JP6634845B2 - Spacer for protective net attached to outdoor unit of air conditioner - Google Patents

Description

  The present invention relates to a spacer for maintaining a protection net attached to an outdoor unit of an air conditioner at a distance from a heat exchanger of the outdoor unit.

  Conventionally, an air conditioner including an indoor unit and an outdoor unit has been known.

The outdoor unit includes a compressor, an expansion valve, an accumulator, a fan, and a housing in which these members are housed.
Further, a part of the housing is constituted by a number of fins parallel to each other. Each fin is formed of, for example, a thin plate member that is long in the vertical direction. The width direction of each fin is parallel to the thickness direction of the side wall of the housing. Further, between the adjacent fins, there are formed a plurality of communication paths which are grooves penetrating the housing in the thickness direction thereof and communicating the inner space and the outer space of the housing. Further, a cooling tube is connected to each fin. The fins and the cooling tube constitute an outdoor heat exchanger.

  When the fan of the outdoor unit operates, the air in the outer space of the housing flows into the inner space through the communication passage of the outdoor heat exchanger, and is formed in a portion different from the communication passage of the housing (the outdoor heat exchanger). Flows out to the outer space from the opening. In this way, the airflow flowing between the inside and outside of the outdoor unit is formed by the operation of the fan.

  Further, for example, when the air-conditioning apparatus performs the cooling operation, the heat of the refrigerant in the cooling tube that constitutes the outdoor heat exchanger is radiated from the surface of the cooling tube and the surface of the fin that contacts the cooling tube. Therefore, the heat is discharged to the outside of the outdoor unit by the airflow formed by the fan.

By the way, generally, a protection net is attached to the surface of the outdoor unit so as to cover the surface of the outdoor heat exchanger (fin).
However, if the protection net is simply attached to the surface of the outdoor unit, the protection net moved by the wind or the vibration of the outdoor unit comes into contact with the outdoor heat exchanger (fin), and as a result, noise may be generated. .

Therefore, in Patent Literature 1, a resin clip engaged with the protection net is attached to the outdoor heat exchanger.
In Patent Document 1, the clip keeps the protection net in contact with the outdoor heat exchanger. Therefore, even if the wind blows or the outdoor unit vibrates, there is almost no possibility that noise is generated between the protection net and the outdoor heat exchanger.

  However, if rainwater or snow attached to the protection net freezes and blocks the holes formed in the protection net, less air flows from the outside space of the outdoor unit into the communication path of the outdoor heat exchanger when the fan is rotated. Or the air stops flowing. That is, for example, when the air conditioner performs the cooling operation, an effective cooling effect cannot be obtained.

Patent Document 2 discloses a means that can solve this problem.
Also in Patent Document 2, a resin clip (spacer) engaged with the protection net is attached to the outdoor heat exchanger.
However, in Patent Literature 2, the protection net is separated from the surface of the outdoor heat exchanger to the outside by the clip, and the separated state is maintained.
Therefore, even if the wind blows or the outdoor unit vibrates, there is almost no possibility that noise is generated between the protection net and the outdoor heat exchanger. Further, a gap is formed between the protection net and the surface of the outdoor heat exchanger. Therefore, even if rainwater or snow attached to the protective net freezes and blocks the hole of the protective net, if the fan is rotated, the air in the outside space of the outdoor unit will pass through the gap between the protective net and the outdoor heat exchanger. It is possible to flow into the communication passage of the heat exchanger. Therefore, for example, when the air conditioner performs a cooling operation, it is possible to obtain an effective cooling effect.

JP 2008-39300 A JP 2013-245882 A

(Problems to be solved by the invention)
When the clip of Patent Literature 2 is attached to the protection net and the outdoor heat exchanger, a part of the clip is located in the space between the protection net and the outdoor heat exchanger.
Therefore, if the clip is attached to the outdoor heat exchanger before attaching the protection net to the outdoor unit, and then the protection net is put on the outdoor unit and the clip is attached to the protection net, the clip and the protection net can be attached to the outdoor heat exchanger. It can be easily attached to

However, in some cases, the protective net must be attached to the outdoor heat exchanger before attaching the clip to the outdoor unit.
For example, as an example of a method for manufacturing an outdoor unit, first, a base portion of a housing including an outdoor heat exchanger is formed as a flat member, and a protective net is placed on the flat member. There is a type in which a flat member is formed into a housing made of a frame by bending an integrated product of a net with a bending machine. If you try to bend a flat member with a bending machine without putting a protective net on it, the end face of the fin that forms a part of the flat member will be caught by the bending machine, and the bending by the bending machine will be smooth. May not be performed. On the other hand, if the bending process is performed by the bending machine after the protection net is put on the flat member, there is no possibility that the end face of the fin is caught by the bending machine. Therefore, the possibility that the bending by the bending machine is not performed smoothly is reduced.
For this reason, after the protective net is put on the flat member, the housing may be manufactured by bending an integrated body of the flat member and the protective net by a bending machine.

  If this manufacturing method is adopted, if the protection net is put on the plate-shaped member after the clip is attached to the plate-shaped member and these integrated members are bent by a bending machine, the possibility of breakage of the clip increases. . Therefore, when this manufacturing method is adopted, it is necessary to attach the clip to the outdoor heat exchanger and the protection net after the housing is completed.

To attach the clip to the outdoor heat exchanger and the protective net after the enclosure is completed, insert a part of the clip into the hole of the protective net from outside the protective net, and then attach the clip to the outdoor heat exchanger and the protective net. Must be attached to a protective net.
However, when each hole formed in the protection net is small, it becomes difficult to insert a part of the clip of Patent Document 2 into the hole.
That is, when the width of the hole is smaller than the width of the clip, a part of the clip cannot be inserted into the hole of the protection net unless the clip is pushed into the hole with a strong force.

  The present invention, even when the hole formed in the protection net attached to the outdoor unit is small, can be attached to the heat exchanger and protection net of the outdoor unit through the hole formed in the protection net, Moreover, it is an object of the present invention to provide a spacer for a protection net mounted on an outdoor unit of an air conditioner capable of maintaining a state where the protection net is separated from the surface of the outdoor heat exchanger.

(Means for solving the problem)
The present invention relates to a protective net attached to an outdoor unit having a heat exchanger having a plurality of fins arranged in parallel with each other on a surface thereof, the heat exchanger constituting a part of an air conditioner and being arranged so as to cover the heat exchanger. A spacer which is insertable into two adjacent holes of the protective net and formed between two adjacent fins when inserted into the two adjacent holes. A pair of insertion legs that are press-fitted into the groove, and the groove of the insertion leg that is provided on each of the pair of insertion legs and that cannot be inserted into the groove and contacts an outer end of the fin. A pair of stoppers for restricting further press-fitting to the back side of the fin, and the protection provided when the stopper is located on the opposite side of the insertion leg portion across the stopper and the stopper contacts the outer end of the fin. The linear objects that make up the net Is input, the net support portion made of the through groove, may be provided with.

Each insertion leg of the spacer of the present invention is narrower than the entire spacer. Therefore, even if the holes formed in the protection net are small, each insertion leg can be easily inserted into two adjacent holes of the protection net. Therefore, even if the hole formed in the protection net is small, the spacer can be attached to the heat exchanger and the protection net of the outdoor unit through the hole formed in the protection net.
Further, the spacer is inserted by contacting a pair of insertion legs press-fitted into a groove formed between two adjacent fins and an outer end surface of the fin provided on each of the pair of insertion legs. A pair of stoppers for restricting further press-fitting into the depth side of the groove of the leg, and a through groove in which the linear body constituting the net is located on the opposite side of the insertion leg across the stopper and is inserted. And a net support portion. Therefore, when the spacer is attached to the heat exchanger and the protection net, the spacer keeps the protection net separated from the surface of the outdoor heat exchanger.

  A communication space that connects the gap formed between the pair of stoppers and the net support is formed, and an end that connects to the net support in the communication space when the spacer is in a free state. The width of a certain connection end portion is smaller than the outer diameter of the linear body of the protective net, and the width of the guide portion, which is a portion of the communication space adjacent to the connection end portion, is greater than the width of the connection end portion from the stopper side. It may be gradually narrowed toward the side.

According to this structure, when the spacer is mounted on the protective net, the linear body of the protective net can easily enter the net support portion formed of the through groove, and the linear body once in the net support portion communicates. It is difficult to escape to the space side.
That is, the attachment of the spacer to the protection net is facilitated, and the possibility that the protection net is unexpectedly dropped from the spacer is reduced.

  The heat exchanger includes a heat transfer fluid flow pipe which penetrates the plurality of fins in the direction in which the fins are arranged and through which heat transfer fluid flows, wherein the heat transfer fluid flow pipes extend linearly and are parallel to each other. Having a plurality of parallel portions, wherein the spacer is elastically deformable in a direction that supports a base end of the pair of the insertion legs and moves the pair of the insertion legs toward and away from each other. When the stopper comes into contact with the outer end of the fin, the base and a part of the two parallel parts adjacent to each other are formed when the stopper contacts the outer end of the fin. And concave portions located respectively.

According to this structure, when a force in the direction of causing the pair of insertion legs to escape from the groove formed between the two fins reaches the spacer, the distal end side of the recess of the pair of insertion legs. Is hooked on the parallel portion of the heat transfer fluid flow pipe.
Therefore, the possibility that the spacers suddenly fall out of the heat exchanger is reduced.

  Even if the distal end surfaces of the distal end portions of the pair of the insertion leg portions are opposed to each other when the spacer is in a free state and have an area larger than a cross-sectional area of a portion adjacent to the distal end portion of the insertion leg portion. Good.

When a force is applied to the spacer in a direction to cause the pair of insertion legs to escape from the groove formed between the two fins, the spacer is elastically deformed in a direction in which the pair of insertion legs approach each other.
However, when the present invention is configured in this way, the tip surfaces of the pair of insertion legs surely come into contact with each other at this time, and the approach of the pair of insertion legs is suppressed. That is, the possibility that the distance between the outer surfaces of the pair of insertion leg portions becomes shorter than the distance between the opposing surfaces of the two adjacent parallel portions is reduced.
Therefore, in such a case, the possibility that the spacers suddenly drop out of the heat exchanger is reduced.

  The spacer may be made of resin.

  With this configuration, it is possible to manufacture an elastically deformable spacer at low cost.

It is a front view of the outdoor unit in the state where the protection net of the air conditioner of one embodiment of the present invention was removed. It is a perspective view in the state where some protection nets of the upper case of the outdoor unit were removed. It is a vertical side view in the state where the protection net of the upper part of the outdoor unit was removed. It is a typical sectional view of the whole outdoor unit from which the protection net was removed. It is a perspective view of an outdoor heat exchanger, a protection net, and a spacer. It is a perspective view of a spacer. It is a top view of a spacer. It is a front view of a spacer. It is a side view of a spacer. It is a schematic front view of an outdoor heat exchanger. It is a typical cross section top view of the upper housing | casing of an outdoor unit. It is a perspective view which shows a mode when attaching a spacer to an outdoor heat exchanger and a protection net from the outside of a protection net. It is a perspective view which shows a mode when a pair of insertion leg part of a spacer is inserted in the hole part of a protective net. It is a perspective view which shows a mode when a pair of insertion leg part of a spacer is press-fitted in the groove | channel formed between fins. It is a perspective view which shows a mode when mounting | wearing to an outdoor heat exchanger and a protection net of a spacer is completed. FIG. 9 is a schematic diagram showing the spacer and the cooling tube when an external force in a pull-out direction is applied to the spacer of the comparative example.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.
The air conditioner 10 of the present embodiment is a gas heat pump air conditioner (GHP). The air-conditioning apparatus 10 includes an indoor unit (not shown) installed inside a building and an outdoor unit 15 installed outside the building. Further, the indoor unit and the outdoor unit 15 are connected to each other by a refrigerant pipe described later.

  As shown in FIG. 1, the outdoor unit 15 includes a housing 16 having a substantially rectangular cross section cut along a horizontal plane. Further, the housing 16 includes a lower housing 17 forming a lower portion of the housing 16 and an upper housing 18 forming an upper portion of the housing 16. The internal space of the lower housing 17 forms an engine room (see FIG. 4), and the internal space of the upper housing 18 forms a heat exchange chamber 20. Further, the housing 16 includes a horizontal plate-shaped partition plate (not shown) for partitioning the engine room and the heat exchange chamber 20 therein.

  As shown in FIG. 4, a gas engine operated by gas, a compressor, an expansion valve, an accumulator, and the like are provided in an engine room of the lower housing 17.

As shown in FIG. 2, most of the inside of the upper housing 18 is constituted by an outdoor heat exchanger 22 and a radiator 28 both having a fin-and-tube structure.
As shown in FIG. 3, a portion of the upper housing 18 formed by the outdoor heat exchanger 22 and the radiator 28 has a four-layer structure. That is, the two layers on the outer peripheral side are constituted by the outdoor heat exchanger 22, and the two layers on the inner peripheral side are constituted by the radiator 28.

The outdoor heat exchanger 22 (heat exchanger) includes a plurality (many) of fins 23 formed of a metal plate and arranged at substantially constant intervals in the horizontal direction. As shown in FIGS. 3 and 10, each fin 23 extends in the vertical direction, and its width direction is parallel to the thickness direction of the side wall of the upper housing 18. The outer peripheral end surface of each fin 23 located on the inner peripheral side is fixed to the inner peripheral end surface of each fin 23 located on the outer peripheral side. The upper and lower ends of each fin 23 are fixed to a fixing member forming the upper end of the upper housing 18 and a fixing member forming the lower end, respectively.
Further, the outdoor heat exchanger 22 is provided with one metal cooling tube 24 (heat transfer fluid flow tube) penetrating through each fin 23 in the horizontal direction. As shown in FIG. 10, the cooling tube 24 includes a plurality of parallel portions 25 extending in the horizontal direction and being parallel to each other, and a plurality of semi-circular portions connecting ends of the parallel portions 25 vertically adjacent to each other. And an end connecting portion 26 of the above.

As shown in FIG. 3, the radiator 28 includes a plurality (many) of fins 29 made of a metal plate arranged in the horizontal direction at substantially the same interval as the interval between the fins 23. Each fin 29 extends vertically, and its width direction is parallel to the thickness direction of the side wall of the upper housing 18. The inner peripheral end face of each fin 29 located on the outer peripheral side is fixed to the outer peripheral end face of each fin 29 located on the inner peripheral side. Further, the outer peripheral end face of each fin 29 located on the outer peripheral side is fixed to the inner peripheral end face of each fin 23 located on the inner peripheral side.
The lower end of each fin 29 is fixed to a fixing member forming the lower end of the upper housing 18.
Further, the radiator 28 includes a single cooling water tube 30 (heat transfer fluid flow tube) made of metal penetrating each fin 29 in the horizontal direction. The cooling water tube 30 includes a plurality of parallel portions 31 extending in the horizontal direction and being parallel to each other, and a plurality of semicircular end portion connecting portions that connect the ends of the parallel portions 31 that are vertically adjacent to each other. (Not shown)).

  As shown in FIG. 10, between the fins 23 and the fins 29 that are horizontally adjacent to each other, a plurality of communication paths 33 penetrating the side wall of the upper housing 18 in the thickness direction thereof are formed. Each communication passage 33 connects the inner space and the outer space of the upper housing 18.

The air conditioner 10 includes a refrigerant pipe (see FIG. 4) provided across the indoor unit and the outdoor unit 15. The inside of the refrigerant pipe is filled with a refrigerant (heat transfer fluid) not shown.
An indoor unit side heat exchanger is connected to a portion of the refrigerant pipe located inside the indoor unit.
A compressor, an expansion valve, an accumulator, and the like are provided at a plurality of portions of the refrigerant pipe located inside the outdoor unit 15. Further, both ends of the cooling tube 24 are connected to portions of the refrigerant pipe different from the compressor, the expansion valve, the accumulator and the like located in the outdoor unit 15.

  The outdoor unit 15 includes a cooling water pipe (see FIG. 4) through which cooling water (heat transfer fluid) flows. A gas engine is connected to a part of the cooling water pipe. Further, a cooling water pump is provided in a part of the cooling water pipe. A part of the cooling water pipe is constituted by a first branch and a second branch which are parallel to each other. The first branch passage is connected to a part of the refrigerant pipe via an engine exhaust heat recovery device (not shown) provided in the housing 16. Both ends of the cooling water tube 30 are connected to the second branch passage. Further, a switching valve (see FIG. 4) for selectively flowing the cooling water to one side of the first branch passage and the second branch passage is provided in a part of the cooling water pipe. The switching valve is switchable between a first switching state in which the cooling water in the cooling water pipe flows only to the first branch path side and a second switching state in which the cooling water flows only to the second branch path side.

As shown in FIG. 3, two exhaust holes 18b are formed in the ceiling plate 18a of the upper housing 18.
Further, on the lower surface of the ceiling plate 18a, two fans 36a and 36b are provided corresponding to the respective exhaust holes 18b.

As shown in FIGS. 5 and 11 and the like, the outer peripheral surface of a portion formed by the outdoor heat exchanger 22 of the upper housing 18 is covered with a protective net 40.
The protection net 40 is made of a flexible material (for example, a resin material). A large number of substantially diamond-shaped holes 42 are formed between the many linear bodies 41 constituting the protection net 40.
The basic structure of the protection net 40 of the present embodiment is not particularly limited, and may be any of a knotted net, a knotless net, and a molded net.

In the present embodiment, the protection net 40 is integrated with the upper housing 18 at the stage of manufacturing the upper housing 18.
That is, the part shown in FIG. 2 in the upper housing 18 is a flat member during the manufacturing of the upper housing 18. The flat member includes an outdoor heat exchanger 22 and a radiator 28. The fins 23 and 29 provided on the flat member are arranged in a direction parallel to a straight line extending along a plane parallel to the flat member. A pair of net support members 19 shown in FIG. 11 are fixed to both ends of one surface (the outer peripheral surface of the upper housing 18) of the flat member. The protection net 40 is put on the one surface of the flat member, and both ends are fixed to the pair of net support members 19 respectively. When the flat plate member and the protection net 40 integrated in this manner are bent by a bending machine (not shown), the integrated product has a shape shown in FIG. 2 (however, in FIG. (Not shown).
If the flat member is bent by the bending machine without covering the protective net 40, the bending by the bending machine may be caused by the outer end surface of the fin 23 forming a part of the flat member being caught by the bending machine. Processing may not be performed smoothly. On the other hand, when the bending process is performed by the bending machine after the protection net 40 is put on the flat member as in the present embodiment, there is no possibility that the outer end surface of the fin 23 is caught by the bending machine. Therefore, it is possible to efficiently manufacture a part forming a part of the upper housing 18 shown in FIG. 2 by the bending machine.

A plurality (many) of spacers 45 that are separate from the outdoor unit 15 and the protection net 40 are attached to the outdoor heat exchanger 22 and the protection net 40 of the outdoor unit 15.
The spacer 45 shown in FIGS. 5 to 9 and FIGS. 12 to 15 is an integrally molded product made of resin and has elasticity. As shown, the spacer 45 is symmetric about its center line L (see FIG. 7).
The spacer 45 integrally includes a base 46, a pair of insertion legs 51 extending from the base 46, and a stopper 57 provided at an intermediate portion between the insertion legs 51.

  On the base 46 having a plate shape, a net supporting portion 47 is formed, which is a penetrating groove that penetrates the base 46 in the thickness direction and extends linearly. The base 46 includes a pair of leg support portions 48 having a substantially triangular shape. As shown, a part of the peripheral surface of the pair of leg support parts 48 defines a part of the net support part 47.

  Insertion leg portions 51 extend from a pair of leg support portions 48 of the base portion 46, respectively. The insertion leg portion 51 is a plate-shaped portion located on the same plane as the base portion 46 and having the same thickness as the base portion 46. A substantially arc-shaped curved portion 52 is formed at an intermediate portion in the longitudinal direction of the insertion leg portion 51. An arc-shaped concave portion 53 is formed on the outer surface of each curved portion 52. The vicinity of the tip of each insertion leg 51 is bent, and the tip 54 of each insertion leg 51 extends from the vicinity of the tip toward the base 46 side. Further, the opposing surfaces of the pair of distal end portions 54 are constituted by the distal end surfaces 55 which are opposed to each other while forming a small gap between the spacers 45 when the spacer 45 is in a free state. When the spacer 45 is in the free state, the two end faces 55 are parallel to each other. The area of the pair of tip surfaces 55 is larger than the cross-sectional area of a portion located between the tip portion 54 of the insertion leg portion 51 and the stopper 57.

  A stopper 57 located between the leg supporting portion 48 and the curved portion 52 is fixed to each insertion leg 51. The stopper 57 is a plate-like portion orthogonal to the base 46 and the insertion leg 51. As shown, the front shape of the stopper 57 is a substantially isosceles triangle. Further, as shown in FIG. 8, the front shape of the stopper 57 is larger than the dimension of the insertion leg portion 51 in the thickness direction.

  Further, a gap formed between the pair of stoppers 57 and the connection end 49a are provided between the leg support 48 of the base 46 and a portion of the insertion leg 51 located closer to the base 46 than the stopper 57. A communication space 50 that communicates is formed. A connection end 49a, which is an end of the communication space 50 on the net support portion 47 side, is formed between the pair of leg support portions 48 on the net support portion 47 side end. When the spacer 45 is in a free state, the width of the connection end 49 a is smaller than the outer diameter of the linear body 41 of the protection net 40. Further, a portion connected to the connection end 49a of the communication space 50 is constituted by a guide portion 49b formed between the pair of leg support portions 48. As shown in the figure, the width of the guide portion 49b is gradually reduced from the stopper 57 side toward the connection end portion 49a side. Further, as shown in FIG. 9, the thickness of the portion of each insertion leg portion 51 located on the distal side from the curved portion 52 (recess 53) gradually increases from the curved portion 52 side to the portion side adjacent to the distal end portion 54. (That is, it has a tapered shape).

  In order to attach the spacer 45 to the outdoor unit 15 and the protection net 40, as shown in FIG. 12, the spacer 45 located outside the protection net 40 is grasped by hand and is brought close to the protection net 40 from the tip end 54 side. . Then, the gap formed between the tip surfaces 55 of the pair of tip portions 54 is opposed to the intersection 41 a where the two linear bodies 41 of the protection net 40 intersect. The gap formed between the pair of tip surfaces 55 when the spacer 45 is in the free state is smaller than the width of the intersection 41a.

Subsequently, the spacer 45 is moved toward the outdoor unit 15 as it is while the pair of distal ends 54 of the spacer 45 are in contact with the intersection 41a.
Then, a part of the base 46 (for example, the pair of leg support portions 48) and the pair of insertion legs 51 are elastically deformed, so that a gap formed between the pair of distal ends 54 is expanded, and the intersection 41 a is formed. Larger than the width. Therefore, when the spacer 45 is moved to the outdoor unit 15 as it is, as shown in FIG. 13, the distal end portion 54 of each insertion leg portion 51 passes through the two hole portions 42 located on both sides of the intersection 41a, respectively. The space enters between the fins 23 and the protection net 40.
When the distal end portion 54 of the insertion leg portion 51 passes through the hole portion 42, a part of the base portion 46 and the pair of insertion leg portions 51 are elastically restored to an initial shape, and thus are formed between the pair of distal end portions 54. The resulting gap is reduced to the initial size.

When the spacer 45 is further moved to the outdoor unit 15 side from the state of FIG. 13, as shown in FIGS. 9 and 14, the distal end portion 54 of the pair of insertion leg portions 51 of the spacer 45 and the adjacent portion of the distal end portion 54 are separated. , Enters a groove formed between two adjacent fins 23. The thickness of the curved portion 52 of each insertion leg portion 51 and a portion located on the stopper 57 side of the curved portion 52 is slightly larger than the width of a groove formed between two adjacent fins 23. Therefore, the curved portion 52 of the pair of insertion leg portions 51 of the spacer 45 and the portion located closer to the stopper 57 than the curved portion 52 are in a state of being pressed into the groove between the two adjacent fins 23. That is, even if the hand is released from the spacer 45 in this state, the state in which the pair of insertion leg portions 51 of the spacer 45 is pressed into the groove formed between the two adjacent fins 23 is maintained.
However, as described above, the thickness of the portion of each insertion leg portion 51 located on the distal end side from the curved portion 52 (recess 53) gradually decreases from the curved portion 52 side toward the portion adjacent to the distal end portion 54. are doing. Therefore, the distal end portion 54 of the pair of insertion leg portions 51 of the spacer 45 and the adjacent portion of the distal end portion 54 are smoothly inserted into the groove formed between the two adjacent fins 23.
Further, the intersection 41 a of the protection net 40 passes through the gap between the pair of stoppers 57 of the spacer 45 and enters the communication space 50.

When the spacer 45 is further moved to the outdoor unit 15 side from the state of FIG. 14, the spacer 45 is completely moved with respect to the outdoor unit 15 (fins 23) and the protection net 40 as shown in FIG. 7, FIG. 9 and FIG. Be attached.
That is, the pair of stoppers 57 of the spacer 45 contact the outer end surfaces of the plurality of fins 23. As shown in the drawing, the dimension of the fins 23 in the arrangement direction is larger at the stopper 57 than at the gap between two adjacent fins 23. Therefore, when the stopper 57 contacts the outer end surface of the fin 23, the further movement of the spacer 45 toward the outdoor unit 15 is restricted.
Furthermore, the dimension of the pair of stoppers 57 in the arrangement direction when the spacer 45 is in the free state (ie, the dimension in the width direction of the intersection 41a) is larger at the intersection 41a than at the connection end 49a. However, as described above, the width of the guide portion 49b of the spacer 45 gradually decreases from the stopper 57 side to the connection end portion 49a side. Therefore, when the spacer 45 is moved to the outdoor unit 15 side with a certain amount of force, the intersection 41a moves to the connection end 49a side along the guide portion 49b, and as shown in FIGS. While elastically deforming the pair of leg support portions 48 located on both sides of the cable, the leg support portions 48 enter the net support portions 47 through the connection end portions 49a. That is, since the guide portion 49 b is formed in the base portion 46, it is easy to move the intersection portion 41 a into the net support portion 47.
Further, when the pair of stoppers 57 of the spacer 45 come into contact with the outer end surfaces of the fins 23, as shown in FIG. 7, the distal end portions 54 of the pair of insertion leg portions 51 and the adjacent portions of the distal end portions 54 are adjacent to each other. And moves to the far side of the parallel portion 25 through the space between the parallel portions 25. When the spacer 45 is in a free state (and when the pair of insertion legs 51 is pressed into the groove between the adjacent fins 23), the distal end portion 54 and the curved portion 52 of the pair of insertion legs 51 The distance between the outer surfaces of the portion located between them is slightly larger than the gap between the two parallel portions 25. Therefore, the pair of insertion leg portions 51 passes through the gap between the two parallel portions 25 while elastically deforming in a direction approaching each other.
Further, as shown in FIG. 7, a part of the two parallel portions 25 is located in the pair of recesses 53 of the spacer 45.

Next, the operation of the air conditioner 10 and the operation and effect of the spacer 45 will be described.
When the air conditioner 10 operates, the two fans 36a and 36b rotate. Then, the air outside the upper housing 18 flows into the heat exchange chamber 20 through the communication passages 33 of the outdoor heat exchanger 22, and the air flowing into the heat exchange chamber 20 is further discharged from the exhaust holes 18 b of the upper housing 18. The air is exhausted above the upper housing 18. That is, when the fans 36a and 36b rotate, an airflow indicated by an arrow in FIG. 3 is formed.

  When the air-conditioning apparatus 10 is operated in the heating mode, the compressor operates by the driving force of the gas engine, and the compressor compresses the low-pressure gas refrigerant to generate the high-temperature high-pressure gas refrigerant. Then, the high-temperature and high-pressure gas refrigerant generated by the compressor is discharged to one side of the refrigerant pipe. Then, the high-temperature and high-pressure gas refrigerant flows through the refrigerant pipe and flows into the indoor unit side heat exchanger. The high-temperature and high-pressure gas refrigerant that has flowed into the indoor unit side heat exchanger discharges heat into the room of the building while passing through the indoor unit side heat exchanger and condenses. That is, the indoor unit side heat exchanger functions as a condenser during heating. At this time, the indoor air of the building is heated by the heat discharged from the high-temperature and high-pressure gas refrigerant. A part of the refrigerant that has discharged heat and condensed into the room is liquefied, and the refrigerant is expanded by an expansion valve provided in the refrigerant pipe.

  When the air-conditioning apparatus 10 operates in the heating mode, the switching valve enters a first switching state in which the cooling water flows only to the first branch path side. Therefore, the cooling water heated by the gas engine and flowing in the cooling water pipe by the power of the cooling water pump flows to the engine exhaust heat recovery device provided in the first branch. Therefore, the heat of the cooling water is transmitted to the low-pressure refrigerant in the refrigerant pipe in the engine exhaust heat recovery device. That is, the refrigerant is overheated by the exhaust heat of the cooling water.

The refrigerant that has passed through the engine exhaust heat recovery unit flows into the cooling tube 24 of the outdoor heat exchanger 22.
Then, while the refrigerant is flowing through the cooling tube 24, part of the heat of the airflow formed by the fans 36 a and 36 b and flowing through the holes 42 and the communication passage 33 of the protection net 40 is absorbed by the cooling tube 24. This heat is transmitted to the refrigerant in the cooling tube 24. Further, part of the heat of the airflow flowing through the communication passage 33 is absorbed by the fins 23 and the fins 29, and this heat is transmitted to the refrigerant in the cooling tube 24 via the fins 23 and 29 and the cooling tube 24.
Thus, the outdoor heat exchanger 22 functions as an evaporator during heating.

Part of the refrigerant evaporated by removing the heat of the outside air is vaporized and further introduced into the accumulator. The refrigerant introduced into the accumulator is separated into gas and liquid, and only low-temperature and low-pressure gas refrigerant is taken out and returned to the compressor.
By repeating such a refrigerant circulation cycle, room heating is continued.

On the other hand, when the air conditioner 10 is operated in the cooling mode, the compressor operates by the driving force of the gas engine, and the compressor compresses the low-pressure gas refrigerant to generate the high-temperature high-pressure gas refrigerant. Then, the high-temperature and high-pressure gas refrigerant generated by the compressor is discharged to one side of the refrigerant pipe. Then, the high-temperature and high-pressure gas refrigerant flows into the cooling tube 24 of the outdoor heat exchanger 22. Then, while the refrigerant flows through the cooling tube 24, part of the heat of the refrigerant is radiated from the surface of the cooling tube 24 to the communication path 33. Another part of the heat of the refrigerant is transmitted from the cooling tube 24 to the fins 23 and 29, and is radiated from the fins 23 and 29 to the communication path 33.
The air in each communication passage 33 heated by the heat radiated from the cooling tube 24, the fins 23 and the fins 29 to the communication passage 33 passes through each hole 42 of the protection net 40 formed by the fans 36a and 36b. The gas flows into the communication passage 33 and is exhausted from the exhaust holes 18 b to above the upper housing 18.
Thus, the outdoor heat exchanger 22 functions as a condenser during cooling.

Further, when the air-conditioning apparatus 10 operates in the cooling mode, the switching valve enters a second switching state in which the cooling water flows only to the second branch. Therefore, the cooling water heated by the gas engine and flowing in the cooling water pipe by the power of the cooling water pump flows to the cooling water tube 30 of the radiator 28 provided in the second branch passage. Then, while the cooling water flows through the cooling water tube 30, part of the heat of the cooling water is radiated from the surface of the cooling water tube 30 to the communication path 33. Further, another part of the heat of the cooling water is transmitted from the cooling water tube 30 to the fins 29 and the fins 23 and is radiated from the fins 29 and the fins 23 to the communication passage 33.
The heat exhausted from the cooling water tube 30 to the communication passage 33 also flows from the exhaust holes 18b to the upper part by the airflow flowing into the communication passage 33 through the holes 42 of the protection net 40 formed by the fans 36a and 36b. The air is exhausted above the housing 18.

  The refrigerant that discharges heat to the outside air and condenses is partially liquefied and then expanded by passing through an expansion valve. That is, the pressure is reduced by the expansion valve so as to easily evaporate. The refrigerant in the refrigerant pipe subsequently flows into the indoor unit side heat exchanger. The refrigerant that has flowed into the indoor unit side heat exchanger takes away the heat of the indoor air and evaporates while passing through the indoor unit side heat exchanger. That is, at the time of cooling, the indoor unit side heat exchanger functions as an evaporator. At this time, the refrigerant takes away the heat of the air in the room of the building, thereby cooling the room air and cooling the room.

  The refrigerant evaporated by removing the heat of the indoor air is partially vaporized, passes through the indoor unit side heat exchanger, flows through the refrigerant pipe, and is introduced into the accumulator. The refrigerant introduced into the accumulator is gas-liquid separated, and only the low-temperature and low-pressure gas refrigerant is returned to the compressor. By repeating such a refrigerant circulation cycle, indoor cooling is continued.

A pair of stoppers 57 of each spacer 45 mounted on the outdoor unit 15 and the protection net 40 are formed on the base 46 which is in contact with the outer end surface of the fin 23 and is located on the opposite side of the tip end 54 with the stopper 57 interposed therebetween. The net support 47 supports the intersections 41a at a plurality of locations of the protection net 40. Therefore, the protection net 40 is maintained in a state separated from the outer end surface of the fin 23 by each spacer 45. Therefore, even if the wind blows or the outdoor unit 15 vibrates at the place where the outdoor unit 15 is placed, there is almost no possibility that noise is generated between the protection net 40 and the fins 23 of the outdoor unit 15.
Furthermore, even if the rainwater or snow adhering to the protection net 40 freezes and blocks the hole 42 of the protection net 40, when the fans 36a and 36b are rotated, the air in the space outside the outdoor unit 15 becomes free of air. It is possible to flow into each communication passage 33 of the outdoor unit 15 from a gap between the fin 23 and the outer end surface. Therefore, even if rainwater, snow, or the like freezes on the protection net 40, the air-conditioning apparatus 10 can exhibit effective cooling and heating functions.

Further, the width of the pair of insertion legs 51 extending bifurcated from the base 46 of the spacer 45 is considerably smaller than the entire width of the spacer 45.
Therefore, even if each hole 42 of the protection net 40 is smaller than the entire width of the spacer 45, each insertion leg 51 can be easily inserted into each hole 42 of the protection net 40.
Therefore, the spacer 45 can be attached to the outdoor unit 15 and the protection net 40 by using the holes 42 even when the holes 42 of the protection net 40 are small.

Further, when the intersection 41a of the protective net 40 enters the net support 47, the base 46 of the spacer 45 returns to the free state. That is, the width of the connection end 49a of the spacer 45 is smaller than the width (outer diameter) of the intersection 41a.
Therefore, even if the spacer 45 is unexpectedly pulled in a direction away from the outdoor unit 15 in a state where the intersection 41a faces the connection end 49a, the intersection 41a moves through the connection end 49a toward the guide 49b. The risk of doing is small. That is, the possibility that the mounting state of the spacer 45 to the protection net 40 is released is small.

Further, when a force is applied to the outdoor unit 15 and the spacer 45 attached to the protection net 40 in a direction away from the outdoor unit 15, the pair of insertion leg portions 51 is located on the distal end portion 54 side of the curved portion 52. The end is hooked on the parallel part 25.
Further, when the curved portion 52 comes into contact with the parallel portion 25, the pair of insertion legs 51 is elastically deformed in a direction approaching each other. However, at this time, the distal end surfaces 55 of the distal end portions 54 of the pair of insertion leg portions 51 surely come into contact with each other, and the further approach of the pair of insertion leg portions 51 is suppressed. That is, the distance between the outer surfaces of the portions located between the distal end portion 54 of the pair of insertion leg portions 51 and the curved portion 52 is prevented from being smaller than the gap between the two parallel portions 25. . In addition, like the spacer 45 'of the modified example shown in FIG. 16, the area of the distal end face 55' of the distal end 54 'of the insertion leg 51' is different from that of the distal end 54 'of the insertion leg 51'. In the case where the cross-sectional area is the same as the cross-sectional area of the portion located between the curved portion 52 ′ and the parallel portion 25, the pair of insertion leg portions 51 ′ is formed. When the elastic members are elastically deformed in a direction approaching each other, there is a possibility that the end surfaces 55 'do not contact each other. In this case, the distance between the outer surfaces of the portions located between the distal end portion 54 'of the pair of insertion leg portions 51' and the curved portion 52 'is smaller than the gap between the two parallel portions 25, As a result, there is a possibility that the insertion leg portion 51 'may pass through between the two parallel portions 25 and move to the outside of the fin 23.
Further, as described above, the pair of insertion leg portions 51 of the spacer 45 is press-fitted into the groove formed between the two adjacent fins 23.
Therefore, even if a force in the direction away from the outdoor unit 15 is applied to the spacer 45, the risk of the spacer 45 suddenly dropping from the outdoor unit 15 (fin 23) is small.

  Further, since the spacer 45 is an integrally molded product made of resin, the spacer 45 can be manufactured at low cost.

The embodiments of the present invention have been described above, but the present invention should not be limited to the above embodiments.
For example, as long as the spacer 45 can be elastically deformed, it does not need to be an integrally molded resin product. For example, the spacer 45 may be made of an elastic metal.

  The concave portion 53 (curved portion 52) may be omitted from the spacer 45, or the area of the distal end face 55 of the distal end portion 54 of the insertion leg portion 51 may be located between the distal end portion 54 of the insertion leg portion 51 and the curved portion 52. It may be equal to or smaller than the cross-sectional area of the site.

When the spacer 45 is mounted on the outdoor unit 15, the pair of insertion legs 51 may be press-fitted into grooves formed between the adjacent fins 29.
When the spacer 45 is mounted on the outdoor unit 15, the pair of concave portions 53 (curved portions 52) face two adjacent cooling water tubes 30, and a part of each cooling water tube 30 corresponds. It may be located in the recess 53.

  When the spacer 45 is attached to the outdoor unit 15 and the protection net 40, after inserting the crossing portion 41a into the net support portion 47, the pair of insertion legs 51 are connected to the two adjacent fins 23 and / or fins 29. You may press-fit into the groove | channel formed between.

  The present invention may be applied to an air conditioner 10 other than a gas heat pump air conditioner (GHP).

10 ... air conditioner, 15 ... outdoor unit, 22 ... outdoor heat exchanger (heat exchanger),
23 fins, 24 refrigerant tubes (heat transfer fluid flow tubes), 25 parallel parts, 28 radiators, 29 fins, 30 cooling water tubes (transfer tubes) Thermal fluid circulation,
33 ... communication passage, 36a, 36b ... fan, 40 ... protection net, 41 ... linear body, 42 ... hole, 45 ... spacer, 46 ... base, 47 ... Net support part, 48 ... Leg support part, 49a ... Connection end part, 49b ... Guide part, 50 ... Communication space, 51 ... Peg-in part, 52 ... -Bending part, 53 ... concave part, 54 ... tip part, 55 ... tip surface, 57 ... stopper.

Claims (4)

A spacer attached to a protective net attached to an outdoor unit which forms a part of an air conditioner and has on its surface a heat exchanger having a large number of fins arranged in parallel with each other is provided so as to cover the heat exchanger. So,
A pair of the protective nets are respectively insertable into two adjacent holes and press-fit into grooves formed between two adjacent fins when inserted into the two adjacent holes. Plug-in legs,
Respectively provided on the pair of the difference Komiashi portion, a pair of restricting any further press-fitted to the inner side of the groove of the difference Komiashi portion by contact with the outer end of the insertion impossible and the fins to the groove And the stopper
A net comprising a through groove, which is located on the opposite side of the insertion leg portion with respect to the stopper and into which the linear body constituting the protection net is inserted when the stopper comes into contact with the outer end of the fin; A support,
Equipped with a,
A communication space that connects the gap formed between the pair of stoppers and the net support is formed,
When the spacer is in a free state, a width of a connection end, which is an end connected to the net support portion of the communication space, is smaller than an outer diameter of the linear body of the protection net,
The width of the guide portion, which is a portion of the communication space adjacent to the connection end, gradually decreases from the stopper side toward the connection end side, for a protective net mounted on an outdoor unit of an air conditioner. Spacer. A spacer for a protective net attached to an outdoor unit of the air conditioner according to claim 1 ,
The heat exchanger includes a heat transfer fluid flow pipe that penetrates the plurality of fins in a direction in which the fins are arranged and through which a heat transfer fluid flows.
The heat transfer fluid flow pipe has a plurality of parallel portions extending linearly and parallel to each other,
The spacer is
A base that supports a base end of the pair of insertion legs and is elastically deformable in a direction to approach and separate the pair of insertion legs,
When the stopper comes into contact with the outer end of the fin formed on the outer surface of the intermediate portion in the longitudinal direction of the pair of insertion legs, a part of each of two adjacent parallel portions is located. A recess,
A spacer for a protective net attached to an outdoor unit of an air conditioner, comprising: A spacer for a protective net attached to an outdoor unit of the air conditioner according to claim 2 ,
The distal end surfaces of the distal ends of the pair of insertion legs are opposed to each other when the spacer is in a free state, and have an area larger than a cross-sectional area of a portion adjacent to the distal end of the insertion leg. Protective net spacer to be installed on the outdoor unit of the harmony device. A spacer for a protective net attached to an outdoor unit of the air conditioner according to any one of claims 1 to 3 ,
A spacer for a protection net mounted on an outdoor unit of an air conditioner, wherein the spacer is made of resin.

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