The present invention relates to an air conditioner, and in particular to an air conditioner having a freeze prevention pipe.
When heating operation of an air conditioner causes frost to form at an outdoor heat exchanger arranged within an outdoor unit, defrosting operation, which is a reverse-cycle operation to heating operation, is performed in order to melt the frost. Upon performing defrosting operation, the outdoor heat exchanger functions as a condenser to dissipate heat, and the formed frost is thawed. Melting of the frost produces thaw water, which falls down from the outdoor heat exchanger and is collected as drain water at a base plate arranged below the outdoor unit and discharged from a drain hole provided in the base plate.
When this defrosting operation is performed under such a severely cold environment that the outdoor temperature stays below the freezing point, drain water flew out to the base plate is cooled to freeze before arriving at the drain hole and becomes no longer dischargeable from the drain hole. Frozen drain water gradually grows larger on the base plate, and eventually causes destruction of the outdoor heat exchanger, an outdoor fan or the like. In addition, even when it does not reach to the point that drain water freezes during flowing out, snow or the like blown into the inside of the outdoor unit or on the base plate may hinder discharge of drain water, which results in freezing of the undischarged drain water, which causes destruction of the outdoor heat exchanger or the like.
To avoid such problems, a water heater in which a portion of high-pressure-side refrigerant piping of a refrigerating cycle is arranged above a base plate is disclosed in a prior art document, Japanese Patent Laying-Open No. 2004-218861 (Patent Document 1). Japanese Patent Laying-Open No. 2004-218861 discloses a drain-pan freeze-prevention structure in which refrigerant piping for freeze prevention is routed in a heat-transmittable manner above a drain pan comprised of base plates and located below an air heat exchanger. Further, an evaporator having a structure in which a refrigerant at a high temperature is allowed to pass through the bottom piping of an outdoor heat exchanger in defrosting operation, thereby increasing an amount of heat given to frost on the drain pan to facilitate thawing of frost is disclosed in a prior art document, Japanese Patent Laying-Open No. 58-49878 (Patent Document 2). An air conditioner having a structure in which a drain outlet is provided below an outdoor heat exchanger, and the vicinity of a drain route is heated by a heater or a base plate heater is disclosed in a prior art document, Japanese Patent Laying-Open No. 2005-49002 (Patent Document 3).
When a heater is employed as a source of heat for heating a drain pan, high power consumption is an obstacle in achieving energy saving. When refrigerant piping which is on a high-pressure side of a refrigerating cycle is used as a source of heat for heating a drain pan, lower power consumption than that of a heater can be achieved; however, without effective use of the heat dissipated by the high-pressure-side refrigerant piping, thawing of frost cannot be effectively performed. Patent Document 1 does not describe the positional relationship between the high-pressure-side refrigerant piping and the drain outlet for discharging drain water and discloses nothing leading to a structure in which thawing of frost can be effectively performed with suppressed power consumption. Since the evaporator described in Patent Document 2 employs a drain pan heater, lower power consumption cannot be achieved sufficiently. The air conditioner described in Patent Document 3 is provided with the drain outlet below the outdoor heat exchanger. In the air conditioner described in this document, however, the base plate heater is provided in the proximity of a lateral part of the drain outlet, which results in heating of frost through the base plate and large heat loss. This causes a large increase in power consumption.
The present invention has been made in view of the problems above, and an object of the invention is to provide an air conditioner in which discharge of drain water can be maintained by preventing drain water from freezing or by thawing frozen drain water, while achieving lower power consumption.
An air conditioner according to the present invention includes a refrigerating cycle including a compressor compressing a refrigerant, an indoor heat exchanger exchanging heat between the refrigerant and the indoor air, a pressure-reducing expansion mechanism reducing pressure of and expanding the refrigerant, and an outdoor heat exchanger exchanging heat between the refrigerant and the outdoor air. The air conditioner according to the present invention further has a base plate arranged below the outdoor heat exchanger and having a drain outlet formed at a position opposing the undersurface of the outdoor heat exchanger, and a freeze prevention pipe arranged between the outdoor heat exchanger and the base plate in a manner, in plan view, to at least partially pass inside the region of the drain outlet. The freeze prevention pipe is connected between the outdoor heat exchanger and the indoor heat exchanger.
According to the present invention, discharge of drain water can be maintained by preventing drain water from freezing or by thawing frozen drain water, while achieving lower power consumption by efficiently utilizing the heat from a freeze prevention pipe.
10 compressor, 20 four-way valve, 30 indoor heat exchanger, 40 refrigerant piping, 41 freeze prevention pipe, 42 the bottom piping, 50 expansion valve, 60 outdoor heat exchanger, 61 fin, 70 base plate, 71 drain outlet, 80 water shield wall, 90 ice, 100 outdoor unit, 200 indoor unit.
An air conditioner in the embodiments based on the present invention will be hereinafter described with reference to the drawings.
First Embodiment
With reference to
As shown in
As shown in
The outdoor unit of the air conditioner according to the present embodiment will be hereinafter described with reference to
At outdoor heat exchanger 60, a plurality of fins 61 each having an approximately rectangular shape are arrayed with the longitudinal direction vertically directed, being spaced apart by a small clearance, and in parallel to one another. Refrigerant piping 40 is provided in a manner to horizontally penetrate through a formed group of fins. This configuration increases the surface area of outdoor heat exchanger 60 and ensures the contact area with the surrounding air available for heat exchange with a refrigerant.
In base plate 70, a plurality of drain outlets 71 are provided at positions opposing the undersurface of outdoor heat exchanger 60. Drain water flowed out from outdoor heat exchanger 60 is collected on base plate 70 and discharged from drain outlet 71 to the outside. Since a plurality of drain outlets 71 are provided, it is only necessary for drain water to be discharged at any of drain outlets 71, and the possibility of drain failure is decreased. Freeze prevention pipe 41 is arranged between outdoor heat exchanger 60 and base plate 70 in a manner, in plan view, to pass through inside the regions of drain outlets 71. For freeze prevention pipe 41, a material with good thermal conductivity is used, for example, a copper pipe or the like is used. In the present embodiment, the outer diameter of the piping of outdoor heat exchanger 60 and the outer diameter of the piping of freeze prevention pipe 41 are the same, however, they may differ from each other. For example, refrigerant piping 40 of outdoor heat exchanger 60 may have an outer diameter of 7 mm and the piping of freeze prevention pipe may have an outer diameter of 6.35 mm, such that the outer diameter of the piping of outdoor heat exchanger 60 is larger than the outer diameter of the piping of freeze prevention pipe 41. It is noted that in the present embodiment, freeze prevention pipe 41 is arranged such that the pipe, in plan view, entirely passes inside the regions of drain outlets 71; however, freeze prevention pipe 41 may be arranged such that the pipe, in plan view, at least partially passes inside regions of drain outlets 71.
Also, since freeze prevention pipe 41 is arranged to pass inside the region of drain outlet 71, a portion of drain outlet 71 (L2-L1) exists outside freeze prevention pipe 41. This allows drain water and the like flowing in from outside freeze prevention pipe 41 to be discharged from a portion of drain outlet 71 (L2-L1). Further, arranging freeze prevention pipe 41 in a manner to allow a portion of drain outlet 71 to exist on both outer sides of freeze prevention pipes 41 arranged in parallel to each other, allows drain water on both outer sides of freeze prevention pipes 41 to be discharged from a portion of drain outlet 71. As shown in
Next, defrosting action in the air conditioner in the present embodiment will be described. As described before, once heating operation is started, a refrigerant at a high temperature and discharged from compressor 10 is sent via four-way valve 20, indoor heat exchanger 30, freeze prevention pipe 41, expansion valve 50, outdoor heat exchanger 60, and four-way valve 20 to compressor 10. The temperature of the refrigerant when passed through indoor heat exchanger 30 and arriving at freeze prevention pipe 41 is maintained at not less than 0° C. Therefore, the surface temperature of freeze prevention pipe 41 is higher than the temperature of ice 90 which exists in the proximity of freeze prevention pipe 41, and the heat dissipated from the refrigerant heats ice 90. For example, ice 90 at a temperature of −20° C. can be heated by freeze prevention pipe 41 to an elevated temperature of about −7° C.
When continuous heating operation causes frost formation to progress at outdoor heat exchanger 60, operation of the air conditioner switches to defrosting operation. As described before, once defrosting operation is started, a refrigerant at a high temperature and discharged from compressor 10 is sent via four-way valve 20, outdoor heat exchanger 60, expansion valve 50, freeze prevention pipe 41, indoor heat exchanger 30, and four-way valve 20 to compressor 10. At this time, the refrigerant at a high temperature flows from the bottom piping 42 into outdoor heat exchanger 60, which causes a lower part of outdoor heat exchanger 60 to be the warmest location in outdoor heat exchanger 60. For this reason, initially, frost at the lower part of outdoor heat exchanger 60 is thawed, and frost at an upper part is gradually thawed. When defrosting progresses on outdoor heat exchanger 60, warm thaw water of melted frost drips down in the proximity of ice 90 freezing on base plate 70. Ice 90 in the vicinity of freeze prevention pipe 41 is easily dissolved upon mixing with this thaw water, since the ice was heated in heating operation to have an elevated temperature. When drain outlet 71 is blocked by ice 90, a concave dent is formed in ice 90 at a portion dissolved by thaw water, and further, thaw water flows into the dent, thereby facilitating dissolution of ice 90. This results in that drain outlet 71 can be opened to maintain discharge of drain water. It is noted that also when drain outlet 71 is not blocked by ice 90, dissolution of ice 90 progresses from a portion mixed with thaw water, and thus drain outlet 71 can be kept open.
If ice 90 which exists in the vicinity of drain outlet 71 were not pre-heated by freeze prevention pipe 41 in heating operation, ice 90 in the vicinity of drain outlet 71 could not be effectively dissolved by thaw water alone. Consequently, there is a possibility that thaw water accumulates on base plate 70 as being cooled and that ice 90 grows to lead to destruction of outdoor heat exchanger 60, an outdoor fan and the like. In the present embodiment, since ice 90 which exists in the vicinity of drain outlet 71 is pre-heated by freeze prevention pipe 41 in heating operation, it can be ensured that drain outlet 71 is open, and drain failure can be made unlikely. It is noted that more preferably, outdoor heat exchanger 60 and freeze prevention pipe 41 are arranged out of contact with each other. Arrangement in such a manner can prevent direct heat exchange between freeze prevention pipe 41 at a high temperature and outdoor heat exchanger 60 at a low temperature in heating operation. This results in that freeze prevention pipe 41 can sufficiently heat ice 90, and that the dissolution efficiency of ice 90 can be maintained high.
Second Embodiment
Next, an air conditioner of a second embodiment of the present invention will be described with reference to
As shown in
As a modification of the first and second embodiments, the shape of drain outlet 71 may be an oval shape having the longitudinal direction in a direction along which freeze prevention pipe 41 extends.
It should be noted that foregoing embodiments disclosed herein are by way of illustration in every respect and not to be taken by way of limitation. Therefore, the technical scope of the present invention is not construed only by the above-described embodiments, but defined based on the recitation of claims and includes all modifications equivalent in meaning and scope to the claims.
Number | Date | Country | Kind |
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2008-215544 | Aug 2008 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2009/056594 | 3/31/2009 | WO | 00 | 2/24/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/023986 | 3/4/2010 | WO | A |
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2407278 | Nov 2000 | CN |
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58-49878 | Mar 1983 | JP |
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Entry |
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International search report dated Jun. 2, 2009 for PCT/JP2009/056594. |
Number | Date | Country | |
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20110154845 A1 | Jun 2011 | US |