JP2008202899A - Heat exchanger - Google Patents

Abstract

[PROBLEMS] To prevent the occurrence of water splattering and spraying due to condensed water in an air heat exchanger such as an air conditioner.
In an air heat exchanger such as an indoor unit for an air conditioner, a part or all of which is installed in a state where the air passage is inclined in a horizontal direction by a predetermined angle or more in a ventilation passage, the heat exchange inclined by the predetermined angle or more. A V-shaped, linear or other cut for condensate water is formed in the vertical direction of the lower end face of the heat transfer fin part, and the condensed water generated on the fin face of the heat transfer fin is quickly lowered through the cut. By making it flow down into the side drain pan, the occurrence of water splashing and spraying was prevented.
[Selection] Figure 2

Description

  The present invention relates to the structure of a heat exchanger such as an indoor unit for an air conditioner.

  For example, as a heat exchanger for an air conditioner indoor unit, a cross fin coil type air heat exchanger is generally adopted, and the condensed water generated on the surface of the heat exchanger (evaporator) during cooling operation is caused by gravity. It flows down along the fin surface of the heat exchanger, is collected in a drain pan portion provided below the heat exchanger, and is discharged outside the room (first conventional example).

  FIG. 8 and FIG. 9 show the configuration of a conventional indoor unit for an air conditioner configured with such a heat exchanger.

  In other words, in this conventional example, a so-called lambda-shaped air heat exchanger 32 bent in a λ shape from the upper side to the lower side and the cross flow fan 31 are used to suck the upper surface side and the front side, and to hang the slanted downward blow wall. The indoor unit 1 for type | mold air conditioners is comprised, and the code | symbol 20 is the cassette-type main body casing of the said indoor unit 1 for wall-mounted type air conditioners. The main body casing 20 is installed on the wall surface such that the back panel portion is in contact with the wall surface of the room.

  An air inlet 25 is provided from the front side to the upper side of the main body casing 20, and a lambda type air heat exchanger 32 and a cross flow fan 31 are provided inside the air inlet 25. The lambda-type air heat exchanger 32 includes a front-side long portion 32a and a rear-side short portion 32b, and is provided with a cross flow fan 31 provided below the inside thereof. The cross-flow fan 31 blows temperature-controlled air obliquely downward from an air outlet 29 at the bottom on the front side of the main body casing 20 via a temperature-control air passage 30 having a scroll structure.

  The air heat exchanger 32 is supported by fixing the lower ends of the front-side long portion 32a and the rear-side short portion 32b in the drain pans 28a and 28b, respectively.

  For example, as shown in FIG. 9, the heat exchangers of the air heat exchanger 32 are arranged in two rows in alternately arranged heat transfer tubes 11, 11... (Downstream side), 12. , 12... (Upstream side) and heat transfer fins A in which a plurality of heat transfer tubes 11, 12..., 12, 12. , A ... (downstream side), B, B ... (upstream side), and each heat transfer tube 11 on the heat transfer surface of the heat transfer fins A, A ..., B, B ... 11.., 12, 12..., And raised and cut pieces 13, 13..., 14, 14. These are composed of tube plates (not shown) provided on both end sides.

  Therefore, in the case of this configuration, for example, in the cooling or heating operation, when the cross flow fan 31 as the air blowing means is driven, the air heat exchanger having a large heat exchange area of the λ shape and a wide air suction area The temperature-controlled air (cold air or warm air) that is uniformly and effectively heat-exchanged with low-pressure loss through the air is blown out from the air outlet 29 below the front portion, and the air descends downward by the user. A comfortable cooling or heating air-conditioning environment is realized.

  In the air heat exchanger 32 applied to such a wall-hanging indoor unit for an air conditioner, the heat transfer fins A and A are used particularly in the cooling operation in which the heat exchanger 32 serves as an evaporator. ... moisture in the air condenses on the heat transfer surfaces of B, B ..., and a lot of condensation occurs on the heat transfer surfaces, and they are formed by the slits (or louvers). It also enters the inside of the pieces 13, 13 ..., 14, 14 ....

  However, in the case of the same configuration, the front and rear heat exchange portions of the air heat exchanger 32 are installed with an extremely small inclination angle (maximum in the horizontal direction) close to a substantially vertical state, as is apparent from FIG. 8, for example. ing.

  Accordingly, the condensed water smoothly flows down obliquely downward along the fin surface due to gravity and is collected in the drain pans 28a and 28b. As a result, even when the air volume is large, it is not blown off in the direction of the air outlet 29 as it is to cause water splash or mist-like moisture.

  However, depending on the type of indoor unit for an air conditioner, for example, as shown in FIG. 10, due to its structure, the air heat exchanger 42 is installed with the windward side greatly inclined downward from the vertical direction. In such a case, since the direction of gravity and the direction of the wind are reversed, the behavior of the condensed water described above becomes unstable, and water splashing or spraying from the air outlet 49 may occur (second conventional technique). Example).

  The indoor unit for an air conditioner of FIG. 10 is of a single flow type having a single air passage 40, a single cross flow fan 41, a single air heat exchanger 42, and a single air outlet 49. It is a ceiling-embedded indoor unit for air conditioners.

  In the figure, reference numeral 50 is a cassette-type main body casing of the ceiling-embedded air conditioner 1. The main body casing 50 is embedded in the ceiling 3 such that the intake / blowout panel (lower surface panel portion) 44 is continuous in substantially the same plane as the ceiling 3.

  The intake / blowout panel 44 of the main body casing 50 is provided with a rectangular air suction port 45 extending in the front-rear direction on one side in the left-right direction, and further on the inner upper side thereof as shown in FIG. A similar heat exchanger 42 extends in the front-rear direction, and the entire left-right width direction is disposed in a state where it is inclined downward from one side to the other side side first drain pan (main drain pan) 48a. Yes. This heat exchanger 42 is in front of the cross flow fan 41 in the air passage 40 having a scroll structure, which will be described later, in order to take a wide heat exchange area as much as possible and not too close to the cross flow fan 41. As shown in the figure, it is bent and installed in a U-shape (lower side 42a, upper side 42b).

  Further, an air outlet 49 having a predetermined width extends in the front-rear direction (paper surface penetrating direction) at the other side (left side in the figure) of the air inlet 45 in the intake / blowout panel 44 of the main body casing 50. It has been.

  Along with this, a single air passage 40 having a scroll structure extending from the air inlet 45 to the air outlet 49 is formed in the main body casing 50, and the heat exchanger of the air passage 40 is formed. A cross flow fan 41 is provided behind the downstream side 42 (upper left side in the figure). When the cross flow fan 41 rotates, as shown by the arrow in the drawing, the air sucked from the air suction port 45 is cooled through the dog-shaped air heat exchanger 42 and then the cross flow fan 41. And is blown out from the air outlet 49.

  In the air heat exchanger 42 applied to such an indoor unit for an air conditioner, in the cooling operation in which the heat exchanger 42 serves as an evaporator, the heat transfer fins A, A,. , B, B..., Moisture in the air condenses on the heat transfer surface, and a lot of condensation occurs on the heat transfer surface, and they are cut and raised pieces 13 or 13 made of slits (or louvers). ..., 14 and 14 ... enter inside.

  In addition, in the case of the same configuration, the lower side 42a of the air heat exchanger 42 bent in the above-described character shape is installed at a large inclination angle close to a substantially horizontal state, as is apparent from FIG.

  Therefore, in such a case, the direction of gravity and the direction of wind are reversed in the same part, so that the behavior of the condensed water described above is likely to be unstable, and water splashing or spraying from the air outlet 49 is likely to occur.

  In relation to the problem of countermeasures against such condensed water, for example, two parallel rows of heat transfer tubes arranged in parallel in the same manner as described above, and plate-like heat transfer fins inserted and arranged in an orthogonal state with respect to the heat transfer tubes In the air heat exchanger, the fin width from the heat transfer tube on the downstream side of the heat transfer tube to the fin rear edge is wider than the fin width from the fin front edge to the heat transfer tube. As described above, for example, as the closest third conventional example, refer to the contents of Patent Document 1 below.

  According to such a configuration, when the heat exchanger is used as an evaporator as described above (especially when used as an evaporator in a kitchen or the like with a lot of oily smoke), the downstream side of the heat transfer tube is The temperature tends to be lower than that of the heat transfer tubes (for example, between the heat transfer tubes), but since the area enlargement portion is formed in that portion, the temperature is likely to be affected by heat from the heat transfer tubes between the high temperatures. Uniformity will proceed.

  Therefore, the temperature drop of the air flow flowing on the downstream side of the heat transfer tube is thereby alleviated, and the temperature of the air flow is less likely to become the dew point temperature or less in the same portion, so that generation of fog components can be suppressed.

JP 10-185476 A (page 1-3 of the specification, FIG. 1-4)

  However, in the case of the configuration of this conventional example, it is only possible to mitigate the temperature drop of the air flow that flows on the wake side of the heat transfer tube as described above, so that it is possible to prevent spraying due to kitchen smoke and the like. However, it is not possible to prevent the above-described behavior of unstable dew condensation water from splashing or spraying.

  The present invention has been made to solve such a problem, and a condensate guide notch is formed in the vertical direction of the lower end face of the heat exchanger heat transfer fin portion inclined at a predetermined angle or more in the horizontal direction. Suitable for air conditioner indoor units that can prevent the occurrence of water splash as much as possible by quickly flowing the condensed water generated on the fin surface through the cut into the lower drain pan. The object is to provide a heat exchanger. .

  In order to achieve the above object, the present invention is configured with the following problem solving means.

(1) Invention of Claim 1 The heat exchanger according to the present invention includes heat transfer tubes 11, 11,..., 12, 12,. A heat exchanger comprising a plurality of heat transfer fins A, A,..., B, B,... Arranged in a crossed state, the heat transfer fins A, A of the heat exchanger. .., B, B... Condensation extending in a substantially vertical direction from below to above in the inclined state on the lower end face when the heat exchanger is installed at a predetermined angle or more in the horizontal direction. .., 16b, 16b,... Are formed.

  According to such a configuration, the heat transfer fins A, A,..., B, B... The incisions 16, 16..., 16b in which the condensed water generated on the surface extends in the vertical direction from below to above. , 16b..., And smoothly flows to the lower end side of the fin, and is quickly introduced into the drain pan through the lower end portion of the fin.

  As a result, there is no condensed water remaining on the fin surface or slit (or louver) portion in the middle of the heat transfer fin, and the water splash phenomenon can be prevented almost certainly.

  If the cuts 16, 16 ..., 16b, 16b ... are provided on the lower end side of the heat exchanger heat transfer fins A, A ..., B, B ... as described above, the cuts 16 are provided. , 16..., 16b, 16b... Can be bent outward and the workability is improved.

  Therefore, the heat exchanger is arbitrarily shaped into a shape capable of widening the heat transfer area and maintaining an appropriate positional relationship with the fan, for example, according to the shape of the main body casing and the air passage of the indoor unit for an air conditioner. Can be composed.

(2) Invention of Claim 2 The heat exchanger of this invention respond | corresponds to the notches 16, 16 ..., 16b, 16b ... of the lower end surface of an upper end surface in the structure of the invention of the said Claim 1. Other cuts 16a, 16a,... Extending in a substantially vertical direction in the same inclined state are formed in the portion.

  According to such a configuration, the condensed water produced on the upper end side surfaces of the heat transfer fins A, A..., B, B... Is first guided by the upper end side cuts 16a, 16a. .., 16b, 16b... Extending smoothly in the vertical direction on the lower end side, and smoothly flowing to the fin lower end side, and then quickly through the fin lower end portion in the drain pan. Will be introduced.

  As a result, the condensed water staying on the fin surface and the slit (or louver) portion in the middle of the heat transfer fins is quickly discharged, and the water splash phenomenon can be prevented more reliably.

  In addition to the notches 16, 16..., 16b, 16b... On the lower end side of the heat exchanger heat transfer fins A, A. When the cuts 16a, 16a,... Are provided, the lower cuts 16, 16,..., 16b, 16b, etc. are extended, and the cuts 16a, 16a,. The entire heat exchanger can be bent outward without difficulty, and the workability is further improved.

  Therefore, as will be described later, the heat exchanger can secure a heat transfer area as wide as possible, for example, according to the shape of the main body casing and the air passage of the indoor unit for an air conditioner, the installation position of the fan, etc. It is optimal to bend arbitrarily into a circular arc shape that can be formed.

(3) Invention of Claim 3 The heat exchanger of the present invention is the structure of the invention of Claim 1 or 2, wherein the heat exchanger is bent into a desired shape using the notches. It is characterized by having.

  According to such a configuration, a heat exchanger having an optimum shape and heat transfer area suitable for the shape of the main body casing and air passage of the indoor unit for the air conditioner that is actually applied, the installation position of the fan, and the like is realized. Can do.

(4) Invention of Claim 4 In the heat exchanger of this invention, in the structure of the invention of Claim 2 or 3, the notches 16a, 16a,... On the upper end side end face are notches 16b, 16b,. ..Characterized by being formed shallower.

  When the cuts 16a, 16a, ..., 16b, 16b, ... are provided on the upper and lower ends of the heat exchanger as described above, at least the cuts 16a, 16a, ... on the upper end side are water guide functions. Considering the above, it is sufficient if the minimum depth required for the bending process is sufficient. Therefore, a depth shallower than the cuts 16b, 16b,.

(5) Invention of Claim 5 The heat exchanger of this invention is the structure of the invention of the said Claim 1, 2, 3 or 4, Incision 16, 16 ..., 16b, 16b ..., 16a, 16a .. Is characterized by a V-shape.

  According to such a configuration, the heat transfer fins A, A..., B, B... The condensed water produced on the surface extends in the vertical direction from the lower side to the upper side. Guided by V-shaped cuts 16, 16 ..., 16b, 16b ..., 16a, 16a ..., flow smoothly to the fin lower end side, and quickly enter the drain pan from the fin upper end side through the lower end side. Will be introduced.

  As a result, there is no condensed water remaining on the fin surface or slit (or louver) portion in the middle of the heat transfer fin, and the water splash phenomenon can be prevented almost certainly.

  Further, as described above, the V-shaped cuts 16, 16..., 16b, 16b... Are formed on the lower end side of the heat exchanger heat transfer fins A, A. .. When 16a, 16a,... Are provided, the heat exchanger can be more freely arcuated using the cuts 16, 16 ..., 16b, 16b ..., 16a, 16a ... It becomes possible to bend, and the workability is further improved.

  Therefore, for example, the heat exchanger has a circular arc shape that can widen the heat transfer area according to the shape of the main body casing and the air passage of the indoor unit for an air conditioner and can maintain an appropriate positional relationship with the fan. It becomes possible to compose easily.

(6) Invention of Claim 6 The heat exchanger of this invention is the structure of the invention of the said Claim 1, 2, 3 or 4, Incision 16, 16 ..., 16b, 16b ..., 16a, 16a ... is characterized by being linear.

  According to such a configuration, the heat transfer fins A, A..., B, B... The condensed water produced on the surface extends in the vertical direction from the lower side to the upper side. .., 16b, 16b..., 16a, 16a... Smoothly flows from the fin upper end side through the lower end side and quickly into the drain pan. Will be introduced.

  As a result, there is no condensed water remaining on the fin surface or slit (or louver) portion in the middle of the heat transfer fin, and the water splash phenomenon can be prevented almost certainly.

  Further, as described above, linear cuts 16, 16..., 16b, 16b... On the lower end side and further the upper end side of the heat exchanger heat transfer fins A, A. .. When 16a, 16a,... Are provided, the heat exchanger can be freely bent into an arc shape by using the cuts 16, 16 ..., 16b, 16b ..., 16a, 16a,. Can be improved, and the workability is further improved.

  Therefore, for example, the heat exchanger can be easily formed into an arc shape that can increase the heat transfer area according to the shape of the main body casing and the air passage of the indoor unit for an air conditioner and can maintain an appropriate positional relationship with the fan. To be able to compose.

(7) Invention of Claim 7 The heat exchanger of this invention is the structure of the invention of the said Claim 1, 2, 3, 4, 5 or 6, The said heat exchanger is heat exchange of the indoor unit for air conditioners A part or all of the air conditioner is installed in a state inclined at a predetermined angle or more in the horizontal direction in the air passage of the indoor unit for the air conditioner.

  According to the heat exchanger of the configuration of each of the above inventions, the heat exchanger is a heat exchanger of an air conditioner indoor unit, and part or all of the heat exchanger is in the air passage of the air conditioner indoor unit. It is installed in a state inclined at a predetermined angle or more in the horizontal direction, and has a V-shaped or linear cut for the condensed water guide in the vertical direction of the lower end face of the heat exchanger heat transfer fin portion inclined at the predetermined angle or more. Thus, an indoor unit for an air conditioner that smoothly discharges condensed water is appropriately realized.

  As a result of the above, according to the present invention, it is possible to provide a heat exchanger suitable for an indoor unit for an air conditioner having a high heat exchanger shape and a high degree of freedom of installation without causing water splash, at a low cost. Will be able to.

(Best Embodiment 1)
1 and 2 show the configuration of the indoor unit for an air conditioner and the heat exchanger part of the indoor unit according to the first embodiment that employs the heat exchanger of the present invention. In this embodiment, for example, as an indoor unit for an air conditioner, a single air passage 40, a single crossflow fan 41, a single air heat exchanger 42, and a single air outlet 49 are provided. A flow-type ceiling-embedded air conditioner is used.

  In FIG. 1, reference numeral 50 is a cassette-type main body casing of the ceiling-embedded air conditioner 1. The main body casing 50 is embedded in the ceiling 3 such that the intake / blowout panel (lower surface panel portion) 44 is continuous in substantially the same plane as the ceiling 3.

  The intake / blowout panel 44 of the main body casing 50 is provided with a rectangular air inlet 45 extending in the front-rear direction on one side in the left-right direction, and further, a heat exchanger 42 is provided on the inner upper side. It extends in the front-rear direction, and is disposed in a state in which the whole in the left-right width direction is inclined downward from the one side portion side toward the first drain pan 48 toward the other side portion side.

  Further, an air outlet 49 having a predetermined width is provided extending in the front-rear direction at a position on the other side (the left side in the drawing) of the air inlet 45 in the intake and outlet panel 44 of the main body casing 50.

  Along with this, a single air passage 40 having a scroll structure extending from the air inlet 45 to the air outlet 49 is formed in the main body casing 50, and the heat exchanger of the air passage 40 is formed. A cross flow fan 41 is provided behind the downstream side 42 (upper left side in the figure).

  When the cross flow fan 41 rotates, the air drawn from the air inlet 45 is cooled (or heated) through the air heat exchanger 42 as shown by the arrow in the figure, and then the cross flow fan 41 is moved. It flows through and blows out from the air outlet 49.

  By the way, in the case of this embodiment, the air heat exchanger 42 is configured as shown in FIG. 2, for example.

  That is, the air heat exchanger 42 is arranged in two rows, for example, in the heat transfer tubes 11, 11,..., 12, 12,. (Downstream side), 12, 12... (Upstream side) heat transfer fins A, A... (Downstream side), B, Between B ... (upstream side) and the heat transfer tubes 11, 11 ..., 12, 12 ... on the heat transfer surfaces of the heat transfer fins A, A ..., B, B ... .., And 14 and 14, and tube plates (not shown) provided at both ends of the slits (or louvers). It consists of and.

  The heat exchanger 42 (especially the portion 42a) is disposed horizontally on the heat transfer surfaces of the heat transfer fins A, A..., B, B. As shown in the figure, a predetermined width is cut up and there is no piece 13, 13,..., 14, 14,. .., Flat surfaces 15, 15..., 16, 16.

  Further, the flat surface portions 15, 15,..., 16, 16,... Have a narrow V-shaped shape for condensate guides as shown in the drawing extending in a substantially vertical direction in an installation state inclined by a predetermined angle or more. .., 16b, 16b... Are formed so as to reach the center of the upper heat transfer fins A, A... From the lower heat transfer fins B, B. Has been.

  According to such a configuration, the flat surfaces 15, 15... Without the cut and raised pieces 13, 13,..., 14, 14. After being collected into 16, 16..., The heat transfer fins B (on the right side in FIG. 2) which are on the lower side in the inclined installation state as shown in FIG. 1 through the V-shaped cuts 16, 16. , B... Smoothly flows to the lower edge side of the heat transfer fins B, B... It is introduced into each of the first to third drain pans 48a, 48b, 48c provided so as to cover the lower end portion of the small inclined surface portion 42b having less than a corner.

  In addition, since the whole inclined surface portion 42b with a small inclination angle stands almost vertically, the generated pre-condensate is the heat transfer fins A, as in the lambda type heat exchange of FIG. The liquid flows down into the third drain pan 48c substantially straight through the A, B, B,.

  Therefore, the heat transfer fins A, A,..., B, B..., Cut fins 13, 13. The condensed water staying in the 14, 14... Portion is eliminated, and water splashing and spraying can be prevented with certainty.

  As a result, according to the configuration of the embodiment, a highly comfortable indoor unit for air conditioner that is less likely to cause water splashing and spraying can be realized at low cost.

  The second and third drain pans 48b and 48c are separated from the first drain pan 48a and are deformed downward in a U-shape to form an air passage through which air smoothly flows. The air resistance is made as small as possible.

  Further, as described above, when the V-shaped cuts 16, 16... Are provided on the lower ends of the heat exchanger heat transfer fins A, A. The whole heat exchanger 42 can be bent outward by using the extension side as an extension side, and the workability is further improved.

  Therefore, for example, the heat exchanger is bent not only in a letter shape as shown in the figure but also in an arc shape advantageous for securing a heat transfer area according to the shape of the main body casing and the air passage of the indoor unit for an air conditioner. Can also be achieved.

  As a result of the above, according to the configuration of the embodiment, air heat exchange suitable for indoor units for air conditioners with high comfort, high heat exchanger shape, and high degree of freedom of installation is unlikely to occur. Can be provided easily and at low cost.

  Of course, the slits or louvers of the cut and raised pieces 13, 13,..., 14, 14,. it can.

(Modification)
In the above configuration, when forming the notches 16, 16,..., First, the heat transfer fins A, A..., B, B. The flat surfaces 15, 16, 15, 16,... Without the parts 13, 13,..., 14, 14 ... are formed, and the V-shaped cuts 16, 16,. As shown in FIG. 3, for example, the flat surfaces 15, 16, 15, 16... Are not formed at all, and the structure of FIG. .. Are formed directly on the heat transfer fins A, A,..., B, B. Needless to say, it may be configured as follows.

  Even with such a configuration, it is possible to obtain the same effect (promotion and discharge of the condensed water flow) as described above, and further, the processing itself is simple and the cost is low.

  Further, since the slits (or louvers) 13, 13,..., 14, 14.

  In the above case, in consideration of the rigidity of the heat exchanger 42 as a whole, cuts 16, 16... Are formed every other space between the upper and lower heat transfer tubes 11, 11,. Of course, this is not every other one, but the notches 16, 16... Are formed between the heat transfer tubes 11, 11. Needless to say, it is good.

(Best Mode 2)
Next, FIGS. 4 and 5 show the configurations of the indoor unit for an air conditioner and the heat exchanger of the indoor unit according to the second preferred embodiment configured by adopting the heat exchanger of the present invention.

  In this embodiment, in a single flow type indoor unit for an air conditioner that employs the same heat exchanger 42 structure as described above, heat transfer fins A, A. .. V-shaped cuts 16a, 16a,... Having a predetermined depth are also formed at upper end positions corresponding to the V-shaped cuts 16b, 16b,. is there.

  According to such a configuration, the condensed water generated on the upper end side surfaces of the heat transfer fins A, A..., B, B... Is first guided by the V-shaped cuts 16a, 16a. Are smoothly guided to the V-shaped cuts 16b, 16b... Extending in the vertical direction on the lower end side, and flow more smoothly toward the lower end of the fin, and then quickly enter the drain pan through the lower end of the fin. Will be introduced.

  As a result, heat transfer fins A, A..., B, B... Condensed water that tends to stay on fin surfaces and slits (or louvers) 13, 13. The discharge of water becomes faster, and the water splash phenomenon can be prevented more reliably.

  In addition to the V-shaped cuts 16b, 16b,... On the lower end side of the heat exchanger heat transfer fins A, A. When 16a, 16a ... are provided, the V-shaped cuts 16, 16 ..., 16b, 16b ... on the lower end side are extended sides, and the V-shaped cuts 16a, 16a ... on the upper end side are provided. As a contraction side, the entire heat exchanger 42 can be bent to the outside without difficulty, and the workability is further improved.

  Therefore, as shown in FIG. 4, the heat exchanger 42 is transmitted as much as possible in accordance with the shape of the main body casing 50 and the air passage 40 of the air conditioner indoor unit 1, the installation position of the cross flow fan 41, and the like. It can be arbitrarily bent into an optimal arc shape with a wide heat area.

  In this case, the depths of the cuts 16a, 16a,... On the upper end side are much shallower than the depths of the cuts 16b, 16b,.

  As described above, V-shaped cuts 16a, 16a,..., 16b, 16b... Are provided on both upper and lower ends of the heat exchanger heat transfer fins A, A. In this case, at least the V-shaped cuts 16a, 16a,... On the upper end side need only have a minimum depth necessary for bending even if the water guide action is taken into account. A shallower one than 16b, 16b... Is sufficient.

  In the above case, in consideration of the rigidity of the heat exchanger 42 as a whole, the cuts 16a, 16a,..., 16b are alternately provided between the upper and lower heat transfer tubes 11, 11,. , 16b..., But of course, this is not every other, and notches 16a, 16a,... Between the heat transfer tubes 11, 11,. , 16b, 16b... May be formed.

(Best Mode 3)
Next, FIGS. 6 and 7 show the configurations of the indoor unit for an air conditioner and the heat exchanger of the indoor unit according to the third preferred embodiment configured by adopting the heat exchanger of the present invention.

  In this embodiment, in a single-flow type indoor unit for an air conditioner that employs the same structure of the heat exchanger 42 as in the first embodiment, the heat transfer fins A, A,. .., B, B... Are cut at the lower end side into linear cuts (cuts in a cutting line state simply cut) 17, 17.

  According to such a configuration, the dew condensation water generated on the surface of the heat transfer fins extends downward in the installation state with a large inclination angle as shown in FIG. 6 through the linear cuts 17, 17. The heat transfer fins B, B... (Smoothly on the right side of FIG. 7) flow smoothly to the lower edge side of the heat transfer fins B, B... It is introduced into each of the first to third drain pans 48a, 48b, 48c provided to cover each part in the width direction of the surface part 42a.

  As a result, the heat transfer fins A, A,..., B, B. Condensed water that remains is eliminated, and water splashing and spraying can be prevented almost certainly.

  Further, as described above, when the same-line-shaped cuts 17, 17... Are provided on the lower end side of the heat exchanger heat transfer fins A, A. , 17... Can be bent outward so that the workability is further improved.

  Therefore, for example, the heat exchanger is bent not only in a letter shape as shown in the figure but also in an arc shape advantageous for securing a heat transfer area according to the shape of the main body casing and the air passage of the indoor unit for an air conditioner. Can also be achieved.

  As a result, according to the configuration of the embodiment, the air heat exchanger suitable for the indoor unit for an air conditioner having high comfort, high heat exchanger shape, and high degree of freedom of installation is unlikely to cause water splashing or spraying. Can be provided easily and at low cost.

  Of course, the slits or louvers of the cut and raised pieces 13, 13,..., 14, 14,. it can.

(Modification)
Also in the above embodiment, as in the case of the best embodiment 2, the heat transfer fins A, A..., B, B. A linear (or preferably V-shaped) cut having a predetermined depth may be formed at the upper end side position corresponding to the linear cuts 17, 17.

  According to such a configuration, the condensed water generated on the upper end side surfaces of the heat transfer fins A, A..., B, B... Is first guided by a linear (or V-shaped) notch on the upper end side. Are smoothly guided to the linear cuts 17, 17... Extending in the vertical direction on the lower end side, and flow more smoothly toward the lower end side of the fin, and then quickly drain pans 48a to 48c through the lower end portion of the fin. Will be introduced in.

  As a result, heat transfer fins A, A..., B, B... Condensed water that tends to stay on fin surfaces and slits (or louvers) 13, 13. The discharge of water becomes faster, and the water splash phenomenon can be prevented more reliably.

  In addition, in addition to the linear notches 17, 17... On the lower end side of the heat exchanger heat transfer fins A, A..., B, B. When the V-shaped notch is provided, the above-described linear cuts 17, 17... On the lower end side are set as the extending side, and the linear (or V-shaped) cuts 17, 17. The entire heat exchanger 42 can be bent outward without difficulty, and the workability is further improved.

  Therefore, as shown in FIG. 4 described above, the heat exchanger 42 is made as much as possible according to the shape of the main body casing 50 and the air passage 40 of the indoor unit 1 for the air conditioner, the installation position of the cross flow fan 41, and the like. It can be arbitrarily bent into an optimal arc shape with a wide heat transfer area.

  In this case, the depth of the cut on the upper end side may be much shallower than the depth of the cuts 17, 17.

  When the cuts are provided on both the upper and lower ends of the heat exchanger heat transfer fins A, A,..., B, B, as described above, at least the cuts on the upper end side consider the water guide action. However, since a minimum depth required for bending is sufficient, a depth shallower than the cuts 17, 17... On the lower end side is sufficient.

  In this case as well, in consideration of the rigidity of the heat exchanger 42 as a whole, cuts may be formed in every other space between the upper and lower heat transfer tubes 11, 11. Instead of every other one, it may be formed between the heat transfer tubes 11, 11,..., 12, 12,.

It is sectional drawing which shows the structure of the indoor unit for air conditioners comprised using the air heat exchanger which concerns on the best Embodiment 1 of this invention. It is a partially notched front view which shows the structure of the principal part of the same air heat exchanger. It is a partially notched front view which shows the structure of the principal part of the air heat exchanger which concerns on the modification of the embodiment. It is sectional drawing which shows the structure of the indoor unit for air conditioners comprised using the air heat exchanger which concerns on best Embodiment 2 of this invention. It is a partially cutaway sectional view showing the composition of the principal part of the air heat exchanger. It is sectional drawing which shows the structure of the indoor unit for air conditioners comprised using the air heat exchanger which concerns on best Embodiment 3 of this invention. It is a partially cutaway sectional view showing the composition of the principal part of the air heat exchanger. It is sectional drawing which shows the structure of the air conditioner comprised using the air heat exchanger which concerns on a 1st prior art example. It is a partially cutaway sectional view showing the composition of the principal part of the air heat exchanger. It is sectional drawing which shows the structure of the air conditioner comprised using the air heat exchanger which concerns on a 2nd prior art example.

Explanation of symbols

  1 is an air conditioner, 3 is a ceiling, 11 and 12 are heat transfer tubes, 13 and 14 are cut and raised pieces such as slits (or louvers), 16 is a V-shaped cut portion, and 16a is a V-shaped first cut. , 16b is a V-shaped second cut portion, 40 is a ventilation passage, 42a is an inclined portion (lower side) of a predetermined angle or more of the heat exchanger 42, 44 is a ceiling panel, 45 is an air inlet, and 49 is air Air outlets 48a to 48c are first to third drain pans.

Claims (7)

  .., 12, 12... And a plurality of heat transfer fins A arranged in parallel with the heat transfer tubes 11, 11... , A ..., B, B ..., the heat exchanger of the heat transfer fins A, A ..., B, B ... of the heat exchanger. , 16b, 16b, 16b, 16b, 16b, 16b, 16b, 16b, 16b, 16b, 16b, 16b .. A heat exchanger characterized by forming   The other notches 16a, 16a,... Extending substantially vertically in the same inclined state are formed in the portions corresponding to the notches 16, 16,..., 16b, 16b,. The heat exchanger according to claim 1, wherein   The heat exchanger is bent into a desired shape by using the cuts 16, 16 ..., 16b, 16b ..., 16a, 16a ... Item 3. The heat exchanger according to item 1 or 2.   4. The heat exchanger according to claim 2, wherein the cuts 16 a, 16 a... On the upper end side end surface are formed shallower than the cuts 16 b, 16 b.   5. The heat exchanger according to claim 1, 2, 3, or 4, wherein the cuts 16, 16 ..., 16b, 16b ..., 16a, 16a ... are V-shaped.   The incisions 16, 16 ..., 16b, 16b ..., 16a, 16a ... are linear, and the heat exchanger according to claim 1, 2, 3 or 4.   The heat exchanger is a heat exchanger for an air conditioner indoor unit, and part or all of the heat exchanger is installed in a state inclined at a predetermined angle or more in the horizontal direction in the air passage of the air conditioner indoor unit. The heat exchanger according to claim 1, 2, 3, 4, 5, or 6.

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