CN217209595U - Refrigerant pipe heat abstractor and have device's air condensing units and air conditioner - Google Patents

Abstract

The utility model relates to the technical field of refrigerant pipe heat dissipation, and discloses a refrigerant pipe heat dissipation device, an air conditioner outdoor unit with the same and an air conditioner, which comprises a soaking area and a spraying area, wherein the refrigerant pipe sequentially passes through the soaking area and the spraying area; a cavity for collecting condensed water is arranged in the soaking area; the upper part of the cavity extends to the upper part of the spraying area to form a spraying section for downward water drainage; the part of the refrigerant pipe in the soaking area is positioned in the containing cavity; the part of the refrigerant pipe in the spraying area is positioned below the spraying section, the spraying area is provided with radiating fins which are uniformly distributed on the refrigerant pipe, and the spraying section is provided with a water outlet which is opposite to the radiating fins. The radiating fins are used for conducting heat on the refrigerant pipes, so that the temperature of the refrigerant in the refrigerant pipes is reduced, and the radiating fins have larger radiating area and can effectively improve the radiating efficiency; the delivery port is used for spraying the condensate water on the heat dissipation sheet, the utility model discloses realize twice cooling, improved heat dispersion, and the air outlet and the inlet scoop of this kind of mode off-premises station do not block up to receive the dust to influence for a short time, do not need extra power consumption, with low costs.

Description

Refrigerant pipe heat abstractor and have device's air condensing units and air conditioner

Technical Field

The utility model relates to a refrigerant pipe heat dissipation technical field, more specifically relates to a refrigerant pipe heat abstractor and have device's air condensing units and air conditioner.

Background

With the continuous improvement of living standard, people increasingly select air-cooled air conditioners to cool and relieve summer heat in summer regardless of office places or families. However, most houses do not have a uniform air conditioning drain duct, and directly drain the condensed water out of the house. Therefore, the beauty and the water resistance of the outer wall can be damaged, environmental noise caused by water dripping can also hinder the life of other people, and the neighborhood relation is influenced; meanwhile, in hot summer, the temperature of the outdoor unit of the air conditioner can reach more than 50 ℃, even the air conditioner is shut down in a protective way due to overhigh temperature, and compared with the prior art, the temperature of condensed water of the air conditioner is only a few degrees generally, so that the air conditioner is a very good cold source. Therefore, the air conditioner outdoor unit is cooled by recycling the condensed water in an auxiliary heat dissipation manner, so that the social harmony is promoted, and the national energy conservation and emission reduction bureau is more satisfied.

In the existing air conditioner condensed water recycling device, an atomizing pump device is expensive and needs to be driven by extra consumed electric energy, and a condensed water disc distributor is used for jet cooling and also needs a condensing fan to consume extra electric energy, so that the cost is extremely high; the grid hole wet towel of the cloth curtain type device is directly covered on the air outlet and the air suction inlet of the outdoor unit, dust is easy to accumulate, and the heat dissipation performance is greatly reduced.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at overcoming above-mentioned prior art's at least one defect, provide a refrigerant pipe heat abstractor for the solution easily receives the dust to influence, leads to the technical problem that heat dispersion descends.

The technical proposal adopted by the utility model is that the refrigerant pipe heat dissipation device comprises a soaking area and a spraying area which are sequentially penetrated by refrigerant pipes; a cavity for collecting condensed water is arranged in the soaking region; the upper part of the cavity extends to the upper part of the spraying area to form a spraying section for downward drainage; the part of the refrigerant pipe in the soaking area is positioned in the containing cavity; the part of the refrigerant pipe in the spraying area is positioned below the spraying section.

The refrigerant pipe heat dissipation device is mainly used for recovering condensed water and using the condensed water for heat dissipation and temperature reduction of the refrigerant pipe; when using in the air conditioning field, mainly collect the comdenstion water that the machine produced in the air conditioning, the comdenstion water that will collect is used for air condensing units's cooling again, realizes the low-cost recovery of comdenstion water and the promotion of air conditioner heat dispersion. The district of soaking is used for once cooling the refrigerant pipe of soaking in its inside, and the district of spraying is used for spraying the secondary cooling to the refrigerant pipe, holds the chamber and is used for collecting the comdenstion water, soaks the refrigerant pipe with the comdenstion water simultaneously and cools down wherein, can also let in the spray segment with a partial comdenstion water of collecting, and the spray segment is used for spraying the comdenstion water to the shower, improves the radiating rate of refrigerant pipe in the spray zone through the evaporation of comdenstion water.

A large amount of refrigerants flow in the refrigerant pipes, and when the refrigerants flow through the refrigerant pipes in the soaking region, heat in the refrigerants is transferred to condensed water in the containing cavity in the soaking region through the pipe walls of the refrigerant pipes to realize heat exchange, so that primary cooling is performed; when the refrigerant flows through the refrigerant pipe in the spraying area, the spraying section sprays condensed water on the refrigerant pipe in advance, so that the heat in the refrigerant is subjected to secondary cooling through evaporation and heat dissipation of the condensed water sprayed on the outer wall of the refrigerant pipe; the condensed water with higher temperature is discharged from the spraying section position in the cavity in a spraying mode, meanwhile, the condensed water with lower temperature of the air conditioning indoor unit is re-injected into the cavity, the lower temperature of the condensed water in the cavity is always ensured to be maintained through the replacement mode of 'heat output and cold input' of the condensed water, and the total amount of the condensed water in the cavity is maintained to be a certain amount. The cooling is carried out to the refrigerant pipe once through holding the chamber in the district of soaking, and the spray section of spray zone top sprays and carries out the secondary cooling to the refrigerant pipe, so realizes twice cooling, has improved heat dispersion, and the air outlet and the inlet scoop of this kind of mode off-premises station do not block up to receive the dust influence little, do not need extra power consumption, with low costs.

Preferably, the spraying area is provided with radiating fins which are uniformly distributed, the radiating fins are connected with the refrigerant pipe, and the spraying section is provided with a water outlet which is opposite to the radiating fins. The radiating fins are used for conducting heat on the refrigerant pipes, so that the temperature of the refrigerant in the refrigerant pipes is reduced, and the radiating fins have larger radiating area and can effectively improve the radiating efficiency; the water outlet is used for spraying condensed water onto the radiating fins, and the heat on the radiating fins can be taken away when the condensed water is evaporated, so that the radiating efficiency of the radiating fins can be further improved.

Preferably, the heat dissipation sheet is internally provided with a hollow cavity for loading a refrigerant, the refrigerant has excellent heat transfer performance, the temperature on the refrigerant pipe can be quickly conducted to the heat dissipation sheet, the heat conduction can be further promoted, and the heat dissipation efficiency can be improved.

Preferably, a fan is arranged in the spraying area and is arranged on the inner side of the radiating fins. The fan is used for increasing the air flow rate between the radiating fins, and the higher the air flow rate is, the higher the speed of taking away heat on the radiating fins is, and the higher the radiating efficiency is; the evaporation capacity of the condensate water sprayed in unit time on the radiating fins can be improved through the air flow rate, and the radiating efficiency can be further improved.

Preferably, a first temperature measurement switch is arranged at the position where the refrigerant pipe enters the spraying area, the first temperature measurement switch is electrically connected with the fan, and the rotating speed of the fan is changed according to the first temperature measurement switch. The first temperature measurement switch is used for measuring the temperature of entering the spraying area, and when the temperature of refrigerant pipe is higher than a certain value when entering the spraying area, the first temperature measurement switch sends an electric signal, the fan receives the electric signal and starts low-gear work, and the fan is used for improving the heat dispersion of the whole spraying area.

Preferably, a water inlet is formed in one side, far away from the spraying section, of the top of the accommodating cavity. The water inlet is used for flowing into the comdenstion water, the spray segment sets up in the top one side that holds the chamber, after the comdenstion water accumulation in holding the intracavity is saved a quantitative, the comdenstion water just can enter into the spray segment, so, mainly be in order to carry out the sediment of comdenstion water, the supernatant of settling the back comdenstion water of accomplishing just can flow into in the spray segment, can effectively prevent the delivery port jam of spray segment, the spray segment is kept away from to the water inlet mainly is that the comdenstion water flows into the spray segment and causes the delivery port to block up under the condition that does not precipitate.

Preferably, a filtering structure is arranged on the water inlet. The filtering structure is used for filtering impurities in condensed water and preventing the impurities from entering the cavity to cause water outlet blockage.

Preferably, the refrigerant pipe is spirally arranged in the accommodating cavity. The length of the refrigerant pipe in the containing cavity can be increased by the aid of the spiral arrangement, so that the contact area between condensate water and the surface of the refrigerant pipe is increased, and the heat is conducted into the condensate water more quickly.

The outdoor unit of the air conditioner is provided with the refrigerant pipe heat dissipation device, a compressor is arranged in the outdoor unit of the air conditioner, the compressor is connected with a refrigerant pipe, a second temperature measurement switch is arranged at the position, where the refrigerant pipe is connected out of a spraying area, of the refrigerant pipe, the second temperature measurement switch is electrically connected with a fan, and the rotating speed of the fan is changed according to the second temperature measurement switch. The compressor is used for compressing the refrigerant in the refrigerant pipe and changing the refrigerant from a gas state to a liquid state in the compression process, so that the temperature of the refrigerant in the refrigerant pipe is reduced, and the cooling effect is achieved; the second temperature measurement switch is used for measuring the temperature of the output spraying area, and when the temperature of the refrigerant output from the spraying area is lower, the fan keeps working at a low gear; when the temperature of the refrigerant output to the spraying area is high, the second temperature measurement switch transmits an electric signal to the fan, the fan performs high-gear work, the fan can increase the air flow rate between the radiating fins again, the air flow rate is increased again, and the radiating efficiency is improved; the evaporation capacity of the condensate water sprayed in unit time on the radiating fins is improved through the air flow rate, and the radiating efficiency can be further improved.

The air conditioner comprises an indoor unit and an outdoor unit, wherein the outdoor unit is connected with the indoor unit, the indoor unit is provided with a condensed water channel, and the channel is connected with a soaking area. The condensed water generated in the indoor unit is collected by the containing cavity and then used for heat dissipation of the air conditioner, the condensed water can be effectively recycled, and meanwhile the heat dissipation performance of the air conditioner is improved.

Compared with the prior art, the beneficial effects of the utility model are that: the refrigerant pipe is cooled for the first time through the containing cavity in the soaking area, and the spraying section above the spraying area sprays the refrigerant pipe for the second time, so that the cooling is realized for the second time, the heat dissipation performance is improved, and the air outlet and the air suction opening of the outdoor unit are not blocked and are slightly influenced by dust; the recovery of the condensed water does not need extra energy consumption and has low cost.

Drawings

Fig. 1 is a schematic view of an overall structure of a first embodiment of the present invention.

Fig. 2 is a partial structural sectional view of a middle chamber according to an embodiment of the present invention.

Fig. 3 is a schematic view of the overall structure of the second embodiment of the present invention.

Fig. 4 is a schematic view of an internal structure of an air conditioner outdoor unit according to a second embodiment of the present invention.

Fig. 5 is a schematic view of the overall structure of the third embodiment of the present invention.

In the figure: 1 soaking area, 2 spraying area, 3 containing cavities, 4 spraying sections, 5 radiating fins, 6 water outlets, 7 hollow cavities, 8 fans, 9 filtering structures, 10 water inlets, 11 first temperature measuring switches, 12 compressors, 13 second temperature measuring switches, 14 indoor units, 15 refrigerant pipes, 16 air conditioner outdoor units and 17 condensed water connecting pipes.

Detailed Description

The drawings of the present invention are for illustration purposes only and are not to be construed as limiting the invention. For a better understanding of the following embodiments, certain features of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

Example 1

As shown in fig. 1, the present embodiment is a cooling device with a cooling medium pipe, which includes a soaking region 1 and a spraying region 2 through which a cooling medium pipe 15 sequentially passes; a containing cavity 3 for collecting condensed water is arranged in the soaking region 1; the upper part of the cavity 3 extends to the upper part of the spraying area 2 to form a spraying section 4 for draining water downwards; the part of the refrigerant pipe 15 in the soaking region 1 is positioned in the cavity 3; the part of the refrigerant pipe 15 in the spraying area 2 is positioned below the spraying section 4.

The refrigerant pipe heat dissipation device is mainly used for recovering condensed water, and the condensed water is used for heat dissipation and cooling of the refrigerant pipe 15; when the air conditioner is applied to the field of air conditioners, the air conditioner mainly collects condensed water generated by the indoor unit 14, and then the collected condensed water is used for cooling the outdoor unit 16 of the air conditioner, so that low-cost recovery of the condensed water and improvement of the heat dissipation performance of the air conditioner are realized. Soaking zone 1 is used for once cooling soaking in its inside refrigerant pipe 15, spraying zone 2 is used for the secondary cooling of spraying the mode to refrigerant pipe 15, it is used for collecting the comdenstion water to hold chamber 3, soak refrigerant pipe 15 with the comdenstion water simultaneously wherein cooling 15, can also let in spray segment 4 with a part of comdenstion water of collecting, spray segment 4 is used for spraying the comdenstion water to spray pipe 15, evaporation through the comdenstion water that sprays improves the radiating rate of refrigerant pipe 15 in spraying zone 2.

A large amount of refrigerants flow in the refrigerant pipe 15, and when the refrigerants flow through the refrigerant pipe 15 in the soaking region 1, heat in the refrigerants is transferred to condensed water in the cavity 3 in the soaking region 1 through the pipe wall of the refrigerant pipe 15 to realize heat exchange, so that primary cooling is performed; when the refrigerant flows through the refrigerant pipe 15 in the spraying area 2, the spraying section 4 sprays condensate water on the refrigerant pipe 15 in advance, so that the heat in the refrigerant is subjected to secondary cooling through evaporation and heat dissipation of the condensate water sprayed on the outer wall of the refrigerant pipe 15; the condensate water with higher temperature is discharged from the position of the spraying section 4 in the cavity 3 in a spraying mode, meanwhile, the condensate water with lower temperature in the indoor unit 14 is re-injected into the cavity 3, the condensate water in the cavity 3 is always kept at lower temperature through the replacement mode of 'heat output and cold input' of the condensate water, and the total amount of the condensate water in the cavity 3 is kept at a certain amount. The cooling is carried out on the refrigerant pipe 15 once through the containing cavity 3 in the soaking area 1, the spraying section 4 above the spraying area 2 sprays to carry out secondary cooling on the refrigerant pipe 15, so that the cooling is carried out twice, the heat dissipation performance is improved, the air outlet and the air suction opening of the outdoor unit in the mode are not blocked and are influenced by dust little, extra energy consumption is not needed, and the cost is low.

As shown in fig. 2, the spraying region 2 has heat dissipation fins 5 uniformly distributed on the refrigerant pipe 15, and the spraying section 4 is provided with water outlets 6 opposite to the heat dissipation fins 5. The radiating fins 5 are used for conducting heat on the refrigerant pipes 15, so that the temperature of the refrigerant in the refrigerant pipes 15 is reduced, and the radiating fins 5 have larger radiating areas and can effectively improve the radiating efficiency; the water outlet 6 is used for spraying condensed water onto the radiating fins 5, and the condensed water can take away heat on the radiating fins 5 when evaporating, so that the radiating efficiency of the radiating fins 5 can be further improved. A plurality of fins 5 are provided on the refrigerant pipe 15, and the fins 5 may be fixed to the refrigerant pipe 15 by welding or other means.

As shown in fig. 2, the heat sink 5 has a hollow chamber 7 for loading a refrigerant, the hollow chamber 7 is used for loading the refrigerant, and the refrigerant has excellent heat transfer performance, so that the temperature on the refrigerant pipe 15 can be quickly conducted to the heat sink 5 and dissipated to the outside, thereby further promoting heat conduction and improving heat dissipation efficiency. The heat sink 5 can be manufactured by casting, and the hollow cavity can be directly cast during casting. The spraying area 2 is provided with a fan 8. The fan 8 is used for improving the air flow rate between the radiating fins 5, and the higher the air flow rate is, the higher the speed of taking away heat on the radiating fins 5 is, and the higher the radiating efficiency is; the evaporation speed of the condensate water sprayed in unit time on the radiating fins 5 can be increased through the air flow rate, and the radiating efficiency can be further improved.

As shown in fig. 2, a first temperature measurement switch 11 is disposed at a connection position of the cooling medium pipe 15 and the spraying region 2, the first temperature measurement switch 11 is electrically connected to the fan 8, and the fan 8 changes a rotation speed thereof according to the first temperature measurement switch 11. The first temperature measurement switch 11 is used for measuring the temperature entering the spraying area 2, when the temperature of the refrigerant pipe 15 is higher than a certain value when the refrigerant pipe enters the spraying area 2, the first temperature measurement switch 11 sends an electric signal, the fan 8 receives the electric signal and starts low-level work, and the fan 8 is used for improving the heat dissipation performance of the whole spraying area 2. The first temperature measurement switch 11 can be a temperature sensor.

As shown in fig. 2, the top of the chamber 3 has an inlet 10 on the side remote from the spray section 4. The water inlet 10 is used for flowing into the comdenstion water, the spray segment 4 sets up in the top one side that holds the chamber 3, after the comdenstion water that holds the chamber 3 is built up a certain amount, the comdenstion water just can enter into the spray segment 4, so, mainly be in order to carry out the sediment of comdenstion water, the supernatant of settling the completion back comdenstion water just can flow into in the spray segment 4, can effectively prevent the delivery port 6 of spray segment 4 from blockking up, the water inlet 10 is kept away from the spray segment 4 and mainly is flowed into the spray segment 4 in order to prevent the comdenstion water under the condition that does not deposit and causes impurity to block up delivery port 6. One end of the water inlet 10 is directly connected with the indoor unit 14, in the actual connection process, the height of the indoor unit 14 is higher than that of the outdoor unit 16 of the air conditioner, condensed water can flow into the water inlet 10 through self gravity, extra power does not need to be provided, spraying of the condensed water is also discharged through self gravity, extra power does not need to be provided, and the condensed water collection cost is low.

As shown in fig. 2, the inlet 10 is ported with a filter structure 9. The filtering structure 9 is used for filtering impurities in condensed water and preventing the impurities from entering the cavity 3 to block the water outlet 6. The filtering structure 9 can adopt a filter screen, a filter plate or other structures capable of filtering the condensed water. Refrigerant pipe 15 spirals and sets up in holding chamber 3, spirals and set up and to increase refrigerant pipe 15 length in holding chamber 3 to increase the area of contact on comdenstion water and refrigerant pipe 15 surface, make the heat scatter and disappear into the comdenstion water more fast, accelerate the heat transfer between the two.

Example two

As shown in fig. 3 and fig. 4, the present embodiment is an improvement of the first embodiment, and discloses, on the basis of the first embodiment: an air conditioner outdoor unit 16 with a refrigerant pipe heat dissipation device is characterized in that a compressor 12 is arranged in the air conditioner outdoor unit 16, the compressor 12 is connected with a refrigerant pipe 15 connected into a soaking area 1, a second temperature measurement switch 13 is arranged on a part, connected out of a spraying area 2, of the refrigerant pipe 15, the second temperature measurement switch 13 is electrically connected with a fan 8, and the rotating speed of the fan 8 is changed according to the second temperature measurement switch 13. The compressor 12 is used for compressing the refrigerant in the refrigerant pipe 15, and the refrigerant is changed from a gas state to a liquid state in the compression process, so that the temperature of the refrigerant in the refrigerant pipe 15 is reduced, and the effect of reducing the temperature is achieved; when the temperature of the refrigerant output from the spraying area 2 is higher, the second temperature measurement switch 13 transmits an electric signal to the fan 8 to enable the fan 8 to work at an upshifting position, the air flow rate between the radiating fins 5 can be increased again due to the increase of the air output of the fan 8, and the radiating efficiency is improved; the evaporation capacity of the condensate water sprayed in unit time on the radiating fins is improved through the air flow rate, and the radiating efficiency can be further improved.

EXAMPLE III

As shown in fig. 5, the present embodiment is an improvement of the second embodiment, and discloses, on the basis of the second embodiment: an air conditioner comprises an indoor unit and an outdoor unit 16 of the second embodiment, wherein the outdoor unit 16 is connected with the indoor unit 14, the indoor unit 14 is provided with a condensed water channel, and the channel is connected with a soaking area 1. The condensed water generated in the indoor unit 14 is collected by the cavity 3 and then used for heat dissipation of the air conditioner, so that the condensed water can be effectively recycled, and the heat dissipation performance of the whole air conditioner can be improved.

Instructions for use: in the air conditioner, the refrigerant pipe 15 is connected between the indoor unit 14 and the outdoor unit 16, and is used for transporting indoor heat to the outside, returning the heat to the inside again after the heat is dissipated outside, and circularly performing heat dissipation between the indoor unit 14 and the outdoor unit 16 in such a way, so as to realize indoor temperature reduction. When the indoor temperature is lower, the heat carried by the refrigerant pipe 15 is less, and at the moment, the refrigerant can dissipate the heat carried by the refrigerant through the condensed water in the cavity 3 of the soaking region 1 and the condensed water sprayed on the radiating fins 5 of the spraying region 2; when the indoor temperature is high, the heat carried by the refrigerant pipe 15 is high, the condensed water in the soaking zone 1 and the spraying zone 2 cannot meet the cooling requirement, at the moment, the temperature of the refrigerant pipe 15 at the first temperature measurement switch 11 rises, after the temperature rises to a certain value, the first temperature measurement switch 11 controls the fan 8 to work at a low gear, the air flow rate of the cooling fins 5 is increased by the fan 8, the heat dissipation performance of the spraying zone 2 is improved, and therefore the heat carried by the refrigerant pipe 15 is dissipated, and the heat dissipation requirement is met; when the indoor temperature is too high and still unsatisfied the heat dissipation demand, refrigerant pipe 15 carries a large amount of heat this moment, soak district 1, spray district 2 and fan 8 in order can not satisfy its heat dissipation demand, the output sprays second temperature measurement switch 13 control fan 8 that sets up on refrigerant pipe 15 of district 2 and carries out high-grade position work, the temperature of refrigerant in refrigerant pipe 15 is reduced through the mode of increasing air flow rate between the fin 5, later attach the cooperation heat dissipation of soaking district 1 and compressor 12 again in order to improve holistic heat dispersion, satisfy the heat dissipation demand when the indoor temperature is higher.

It is obvious that the above embodiments of the present invention are only examples for clearly illustrating the technical solutions of the present invention, and are not limitations to the specific embodiments of the present invention. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention shall be included in the protection scope of the present invention.

Claims (10)

1. A refrigerant pipe heat dissipation device is characterized by comprising a soaking area and a spraying area, wherein refrigerant pipes sequentially penetrate through the soaking area and the spraying area; a containing cavity for collecting condensed water is arranged in the soaking area; the upper part of the cavity extends to the upper part of the spraying area to form a spraying section for downward water drainage; the part of the refrigerant pipe in the soaking area is positioned in the containing cavity; the part of the refrigerant pipe in the spraying area is positioned below the spraying section.

2. The refrigerant pipe heat dissipating device of claim 1, wherein: the spraying area is provided with radiating fins which are uniformly distributed, the radiating fins are connected with the refrigerant pipe, and a water outlet which is opposite to the radiating fins is formed in the spraying section.

3. The refrigerant tube heat sink as claimed in claim 2, wherein the heat sink has a hollow chamber for containing refrigerant therein.

4. The refrigerant pipe heat dissipating device of claim 2, wherein: a fan is arranged in the spraying area and is arranged on the inner side of the radiating fin.

5. The refrigerant tube heat sink of claim 4, wherein: the refrigerant pipe is provided with a first temperature measurement switch at the position of entering the spraying area, the first temperature measurement switch is electrically connected with the fan, and the fan changes the rotating speed according to the first temperature measurement switch.

6. The refrigerant tube heat sink of claim 4, wherein: and a water inlet is formed in one side, far away from the spraying section, of the top of the accommodating cavity.

7. The refrigerant tube heat sink of claim 6, wherein: and a filtering structure is arranged on the water inlet.

8. The refrigerant tube heat sink of claim 4, wherein: the refrigerant pipe is spirally arranged in the containing cavity.

9. An outdoor unit of an air conditioner having the refrigerant pipe heat dissipating device as claimed in any one of claims 4 to 8, wherein a compressor is provided in the outdoor unit of the air conditioner, the compressor being connected to the refrigerant pipe; and a second temperature measurement switch is arranged at the position of the refrigerant pipe connected out of the spraying area, the second temperature measurement switch is electrically connected with the fan, and the fan changes the rotating speed according to the second temperature measurement switch.

10. An air conditioner comprising an indoor unit, and further comprising the outdoor unit of claim 9, wherein the outdoor unit is connected to the indoor unit, and the indoor unit is provided with a condensate passage connected to the soak zone.

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