JP2022001798A - Air conditioner - Google Patents

Abstract

To prolong adhesion time of water as the whole condenser.SOLUTION: In an air conditioner where a refrigerant circulates in a compressor, a radiator 10 and an evaporator 12 in this order, when dew condensation water from the evaporator 12 falls in a plane region of a fin 101 of the radiator 10 of the air conditioner, the dew condensation water is hard to flow down since the plane region of the fin 101 faces upward and stays on the fin 101 for a long time, and the evaporation amount of the dew condensation water increases. A lower end of the evaporator is positioned at a position higher than a lower end of the radiator.SELECTED DRAWING: Figure 6

Description

The present invention relates to an air conditioner in which a refrigerant circuit is housed in one casing.

In recent years, an air conditioner configured to reduce the amount of water stored in a water storage tank by sprinkling condensed water generated in an evaporator on a condenser to evaporate it has become widespread. For example, in the air conditioner described in Patent Document 1 (Japanese Unexamined Patent Publication No. 58-35343), a slit that meanders in the vertical direction is provided with respect to the fins, and dew condensation water adheres to the fin surface of the condenser due to surface tension. The time is lengthened to increase the amount of condensation water evaporation.

However, even in the above-mentioned condenser, the water adhesion time is short in the place where there is no slit, so that it is a problem to lengthen the water adhesion time in the condenser as a whole.

The air conditioner of the first aspect is an air conditioner that circulates a refrigerant in the order of a compressor, a radiator, and an evaporator, and includes a fan and a casing. The fan creates a flow of air through the radiator and evaporator. The casing houses the compressor, radiator, evaporator and fan. The radiator has a heat radiating member. The heat radiating member is arranged so that the plane area for heat radiating faces upward. The lower end of the evaporator is located higher than the lower end of the radiator.

In this air conditioner, when the dew condensation water from the evaporator falls on the flat area of the radiator member of the radiator, the dew condensation water does not easily flow down because the flat area faces upward, and stays on the heat dissipation member for a long time. The amount of evaporation increases.

The air conditioner of the second aspect is the air conditioner of the first aspect, and the projected regions of the evaporator and the radiator overlap at least a part in a plan view from vertically above the evaporator.

The air conditioner of the third aspect is the air conditioner of the second aspect, and further includes a water conveyance section. The water guide section guides the dew condensation water to the windward side of the radiator.

In this air conditioner, dew condensation water can be guided from the windward side of the radiator to the flat area of the heat dissipation member, and the water is pushed by the wind of the fan and diffuses the flat area from the windward side to the leeward side, so that the evaporation efficiency Is good.

The air conditioner of the fourth aspect is the air conditioner of the third aspect, and further includes a water receiving member (60) that receives the dew condensation water generated by the evaporator. A water guiding portion is provided on the water receiving member.

In this air conditioner, the presence of the water receiving member allows dew condensation water falling from the evaporator to be accumulated and flowed to the headrace.

The air conditioner of the fifth aspect is the air conditioner of the fourth aspect, and the water receiving member is provided with an extension portion. The extension extends horizontally or diagonally upward toward the leeward side of the evaporator.

In this air conditioner, even if the dew condensation water generated in the evaporator is scattered to the leeward side by the wind of the fan, it can be captured by the expansion part.

The air conditioner according to the sixth aspect is any one of the air conditioners according to the first aspect to the fifth aspect, and the radiator is a fin-and-tube type heat having a plurality of fins and a plurality of heat transfer tubes. It is an exchanger. The plurality of fins are arranged so as to be stacked vertically at intervals. The plurality of heat transfer tubes penetrate the plurality of fins in the thickness direction. The heat dissipation member is a fin.

In this air conditioner, the fins, which are heat dissipation members, are arranged in parallel at intervals in the vertical direction, so that the dew condensation water guided from the evaporator onto the fins does not easily flow down and stays on the heat dissipation member for a long time, causing dew condensation. The amount of water evaporation increases.

The air conditioner according to the seventh aspect is an air conditioner according to any one of the first aspect to the fifth aspect, and the radiator is a heat exchanger having a plurality of flat tubes and fins. A plurality of flat tubes are arranged so as to be stacked vertically at intervals. The fins are sandwiched between adjacent flat tubes. The heat dissipation member is a flat tube.

In this air conditioner, the flat tubes, which are heat dissipation members, are arranged in parallel at intervals in the vertical direction, so that the dew condensation water guided from the evaporator onto the flat tubes does not easily flow down and stays on the heat dissipation members for a long time. , The amount of condensation water evaporation increases.

The air conditioner according to the eighth aspect is the air conditioner according to any one of the first aspect to the fifth aspect, and the evaporator has a heat transfer member. In the heat transfer member, a plane region for heat transfer extends in the vertical direction.

In this air conditioner, since the planar region of the evaporator (for example, the fin surface) extends in the vertical direction, the dew condensation water generated in the evaporator is difficult to stay and can be easily dropped.

The refrigerant circuit diagram of the air conditioner of one Embodiment of this disclosure. Perspective view of the air conditioner. FIG. 3 is a perspective view of an air conditioner when the second side surface and the third side surface of the casing are arranged so as to be on the front side. A plan view of an air conditioner when viewed from directly above by arranging the second side surface so as to be on the front side. The perspective view which shows the positional relationship of a radiator, an evaporator and a fan. FIG. 5 is a perspective view of the radiator, evaporator and fan of FIG. 5 when viewed from different angles. Perspective view of the water receiving member. FIG. 3 is a perspective view of the water receiving member of FIG. 7 when viewed from below. FIG. 3 is a partial cross-sectional view of an air conditioner cut in the virtual plane F1 shown in FIG. FIG. 3 is a partial cross-sectional view of an air conditioner cut in the virtual plane F2 shown in FIG. Perspective view of the first ventilation passage and the second ventilation passage. The perspective view of the radiator used in the modification of this embodiment.

(1) Configuration of Air Conditioning Device 100 FIG. 1 is a refrigerant circuit diagram of the air conditioning device 100 according to the embodiment of the present disclosure. In FIG. 1, the air conditioner 100 has a refrigerant circuit in which a refrigerant circulates in the order of a compressor 9, a radiator 10, an expansion valve 11, and an evaporator 12.

The radiator 10 and the evaporator 12 are both fin-and-tube heat exchangers. The casing 20 houses the compressor 9, the radiator 10, the expansion valve 11, and the evaporator 12. Further, the casing 20 also houses a fan 13 and an electrical component 50 (see FIGS. 3 and 4) that controls the compressor 9 and the fan 13.

In this embodiment, the fan 13 is a cross-flow fan, which is arranged on the windward side of the radiator 10 and the evaporator 12 to generate a flow of air passing through the radiator 10 and the evaporator 12.

(2) Details of each part of the air conditioner 100 FIG. 2 is a perspective view of the air conditioner 100. In FIG. 2, the casing 20 has a rectangular parallelepiped shape having a substantially rectangular horizontal cross section, and is arranged so that the longitudinal direction is the vertical direction.

(2-1) Casing 20
As shown in FIG. 2, the casing 20 has a first side wall 21, a second side wall 22, a third side wall 23, and a fourth side wall 24. Further, it further has a bottom plate 29 (see FIG. 3) and a top plate 30. The casing 20 is an embodiment in which the openings at both ends of the cylinder formed by the first side wall 21, the second side wall 22, the third side wall 23, and the fourth side wall 24 are closed by the bottom plate 29 and the top plate 30.

Further, in FIG. 2, as for the four corners formed by the four side walls, the one formed between the first side wall 21 and the fourth side wall 24 is referred to as the first corner 25, and the fourth corner is clockwise from there. The second corner 26, the third corner 27, and the fourth corner 28.

The casing 20 is provided with a first suction port 5, a second suction port 6, a first outlet 7, and a second outlet 8. The first suction port 5 and the first outlet 7 are formed on the first side wall 21. The second suction port 6 is formed on the fourth side wall 24. The second outlet 8 is formed on the second side wall 22.

Further, below the second side wall 22, a water storage tank mounting port 22a for attaching / detaching the water storage tank 80 is formed. The water storage tank 80 stores the dew condensation water generated inside the air conditioner 100.

The top plate 30 is provided with an operation panel 301 and a handle 303. The operation panel 301 includes switches for performing various operations such as starting / stopping the air conditioner 100. The operation panel 301 is provided so as to be located on the front side when the user confronts the second outlet 8.

FIG. 3 is a perspective view of the air conditioner 100 when the second side wall 22 and the third side wall 23 of the casing 20 are arranged so as to be on the front side. Further, FIG. 4 is a plan view of the air conditioner 100 when the second side wall 22 is arranged so as to be on the front side and viewed from directly above.

In FIGS. 3 and 4, the casing 20 is indicated by a two-dot chain line showing only the outline. As shown in FIGS. 3 and 4, the compressor 9 and the fan 13 are arranged on the fourth side wall 24 side of the virtual central axis that vertically penetrates the casing 20. Since these are heavier than other devices, the position of the center of gravity is biased toward the fourth side wall 24 side from the central axis.

Therefore, as shown in FIG. 2, the handle 303 is provided at a position biased toward the fourth side wall 24 from the center of the top plate 30 so as not to tilt when the handle 303 is grasped and the air conditioner 100 is lifted. ing.

Further, as shown in FIG. 2, the handle 303 is provided on a flat surface recessed from the surface of the other portion of the top plate 30, and the handle 303 is to the extent that a human finger can enter when the handle 303 is grasped and lifted. It is configured so that there is a gap.

(2-2) Heat sink 10, evaporator 12, and fan 13
FIG. 5 is a perspective view showing the positional relationship between the radiator 10, the evaporator 12, and the fan 13. Further, FIG. 6 is a perspective view of the radiator 10, the evaporator 12, and the fan 13 of FIG. 5 when viewed from different angles.

In FIG. 5, the radiator 10 and the evaporator 12 are fin-and-tube heat exchangers. The evaporator 12 is located above the radiator 10 and is arranged so that the projected portions of the evaporator 12 and the radiator 10 overlap each other when viewed from vertically above the evaporator 12.

(2-2-1) Heat sink 10
The radiator 10 has a plurality of fins 101 arranged so as to be stacked at intervals in the vertical direction, and a plurality of heat transfer tubes 103 penetrating the plurality of fins 101 in the thickness direction. The heat transfer tubes 103 are configured to form three rows in the air flow direction.

The dew condensation water generated by the evaporator 12 is guided onto the fin 101, but since the planar region of the fin 101 faces upward, the dew condensation water does not easily flow down and stays on the fin 101 for a long time.

Therefore, as compared with the case where the plane region of the fin is arranged parallel to the vertical direction, the amount of dew condensation water evaporated is large, and the amount of dew condensation water accumulated in the water storage tank 80 can be reduced accordingly.

(2-2-2) Evaporator 12
The evaporator 12 has a plurality of fins 121 arranged so as to be stacked at intervals in the horizontal direction, and a plurality of heat transfer tubes 123 penetrating the plurality of fins 121 in the thickness direction. The heat transfer tubes 123 are configured to form two rows in the air flow direction.

Since the plane region of the fin 121 extends in the vertical direction, the dew condensation water generated in the evaporator 12 is difficult to stay and can easily fall.

(2-2-3) Fan 13
The fan 13 has a fan rotor 13a, a fan rotor 13b, and a fan motor 13c. In the present embodiment, the fan rotor 13a and the fan rotor 13b are one fan rotor integrally formed, but for convenience of explanation, the radiator 10 side portion of the fan rotor is the fan rotor 13a and the evaporator 12 side portion. It is distinguished from the fan rotor 13b.

The fan motor 13c is fixed on the bottom plate 29, and the rotating shaft of the fan motor 13c is connected to the fan rotor 13a.

The fan rotor 13a is located at a position facing the radiator 10 and pushes air toward the radiator 10. The fan rotor 13b is located at a position facing the evaporator 12 and pushes air toward the evaporator 12.

As described above, since the fan 13 is arranged on the windward side of the radiator 10 and the evaporator 12, there is an advantage that at least the suction port of the air flowing through the radiator 10 and the evaporator 12 can be shared.

(2-3) Water receiving member 60
As shown in FIGS. 5 and 6, a water receiving member 60 is provided between the radiator 10 and the evaporator 12. FIG. 7 is a perspective view of the water receiving member 60. In FIGS. 5, 6 and 7, the water receiving member 60 forms a container by the water receiving plate 600, the first side plate 601 and the second side plate 602.

(2-3-1) Water receiving plate 600
As shown in FIG. 7, the water receiving plate 600 has a water receiving surface 60a. The water receiving surface 60a includes a first water receiving surface 60aa, a second water receiving surface 60ab, and a third water receiving surface 60ac.

(2-3-1-1) First water receiving surface 60aa
The first water receiving surface 60aa is inclined so that the height position becomes higher toward the leeward side of the air flow, and the dew condensation water that has fallen on the water receiving surface 60a flows to the leeward side.

(2-3-1-2) Second water receiving surface 60ab
The second water receiving surface 60ab is a triangular region pqr formed on the windward side of the first water receiving surface 60aa and on the right side of the drain hole 60ad when viewed from the evaporator 12 side. The second water receiving surface 60ab has three vertices p, q, r, and the short side pq of the three sides of the triangular region pqr also serves as a part of the right end of the water receiving surface 60a, and the rest. The side pr and the side q-r extend to the left while being close to each other, and the apex r is formed so as to join the drain hole 60ad. The side qr is a boundary line between the first water receiving surface 60aa and the second water receiving surface 60ab.

Since the height position of the side p-q is set higher than that of the apex r, the height position of the side p-r and the side q-r becomes lower as it approaches the apex r.

The second water receiving surface 60ab is formed with a relief region 60ab'removed on an arc in order to avoid interference with a part of the shape of the evaporator 12, and this relief region 60ab'is also a drainage hole. It is molded so that the height position becomes lower as it approaches 60ad.

(2-3-1-3) Third water receiving surface 60ac
The third water receiving surface 60ac is a triangular region xyz formed on the windward side of the first water receiving surface 60aa and on the left side of the drain hole 60ad when viewed from the evaporator 12 side. The third water receiving surface 60ac has three vertices x, y, z, and the short side xy of the three sides of the triangular region xyz also serves as a part of the left end of the water receiving surface 60a, and the rest. The apex z is formed so that the side x-z and the side y-z extend to the right while being close to each other and merge with the drain hole 60ad. The side yz is a boundary line between the first water receiving surface 60aa and the third water receiving surface 60ac.

Since the height position of the side xy is set higher than that of the apex z, the height positions of the side yz and the side xx become lower as they approach the apex z.

(2-3-1-4) Drain hole 60ad
The drain hole 60ad is provided so as to penetrate the water receiving plate 600 after forming a portion of the water receiving surface 60a having the lowest height position. As shown in FIGS. 6 and 7, the water drain hole 60ad is provided on the left side of the center of the water receiving member 60 when viewed from the fan 13 side.

(2-3-2) First side plate 601
The first side plate 601 stands vertically from the left end of the water receiving plate 600 when viewed from the evaporator 12 side. The first side plate 601 has a function of blocking the dew condensation water that has fallen on the water receiving surface 60a so as not to overflow from the left side.

A similar side plate may be provided on the side opposite to the first side plate 601 with the water receiving surface 60a interposed therebetween. However, in the present embodiment, since the evaporator 12 can be inserted from the side, the side facing the first side plate 601 is open.

(2-3-3) Second side plate 602
The second side plate 602 stands vertically upward from the windward end of the water receiving plate 600 when viewed from the fan 13 side. When viewed from the fan 13 side, the windward end of the first side plate 601 and the left end of the second side plate 602 are connected. The second side plate 602 has a function of blocking the dew condensation water flowing on the windward side along the inclination of the water receiving surface 60a on the windward side of the water receiving surface 60a.

(2-3-4) Water guide unit 61
FIG. 8 is a perspective view of the water receiving member 60 of FIG. 7 when viewed from below. In FIG. 8, the water guide portion 61 is a water channel extending downward from the portion where the height position of the water receiving surface 60a is the lowest. The water guide portion 61 has a cylindrical shape, and the hollow portion thereof is connected to a drain hole 60ad (see FIG. 7) of the water receiving plate 600. As shown in FIG. 6, the tip of the water guide portion 61 is located on the windward side of the radiator 10, and the tip extends from the top of the radiator 10 to the height position of the plurality of fins 101.

The tip portion 61a of the water guide portion 61 is formed into a smooth arc shape that approaches the radiator 10 toward the lower side. The cross-sectional shape of the tip portion 61a is concave, and the concave shape is open toward the fin 101 of the radiator 10 with the bottom facing upwind. Therefore, the dew condensation water is guided to the fin 101 of the radiator 10 by the water guide portion 61.

As shown in FIGS. 6 and 8, the water drain hole 60ad of the water guide portion 61 and the water receiving plate 600 is provided on the left side of the center of the water receiving member 60 when viewed from the fan 13 side. It is desirable that the water guide portion 61 is arranged in a place where wind resistance is unlikely to occur (for example, a place where the wind speed is low).

(2-3-5) Expansion unit 62
The water receiving member 60 further has an expansion portion 62. As shown in FIG. 6, the expansion portion 62 extends further toward the leeward side from the leeward end of the water receiving plate 600. The expansion portion 62 has an expansion surface 62a, and the expansion surface 62a extends substantially horizontally from the leeward end of the water receiving surface 60a toward the leeward side.

Further, the expansion portion 62 also functions as a partition member that vertically separates the first ventilation passage 18 through which the air passing through the radiator 10 passes and the second ventilation passage 19 through which the air passing through the evaporator 12 passes.

(2-3-6) Rib 63
As shown in FIGS. 5 and 7, two ribs 63 are provided on the water receiving member 60. The rib 63 extends from the water receiving surface 60a toward the tip of the expansion surface 62a when viewed from the evaporator 12 side. The two ribs 63 are parallel to each other, and the distance between them is larger than the width of the evaporator 12 excluding the heat transfer tube 123.

For convenience of explanation, the rib 63 on the left side is referred to as a first rib 631 and the rib 63 on the right side is referred to as a second rib 632 when viewed from the evaporator 12. The first rib 631 is provided with a groove 631a extending in the longitudinal direction. Similarly, the second rib 632 is provided with a groove 632a extending in the longitudinal direction. The members of the second ventilation passage 19 on the evaporator 12 side are fitted into the grooves 631a and 632a.

(2-3-7) Fan side guide plate 64
As shown in FIGS. 6 and 7, the fan side guide plate 64 is a plate extending from the second side plate 602 toward the fan 13. The fan side guide plate 64 has an arc end 64a along the outer periphery of the fan rotor 13a or the fan rotor 13b, and the arc end 64a is close to the fan rotor 13a or the fan rotor 13b.

The fan side guide plate 64 divides the air blown out from the fan 13 into the radiator 10 side and the evaporator 12. In the present embodiment, the fan-side guide plate 64 is tilted diagonally upward toward the fan 13. This is because the ventilation resistance of the radiator 10 is larger than that of the evaporator 12, so that more air is pushed into the radiator 10 than that of the evaporator 12.

(2-4) Water storage tank 80
As shown in FIGS. 5 and 6, the water storage tank 80 is arranged below the radiator 10, and the radiator 10 receives and stores the dew condensation water that has fallen without being completely evaporated. Therefore, the upper lid 81 of the water storage tank 80 is formed with a concave surface 81a whose height position is lowered toward the center, and the central portion of the concave surface 81a is provided with a through hole 81b.

The dew condensation water that has fallen on the concave surface 81a of the upper lid 81 collects in the center and enters the water storage tank 80 through the through hole 81b.

(3) Path of air passing through the radiator 10 FIG. 9A is a partial cross-sectional view of the air conditioner 100 cut in the virtual plane F1 shown in FIG. In FIG. 9A, the fan rotor 13a of the fan 13 is arranged in a space close to the first corner 25 formed by the first side wall 21 and the fourth side wall 24 with the rotation axis directed in the vertical direction. When the fan rotor 13a rotates, the air outside the casing 20 is sucked from the first suction port 5 and the second suction port 6.

(3-1) First diffuser 15a
The first diffuser 15a diffuses the air introduced by the fan rotor 13a toward the radiator 10 arranged on the downstream side of the air flow. The maximum width of the first diffuser 15a is set to correspond to the width of the radiator 10 when viewed from the rotation axis direction of the fan rotor 13a. The first diffuser 15a is made of a foam material for weight reduction.

(3-2) First scroll 16a
The first scroll 16a is located on the windward side of the first diffuser 15a, and extends from the outer periphery of the fan rotor 13a while being curved so as to gradually move away in the centrifugal direction, and is connected to the first diffuser 15a. The first scroll 16a is made of a foam material for weight reduction.

(3-3) First tongue portion 17a
The first tongue portion 17a is located on the windward side of the first diffuser 15a, and is located at a position different from that of the first scroll 16a. It is connected to the diffuser 15a. The first tongue portion 17a is made of a foam material for weight reduction.

(3-4) First ventilation path 18
FIG. 10 is a perspective view of the first ventilation passage 18 and the second ventilation passage 19. In FIG. 10, the first ventilation passage 18 is located on the leeward side of the radiator 10 and below the water receiving member 60. The first ventilation passage 18 has an arc-shaped polarizing plate 181 and a guide plate 182 extending straight from the end of the polarizing plate 181. When the guide plate 182 is arranged so as to face the radiator 10, the polarizing plate 181 becomes a wall connecting one end of the radiator 10 and one end of the guide plate 182.

Therefore, as shown in FIG. 9A, the first ventilation passage 18 extends toward the second side wall 22 and then gradually turns toward the first side wall 21 and finally turns approximately 90 ° to the second. 1 It is connected to the first outlet 7 of the side wall 21. The first ventilation passage 18 is made of resin.

(4) Path of air passing through the evaporator 12 FIG. 9B is a partial cross-sectional view of the air conditioner 100 cut in the virtual plane F2 shown in FIG. In FIG. 9B, the fan rotor 13b of the fan 13 is arranged in a space close to the first corner 25 formed by the first side wall 21 and the fourth side wall 24 with the rotation axis directed in the vertical direction. When the fan rotor 13b rotates, the air outside the casing 20 is sucked from the first suction port 5 and the second suction port 6.

(4-1) Second diffuser 15b
The second diffuser 15b diffuses the air introduced by the fan rotor 13b toward the evaporator 12 located on the downstream side of the air flow. The maximum width of the second diffuser 15b when viewed from the rotation axis direction of the fan rotor 13b is set to correspond to the width of the evaporator 12. The second diffuser 15b is made of a foam material for weight reduction.

(4-2) Second scroll 16b
The second scroll 16b is located on the windward side of the second diffuser 15b, and extends from the outer periphery of the fan rotor 13b while being curved so as to gradually move away from the outer circumference in the centrifugal direction, and is connected to the second diffuser 15b. The second scroll 16b is made of a foam material for weight reduction.

In the present embodiment, the first scroll 16a and the second scroll 16b are integrally molded, and the first scroll 16a and the second scroll 16b are at the same position when viewed from the rotation axis direction of the fan 13. Blower efficiency is improved by the configuration.

However, even if the first scroll 16a and the second scroll 16b are separately molded, the deviation between the first scroll 16a and the second scroll 16b is the central angle when viewed from the rotation axis direction of the fan 13. If it is within 5 °, the same ventilation efficiency can be obtained.

(4-3) Second tongue 17b
The second tongue portion 17b is located on the windward side of the second diffuser 15b, and at a position different from that of the second scroll 16b, the second tongue portion 17b warps from the end of the wall closest to the outer circumference of the fan rotor 13b. It is connected to the diffuser 15b. The second tongue portion 17b is made of a foam material for weight reduction.

In the present embodiment, the first tongue portion 17a and the second tongue portion 17b are integrally molded, and the first tongue portion 17a and the second tongue portion 17b are at the same position when viewed from the rotation axis direction of the fan 13. This configuration improves the ventilation efficiency.

However, even if the first tongue portion 17a and the second tongue portion 17b are separately molded, the deviation between the first tongue portion 17a and the second tongue portion 17b when viewed from the rotation axis direction of the fan 13. If the central angle is within 5 °, the same ventilation efficiency can be obtained.

(4-4) Second ventilation passage 19
As shown in FIG. 10, the second ventilation passage 19 is located on the leeward side of the evaporator 12 and above the water receiving member 60. The second ventilation passage 19 has a first vertical plate 191 and a second vertical plate 192, and a horizontal plate 193 connecting the upper ends of the two vertical plates.

The lower end of the first vertical plate 191 is fitted in the groove 631a of the first rib 631 of the water receiving member 60. Further, the lower end of the second vertical plate 192 is fitted in the groove 632a of the second rib 632 of the water receiving member 60.

Therefore, the second ventilation passage 19 is a space that extends straight and is surrounded by the water receiving member 60, the first vertical plate 191 and the second vertical plate 192, and the horizontal plate 193. Therefore, as shown in FIG. 9B, the second ventilation passage 19 extends toward the second side wall 22 and connects to the second outlet 8 of the second side wall 22. The second ventilation passage 19 is made of a foam material for weight reduction.

(5) Features (5-1)
In the air conditioner 100, when the dew condensation water from the evaporator 12 falls on the flat region of the fin 101 of the radiator 10, the flat region of the fin 101 faces upward, so that the dew condensation water does not easily flow down and stays on the fin 101 for a long time. It stays and the amount of condensation water evaporates increases.

(5-2)
In the air conditioner 100, the projection regions of the evaporator 12 and the radiator 10 overlap at least a part in a plan view from vertically above the evaporator 12.

(5-3)
Further, since the water guide portion 61 is provided between the evaporator 12 and the radiator 10, the condensed water can be guided from the windward side of the radiator 10 to the flat region of the fin 101, and the water is the fan 13. Since it is pushed by the wind and diffuses the plane area from the windward side to the leeward side, the evaporation efficiency is good.

(5-4)
The air conditioner 100 further includes a water receiving member 60 that receives the dew condensation water generated by the evaporator 12, and the water receiving member 60 is provided with a water guiding portion 61. Therefore, the water receiving member 60 can collect the dew condensation water falling from the evaporator 12 and flow it to the water guiding unit 61.

(5-5)
Further, the water receiving member 60 has an expansion portion 62. The expansion portion 62 extends substantially horizontally toward the leeward side of the evaporator 12.

(5-6)
In the air conditioner 100, the radiator 10 is a fin-and-tube heat exchanger, and a plurality of fins are arranged so as to be stacked at intervals in the vertical direction. The dew condensation water guided from the evaporator 12 onto the fins 101 does not easily flow down and stays on the fins 101 for a long time, and the amount of dew condensation water evaporated increases.

(5-7)
In the air conditioner 100, since the plane region of the fin 121 of the evaporator 12 extends in the vertical direction, the dew condensation water generated in the evaporator 12 does not easily stay and can easily fall.

(6) Modification Example In the above embodiment, a fin-and-tube heat exchanger is used as the radiator, but the present invention is not limited to this. For example, the radiator 10 may be a heat exchanger having a plurality of flat tubes and fins.

FIG. 11 is a perspective view of the radiator 10 used in the modified example of the present embodiment. In FIG. 11, the radiator 10 has a flat tube 113, a corrugated fin 115, and a header 151. The flat tube 113 is formed of aluminum or an aluminum alloy, and has a flat region serving as a heat dissipation surface and a plurality of refrigerant flow paths (not shown) through which the refrigerant flows. As shown in FIG. 11, the flat tubes 113 are arranged in a plurality of stages with the plane region facing up and down.

The corrugated fin 115 is a fin made of aluminum or an aluminum alloy that is bent into a corrugated shape. As shown in FIG. 11, the corrugated fins 115 are arranged in a ventilation space sandwiched between vertically adjacent flat pipes 113, and the valleys and peaks are in contact with the plane region of the flat pipes 113. The valley portion, the mountain portion, and the plane region are brazed and welded.

In FIG. 11, the header 151 is connected to both ends of the flat tubes 113 arranged in a plurality of stages in the vertical direction. The header 151 has a function of supporting the flat pipe 113, a function of guiding the refrigerant to the refrigerant flow path of the flat pipe 113, and a function of collecting the refrigerant discharged from the refrigerant flow path.

In such a radiator 10, since the flat tubes 113 are arranged in parallel at intervals in the vertical direction, the dew condensation water guided from the evaporator 12 onto the flat tube 113 does not easily flow down and is long on the flat tube 113. The amount of condensation water evaporates increases.

Although the embodiments of the present disclosure have been described above, it will be understood that various modifications of the embodiments and details are possible without departing from the spirit and scope of the present disclosure described in the claims. ..

The contents of the present disclosure are useful for air conditioners or window air conditioners that perform local cooling or heating.

9 Compressor 10 Heat sink 12 Evaporator 13 Fan 20 Casing 60 Water receiving member 61 Water conducting part 62 Expansion part 100 Air conditioner 101 Fin (heat dissipation member)
103 Heat transfer tube 113 Flat tube (heat dissipation member)
115 Corrugated fins 121 fins (heat transfer member)

Japanese Unexamined Patent Publication No. 58-355343

Claims (8)

An air conditioner that circulates a refrigerant in the order of a compressor (9), a radiator (10), and an evaporator (12).
A fan (13) that creates a flow of air through the radiator (10) and the evaporator (12).
A casing (20) for accommodating the compressor (9), the radiator (10), the evaporator (12), and the fan (13).
Equipped with
The radiator (10) has a heat radiating member (101, 113) arranged so that a plane region for heat radiating faces upward.
The lower end of the evaporator (12) is arranged at a position higher than the lower end of the radiator (10).
Air conditioner (100). In a plan view from vertically above the evaporator (12), the projection regions of the evaporator (12) and the radiator (10) overlap at least in a part.
The air conditioner (100) according to claim 1. A water guide portion (61) for guiding the dew condensation water to the windward side of the radiator (10) is further provided.
The air conditioner according to claim 2. A water receiving member (60) that receives the dew condensation water generated by the evaporator (12) is further provided.
The water guiding portion (61) is provided on the water receiving member (60).
The air conditioner (100) according to claim 3. The water receiving member (60) is provided with an expansion portion (62) extending toward the leeward side of the evaporator (12).
The air conditioner (100) according to claim 4. The radiator (10) includes a plurality of fins (101) arranged so as to be stacked at intervals in the vertical direction, and a plurality of heat transfer tubes (103) penetrating the plurality of fins (101) in the thickness direction. A fin-and-tube heat exchanger with,
The heat radiating member is the fin (101).
The air conditioner (100) according to any one of claims 1 to 5. The radiator (10) has a plurality of flat tubes (113) arranged so as to be stacked at intervals in the vertical direction, and fins (115) sandwiched between adjacent flat tubes (113). It ’s a heat exchanger,
The heat radiating member is the flat tube (113).
The air conditioner (100) according to any one of claims 1 to 5. The evaporator (12) has a heat transfer member (121) in which a plane region for heat transfer extends in the vertical direction.
The air conditioner (100) according to any one of claims 1 to 5.

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