KR20080083356A - Air conditioner - Google Patents

Abstract

An indoor heat exchanger (5) has refrigerant passes, and the lowermost refrigerant pass of the refrigerant passes is laid such that, in cooling operation, it allows refrigerant to flow to heat transmission tubes (6) on both the windward and the leeward of air that is sent from a fan device (21) and also allows the refrigerant to flow out of an exit side heat transmission tube (6) that is located on the windward side, at the second row from the lowermost part of the indoor heat exchanger (5).

Description

Air Conditioning Equipment {AIR CONDITIONER}

The present invention relates to an air conditioner for suppressing refrigerant drift of a heat exchanger.

In recent years, as the demand for energy saving is increased, in order to avoid the performance degradation of the apparatus due to the pressure loss of the evaporator, a heat exchanger of a high capacity air conditioner uses one U-shaped heat exchanger as one refrigerant passage. A multipath configuration is needed.

In this case, when the number of refrigerant paths is increased, it is necessary to suppress the difference in the amount of heat exchange for each refrigerant path due to the difference in the wind speed distribution, and to guide the sucked indoor air to the indoor heat exchanger without leakage. For this purpose, the lower end part is placed directly on the bottom of the drain pan (see, for example, Patent Document 1 (Japanese Patent Laid-Open No. 2005-315455).

Hereinafter, an example of a path arrangement of a conventional refrigerant path will be described with reference to FIGS. 4 to 6. 4 to 6, a case in which the indoor heat exchanger 5 is used as an evaporator will be described.

Among the plurality of refrigerant paths shown in FIG. 4, the lowermost refrigerant path is the second stage at the bottom and the refrigerant flows in the downstream side heat transfer pipe 6, and the second stage at the above flow side. And the heat-transfer tube 6 at the bottom end of the downstream side in turn, and are piped so that the coolant flows out from the bottom-most heat-transfer tube 6 at the side of the upstream side.

In addition, the coolant flows in from the lowermost heat transfer tube 6 of the said flow side, and the 2nd stage heat exchanger tube of the downstream side and the 2nd stage heat exchanger tube of the downstream side flow in order, and the lowermost refrigerant path shown in FIG. Piping is carried out so that refrigerant | coolant may flow out from the lowermost heat exchanger tube 6 of the downstream side.

6, the refrigerant flows in from the heat transfer pipe 6 at the bottom end of the upstream side, flows through the second stage on the flow side and the bottom heat transfer tube 6 on the downstream side in turn, Piping is carried out so that refrigerant | coolant flows out from the 2nd stage heat exchanger tube 6 of the side.

[Initiation of invention]

[Problem to Solve Invention]

However, in the refrigerant path shown in Fig. 4, when the indoor heat exchanger 5 is used as the evaporator, the condensed water generated in the indoor heat exchanger 5 is stored in the drain pan 22, so that the refrigerant at the bottom of the indoor heat exchanger 5 is reduced. There is a problem that the heat transfer pipe 6 at the path exit side is submerged, and a part of the capacity is used for heat exchange with the condensate, resulting in an extreme drop in the capacity at the exit side.

5 and 6, there is a problem that the heat exchange efficiency of the indoor heat exchanger 5 is deteriorated because the heat transfer pipe 6 on the outlet side of the refrigerant path is disposed on the downstream side.

This invention is made | formed in view of such a point, and the objective is to provide the air conditioner which is excellent in a cooling ability and heat exchange efficiency, by suppressing the coolant drift of a heat exchanger.

[Means for solving the problem]

In order to achieve the above object, in the present invention, in order to prevent the sinking of the lowermost refrigerant path outlet side heat exchanger tube 6, the outlet side heat exchanger tube 6 is arranged on the upper side of the second side or more in the lowermost stage.

That is, according to the first aspect of the present invention, a heat exchanger (5) having a plurality of refrigerant paths formed of a plurality of heat transfer tubes (6) arranged at predetermined intervals, and a blower that blows and heat-exchanges indoor air to the heat exchanger ( 21 and an air conditioner having a drain pan 22 for storing condensate generated in the heat exchanger 5.

The coolant path at the lowermost end of the plurality of coolant paths distributes the coolant through the heat transfer pipes 6 respectively positioned on the upstream side and the downstream side of the air blown by the blower 21 during the cooling operation. The lower end of the heat exchanger (5) is piped to allow the refrigerant to flow out of the outlet side heat transfer pipe (6) located at the second side or more and located on the upstream side.

In the first coolant path of the first invention, the coolant is circulated through the heat transfer pipes 6 respectively located on the upstream side and the downstream side during the cooling operation, and at least the second stage at the bottom of the heat exchanger 5. The refrigerant flows out of the heat transfer tube 6 on the outlet side located at the upstream side.

As a result, the number of turns of the heat transfer tube 6 is increased to increase the heat exchange capacity of the coolant path at the lowermost end of the heat exchanger 5 and to suppress the decrease in the evaporation capacity of the heat exchanger 5. In addition, since the heat transfer pipe 6, which is the outlet side of the coolant, is disposed at the lowermost side of the heat exchanger 5 in the second stage or more, the heat exchanger tube 6 has a minimum decrease in the heat exchange rate due to the condensed water stored in the drain pan 22. Can be suppressed.

In the first invention, the second invention includes a drain pump 23 for draining the condensed water stored in the drain pan 22. The drain pump 23 is configured to drain the condensed water until the condensed water stored in the drain pan 22 reaches the outlet side heat transfer pipe 6.

In the second invention, the condensate is drained until the condensate stored in the drain pan 22 reaches the outlet side heat transfer pipe (6). As a result, the outlet heat transfer pipe 6 of the refrigerant path is not submerged in the condensed water, and a part of the capacity can be prevented from being used for heat exchange with the condensed water, thereby suppressing the decrease in the heat exchange rate.

In the first aspect of the present invention, the third invention includes a drain pump (23) for draining the condensate stored in the drain pan (22), and condensate stored in the drain pan (22) than the heat transfer pipe (6) on the outlet side. The water level detecting means 24 for detecting that the low predetermined water level has been reached is provided. The drain pump 23 is configured to drain the condensed water based on the detection result of the water level detecting means 24.

In the third invention, the water level detecting means 24 detects that the condensed water stored in the drain pan 22 has reached a predetermined level lower than that of the outlet side heat transfer pipe 6, and the drain pump 23 is based on the detection result. The drainage of the condensate takes place. Thus, the drain pump 23, which has always been operated regardless of the level of the condensate, can be intermittently operated based on the level of the condensate in order to prevent the refrigerant path from sinking, thereby reducing power consumption.

[Effects of the Invention]

As described above, according to the present invention, the number of turns of the heat exchanger tube 6 is increased, and the heat exchange capacity of the lowermost refrigerant path of the heat exchanger 5 is increased, which is advantageous for suppressing a decrease in the evaporation capacity of the heat exchanger 5. . Moreover, since the heat exchanger tube 6 which is the outlet side of a refrigerant | coolant is arrange | positioned at the lowermost side of a heat exchanger 5 more than a 2nd stage, and is located in the said upstream, the fall of the heat exchange rate by the condensate stored in the drain pan 22 is suppressed to the minimum. can do.

Further, according to the second invention, the outlet side heat transfer pipe 6 of the refrigerant path is not submerged in the condensed water, and a part of the capacity can be prevented from being used for heat exchange with the condensed water, thereby reducing the decrease in the heat exchange rate.

According to the third aspect of the present invention, the drain pump 23, which has always been operated regardless of the condensate level, can be operated intermittently based on the condensate level in order to prevent the refrigerant path from being submerged, thereby reducing power consumption. Become.

1 is a refrigerant circuit diagram of an air conditioner according to an embodiment of the present invention.

2 is a schematic view showing the internal structure of the indoor unit of the air conditioner according to the present embodiment.

3 is a side view showing the refrigerant path structure of the indoor heat exchanger according to the present embodiment.

Figure 4 is a schematic diagram showing the internal structure of the indoor unit of the conventional air conditioner.

5 is a schematic diagram showing the internal structure of another indoor unit of the conventional air conditioner.

6 is a schematic diagram showing the internal structure of another indoor unit of the conventional air conditioner.

[Description of the code]

5: indoor heat exchanger (heat exchanger) 6: heat transfer tube

21: blower 22: drain pan

23: drain pump

24: floating switch (water level detection means)

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail based on drawing. The following description of the preferred embodiments is merely exemplary in nature and is not intended to limit the invention, its application, or its uses.

1 is a diagram showing a refrigerant circuit configuration of an air conditioner in an embodiment of the present invention. As shown in Fig. 1, the refrigerant circuit 1 includes a compressor 7 as a compressor, a cross switching valve 9 as a refrigerant control means, an outdoor heat exchanger 3, an expansion valve 11 as an expansion mechanism, and an indoor heat exchanger. (5) is connected in order to form a closed circuit. The refrigerant circuit 1 is filled with a refrigerant, and the refrigerant is circulated to perform a vapor compression freezing cycle. Here, the four-way switch 9 is provided with first to fourth ports 9a, 9b, 9c, 9d to which pipes of the refrigerant circuit 1 can be connected.

In addition, the indoor heat exchanger (5) includes a classifier (13) for reducing the refrigerant condensed in the outdoor heat exchanger (3) in the cooling operation and branching the refrigerant to the respective refrigerant paths of the indoor heat exchanger (5), and the indoor heat exchanger ( The combiner 15 for reflowing the refrigerant evaporated in the plurality of refrigerant paths of 5) and introducing the refrigerant into the outdoor heat exchanger 3 is connected.

In this refrigerant circuit 1, the discharge port of the compressor 7 is connected to the first port 9a of the crossover valve 9. The third port 9c of the four-way valve 9 is connected to one end of the outdoor heat exchanger 3. The other end of the outdoor heat exchanger 3 is connected to one end of the indoor heat exchanger 5 via an expansion valve 11. The other end of the indoor heat exchanger 5 is connected to the fourth port 9d of the crossover valve 9. The second port 9b of the four-way valve 9 is connected to the inlet port of the compressor 7.

The cross switching valve 9 is in a state in which the first port 9a and the third port 9c communicate with each other, and the second port 9b and the fourth port 9d communicate with each other (Fig. 1 (a)). ) And a state in which the first port 9a and the fourth port 9d communicate with each other, and the second port 9b and the third port 9c communicate with each other (state shown in FIG. 1B). Is freely configured to switch.

That is, the four-way switching valve (9), by changing the refrigerant circulation direction in the refrigerant circuit 1, condenses the refrigerant of the outdoor heat exchanger (3) and at the same time evaporates the refrigerant of the indoor heat exchanger (5), The state which condenses the refrigerant | coolant of the indoor heat exchanger 5 while evaporating the refrigerant | coolant of the outdoor heat exchanger 3 is comprised so that switching is possible.

2 is a schematic view showing the internal structure of the indoor unit of the air conditioner according to the present embodiment. 2, the indoor unit is equipped with an indoor heat exchanger (5), a blower (21) for blowing and heat-exchanging indoor air by the indoor heat exchanger (5), and an indoor heat exchanger (5). Drain pan 22 for storing the condensate generated in the c), the drain pump 23 for draining the condensate stored in the drain pan 22, and the water level for detecting that the condensate stored in the drain pan 22 has reached a predetermined level The floating switch 24 as a detection means is provided.

The indoor heat exchanger (5) has a plurality of refrigerant paths formed of a plurality of heat transfer tubes (6) disposed at predetermined intervals. Specifically, in the present embodiment, 24 heat transfer tubes 6 are arranged, and 11 coolant paths are formed by connecting end portions of the plurality of heat transfer tubes 6 with U-shaped tubes (see FIG. 3). 2 and 3 show the arrows in the refrigerant circulation direction during the cooling operation.

The refrigerant classified in the classifier 13 flows into each of the plurality of refrigerant paths. Then, the refrigerant flowing out from each of the plurality of refrigerant paths is configured to be introduced into the outdoor heat exchanger 3 after joining in the combiner 15.

Here, only the lowermost path arrangement is different for the plurality of refrigerant paths, and the path arrangement of the other refrigerant paths is the same. Specifically, the lowermost refrigerant path is formed of four heat transfer tubes 6, and refrigerant flows from the lowermost upstream side heat exchanger tube 6 of the indoor heat exchanger 5, and the lowermost side of the downstream side and the downstream side side of the downstream side heat exchanger tube 6 are introduced. The 2nd stage heat exchanger tube 6 is flowed in order, and is piping so that a refrigerant | coolant may flow out from the said 2nd stage heat exchanger tube 6 of the said stream side.

On the other hand, the other refrigerant path except for the lowermost refrigerant path is formed of two heat pipes (6), the refrigerant flows in the upstream heat transfer pipe (6) and is piped so that the refrigerant flows out of the downstream heat transfer pipe (6).

Here, in the heating operation, the circulation direction of the refrigerant with respect to the refrigerant path of the indoor heat exchanger 5 is configured in the reverse direction as in the cooling operation. That is, in the lowermost refrigerant path, the refrigerant flows in from the second side heat transfer pipe 6 on the upstream side of the indoor heat exchanger 5, and the second stage on the downstream side and the lowest heat transfer pipe 6 on the downstream side in turn. It distribute | circulates and it is comprised so that refrigerant | coolant may flow out from the said lowermost heat exchanger tube 6 of the said stream.

On the other hand, in the other refrigerant paths except for the lowermost refrigerant path, the refrigerant flows in from the downstream side heat transfer pipe 6 and flows out of the coolant layer heat transfer pipe 6.

The floating switch 24 detects that the condensate stored in the drain pan 22 has reached a predetermined level lower than that of the heat transfer pipe 6 on the outlet side. Specifically, the predetermined level is at the bottom of the indoor heat exchanger 5. It is a water level lower than the height position of the upstream side heat exchanger tube 6 of a 2nd stage.

The drain pump 23 is configured to drain the condensed water in the drain pan 22 based on the detection result of the floating switch 24. As a result, the outlet heat transfer pipe 6 in the lowermost refrigerant path is prevented from being submerged, which is advantageous for securing the heat exchange rate.

As described above, according to the air conditioner according to the embodiment of the present invention, the number of turns of the heat transfer tube 6 is increased, the heat exchange capacity of the lowermost refrigerant path of the heat exchanger 5 is increased, and the evaporation as the heat exchanger 5 is increased. It is advantageous to suppress the deterioration of capability. Moreover, since the heat exchanger tube 6 which is the exit side of a refrigerant | coolant is arrange | positioned in the upper stream side of a 2nd stage from the lower part of the heat exchanger 5, the fall of the heat exchange rate by the condensate stored by the drain pan 22 is suppressed to the minimum. can do.

In addition, since the condensate is drained before the condensate stored in the drain pan 22 reaches the outlet side heat transfer pipe 6, the outlet side heat transfer pipe 6 of the refrigerant path is not submerged in the condensate water. A part can be prevented from being used for heat exchange with condensate, and the fall of heat exchange rate can be suppressed.

In addition, the floating switch 24 detects that the condensate stored in the drain pan 22 has reached a predetermined level lower than that of the outlet side heat transfer pipe 6, and the condensed water is discharged by the drain pump 23 based on the detection result. In order to prevent the coolant path from sinking, the drain pump 23, which has always been operated regardless of the condensate level, can be operated intermittently based on the condensate level, thereby reducing power consumption.

As described above, the present invention is useful in minimizing the decrease in the heat exchange rate caused by condensate generated during the cooling operation.

Claims (3)

A heat exchanger (5) having a plurality of refrigerant paths formed of a plurality of heat transfer tubes (6) arranged at predetermined intervals; A blower 21 for blowing heat by blowing indoor air into the heat exchanger 5, In the air conditioner having a drain pan 22 for storing the condensate generated in the heat exchanger (5), Among the plurality of refrigerant paths, the lowermost refrigerant path distributes the refrigerant through the heat transfer pipes 6 located on the upstream side and the downstream side of the air blown by the blower 21 during the cooling operation. An air conditioning apparatus, characterized in that the pipe is arranged to allow the refrigerant to flow out of the heat transfer pipe (6) at the lowermost side of the heat exchanger (5) or more and located at the upstream side. The method of claim 1, A drain pump 23 for draining the condensed water stored in the drain pan 22, The drain pump (23) is configured to drain the condensate until the condensate stored in the drain pan (22) reaches the outlet side heat transfer pipe (6). The method of claim 1, A drain pump 23 for draining the condensed water stored in the drain pan 22; It is provided with a water level detecting means 24 for detecting that the condensed water stored in the drain pan 22 has reached a predetermined level lower than the outlet side heat transfer pipe (6), The drain pump (23) is configured to drain the condensed water based on a detection result of the water level detecting means (24).

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