigerant passing through the heat dissipating unit 70 flows into the inflator 6 after being further cooled immediately before the inflator 6 and the refrigerating efficiency of the air conditioner is increased do.

That is, the refrigerant condensed in the actual condenser 4 is discharged from the condenser 4 without being sufficiently cooled in the condenser 4, passes through the condenser-expander connecting pipe 20 and is then expanded in the expander 6 If the refrigerant is not cooled by the condensed water W, the refrigerant is circulated to the process B-> C-> D-> E-> A-> B, as shown in FIG.

On the other hand, when the refrigerant is cooled by the condensed water W, even if the refrigerant that has passed through the condenser 4 is not sufficiently cooled in the condenser 4, The refrigerant is further cooled by the condensed water W contacting with the heat dissipating unit 70 while passing through the refrigerant passage B and the refrigerant is supplied to the refrigerant line B-> C-> D-> D '-> E' A-> B process.

That is, the refrigeration cycle of the air conditioner has a simple structure in which a part of the condenser-inflator connecting pipe 20, which passes over the upper side of the drain pan 52, is bent into the flow channel 54 of the drain pan 52, The efficiency is increased by D-> D '-> E' -> E region.

As the condenser-expander connection pipe 20 and the evaporator-compressor connection pipe 40 become closer to each other, heat loss due to mutual heat exchange occurs. The upper side of the drain pan 52 of the condenser-expander connection pipe 20 The heat dissipating portion 70 is bent at a distance from the evaporator-compressor connecting pipe 40 so that the heat loss due to the heat exchange is not generated by the bent portion of the heat dissipating portion 70, ) 40 is minimized.

On the other hand, as time elapses, the water level of the condensed water W of the drain pan 52 gradually increases. When the water level of the condensed water W becomes higher than the upper end of the cylinder 82, And then the condensed water discharge portion 56 and the drain hose 62 are shielded and drained to the outside of the indoor unit I. That is, the condensed water W can not reach the upper end of the drain pan 52, and continuously cools the radiator 80 while being filled with the upper water level of the cylinder 82.

When the operation of the air conditioner is stopped when the air conditioner is in the cooling operation and the condensed water W is filled in the drain pan 52 as described above, the controller 110 controls the compressor 2 of the outdoor unit O, The indoor fan 9 of the indoor unit I is stopped and the cylinder elevating mechanism 84 and particularly the drain adjusting motor 86 are controlled in the descending mode.

The drain adjusting motor 86 rotates the driving gear 90 in the counterclockwise direction in Figs. 8 and 9 while the driven gear 92 is lowered by the driving gear 92 in the descending mode of the drain adjusting motor 86 The upper end of the cylinder 82 is lowered to the same height or lower than the upper end of the condensed water discharge portion 56 as shown in Fig.

That is, the cylinder 82 is inserted into the condensed water discharging portion 56, and the condensed water W of the drain pan 52 passes through the inside of the cylinder 82 through the upper end of the cylinder 82, Passes through the discharge portion 56 and the drain hose 62 and is drained to the outside of the indoor unit I. That is, the condensed water W is naturally drained in the drain pan 52, and no condensed water W is left in the drain pan 52.

1 is a schematic configuration diagram of an air conditioner according to the related art,

2 is an actual P-H diagram of a refrigeration cycle of an air conditioner according to the prior art,

FIG. 3 is a schematic configuration diagram of an embodiment of an air conditioner according to the present invention,

4 is a P-H diagram of a refrigeration cycle of an air conditioner according to an embodiment of the present invention,

5 is a partial perspective view of one embodiment of an air conditioner according to the present invention,

6 is a longitudinal sectional view of the drain pan shown in Fig. 5,

7 is a cross-sectional view of the drain pan shown in Fig.

FIG. 8 is a side sectional view of the drain pan shown in FIG. 5 when the condensed water discharge portion is closed;

Fig. 9 is a sectional side view of the drain pan shown in Fig. 5 when the condensed water discharge portion is opened;

10 is a control block diagram of an air conditioner according to the present invention.

11 is a flow chart of an embodiment of a control method of an air conditioner according to the present invention.

DESCRIPTION OF THE EMBODIMENTS

 2: compressor 4: condenser

6: inflator 8: evaporator

10: compressor-condenser connection pipe 20: condenser-expander connection pipe

24: High temperature indoor unit piping 30: Inflator-evaporator connection piping

40: Evaporator-compressor connecting pipe 44: Low temperature indoor unit piping

50: drain mechanism 52: drain pan

54: Flow path 56: Condensate discharge part

62: drain hose 70:

72: straight line portion 80: opening /

82: Cylinder 84: Cylinder lifting mechanism

86: driving source 88: power transmission mechanism

90: drive gear 92: driven gear

100: operation unit 110:

W: Condensate

Claims (10)

A compressor, a condenser, an inflator, and an evaporator are connected by a refrigerant pipe, A drain pan installed to receive the condensed water dropped from the evaporator and having a condensed water discharge portion for discharging the condensed water; A cylinder arranged to rise inside the condensed water discharge part or to descend into the condensed water discharge part; And a cylinder elevating mechanism for raising and lowering the cylinder. The method according to claim 1, Wherein the cylinder is disposed lower than an upper end of the drain pan at a maximum rise. 3. The method of claim 2, Wherein the cylinder is disposed lower than or equal to an upper end of the condensed water discharge portion when the cylinder is at a maximum fall. The method according to claim 1, And the condenser discharge portion has a catching jaw for receiving the cylinder downward. The method according to claim 1, Wherein the cylinder lift mechanism includes a drain adjustment motor and a power transmission mechanism interlocked with the drain adjustment motor to raise and lower the cylinder. 6. The method of claim 5, Wherein the power transmission mechanism includes a driving gear connected to the drain adjusting motor, and a driven gear formed vertically in the cylinder and engaged with the driving gear. The method according to claim 1, And a refrigerant pipe between the evaporator and the compressor is arranged so that a part of the refrigerant pipe passes over the upper side of the drain pan. 8. The method according to any one of claims 1 to 7, Wherein the air conditioner includes a refrigerant pipe between the condenser and the inflator, and a heat radiating part arranged to exchange heat with condensed water flowing along the drain pan. 9. The method of claim 8, Further comprising a control unit for controlling said air conditioner and controlling said cylinder rising mechanism in an ascending mode during a cooling operation of said air conditioner and controlling said cylinder ascending mechanism in a descending mode upon stopping the operation of said air conditioner Harmonics. delete

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