JP5974229B2 - Waste heat air cooling device - Google Patents

Description

  The present invention relates to an exhaust heat air cooling apparatus that is provided in an outdoor unit of an air conditioner such as a room air conditioner and cools exhaust heat air of the outdoor unit with condensed water flowing down from the indoor unit.

2. Description of the Related Art Conventionally, as this type of exhaust heat air cooling device, there has been known an exhaust air processing device disposed to face an outlet of an outdoor unit (see Patent Document 1). This processing apparatus includes a first processing apparatus (product of the present invention) disposed opposite to the front of the outdoor unit and a second processing apparatus (rear receiving body) disposed with a gap behind the first processing apparatus. And. The first treatment device includes a crown-shaped fiber body whose frame is covered with fibers, a support base that supports the fiber body, and a water supply unit that is provided on the top of the fiber body and supplies tap water to the fiber body. And. The fibrous body is provided with a plurality of small holes penetrating in the front-rear direction and a large hole portion penetrating in the front-rear direction at the center. Similarly, the second treatment apparatus includes a rear fiber body that is complementary to the back side of the fiber body, a base that supports the rear fiber body, a water supply unit that supplies tap water to the fiber body, It has. The rear fiber body is also provided with a hole, and the first processing device and the second processing device are connected by a connecting cylinder portion that communicates the holes. And tap water is introduce | transduced into a fiber body and a rear part fiber body, and these are made to get wet.
The exhaust heat air discharged from the outdoor unit is blown from the front onto the fiber body of the first processing apparatus, and when passing through this, the tap water impregnated in the fiber body is vaporized and cooled. Part of the exhaust heat air deprived of vaporization heat by the fibrous body flows through the hole and the connecting cylinder part, and part of the exhaust air passes through the small hole and is blown to the second processing apparatus from the front. The exhaust heat air blown to the rear fiber body flows in the circumferential direction and is cooled by vaporizing tap water impregnated in the rear fiber body. Thus, by cooling the exhaust heat air from the outdoor unit, the heat quantity of the exhaust heat is suppressed, thereby contributing to the elimination of the heat island phenomenon.

JP 2004-150782 A

  In such a conventional exhaust air processing apparatus, exhaust air is cooled by allowing the fibrous body impregnated with tap water to permeate using the wind pressure of the exhaust air from the outdoor unit. For this reason, the exhaust heat air which permeate | transmits a fiber body reduces a flow velocity extremely by the flow-path resistance of a fiber. When the flow rate of exhaust heat air decreases, the evaporation of tap water is suppressed and the load on the fan of the outdoor unit increases. That is, the conventional exhaust air processing apparatus has a problem in that the outdoor unit is loaded and power consumption is increased, and the exhaust heat air is not efficiently cooled.

  An object of the present invention is to provide an exhaust heat air cooling device capable of efficiently cooling exhaust heat air of an outdoor unit while suppressing a load on the fan of the outdoor unit.

An exhaust heat air cooling device according to the present invention is provided in an outdoor unit of an air conditioner, and is an exhaust heat air cooling device that cools exhaust heat air of an outdoor unit with condensed water flowing down from the indoor unit. A plate-like cooling body disposed in front of the mouth for cooling the exhaust heat air by the heat of vaporization of the impregnated condensed water, and a condensation disposed above the cooling body for receiving the condensed water and guiding it to the cooling body A cooling body is arranged in a horizontal posture along the flow of exhaust heat air, and the condensed water introducing section is a drain pan that guides the condensed water to the cooling body, and a water absorption laid on the drain pan. And a pad .

By the way, the condensed water from the indoor unit is condensed on the evaporator and is sufficiently low in temperature as compared with the exhaust heat air of the outdoor unit.
According to this configuration, when the condensed water from the indoor unit is guided to the cooling body and impregnated in the cooling body, the exhaust heat air of the outdoor unit is passed (ventilated) along the cooling body, It is cooled by heat transfer (heat exchange) with the condensed water and also cooled by the heat of vaporization of the condensed water. Therefore, the exhaust heat air of the outdoor unit can be efficiently cooled, and the condensed water originally discarded outdoors (rain water pipe) can be effectively used for exhaust heat air cooling. Further, since the cooling body is arranged in a posture along the flow of the exhaust heat air, the air resistance is small and the flow rate of the exhaust heat air is not greatly reduced. Therefore, it is possible to sufficiently suppress an increase in the load on the fan of the outdoor unit due to the ventilation of the cooling body. Therefore, it is possible to contribute to the elimination of the heat island phenomenon without increasing the power consumption. In addition, this waste heat air cooling device can be installed not only on an existing outdoor unit but also on a new outdoor unit. Further, as long as the cooling body has a shape along the flow of exhaust heat air, the blade plate shape may be a cylinder shape, a front spiral shape, a front view lattice shape, or the like.
On the other hand, use of the cooling body in a horizontal posture suppresses unnecessary dripping of the introduced condensed water, and the condensed water can be sufficiently impregnated and held in the cooling body. In addition, a plurality of cooling bodies can be installed in a space efficient manner in front of the outdoor unit. It should be noted that the cooling body may be in a substantially horizontal posture as long as the water retaining function can be exhibited even if it is not in a complete horizontal posture.
In addition, by providing the drain pan, the condensed water flowing down from the indoor unit can be temporarily stored by the water absorption pad laid on the drain pan.

In this case, the cooling body is preferably made of those of the plurality disposed to exist a mutually spacing.

According to this configuration, the contact area between the exhaust heat air and the cooling body is increased, and the cooling efficiency of the exhaust heat air can be improved. Further, since the cooling bodies are arranged with a space between each other, a sufficient ventilation space can be secured. Thus without increasing the substantial air resistance, Ru can be placed a plurality of cooling bodies.

  In this case, each cooling body preferably includes a net-like base body and an absorber that is supported by the base body and impregnated with condensed water.

  According to this configuration, the cooling body can be configured with a simple structure. Moreover, the volume ratio of an absorber can be raised with respect to the whole cooling body, and condensed water can fully be impregnated. Furthermore, condensed water can be vaporized from both front and back surfaces of the absorber. Furthermore, the cooling body can be easily minutely deformed according to the flow of exhaust heat air or the like by the net-like base body. When the cooling body is impregnated with the condensed water, the portion of the absorber that has been removed from the base body is depressed by gravity, and the condensed water that has become saturated can flow smoothly to the lower cooling body. In addition, it is preferable that an absorber is a woven fabric, a nonwoven fabric, sponge, etc.

Moreover, it is preferable that the water absorption pad is formed with a dripping portion that protrudes from the drain pan and causes the uppermost cooling body to drain the condensed water.

  Furthermore, it is preferable that the dripping part is comprised by several protrusion site | parts.

According to these configurations, with respect to cold却体, the condensed water can be dropped at any position in the plane. Therefore, if a plurality of dropping portions are dispersed and arranged, condensed water can be uniformly dropped onto the cooling body.

  Moreover, it is preferable that each cooling body has a water-conducting gradient inclined downward toward the center.

  According to this configuration, the condensed water (saturated condensed water) that has not been absorbed by the absorber gathers at the center of the cooling body along the introduction gradient, and is dropped from the center to the lower cooling body. Therefore, the condensed water can be smoothly and efficiently supplied to the plurality of cooling bodies by natural flow.

  Similarly, in two vertically adjacent cooling bodies, the upper cooling body is set back with respect to the lower cooling body and is set back to the outlet side, and each cooling body has a forward-lowering water guiding gradient. It is preferable.

  According to this configuration, since a plurality of cooling bodies will be arranged stepwise, condensed water that could not be absorbed by the absorber smoothly dropped from the front end to the lower cooling body according to the gradient, Can be supplied. In addition, the condensed water dripping from the edge of the upper cooling body will drop obliquely forward due to the wind pressure of the exhaust heat air. Can receive.

  On the other hand, it is preferable to further include a support frame that supports the cooling body, and the support frame preferably has a latching portion that is latched to the outdoor unit.

  According to this configuration, the entire apparatus can be unitized by the support frame. Further, the entire device can be fixed to the outdoor unit by the latching portion, and can be stably installed in front of it.

  In addition, it is preferable to further include a guide plate that is disposed outside the cooling body and guides the exhaust heat air forward.

  According to this configuration, the exhaust heat air can be efficiently ventilated to the cooling body by guiding the flow of the exhaust heat air with the guide plate. Thereby, exhaust air can be cooled efficiently. Further, the influence of wind and the like can be eliminated when cooling the exhaust heat air.

It is an apparatus block diagram for demonstrating the cooling operation of a room air conditioner (air conditioner). It is the front view (a) and side view (b) which show the installation state of the exhaust heat air cooling device and room air conditioner which concern on 1st Embodiment. It is the front view (a) and side view (b) of the exhaust heat air cooling device which concern on 1st Embodiment. It is the top view (a) and sectional drawing (b) of a cooling body. It is a figure which shows the measurement result (a) of the exhaust heat air temperature in a waste heat air cooling device, and the figure which shows the measurement result (a) of the flow velocity and flow volume of exhaust heat air. It is a side view of the exhaust heat air cooling device concerning a 2nd embodiment. It is the front schematic diagram (a) and cross-sectional schematic diagram (b) of the outdoor unit incorporating the exhaust heat air cooling device which concerns on 3rd Embodiment.

Hereinafter, an exhaust heat air cooling device according to an embodiment of the present invention will be described with reference to the accompanying drawings. This exhaust heat air cooling device is provided in an outdoor unit of an air conditioner (room air conditioner), and cools exhaust heat air discharged from the outdoor unit by condensed water flowing down from the indoor unit. By cooling the exhaust heat air of the outdoor unit during the cooling operation in summer, the amount of heat of the exhaust heat air released into the atmosphere is suppressed, and the heat island phenomenon is alleviated. Hereinafter, the exhaust heat air cooling device will be described in the case where it is installed in an outdoor unit of a room air conditioner, but before that, the room air conditioner will be briefly described in consideration of the refrigeration cycle.
* “Refrigeration cycle” is a thermodynamic term.

  As shown in FIG. 1, the room air conditioner 100 is a so-called heat pump, which absorbs heat from indoor air (heat absorption) by the indoor unit 101 and exhausts this heat into the atmosphere by the outdoor unit 102. The cooling operation is performed by continuously performing this operation through the refrigerant that carries heat. Specifically, the low-temperature and high-pressure liquefied refrigerant supplied from the outdoor unit 102 to the indoor unit 101 is expanded and vaporized by the expansion valve 104 of the indoor unit 101 and further supplied to the evaporator 105 as a low-temperature refrigerant gas. The Indoor air is blown (ventilated) to the evaporator 105 by the indoor unit fan 106, and heat is exchanged between the indoor air and the refrigerant gas by the evaporator 105. The indoor air is cooled by this heat exchange (room cooling), and the refrigerant gas whose temperature has been raised is sent from the indoor unit 101 to the outdoor unit 102. On the other hand, condensation is generated on the surface of the evaporator 105 when the room air is cooled (condensed), and this condensed water is received by the pan 107 provided below the evaporator 105, and the condensed water pipe 108 (flexible hose) is passed through. It is drained out of the room.

  In the outdoor unit 102, the refrigerant gas is compressed by the compressor 110 and is sent to the condenser 111 as a high-temperature and high-pressure liquid (refrigerant). Outside air is blown (ventilated) to the condenser 111 by the outdoor unit fan 112, and heat exchange is performed between the outside air and the refrigerant by the condenser 111. The refrigerant that has fallen in temperature due to this heat exchange and has become low temperature and high pressure is sent to the indoor unit 101 via the receiver 113. Moreover, the outside air heated by heat exchange is discharged into the atmosphere as exhaust heat air. Heat (exhaust heat) released by exhaust heat air is one of the causes of the heat island phenomenon. Therefore, in the present embodiment, the exhaust heat air cooling device 1 (see FIG. 2) cools the exhaust heat air using the condensed water drained from the condensed water pipe 108 to suppress the amount of heat released into the atmosphere. I am doing so.

  FIG. 2 shows the room air conditioner 100 installed in the apartment room S1. The indoor unit 101 is installed in the living room S1, and the outdoor unit 102 is installed in the veranda S2 facing the living room S1. Further, the outdoor unit 102 is provided with the exhaust heat air cooling device 1. Between the indoor unit 101 and the outdoor unit 102, a refrigerant forward pipe 114 and a refrigerant return pipe 115 are connected through the outer wall S3, and a condensed water pipe 108 piped from the indoor unit 101 through the outer wall S3. Is connected to the exhaust heat air cooling device 1. A blower outlet 116 for blowing exhaust heat air from the built-in outdoor unit fan 112 is provided on the front surface of the outdoor unit 102, and the exhaust heat air cooling device 1 is installed so as to face the blower outlet 116.

  The indoor unit 101 cools the indoor air in the living room S1 and the heat taken from the living room S1 is carried to the outdoor unit 102. The heat carried to the outdoor unit 102 is cooled by the exhaust heat air cooling device 1 and radiated to the atmosphere. On the other hand, the veranda S2 is surrounded by a partition wall S4 between the neighboring houses and a handrail wall S5, and the exhaust heat air cooled by the exhaust heat air cooling device 1 is released to the half-open veranda S2. It will be.

  As shown in FIGS. 2 and 3, the exhaust heat air cooling device 1 is installed in front of a support frame 2 having an upper end hooked to the outdoor unit 102 and having a lower end installed on the floor, and an outlet 116. A plurality of cooling bodies 3 supported by the support frame 2, a condensate introduction unit 4 disposed on the upper side of the outdoor unit 102 and supported by the support frame 2, and provided on both sides of the support frame 2, A pair of guide plates 5 for guiding the hot air forward. A condensed water pipe 108 is connected to the condensed water introduction part 4, and condensed water flowing down from the indoor unit 101 through the condensed water pipe 108 is supplied from the condensed water introduction part 4 to a plurality of cooling bodies 3.

  The condensed water introduction part 4 is provided so as to be placed on the upper surface of the outdoor unit 102, a drain pan 11 that receives condensed water from the condensed water pipe 108 (flexible hose), and a water absorption pad 12 that is laid on the drain pan 11. And have. The drain pan 11 is made of steel, stainless steel, resin, or the like, and has a raised portion 14 around the bottom plate 13 and is formed in a rectangular dish shape. The front rising portion 14 is provided with a notch 15 widely in the center so as to be flush with the bottom surface. Further, a pipe support piece 16 protrudes upward from the center of the rear riser 14, and the downstream end of the condensed water pipe 108 is band-fixed to the pipe support piece 16. Although details will be described later, the drain pan 11 also serves as a part of the support frame 2, and a front hooking portion 34 of the support frame 2 is attached to the front lower surface of the drain pan 11, and the support frame 2 is attached to the rear end. The rear latching part 35 is attached (refer FIG.3 (b)).

  The water absorbent pad 12 is composed of a woven fabric, nonwoven fabric, sponge or the like having high water absorption, and a pad main body 17 laid on the entire bottom surface of the drain pan 11 and a drooping portion 18 that protrudes from the notch 15 of the drain pan 11 and hangs downward. And are integrally formed. A lower end portion of the drooping portion 18 is formed in a saw blade shape, and a plurality of dripping portions 18 a for allowing the cooling body 3 to drain condensed water is formed. The condensed water flowing down on the water absorption pad 12 is absorbed by the water absorption pad 12 so as to spread out and is temporarily stored in the water absorption pad 12. The condensed water temporarily stored in the water absorption pad 12 eventually becomes saturated and drops onto the cooling body 3 from the plurality of dropping portions 18a.

  Each cooling body 3 is formed in a blade plate shape, and a plurality (three in the embodiment) of cooling bodies 3 are arranged at equal intervals in the vertical direction facing the outlet 116 of the outdoor unit 102. (See FIG. 2). And each cooling body 3 is arrange | positioned by the horizontal attitude | position so that the flow of the exhaust heat air sent from the outdoor unit 102 may be followed. In other words, the plurality of cooling bodies 3 are horizontally attached to the support frame 2 on both sides of the rear part so as to be positioned at the upper, middle, and lower stages of the outlet 116.

  As shown in FIG. 4, each cooling body 3 has a net-like base body 21 and an absorber 22 supported by the base body 21. The base body 21 is composed of a base body body 24 in which steel or stainless steel rods 25 are assembled (welded) in a lattice shape, and a pair of attachments provided on both sides of the base body body 24. And a plate 26. The base body main body 24 and the pair of attachment plates 26 are integrated by welding or the like, and each cooling body 3 is attached to the support frame 2 at a portion of the pair of attachment plates 26 (in the embodiment, Screwed). Further, the base body 21 of the present embodiment is slightly bent and formed in a reverse “H” shape when viewed from the side, and the absorber 22 is also slightly bent and deformed following this. Thereby, the condensed water that could not be absorbed by the absorber 22 flows to the bent portion according to a slight water guide gradient, and then flows down onto the cooling body 3 immediately below.

  In addition, when the absorber 22 is deformed into a concave shape due to the weight of the impregnated condensed water at the portion of each base plate of the base body main body 24, the drainage of the condensed water can be expected from this portion. The body 21 need not be bent. Further, the base body main body 24 may be made of various types of wire mesh or punching metal. However, in this case, it is preferable to replace the pair of mounting plates 26 with a frame-shaped mounting member that supports a wire mesh or the like. Further, the mounting plate 26 may be omitted, and the base body main body 24 may be directly welded to the support frame 2.

  The absorbent body 22 is composed of a woven fabric, a non-woven fabric, a sponge or the like having a high water absorption like the water absorbing pad 12 described above. The absorber 22 may be configured to be laid on the base body 21 or may be configured to wrap the base body 21. In either case, it is preferable to fix the folded portion of the absorbent body 22 to the base body 21 with a holding tool or the like. Moreover, the base body main body 24 may be a wire mesh, and the front and back absorbent bodies 22 (for example, non-woven fabrics) may be sandwiched and bonded and integrated.

  As shown in FIGS. 2 and 3, the support frame 2 includes the drain pan 11 described above, and has an upper frame portion 31 (hanging portion) that is hooked on the upper portion of the outdoor unit 102, and a front end portion of the upper frame portion 31. And a main frame portion 32 that extends vertically from the floor to the floor and supports the plurality of cooling bodies 3. The upper frame portion 31 is placed on the upper surface of the outdoor unit 102 together with the drain pan 11, and is hung on the upper portion of the outdoor unit 102 so as not to move forward, backward, left and right in this state. The main frame portion 32 is connected to the front end portion of the upper frame portion 31 at the upper end so as to make a right angle with the upper frame portion 31, and is seated on the floor surface of the veranda S2 at the lower end portion.

  The drain pan 11 also serves as a part of the support frame 2 (upper frame portion 31). The upper frame portion 31 includes a drain pan 11 and a pair of left and right front hooking portions 34 fixed to the front lower surface of the drain pan 11. And a pair of left and right rear latching portions 35 fixed to the rear end of the drain pan 11. Each front hooking portion 34 is formed in an “L” shape, and is fixed to the bottom plate 13 of the drain pan 11 by welding or the like. Each of the rear latch portions 35 includes a first latch piece 36 formed in an “L” shape, a second latch piece 37 formed in an inverted “L” shape, and a first latch piece. 36 and an adjusting screw portion 38 for connecting the second latching piece 37.

  In the first latching piece 36, a long hole 45 (not shown) into which the male screw of the adjusting screw portion 38 is fitted is formed in the extending piece portion extending in the front-rear direction, and the drain pan 11 is in the upward piece portion. It is fixed to the rear rising portion 14 by welding or the like. The second latching piece 37 has an adjustment screw portion (male screw) 38 fixed to a portion of the extending piece extending in the front-rear direction, and is latched at the rear corner portion of the outdoor unit 102 at the downwardly facing piece portion. Yes. The first latching piece 36 and the second latching piece 37 are disposed so as to overlap in the front-rear direction at the extended pieces, and this overlap dimension is the thickness before and after the outdoor unit 102. It is adjusted by the adjusting screw portion 38 so as to correspond to the above.

  In the present embodiment, a rubber pad 39 having a “L” cross section is provided as a protector for protecting the outdoor unit 102 from the upper frame portion 31, and the rubber pad 39 is provided at the front and rear corners of the outdoor unit 102, respectively. The drain pan 11 is set so that the pair of the front hooking portions 34 and the pair of the rear hooking portions 35 are respectively positioned on the pair. After the drain pan 11 is set, the drain pan 11 is shifted rearward so that the pair of front latching portions 34 abuts the front corners of the outdoor unit 102, and then the second latching pieces 37 of the respective rear latching portions 35 are moved. The upper end portion of the outdoor unit 102 is sandwiched from the front and rear by the pair of front hooking portions 34 and the pair of second hooking pieces 37. Here, the adjusting screw portion 38 (in the embodiment, a female screw such as a wing nut) is tightened to connect and fix the front latching portion 34 and the second latching piece 37, and the upper frame portion 31 (including the drain pan 11). The outdoor unit 102 is latched and fixed so as not to move.

  On the other hand, the main frame portion 32 includes a pair of left and right cooling body frame portions 41 to which a plurality of cooling bodies 3 are attached, and a pair of left and right mounting portions that are vertically attached to the lower portion of each cooling body frame portion 41. It has a self-supporting frame part 42 and a pair of left and right connecting screw parts 43 that connect each self-supporting frame part 42 to each cooling body frame part 41 so that the height can be adjusted. The distance between the pair of cooling body frame portions 41 corresponds to the width of the cooling body 3 (the size in the left-right direction), and each cooling body 3 is sandwiched between the pair of left and right cooling body frame portions 41. It is fixed to the pair of cooling body frame portions 41 by screws or the like.

  Each cooling body frame portion 41 is formed of, for example, an L angle of steel or stainless steel, and an upper end portion thereof is fixed to a front end portion of the upper frame portion 31 (drain pan 11). More specifically, the upper end portion of each cooling body frame portion 41 is fixed to the front end portion of the rising portion 14 (side plate portion) of the drain pan 11 by screwing or welding from the outside. In addition, a long hole 45 extending in the vertical direction is formed in the lower portion of each cooling body frame portion 41. Then, the male screw of the connecting screw portion 43 is inserted into the long hole 45.

  Similarly, each self-supporting frame portion 42 is formed of an L angle of steel or stainless steel, and is attached inside the cooling body frame portion 41. A connecting screw portion 43 (a male screw) is fixed to the upper portion of each self-supporting frame portion 42, and an “L” -shaped landing portion 46 is fixed to the lower end portion. The connection screw portion 43 includes a male screw fixed to the self-supporting frame portion 42 by welding or the like and a female screw such as a wing nut screwed to the male screw, and the male screw fixed to the self-supporting frame portion 42 is the length of the cooling body frame portion 41. The wing nut is threaded into the hole 45.

  Therefore, the wing nut is loosened, the self-supporting frame portion 42 is slid up and down with respect to the cooling body frame portion 41, and the height of the main frame portion 32 is adjusted to the height of the outdoor unit 102. Subsequently, the height adjustment of the main frame portion 32 is completed by tightening the wing nut. In addition, the main frame part 32 can also be comprised with a pipe (a square pipe or a round pipe) etc. other than L angle. Further, the floor 46 may be provided with a slip stopper such as rubber. Alternatively, the cooling body frame portion 41 may be formed in an inverted “U” shape (a self-supporting frame portion 42 is also added), and the cooling body 3 may be supported at two locations on one side.

  The pair of guide plates 5 guides the exhaust heat air blown from the blow-out ports 116 forward, and is disposed on the left and right outer sides of the plurality of cooling bodies 3. Each guide plate 5 is formed of a rectangular resin plate such as acrylic and is fixed to the cooling body frame portion 41 with screws or the like. In this state, each guide plate 5 has a width from a position near the front surface of the outdoor unit 102 to a front position beyond the cooling body 3 and a height substantially corresponding to the cooling body frame portion 41. In this case, each guide plate 5 may be fixed to the outside of the cooling body frame portion 41, or may be sandwiched between the cooling body frame portion 41 and the side ends of the plurality of cooling bodies 3 to cool the cooling body. You may fix to the frame part 41. FIG. Moreover, it is preferable to fix the cooling body 3 and the guide plate 5 to the cooling body frame part 41 by fastening together.

  As described above, by arranging the pair of guide plates 5 outside the plurality of cooling bodies 3, the exhaust heat air can be smoothly guided forward. Therefore, the influence of wind or the like is eliminated, and the exhaust heat air smoothly blows through the front surface (and the back surface) of each cooling body 3, so that vaporization of the impregnated condensed water can be promoted.

Next, the cooling operation of the room air conditioner 100 and the accompanying cooling function of the exhaust heat air cooling device 1 will be described with reference to FIGS.
When the operation of the room air conditioner 100 is started, the outdoor unit 102 is first driven, and low-temperature and high-pressure refrigerant is prepared in the outdoor unit 102. Subsequently, the indoor unit 101 is driven, and the refrigeration cycle of the room air conditioner 100 is started. In the indoor unit 101, condensation occurs in the evaporator 105, and condensed water (condensed water) flows down to the condensed water introduction unit 4 (drain pan 11) via the condensed water pipe 108. The condensed water flowing down on the drain pan 11 is absorbed by the water absorption pad 12 and eventually flows down from the dripping portion 18a onto the uppermost cooling body 3 in the form of dripping. In the uppermost cooling body 3, the condensed water that has flowed down spreads over the entire area so as to spread out, and eventually saturates, and then flows down from the bent part or the grid part onto the cooling body 3 immediately below. In this way, the condensed water sequentially reaches the plurality of cooling bodies 3 and is impregnated in the absorber 22.

  On the other hand, as the outdoor unit 102 is driven, exhaust air is blown from the outlet 116. The exhaust heat air blows forward so as to trace the front and back of each cooling body 3, and vaporizes the condensed water impregnated in each cooling body 3. That is, the supply of the condensed water to each cooling body 3 and the vaporization of the condensed water in each cooling body 3 are performed continuously, and the exhaust heat air blown along the plurality of cooling bodies 3 is It is cooled by the heat exchange between them and the heat of vaporization of the condensed water. In this way, the cooled exhaust heat air is released into the atmosphere. Since the thing of embodiment is discharge | released to the veranda S2, the part is suck | inhaled from the suction inlet (illustration omitted) of the outdoor unit 102.

  Next, with reference to FIG. 5, the measurement results of the exhaust heat air temperature and the wind speed when the exhaust heat air cooling device 1 is used will be described. In this measurement, the indoor set temperature is set to 20 ° C., the temperature of the outdoor air A immediately before flowing into the suction port of the outdoor unit 102, and the pre-cooling exhaust at the position immediately after being blown out from the outlet 116 of the outdoor unit 102. The temperature of the hot air B and the temperature of the exhaust heat air C after cooling at the position immediately after passing through the cooling body 3 were measured over time (FIG. 5A). Further, at the position immediately after passing through the cooling body 3, the wind speed and the air volume of the exhaust heat air were measured with and without the exhaust heat air cooling device 1 (FIG. 5B).

  As shown in FIG. 5 (a), the outside air A reflects the outside air temperature, and is slightly higher than 32 ° C. in a time zone where the temperature fluctuation is small from 120 minutes to 300 minutes from the start of the operation of the outdoor unit 102. there were. The pre-cooling exhaust heat air B was a little less than 39 ° C. in the time period between 120 minutes and 300 minutes. On the other hand, the exhaust heat air C after cooling was a little less than 35 ° C. in the time period between 120 minutes and 300 minutes. However, in the time period from the start of operation to 60 minutes, the temperature difference between the pre-cooling exhaust heat air B and the post-cooling exhaust heat air C is not recognized so much. It is estimated that the temperature will drop (cool).

FIG. 5 (b) shows the wind speed and air volume measured seven times at 30-minute intervals for "before installation" without the exhaust heat air cooling device 1 and "after installation" with the exhaust heat air cooling device 1. It is. When the maximum value and the minimum value of the measurement results were deleted and averaged, the wind speed was 2.62 m / min and the air volume was 0.694 m ³ / min “before installation”. On the other hand, in “after installation”, the wind speed was 2.51 m / min, and the air volume was 0.665 m ³ / min. As a result, the decrease in wind speed was 0.11 m / min, and the decrease in air volume was 0.029 m ³ / min. In other words, although a loss of about 4.2% occurred in the air volume, it was confirmed that the flow path resistance by the cooling body 3 was extremely small.

  As described above, according to the present embodiment, the exhaust heat air of the outdoor unit 102 is allowed to pass (ventilate) along the plurality of cooling bodies 3, so the exhaust heat air is converted into condensed water. In addition to being able to be cooled by heat transfer (heat exchange), it can be efficiently cooled by the heat of vaporization of the condensed water. Moreover, since the condensed water of the indoor unit 101 is guided to the cooling body 3, the exhaust heat air can be cooled without requiring a separate water supply facility. That is, condensed water can be used effectively. Moreover, since the cooling body 3 is arrange | positioned with the attitude | position along the flow of exhaust heat air, air resistance is small and it can reduce the load to the outdoor unit fan 112. Therefore, it is possible to contribute to the elimination of the heat island phenomenon without increasing the power consumption.

  Next, with reference to FIG. 6, the second embodiment of the exhaust heat air cooling device 1 will be described mainly with respect to differences from the first embodiment. In this embodiment, unlike the first embodiment, a plurality of cooling bodies 3 are arranged in a staircase pattern. In other words, in the two cooling bodies 3 adjacent to each other in the vertical direction, the upper cooling body 3 is set back to the rear side of the outlet 116 with respect to the lower cooling body 3. Each cooling body 3 has an introduction gradient that is somewhat lower than the previous one. Further, the main frame portion 32 is disposed so as to be inclined obliquely so as to appropriately support the plurality of stepped cooling bodies 3.

  In such a configuration, when the condensed water is saturated in the uppermost cooling body 3 (absorber 22), the condensed water flows down from the front end of the cooling body 3 onto the cooling body 3 immediately below along the water guide gradient. To do. At that time, even if the condensed water flows forward due to the wind pressure of the exhaust heat air, it is received by the cooling body 3 directly below. In this way, the condensed water is supplied to all the cooling bodies 3. Therefore, similarly to the first embodiment, the exhaust heat air can be efficiently cooled by heat exchange with the exhaust heat air or by heat of vaporization of the condensed water.

  Next, with reference to FIG. 7, a different part from 1st Embodiment is mainly demonstrated about 3rd Embodiment of the exhaust heat air cooling device 1. FIG. The exhaust heat air cooling device 1 according to the third embodiment is incorporated in the outdoor unit 102. The exhaust heat air cooling apparatus 1 includes a plurality of cylindrical cooling bodies 3 having different diameters located at the outlet 116 of the outdoor unit 102. The plurality of cooling bodies 3 includes a large-diameter cooling body 3, a medium-diameter cooling body 3 and a small-diameter cooling body 3 concentrically with the air outlet 116, and are equally spaced in a radial direction (triple). It is arranged. In this case, the cooling body 3 having the largest diameter is formed with a smaller diameter than the outlet 116, and in each cooling body 3, exhaust heat air can be blown on the inner peripheral surface and the outer peripheral surface thereof. In addition, the number of the cooling bodies 3 is arbitrary.

  Also in this case, each cooling body 3 includes a net-like cylindrical base body 21 and an absorber 22 supported by the base body 21. The absorber 22 includes, for example, an inner periphery side absorber and an outer periphery side absorber (not shown), and is sandwiched and supported by the base body 21. In this case, it is preferable that the inner peripheral side absorbent body and the outer peripheral side absorbent body are bonded together with a hook-and-loop fastener or the like.

  The plurality of cooling bodies 3 configured as described above are attached to the cross-shaped frame 51 by cantilevering or welding on the outdoor unit 102 side. The frame 51 is fixed to the front panel 102a of the outdoor unit 102 from the inside. A cylindrical guide plate 5 is provided outside the large-diameter cooling body 3 so as to be concentric with the air outlet 116. The guide plate 5 is formed with a larger diameter than the outlet 116 and extends to the front position of the plurality of cooling bodies 3. The guide plate 5 is fixed to the front panel 102a of the outdoor unit 102 by a fixture or the like. The frame 51 may be fixed to the outside of the front panel 102a. In such a case, it is preferable that the guide plate 5 is also fixed to the frame 51.

  The condensed water introduction section 4 has an upstream end connected to the condensed water pipe 108 and has a distribution pipe 53 and three water spray pipes 54 attached to the top of each cooling body 3. The distribution pipe 53 is piped inside the outdoor unit 102, is branched into three at the downstream end, and is connected to the three sprinkling pipes 54. Each sprinkling pipe 54 penetrates the frame 51 and extends forward along the top of each cooling body 3, and a plurality of small holes are dispersedly formed on the peripheral surface thereof. The condensed water flowing down from the condensed water pipe 108 flows to the three water spray pipes 54 via the distribution pipe 53 and is absorbed by the absorber 22 of each cooling body 3.

  In this case, since the three cooling bodies 3 have different diameters, the amount of condensed water absorbed also differs. For this reason, it is preferable to adjust the supply flow rate to the three sprinkling pipes 54 in the distribution pipe 53. However, in the small-diameter cooling body 3 where the flow rate is the most excessive, the amount of liquid dripping moves to the medium-diameter cooling body 3, and the amount of liquid dripping in the medium-diameter cooling body 3 is transferred to the large-diameter cooling body 3. Therefore, the condensed water can be sufficiently distributed to the three cooling bodies 3 without adjusting the flow rate. As described above, also in the third embodiment, the exhaust heat air can be efficiently cooled by the heat exchange with the exhaust heat air and the heat of vaporization of the condensed water. A part or all of the plurality of cooling bodies 3 may be built in the outdoor unit 102.

  DESCRIPTION OF SYMBOLS 1 Waste heat air cooling device, 2 Support frame, 3 Cooling body, 4 Condensate introduction part, 5 Guide plate, 11 Drain pan, 12 Water absorption pad, 14 Startup part, 15 Notch part, 18 Hanging part, 18a Drop part, 21 Base body, 22 Absorber, 31 Upper frame part, 32 Main frame part, 34 Front hook part, 35 Rear hook part, 100 Room air conditioner, 101 Indoor unit, 102 Outdoor unit, 108 Condensate water pipe, 116 Outlet

Claims (9)

An exhaust heat air cooling device that is attached to an outdoor unit of an air conditioner and cools the exhaust heat air of the outdoor unit with condensed water flowing down from the indoor unit,
A plate-like cooling body that is disposed in front of the outlet of the outdoor unit and that cools the exhaust heat air by heat of vaporization of the impregnated condensed water;
A condensed water introduction section disposed above the cooling body and receiving the condensed water and guiding the condensed water to the cooling body,
The cooling body is disposed in a horizontal posture along the flow of the exhaust heat air ,
The said condensed water introduction part has a drain pan which guides the said condensed water to the said cooling body, and the water absorption pad laid on the said drain pan, The exhaust heat air cooling device characterized by the above-mentioned . The cooling body is exhaust heat air cooling device according to claim 1, characterized in that it consists of the plurality disposed to exist a mutually spacing. Each of the cooling bodies includes a net-like base body,
The exhaust heat air cooling device according to claim 2, further comprising an absorbent body supported by the base body and impregnated with the condensed water. 4. The exhaust heat air according to claim 2 , wherein the water absorption pad is formed with a dropping portion that protrudes from the drain pan and causes the uppermost cooling body to spill the condensed water. 5. Cooling system. The exhaust heat air cooling device according to claim 4 , wherein the dripping portion includes a plurality of projecting portions. The exhaust heat air cooling device according to any one of claims 2 to 5 , wherein each of the cooling bodies has a water guide gradient that is inclined downward toward the center. In the two adjacent cooling bodies in the vertical direction, the upper cooling body is set back with respect to the lower cooling body and is set back on the outlet side.
The exhaust heat air cooling device according to any one of claims 2 to 5 , wherein each of the cooling bodies has a water guide gradient that is lowered downward. A support frame for supporting the cooling body;
The support frame, exhaust heat air cooling device according to any of claims 1 to 7, characterized in that it has a latching portion that is latched to the outdoor unit. 9. The exhaust heat air cooling device according to claim 1 , further comprising a guide plate disposed outside the cooling body and guiding the exhaust heat air forward.

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