CN101523123B - Air conditioner - Google Patents

Abstract

An air conditioner that, even if a drain passage for condensed water straddles a portion where condensation by cooling is not desired, can avoid cooling of the portion. The air conditioner has a rear heat exchanger (10b), a rear drain pan (70), and guide ribs (76a to 76c). The rear drain pan (70) has a vertical surface part (75), an upper drain pan (72), and a lower drain pan (77). The vertical surface part (75) is a member expanding generally vertically. The upper drain pan (72) extends from the upper end toward one side when viewed from the vertical surface part (75). The lower drain pan (77) extends from a low position toward the other side on the generally opposite side of one side of the vertical surface part (75). The rear drain pan (70) is obliquely disposed so that condensed water generated in the rear heat exchanger (10b) is received by the upper drain pan (72), led over the vertical surface part (75), and guided to an outlet (80) through the lower drain pan (77). The guide ribs (76a to 76c) are formed so as to extend from near the upper end of the vertical surface part (75) toward the other side.

Description

Aircondition

Technical field

The aircondition that the condensed water that the present invention relates to produce at heat exchanger is discharged.

Background technology

In the past, in aircondition, when cooling operation or when running dehumidifying room air in heat exchanger, produced under the situation of condensed water at the surface condensation of heat exchanger by heat exchange, airborne moisture, carry out draining via drainage mechanism.

In this case, owing to the condensed water at the surface condensation of heat exchanger is the water that airborne moisture is cooled and produces, so temperature is low.Therefore, this cold condensed water is being guided in the way of discharge outlet, the part of being flowed through is produced time condensation in the part that is cooled sometimes by cold condensed water cooling.

To this, for example in the aircondition of patent documentation shown below 1 record, following aircondition has been proposed: as drainage mechanism, between the part of part of not wishing to produce the condensation that causes by cooling and condensation flow warp, the space is set, avoids time condensation to carry out draining simultaneously thus.

Patent documentation 1: Japanese kokai publication hei 9-96423 communique

But, in the aircondition that above-mentioned patent documentation 1 is put down in writing, for example when the part of not wishing to produce the condensation that causes by cooling long and when big, need to be provided with the space corresponding with it, the situation that have that the structure scale that is used to be provided with this space is big, number of components increase, production cost is increased.

And then, in the aircondition that above-mentioned patent documentation 1 is put down in writing, the structure that the space that is provided with in order to prevent time condensation forms the structure of the current setting that is directed along condensed water, promptly is provided with along the part of not wishing to produce condensation.Therefore,, can't use same technology, be difficult to suppress the cooling of this part forming under the situation that makes the structure that cold condensed water flows in the mode of crossing over the part do not wish to produce condensation.

Summary of the invention

The present invention finishes in view of the above problems, even problem of the present invention is to provide the aircondition that also can avoid the cooling of this part under the discharge path of condensed water is crossed over the situation of structure of the part of wanting to avoid the condensation that caused by cooling.

The related aircondition of first aspect present invention is that the condensed water that will produce owing to heat exchange guides to the aircondition that outlet is also discharged, and described aircondition has heat exchanger, guide portion and rib.Guide portion has predetermined vertical parts, high guide portion and low guide portion.These predetermined vertical parts are parts of generally perpendicularly expanding.Observe from the predetermined vertical parts, high guide portion is side extension facing one direction from the upper end.Low guide portion from than the low position of high guide portion towards extending with the other direction side of a roughly opposite side of direction side of predetermined vertical parts.This guide portion sets obliquely, via low guide portion it is guided to outlet to be received in the condensed water that produces in the heat exchanger at high guide portion side joint and to cross over the predetermined vertical parts.Rib is to be provided with near the mode of extending towards the other direction side upper end of predetermined vertical parts.

Herein, owing to the condensed water that produces that is cooled of the heat exchange in the heat exchanger is received in high guide portion side, and, on low guide portion, flow by crossing over the predetermined vertical parts in upper surface transmission near extend towards the downstream of the current of condensed water the upper end of predetermined vertical parts rib.Therefore, the condensed water that produces in heat exchanger is directed to discharge outlet.

Thereby the condensed water that produces in heat exchanger can not transmit on the predetermined vertical parts via high guide portion, can prevent the cooling of predetermined vertical parts with the mode draining that does not directly contact with the predetermined vertical parts.

Thus, even cross at the discharge path of condensed water under the situation of structure of the predetermined vertical parts of wanting to avoid the condensation that causes by cooling, also can avoid the cooling of these predetermined vertical parts, can suppress to be cooled and the time condensation that produces by the predetermined vertical parts.

In addition, even because surface tension makes condensed water want from high guide portion towards the transmission of predetermined vertical parts, extend towards the downstream of the current of condensed water and under the situation that can stop, condensed water is directed to the front end of rib, can not return the predetermined vertical component side at rib.Therefore thus, condensed water flows down in the mode of leaving from the predetermined vertical parts, can avoid contacting of cold condensed water and predetermined vertical parts more reliably.

For the related aircondition of second aspect present invention, in the related aircondition of first aspect present invention, rib has the part that tilts to the other direction side-lower in the other direction side.

Herein, because the other direction side direction other direction side-lower of rib tilts, therefore can stop and transmit overleaf after the upper surface that flows through rib and return the current of the such condensed water of predetermined vertical parts.

Thus, can avoid the cooling of predetermined vertical parts more reliably.

For the related aircondition of third aspect present invention, in the related aircondition of first aspect present invention or second aspect, rib has first rib and the second rib that leaves setting mutually.Observe from first rib, it is the other direction side that second rib is configured in the below.And then first rib and second rib at least a portion when overlooking is overlapping.

Herein, because first rib and second rib leave configuration mutually, even thereby therefore because condensed water transmits first rib and is cooled on first rib, condensed water also can be towards the second rib transmission that is positioned to the position that opposite side leaves.Thus, the water-cooled part that is condensed is left as far as possible from the predetermined vertical parts.In addition, even the rear side because first rib is cooled at first rib produces time condensation, because the condensed water that this time condensation produces can not contact with the predetermined vertical parts yet, but the other direction side from first rib is directed to second rib along the back side of first rib, can avoid the cooling of predetermined vertical parts more reliably.

In the aircondition of first aspect present invention, even cross at the discharge path of condensed water under the situation of structure of the predetermined vertical parts of wanting to avoid the condensation that causes by cooling, also can avoid the cooling of these predetermined vertical parts, can suppress to be cooled and the time condensation that produces by the predetermined vertical parts.

In the aircondition of second aspect present invention, can stop and transmit overleaf after the upper surface that flows through rib and be back to the current of the such condensed water of predetermined vertical parts, can avoid the cooling of predetermined vertical parts more reliably.

In the aircondition of third aspect present invention, the water-cooled part that is condensed is left as far as possible from the predetermined vertical parts.In addition,, also can not contact, but the other direction side from first rib is directed to second rib along the back side of first rib, can avoid the cooling of predetermined vertical parts more reliably with the predetermined vertical parts even produce time condensation in the rear side of first rib.

Description of drawings

Fig. 1 is the outside drawing that adopts the aircondition of first embodiment of the present invention.

Fig. 2 is the structure chart of refrigerant loop.

Fig. 3 is the summary stereogram of indoor set.

Fig. 4 is the stereogram that the internal structure of indoor set is shown.

Fig. 5 is the right side pseudosection of indoor set.

Fig. 6 is the right side pseudosection of back side framework.

Fig. 7 is the vertical view of back side framework.

Fig. 8 is the front view of back side framework.

Fig. 9 is the rearview of back side framework.

Figure 10 is illustrated in the rearview that the state of heat-insulating material is installed on the framework of the back side.

Figure 11 is the figure that near the detailed construction the guiding rib of back side framework is shown.

Symbol description

1: indoor set;

2: off-premises station;

10b: back square heat-exchanger (heat exchanger);

72: top drain pan (high guide portion);

73: the top rib;

74: the top bottom surface sections;

75: vertical surface part (predetermined vertical parts);

76a～76c: first guiding rib～the 3rd guiding rib (first rib～the 3rd rib);

77: lower drain pan (low guide portion);

80: discharge outlet;

100: aircondition.

The specific embodiment

Below, the embodiment to the aircondition that the present invention relates to describes with reference to the accompanying drawings.

The summary structure of＜aircondition 〉

Adopted the aircondition 100 of an embodiment of the invention to have the indoor set 1 that is used to be arranged on the indoor wall and be used to be arranged on outdoor off-premises station 2.

Taken in heat exchanger respectively in indoor set 1 He in the off-premises station 2, each heat exchanger connects by refrigerant piping 5, constitutes refrigerant loop thus.

The structural outline of the refrigerant loop of＜aircondition 100 〉

The structure of the refrigerant loop of aircondition shown in Fig. 2 100.

This refrigerant loop mainly is made of indoor heat converter 10, gas receiver (accumulator) 21, compressor 22, No. four transfer valves 23, outdoor heat converter 20 and expansion valve 24.

Be arranged between indoor heat converter 10 and its air that is contacted in the indoor set 1 and carry out heat exchange.Herein, as shown in Figure 5, indoor heat converter 10 is made of with the back square heat-exchanger 10b that is configured in the rear the preceding square heat-exchanger 10f in the place ahead that is configured in indoor set 1.Below the bottom, the place ahead of this preceding square heat-exchanger 10f, be provided with the place ahead drain pan 60 of the condensed water of the airborne moisture that produces among the square heat-exchanger 10f before being captured in.And then the below of the bottom, rear of heat exchanger 10b is provided with the rear drain pan 70 of the condensed water that is captured in the airborne moisture that produces among the square heat-exchanger 10b of back in the wings.And, in indoor set 1, be provided with and be used to suck room air and will have carried out heat-exchanged air by indoor heat converter 10 and be expelled to indoor cross flow fan 11.Cross flow fan 11 is driving and is rotating by being arranged on 1 indoor fan motor 12 in the indoor set 1.As Fig. 2, Fig. 4 and shown in Figure 5 as the side view of indoor set 1, cross flow fan 11 is configured in the indoor set shell 4, in indoor set shell 4, suction inlet 42 is arranged on the place ahead, top, and blow-off outlet 49 is arranged on the below.As Fig. 3, shown in Figure 5, in this indoor set shell 4, side is provided with front panel 41 in front, and side is provided with installing plate 43 overleaf.As shown in Figure 3, Figure 4, below the preceding square heat-exchanger 10f of the inboard that is disposed at front panel 41, be provided with the place ahead drain pan 60.This place ahead drain pan 60 has along the water acceptance division 61 of the length direction extension of indoor set 1 and near the slot part 62 that connects in the fore-and-aft direction part substantial middle of length direction.And then, as Fig. 5, shown in Figure 6, dispose the back side framework 50 of the rotary shaft etc. of supporting back square heat-exchanger 10b and cross flow fan 11 in the inboard of this installing plate 43.As shown in figure 10, the local adhesion in the rear side of framework 50 below has heat-insulating material 90 overleaf.The preceding square heat-exchanger 10f of indoor heat converter 10 and back square heat-exchanger 10b indoor set shell 4 in between cross flow fan 11 and suction inlet and surround the mutual multistage bending of mode of cross flow fan 11 and dispose.When cross flow fan 11 had been driven rotation, indoor set 1 was taken into room air via indoor heat converter 10, and made by the tempered air after the heat exchange and once more in the return chamber, thus air conditioning is carried out in the space as object.

In off-premises station 2, be provided with: compressor 22; No. four transfer valves 23 that are connected with the discharge side of compressor 22; The gas receiver 21 that is connected with the suction side of compressor 22; The outdoor heat converter 20 that is connected with No. four transfer valves 23; And the expansion valve 24 that is connected with outdoor heat converter 20.Expansion valve 24 is connected with pipe arrangement via liquid draught excluder 26, and is connected with an end of indoor heat converter 10 via this pipe arrangement.And No. four transfer valves 23 are connected with pipe arrangement via gas draught excluder 27, and are connected via the other end of this pipe arrangement with indoor heat converter 10.And, in off-premises station 2, be provided with and be used for being expelled to outside propeller type fan 28 carry out heat-exchanged air at outdoor heat converter 20.This propeller type fan 28 is being driven by outdoor fan motor 29 and is rotating.

Below, back square heat-exchanger 10b is made airborne condensate moisture and the drainage mechanism of the condensed water that produces describes.

＜back side framework 50 〉

As shown in Figure 5, back side framework 50 has: fan support 53, and it is configured between the installing plate 43 and back square heat-exchanger 10b of indoor set 1, and at shaft portion supporting cross flow fan 11 (with reference to Fig. 3); Will be to baffle plate 59 baffle plate support 57 and the baffle plate bearing portions 58 of supporting that regulate from the flow direction of the blow out air of blow-off outlet 49 for rotating; And the condensed water that will be in the wings produces among the heat exchanger 10b rear drain pan 70 of discharging is (with reference to Fig. 6～Figure 10).

Herein, the right side pseudosection of the framework of the back side shown in Fig. 6 50.And then, the vertical view of observing from top (direction of among Fig. 6, representing) shown in Fig. 7 with arrow A, the front view that (direction of representing with arrow B among Fig. 6) observes from the front shown in Fig. 8, the rearview that (direction of representing with arrow C among Fig. 6) observes from the back side shown in Fig. 9.In addition, Figure 10 illustrates the rearview of back side framework 50, and the state that heat-insulating material 90 is installed is shown.

As shown in figure 11, be provided with in the rear of this back side framework 50 drain pan 70: side is used for the condensed water from back square heat-exchanger 10b drippage is delivered to the backside openings 71 of rear side in front one-body moldedly; Top drain pan 72, lower drain pan 77, vertical surface part 75 and the guiding rib 76 of side to be provided with overleaf to the side-prominent mode in the back side; And discharge outlet 80.Vertical surface part 75 is provided with in the mode of an end of the end that connects top drain pan 72 and lower drain pan 77.In addition, shown in Figure 11 overleaf the rearview of framework 50 be the local amplification stereogram of the P portion that surrounds with chain-dotted line among Fig. 9.

As Figure 11, Fig. 7～shown in Figure 10, backside openings 71 is the openings that are used for the cold condensed water that the back square heat-exchanger 10b at the front side that is disposed at back side framework 50 produces is guided to the rear side of back side framework 50, at approximate vertical direction opening.

Shown in Fig. 9 waits, discharge outlet 80 is following openings: thus the condensed water that is directed to rear side via backside openings 71 flows with the order of transmitting and be directed rib 76a～76c guiding leap vertical surface part 75 on the drain pan 72 up, transmit on lower drain pan 77, and final condensed water is directed to this discharge outlet 80 and carries out draining.This discharge outlet 80 is connected with not shown scupper hose, thus condensed water is sent to outdoor from indoor.In addition, below, in Figure 11 etc. with drawing on roughly left side (direction that condensation flow is come) be called " upstream side ", with drawing on roughly right side (direction that condensed water flows away) be called " downstream " and describe.

Top drain pan 72 has: receive and guide to the top rib 73 of guiding rib 76a via backside openings 71 fallen condensed waters and with it; And top bottom surface sections 74.Top rib 73 leans on the top slightly than top bottom surface sections 74, and is provided with in the mode of extending in parallel to each other at length direction.The top rib 73 of this top drain pan 72 and top bottom surface sections 74 tilt up to the downstream (tilting from horizontal direction about about 1 degree) slightly from upstream side, so that condensed water is towards below drain pan 77 side flow.

As shown in figure 11, guiding rib 76a～76c has the first guiding rib 76a, the second guiding rib 76b and the 3rd guiding rib 76c.First～the 3rd guiding rib 76a～76c forms the shape that about 45 sloping portions of spending that tilt below the downstream along the horizontal component of general horizontal direction (tilting about about 1 degree from horizontal direction) extension with in the downstream at upstream side are formed by connecting.The upstream-side-end of the approximate horizontal part of the first guiding rib 76a is connected smoothly with the end of downstream side of identical angle of inclination with the top bottom surface sections 74 of top drain pan 72.The second guiding rib 76b is configured in from the below, downstream that the first guiding rib 76a observes, though not overlapping mutually in side view, the part of the horizontal component of the part of the sloping portion of the first guiding rib 76a and the second guiding rib 76b is overlapped in vertical view.The 3rd guiding rib 76c too, be configured in from the below, downstream that the second guiding rib 76b observes, though not overlapping mutually in side view, the part of the horizontal component of the part of the sloping portion of the second guiding rib 76b and the 3rd guiding rib 76c is overlapped in vertical view.

Lower drain pan 77 is positioned at the below of guiding rib 76a～76c.Above-mentioned vertical surface part 75 utilizes the face of expansion in vertical direction to connect the upstream-side-end of this lower drain pan 77 and the end of downstream side of top drain pan (top bottom surface sections 74).For condensed water being guided to discharge outlet 80, this lower drain pan 77 is also from upstream side tilt slightly up to the downstream (tilting from horizontal direction about about 1 degree).

＜heat-insulating material 90 〉

As shown in figure 10, the adhesion of the below of the lower drain pan 77 of framework 50 has heat-insulating material 90 overleaf.Thus, when making cold condensed water when lower drain pan 77 flows and it is guided to discharge outlet, even lower drain pan 77 is cooled, also can suppress the part that airborne moisture flows through at condensed water the back side (below) condensation and produce the situation of adhering to of time condensation water.

The drainage path of＜condensed water 〉

Condensation and the cold condensed water that produces is directed to the rear side of back side framework 50 via the backside openings 71 of above-mentioned back side framework 50 among the heat exchanger 10b in the wings.

This cold condensed water that is directed to rear side is received by top drain pan 72 (being mainly top rib 73), and is directed to the horizontal component of the first guiding rib 76a.

The cold condensed water that is directed to the horizontal component of the first guiding rib 76a transmits on the sloping portion of the first guiding rib 76a, and drips towards the horizontal component of the second guiding rib 76b from the end of downstream side of the first guiding rib 76a.The condensed water that drops to the horizontal component of the second guiding rib 76b transmits on the sloping portion of the second guiding rib 76b, and drips towards the horizontal component of the 3rd guiding rib 76c from the end of downstream side of the second guiding rib 76b.The condensed water that drops to the horizontal component of the 3rd guiding rib 76c transmits on the sloping portion of the 3rd guiding rib 76c, and drips towards lower drain pan 77 from the end of downstream side of the 3rd guiding rib 76c.

The condensed water that drops to lower drain pan 77 is along with the inclination slightly of lower drain pan 77 is directed to discharge outlet 80.

Like this, owing to cold condensed water can not transmit on vertical surface part 75, so vertical surface part 75 can not be cooled.Thus, airborne moisture can condensation and attached on vertical surface part 75 and a face side opposition side that is provided with guiding rib 76a～76c that condensed water flows through.

And, because cold condensed water flows in the mode along the top rib 73 of top drain pan 72, substantially flow on the bottom surface sections 74 up, therefore top bottom surface sections 74 is difficult to be cooled.Thus, airborne moisture is difficult on condensation and the face attached to the following side of top bottom surface sections 74.

The feature of the aircondition 100 of＜present embodiment 〉

(1)

In the aircondition 100 of present embodiment, as mentioned above, with the lower part heat-insulating material 90 be not set especially: the part of top drain pan 72 and the side opposition side condensation flow warp, and part vertical surface part 75 and the side opposition side condensation flow warp.This is because in the drain pan 72, cold condensed water is not to flow along top bottom surface sections 74, but mainly flows along top rib 73 up.Therefore, cold condensed water is difficult to up to transmit on the bottom surface sections 74, and top bottom surface sections 74 is difficult to be cooled, so the following side of drain pan 72 (top bottom surface sections 74) airborne condensate moisture can not occur and produce the situation of adhering to of time condensation water up.And in vertical surface part 75, cold condensed water is not to flow down along vertical surface part 75, but mainly flows down along guiding rib 76a～76c.Therefore, cold condensed water is difficult to transmit on vertical surface part 75, vertical surface part 75 is difficult to be cooled, so airborne condensate moisture can not occur in the rear side (opposition side of a side of condensation flow warp) of vertical surface part 75 and produce the situation of adhering to of time condensation water.

Therefore, above-mentioned heat-insulating material 90 does not need to be arranged to be crimped onto the top bottom surface sections 74 of vertical surface part 75 or top drain pan 72 always.Therefore, the amount of the heat-insulating material 90 of needs can be suppressed to make air conditioner 100 at an easy rate for less.

In addition, even because the surface tension of condensed water makes condensed water want 75 transmission from top drain pan 72 towards vertical surface part, because guiding rib 76a～76c extends and channeling conduct towards the downstream of the current of condensed water, therefore can stop condensed water to be passed to vertical surface part 75 sides.Thus, can avoid contacting of cold condensed water and vertical surface part 75 more reliably.

(2)

In the aircondition 100 of present embodiment,, therefore can stop the current that transmit and turn back to the such condensed water of vertical surface part 75 after the upper surface that flows through guiding rib 76a～76c overleaf because guiding rib 76a～76c has the oblique part of square neck down.Thus, can avoid the cooling of vertical surface part 75 more reliably.

(3)

In the aircondition 100 of present embodiment, because guiding rib 76a～76c leaves configuration each other mutually, therefore, even for example because condensed water transmits on the first guiding rib 76a and makes the first guiding rib 76a be cooled, condensed water also can be towards the second guiding rib 76b transmission that is positioned at the position that side downstream leaves.Thus, the water-cooled part that is condensed is left as far as possible from vertical surface part 75.In addition, even make rear side produce time condensation at the first guiding rib 76a because the first guiding rib 76a is cooled, the condensed water that produces because of this time condensation can not contact with vertical surface part 75 yet, but the downstream from the first guiding rib 76a is directed to the second guiding rib 76b along the back side of the first guiding rib 76a, can avoid the cooling of vertical surface part 75 more reliably.

＜variation 〉

More than describe the present invention, still, concrete structure is not limited to above-mentioned embodiment, can change in the scope of the purport that does not break away from invention.

(A)

In the aircondition 100 of the first above-mentioned embodiment, enumerated the face component of expanding in the approximate vertical direction as vertical surface part 75.

But, the invention is not restricted to this, for example, vertical surface part 75 also can be from the upper end towards the lower end the oblique structure of inclination slightly downstream, also can be the oblique structure of inclination slightly upstream.

(B)

In the aircondition 100 of the first above-mentioned embodiment, understand that for example the back side (side that condensed water is not flowed through) of dorsal part (side that condensed water is not flowed through) in vertical surface part 75 and top drain pan 72 is not provided with the situation of heat-insulating material 90.

But, the invention is not restricted to this, for example, also can be in this position, be the back side (side that condensed water is not flowed through) of the dorsal part (side that condensed water is not flowed through) of vertical surface part 75 and top drain pan 72 also is provided with heat-insulating material 90 in the mode of extending structure.

In this case, can prevent the generation of secondary dewfall more fully.

Utilizability on the industry

If utilize the present invention, even cross at the discharge path that forms condensed water in the situation of structure of the part want to avoid the condensation that caused by cooling, also can avoid the cooling of this part, the aircondition that the condensed water that therefore, especially can be applied to produce owing to heat exchange guides to outlet and discharges.

Claims (1)

1. an aircondition (100), described aircondition (100) will guide to outlet (80) owing to the condensed water that heat exchange produces and discharge, wherein,

Described aircondition (100) has:

Heat exchanger (10b);

Guide portion (70), this guide portion (70) has: Kuo Zhan predetermined vertical parts (75) generally perpendicularly; Observe the high guide portion (72,73,74) of side extension facing one direction from the upper end from described predetermined vertical parts (75); And from than the low position of described high guide portion (72,73,74) towards the low guide portion (77) of extending with the other direction side of the described roughly opposite side of direction side of described predetermined vertical parts (75), described guide portion (70) sets obliquely, via described low guide portion (77) it is guided to described outlet (80) to be received in the condensed water that produces in the described heat exchanger (10b) at described high guide portion (72,73,74) side joint and to cross over described predetermined vertical parts (75); And

From near the rib (76a, 76b, 76c) that extends towards described other direction side the upper end of described predetermined vertical parts (75),

Wherein, described rib (76a, 76b, 76c) has the part that tilts to described other direction side-lower in described other direction side,

Described rib (76a, 76b, 76c) has the first rib (76a, 76b) that leaves setting mutually and is configured in the below from described first rib (76a, 76b) observation is the second rib (76b, 76c) of described other direction side,

At least a portion is overlapping when overlooking for described first rib (76a, 76b) and described second rib (76b, 76c).

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