JP4661542B2 - Air conditioner - Google Patents

Description

  The present invention relates to a condensate drainage structure in an air conditioner in which air flows through a cooling heat exchanger disposed substantially horizontally from below to above.

  2. Description of the Related Art Conventionally, in a vehicle air conditioner, in order to reduce a vehicle mounting space of an indoor unit portion, a cooling heat exchanger is disposed substantially horizontally in a resin case of the indoor unit portion, and the cooling heat exchanger There is known an arrangement in which the blown air flows from below to above (see, for example, Patent Document 1).

  And in patent document 1, the drainage structure for improving the drainage property of the condensed water which generate | occur | produces in the heat exchanger for cooling in this kind of horizontal installation type vehicle air conditioner is proposed. Specifically, the cooling heat exchanger is inclined at a minute angle from the horizontal plane, and the rib portion is formed integrally with the case at a position below the inclined lower end portion of the cooling heat exchanger in the case.

  The rib portion has a plate shape extending in a direction perpendicular to the inclination direction of the cooling heat exchanger in a plane parallel to the air suction side surface (lower surface) of the cooling heat exchanger.

  And the packing member which consists of an elastic material is engage | inserted and fixed to the edge part which faced the heat exchanger side for cooling of the rib part, and this packing member is made to contact the lower surface part of the heat exchanger for cooling. The rib portion and the packing member serve to partition the lower space of the cooling heat exchanger into a blower space and a drainage space.

  Here, the air blowing space is a space located on the inclined upper side (heat exchange core portion side) of the cooling heat exchanger with respect to the rib portion and the packing member, and the drainage space is more than the rib portion and the packing member. This is a space located on the inclined lower side (tank side) of the cooling heat exchanger.

  Thereby, since the tank part located in the inclination lower end part of the heat exchanger for cooling is located in the space for drainage, the air flow of the space for ventilation does not directly blow against the tank part. As a result, it is possible to smoothly drop the condensed water collected in the tank portion positioned at the inclined lower end portion of the cooling heat exchanger to the bottom surface of the case without blowing it up with the wind pressure of the blown air.

  In Patent Document 1, a contact portion that contacts the heat exchanger for cooling is formed in a flat plate shape on the uppermost portion of the packing member, and a cross section that allows the contact portion to be displaced in the vertical direction below the contact portion. A pantograph-shaped cushion is provided.

Thus, when the packing member comes into contact with the cooling heat exchanger, the cushion portion is crushed and deformed, and the contact portion is not deformed. For this reason, even if the position of the cooling heat exchanger relative to the case shifts in the vertical direction due to dimensional variations due to the molding accuracy of the case, the cushion part absorbs this shift and the contact portion is good for the cooling heat exchanger. Can be contacted.
JP-A-2005-75022

  By the way, although not described in Patent Document 1, in the indoor unit of the vehicle air conditioner, in order to prevent air from passing between the inner wall surface of the case and the cooling heat exchanger, It is well known that a sealing member (packing) is attached to the outer peripheral surface of the cooling heat exchanger so that the cooling heat exchanger contacts the inner wall surface of the case via the sealing member.

  According to the detailed examination of the present inventor, in the prior art of Patent Document 1, the compression amount of the seal member attached to the both end surfaces in the inclined direction of the cooling heat exchanger in the outer peripheral surface of the cooling heat exchanger. It has been found that due to the variation in position, the arrangement position of the cooling heat exchanger with respect to the case may shift in the inclination direction (substantially horizontal direction) of the cooling heat exchanger.

  Further, according to the detailed examination of the present inventor, in the prior art of Patent Document 1, the arrangement position of the cooling heat exchanger relative to the case depends on the inclination direction or the vertical direction of the cooling heat exchanger due to variations in the molding accuracy of the case. It turned out that it may shift.

  In this way, if the arrangement position of the cooling heat exchanger relative to the case is shifted in the inclination direction or the vertical direction of the cooling heat exchanger, the amount of air passing through the cooling heat exchanger may be reduced, or the drainage property It turns out that there is a problem of getting worse.

  That is, when the position of the cooling heat exchanger with respect to the case is shifted in the inclination direction of the cooling heat exchanger, the relative position between the packing member that contacts the lower surface of the cooling heat exchanger and the cooling heat exchanger Will shift.

  If this relative position shifts to the side of narrowing the air blowing space, the amount of air passing through the cooling heat exchanger is reduced. On the contrary, if this relative position shifts to the side where the blowing space is expanded, the wind pressure is applied to the portion where the condensed water collects, and the drainage performance is deteriorated.

  Moreover, since the contact part of a packing member is formed in a flat plate shape with an elastic material, it is not the structure which supports the dead weight of the heat exchanger for cooling. For this reason, when the arrangement position of the cooling heat exchanger with respect to the case is shifted downward by more than the crushing amount of the cushion portion, the contact portion receives the weight of the cooling heat exchanger and falls in the inclination direction of the cooling heat exchanger. It will be deformed.

  As a result, the seal between the blower space and the drainage space becomes insufficient, and air enters the drainage space, so that the drainage performance deteriorates.

  Moreover, in the prior art of patent document 1, when the case of an indoor unit part is a 2 division structure which has a division surface in a perpendicular direction, after attaching a packing member to a case, a heat exchanger for cooling is used for the division surface of a case. Therefore, the cooling heat exchanger must be inserted into the case while sliding on the packing member.

  For this reason, there exists a problem that the packing member inserted in the rib part will be caught in the unevenness | corrugation (irregularity by a tube or a fin) of the surface of the heat exchanger for cooling, and will remove | deviate from a rib part.

  In view of the above points, the present invention provides a cooling heat exchanger that is not affected by the molding accuracy of a case in an air conditioner in which air flows from a lower side to an upper side in a cooling heat exchanger that is disposed substantially horizontally. It aims at providing the condensed water drainage structure which can be made to contact reliably.

  Another object of the present invention is to improve the assembly of the condensate drainage structure in a case division structure having a division surface in the vertical direction.

In order to achieve the above object, the present invention comprises a case (11) that forms an air passage through which air flows toward the passenger compartment.
Cooling heat that is arranged in the case (11) so as to be inclined with respect to the horizontal plane, introduces air from the lower space (15) to the heat exchange section (13a), cools it, and guides the cooled air upward. An exchanger (13);
Condensed water of the cooling heat exchanger (13), which is disposed between the bottom surface (11c) of the case (11) located below the cooling heat exchanger (13) and the cooling heat exchanger (13). A drainage guide member (14) for guiding the drainage of
The drainage guide member (14) has a longitudinal direction in a direction (b) perpendicular to the inclination direction (a) of the cooling heat exchanger (13),
The condensed water generated in the cooling heat exchanger (13) is drained into the drainage space (27) below the drainage guide member (14) in the inclined direction (a) of the lower space (15). And
The drainage guide member (14) is in contact with the air flow upstream surface (13e) of the cooling heat exchanger (13), and the contact portion (21) is connected to the air flow upstream surface (13e). Holding portions (19, 20) for holding and fixing to the cooling heat exchanger (13) in a state of being in contact with
After the drainage guide member (14) is fixedly disposed on the cooling heat exchanger (13), the cooling heat exchanger (13) is disposed in the case (11), and the drainage guide member (14) is disposed on the case ( 11) comes into contact with the bottom surface (11c) side portion ,
The contact portion (21) is formed to extend in the orthogonal direction (b),
A protruding insertion portion (21a) to be inserted into the gap of the heat exchange portion (13a) is formed at the tip of the contact portion (21) .

  According to this, since the drainage guide member (14) including the contact portion (21) is directly fixed to the cooling heat exchanger (13) by the holding portions (19, 20), the cooling heat exchanger (13) The arrangement position of the contact portion (21) is determined only by the accuracy of the cooling heat exchanger (13) and the drainage guide member (14) itself.

  In other words, since it is possible to avoid the arrangement position of the contact portion (21) with respect to the cooling heat exchanger (13) being determined by the molding accuracy of the case (11) or the like, the cooling heat exchanger (13 ) Can be prevented from shifting the position of the drainage guide member (14).

  Furthermore, by providing the holding portions (19, 20), the drainage guide member (14) comes into contact with the bottom surface (11c) side portion of the case (11), and the bottom surface of the case (11) ( 11c) It is possible to prevent the position of the drainage guide member (14) from shifting when an external force is applied from the side portion.

As a result, the contact portion (21) of the drainage guide member (14) can be reliably brought into contact with the cooling heat exchanger (13) without being affected by the molding accuracy of the case (11).
Furthermore, since the insertion part (21a) can pull out the condensed water collected on the surface (13e) on the upstream side of the air flow of the heat exchange part (13a), the condensed water can be drained more smoothly. .

Specifically, in the present invention, the lower space (15) is disposed on the drainage space (27) and on the upper side in the inclined direction (a) than the drainage space (27) by the drainage guide member (14). It is designed to be separated from the flowing air space (30).
The cooling heat exchanger (13) may introduce air into the heat exchange section (13a) from the blowing space (30) in the lower space (15).

  Thereby, the condensed water drained into the drainage space (27) can be smoothly drained without blowing up with the wind pressure of the blown air.

Further, in the present invention, specifically, a rib portion (29) having a protruding shape protruding from the bottom surface (11c) toward the drainage guide member (14) is formed integrally with the bottom surface (11c),
The rib portion (29) has a longitudinal direction substantially parallel to the longitudinal direction of the drainage guide member (14),
The drainage guide member (14) may be in contact with the rib portion (29) of the bottom surface (11c) side portion.

  According to this, the drainage guide member (14) can come into contact with the bottom (11c) side portion of the case (11) by coming into contact with the rib portion (29) formed integrally with the bottom (11c). The drainage guide member (14) can be easily formed as compared with the case where the drainage guide member (14) is formed with a protruding shape for directly contacting the bottom surface (11c) of the case (11).

Further, in the present invention, specifically, the lower space (15) is more inclined than the drainage space (27) and the drainage space (27) by the rib portion (29) and the drainage guide member (14). ) It is divided into the upper side and the ventilation space (30) through which air flows,
The cooling heat exchanger (13) may introduce air into the heat exchange section (13a) from the blowing space (30) in the lower space (15).

  Thereby, the condensed water drained into the drainage space (27) can be smoothly drained without blowing up with the wind pressure of the blown air.

Further, in the present invention, specifically, the drainage guide member (14) has a base portion (18) extending in a direction (b) perpendicular to the space between the cooling heat exchanger (13) and the rib portion (29). )
The base part (18) may be formed integrally with the contact part (21) and the holding part (19, 20).

  Thereby, since the number of parts of a drainage guide member (14) can be reduced, the assembly man-hour of a drainage guide member (14) can be reduced.

Further, in the present invention, specifically, the base portion (18) is disposed over the entire length of the cooling heat exchanger (13) in the orthogonal direction (b),
The holding portion is constituted by a claw portion (19) protruding from the both end portions in the orthogonal direction (b) of the base portion (18) to the cooling heat exchanger (13) side,
You may make it a nail | claw part (19) engage with the outer surface of the orthogonal | vertical direction (b) side among the heat exchangers for cooling (13).

  According to this, the nail | claw part (19) engages with the outer surface of the orthogonal | vertical direction (b) side among the heat exchangers for cooling (13), and thereby the drainage guide member (14) is moved to the heat exchanger for cooling ( 13).

  For this reason, the contact portion (21) can be held and fixed to the cooling heat exchanger (13) in a state where the contact portion (21) is in contact with the surface (13e) on the upstream side of the air flow of the cooling heat exchanger (13).

Further, in the present invention, specifically, the base portion (18) is disposed at least between the rib portion (29) and the heat exchange portion (13a) in the inclination direction (a),
The holding part is constituted by a pillar part (20) protruding from the part facing the heat exchange part (13a) in the base part (18) to the heat exchange part (13a) side,
The column part (20) may be inserted and held in the gap of the heat exchange part (13a).

  According to this, the drainage guide member (14) can be fixed to the cooling heat exchanger (13) by the column part (20) being inserted and held in the gap of the heat exchange part (13a). Therefore, the contact portion (21) can be held and fixed to the cooling heat exchanger (13) in a state where it is in contact with the air flow upstream surface (13e) of the cooling heat exchanger (13).

Further, in the present invention, specifically, the base portion (18) is disposed over the entire length of the cooling heat exchanger (13) in the orthogonal direction (b), and at least the rib portion in the inclined direction (a). (29) and the heat exchange part (13a),
The holding part includes a claw part (19) projecting from both ends in the direction (b) perpendicular to the base part (18) to the cooling heat exchanger (13) side, and a heat exchanging part ( 13a) and a column part (20) protruding from the part facing the heat exchange part (13a) side,
The claw portion (19) is adapted to engage with the outer surface of the cooling heat exchanger (13) on the orthogonal direction (b) side,
Further, the column part (20) may be inserted and held in the gap of the heat exchange part (13a).

  According to this, the nail | claw part (19) engages with the outer surface of the orthogonal | vertical direction (b) side among the heat exchangers for cooling (13), and thereby the drainage guide member (14) is moved to the heat exchanger for cooling ( 13), and the column part (20) is inserted and held in the gap of the heat exchange part (13a), whereby the drainage guide member (14) is cooled by the cooling heat exchanger (13). ).

  For this reason, the contact portion (21) can be reliably held and fixed to the cooling heat exchanger (13) in a state in contact with the surface (13e) on the upstream side of the air flow of the cooling heat exchanger (13).

  Further, in the present invention, specifically, the contact portion (21) protrudes from the upper end portion in the inclination direction (a) of the base portion (18) to the heat exchange portion (13a) side of the heat exchange portion (13a). What is necessary is just to make it contact the surface (13e) of an air flow upstream.

  According to this, the condensed water collected on the surface (13e) on the upstream side of the air flow of the heat exchanging portion (13a) can flow along the contact portion (21), so that the condensed water can be smoothly drained. it can.

  Further, since the contact portion (21) is arranged at the upper end portion in the inclination direction (a) of the base portion (18), the holding portions (19, 20) are lower in the inclination direction (a) than the contact portion (21). Can be placed on the side.

  For this reason, since a holding | maintenance part (19, 20) is not exposed in the ventilation space (30), a holding | maintenance part (19, 20) does not block the flow of the ventilation air to a heat exchange part (13a). It is possible to avoid a decrease in the flow rate of the air passing through the heat exchange part (13a).

Further, according to the present invention, specifically, a projecting contact portion that contacts the cooling heat exchanger (13) is provided in a portion of the base portion (18) facing the cooling heat exchanger (13). (25) is integrally formed,
The contact portion (25) may form a gap (26) between the base portion (18) and the cooling heat exchanger (13).

  According to this, since the condensed water flowing along the contact portion (21) can flow through the gap (26) and be dropped into the drainage space (27), the condensed water can be drained more smoothly.

  Further, in the present invention, specifically, the base portion of the contact portion (21) in the base portion (18) penetrates from the cooling heat exchanger (13) side to the rib portion (29) side. A hole (28) may be formed.

  According to this, the condensed water flowing along the contact portion (21) not only flows through the gap (26) and falls into the drainage space (27), but also from the through hole (28) to the rib portion (29) side, that is, Since it can fall to the bottom face (11c) side of the case (11), the condensed water can be drained more smoothly.

  Further, in the present invention, specifically, a peripheral portion on the rib portion (29) side of the through hole (28) is provided with a protruding portion (22) protruding toward the bottom surface (11c) side. Good.

  According to this, since the condensed water which flowed along the contact part (21) and reached the through hole (28) can be collected in the protrusion part (22) to form water droplets, the condensed water can be removed from the through hole (28). It becomes easy to fall.

  For this reason, condensed water can be drained more smoothly.

Further, in the present invention, specifically, the drainage guide member (14) is formed of a resin,
A projecting insertion portion (21a) that is inserted into the gap of the heat exchange portion (13a) may be integrally formed at the distal end portion of the contact portion (21).

  As described above, by directly fixing the drainage guide member (14) to the cooling heat exchanger (13), the displacement of the arrangement position of the drainage guide member (14) with respect to the cooling heat exchanger (13) is suppressed. Therefore, even if the contact portion (21) is formed of resin instead of an elastic material, the contact portion (21) can be reliably brought into contact with the surface of the cooling heat exchanger (13).

  Then, by forming the drainage guide member (14) with resin, a protruding insertion portion (21a) to be inserted into the gap of the heat exchange portion (13a) is easily formed at the tip of the contact portion (21). can do.

  For this reason, since the insertion part (21a) can pull out the condensed water collected on the surface (13e) on the air flow upstream side of the heat exchange part (13a), the condensed water can be drained more smoothly. it can.

Further, in the present invention, specifically, the drainage guide member (14) includes a base portion (18) and a holding portion (19, 20) made of resin, and a contact portion (21) made of an elastically deformable elastic material. Is molded in one piece,
The portion of the contact portion (21) that directly contacts the heat exchange portion (13a) is elastically deformed,
A portion of the contact portion (21) that does not directly contact the heat exchange portion (13a) may be inserted into the gap portion of the heat exchange portion (13a).

  According to this, since the contact portion (21) is formed of an elastically deformable elastic material, a portion of the contact portion (21) that does not directly contact the heat exchange portion (13a) is in the gap portion of the heat exchange portion (13a). Inserted. Also by this, the contact part (21) inserted in the space | gap part of a heat exchange part (13a) can pull out the condensed water which collects on the surface (13e) of the air flow upstream side of a heat exchange part (13a). it can.

Further, in the present invention, specifically, the drainage guide member (14) includes an elastic member (23) formed of an elastically deformable elastic material,
The elastic member (23) is fixed to the rib portion (29) side portion of the base portion (18), and is elastically deformed in close contact with the tip surface of the rib portion (29).

  According to this, the elastic member (23) is elastically deformed between the base portion (18) and the rib portion (29) of the drainage guide member (14) fixed to the cooling heat exchanger (13) side. The displacement of the arrangement position in the vertical direction of the cooling heat exchanger (13) with respect to the case (11) can be absorbed, and the space between the drainage guide member (14) and the rib portion (29) can be sealed.

  For this reason, since it can prevent that blowing air flows in into the drainage space (27) side from between a drainage guide member (14) and a rib part (29), condensed water can be drained smoothly. .

Further, in the present invention, specifically, the drainage guide member (14) includes an elastic member (23) formed of an elastically deformable elastic material,
The elastic member (23) is fixed to a portion of the drainage guide member (14) that contacts the bottom surface (11c) side portion of the case (11), and is in close contact with the bottom surface (11c) side portion of the case (11) to be elastic. You may make it deform | transform.

  According to this, the elastic member (23) is elastically deformed between the drainage guide member (14) fixed to the cooling heat exchanger (13) side and the bottom (11c) side portion of the case case (11). By absorbing the displacement of the arrangement position of the cooling heat exchanger (13) in the vertical direction with respect to the case (11), the gap between the drainage guide member (14) and the bottom surface (11c) side portion of the case (11) is absorbed. Can be sealed.

  For this reason, since it can prevent that blowing air flows in into the drainage space (27) side from between the drainage guide member (14) and the bottom face (11c) side site | part of a case (11), condensed water is smooth. Can be drained.

Further, the case (11) in the present invention is configured to integrally fasten a plurality of divided cases (11a, 11b),
The coupling surfaces of the plurality of divided cases (11a, 11b) may extend in a substantially vertical direction.

  According to this, since the coupling surfaces of the plurality of divided cases (11a, 11b) extend in a substantially vertical direction, the cooling heat exchanger (13) is connected to the plurality of divided cases (11a, 11b) with respect to the coupling surfaces. However, after the drainage guide member (14) is disposed in the cooling heat exchanger (13), the cooling heat exchanger (13) is disposed in the case (11). Therefore, it can avoid that the unevenness | corrugation of the heat exchange part (13a) of the heat exchanger for cooling (13) slides and catches with the drainage guide member (14) at the time of an assembly | attachment.

  For this reason, the assembly | attachment property of a condensed water drainage structure can be improved in the case division | segmentation structure which has a division surface in a perpendicular direction.

  In addition, the code | symbol in the bracket | parenthesis of each means described in this column and the claim shows the correspondence with the specific means as described in embodiment mentioned later.

(First embodiment)
1 to 9 show a first embodiment of the present invention. FIG. 1 is a sectional view of a main part of an indoor air conditioning unit 10 of a vehicle air conditioner. FIG. 2 is a case of the indoor air conditioning unit 10. It is a typical perspective view which shows these division | segmentation structures. Each of the up / down, left / right, and front / rear arrows in FIGS.

  The indoor air-conditioning unit 10 is mounted, for example, at the center in the vehicle left-right (width) direction inside an instrument panel (instrument panel) arranged at the foremost part in the vehicle interior.

  The air conditioning case 11 of the indoor air conditioning unit 10 is a resin molded product. In this embodiment, as shown in FIG. 2, the air conditioning case 11 is divided into a left divided case 11a and a right divided case 11b. The left divided case 11a and the right divided case 11b are fastened together by fastening means such as screws and clips (not shown).

  The left divided case 11a and the right divided case 11b correspond to a plurality of divided cases in the present invention.

  An electric blower 12 is disposed in front of the vehicle of the indoor air conditioning unit 10, and air is blown toward the evaporator 13 by the blower 12.

  The substantially rectangular evaporator 13 is a cooling heat exchanger that cools the air blown from the blower 12, and is close to the lower side of the cases 11 a and 11 b in the air conditioning case 11 with a drainage guide member 14 to be described later attached thereto. Contained in the site. Here, the evaporator 13 is inclined substantially at a predetermined angle θ (for example, about 15 to 45 °) from the horizontal plane and is disposed substantially horizontally.

  In the present embodiment, the evaporator 13 is inclined and arranged so that the front side of the vehicle, specifically, the front side of the vehicle is high and the rear side is low. On the other hand, the air blown from the blower 12 flows from the front of the vehicle toward the lower space 15 of the evaporator 13.

  As is well known, the evaporator 13 has a heat exchanging portion 13a composed of a combination of a large number of flat tubes 16 constituting a refrigerant passage and fins 17 such as corrugated fins, and the tubes 16 of the heat exchanging portion 13a Tank parts 13b and 13c are arranged at both ends in the longitudinal direction.

  The tank portions 13 b and 13 c perform refrigerant distribution to the tube 16 or refrigerant collection from the tube 16. The lower tank portion 13b on one side is located at the lower end portion in the inclination direction a of the evaporator 13, and the upper tank portion 13c on the other side is located at the upper end portion in the inclination direction a of the evaporator 13. Therefore, the stacking direction of the tubes 16 (width direction of the evaporator 13) is a direction (b direction in FIG. 3) orthogonal to the inclination direction a of the evaporator 13.

  Side plates 13 d (FIG. 3) that hold both the tanks 13 b and 13 c and hold the rectangular outer shape of the evaporator 13 are arranged in parallel to the tubes 16 at both longitudinal ends of the tanks 13 b and 13 c. .

  The blown air that has flowed into the lower space 15 of the evaporator 13 flows upward from below through the gap between the tubes 16 and the fins 17 of the heat exchanging portion 13a of the evaporator 13 as indicated by an arrow d.

  On the upper side of the evaporator 13, a heating heat exchanger, a temperature adjusting air mix door, a blow mode switching mechanism, and the like (not shown) are arranged.

  Thereby, the cold air cooled through the evaporator 13 is mixed with the warm air heated by the heat exchanger for heating by the temperature adjusting air mix door at a predetermined ratio to become the conditioned air at the desired temperature, and the blowing mode is switched. It is blown out into the passenger compartment through a mechanism or the like.

  In the evaporator 13, a drainage guide member 14 is disposed over the entire length in the width direction b of the evaporator 13 at a lower part of the boundary between the heat exchange part 13 a and the lower tank part 13 b.

  Here, the drainage guide member 14 will be described in detail with reference to FIGS. 3 to 9. FIG. 3 is a partially enlarged front view of the evaporator 13 in which the drainage guide member 14 is disposed, and the evaporator 13 and the drainage guide member 14 of FIG. 1 are viewed from below. 4A is an enlarged view of a single body of the drainage guide member 14, FIG. 4B is a view taken in the direction of the arrow A in FIG. 4A, and FIG. It is a B direction arrow directional view in a).

  FIG. 5 is an enlarged view in the D direction in FIG. 6 is an enlarged cross-sectional view taken along line EE in FIG. FIG. 7 is an FF enlarged cross-sectional view in FIG. FIG. 8 is a schematic perspective view of the evaporator 13 in which the drainage guide member 14 is disposed. FIG. 9 is an enlarged view of a portion G in FIG.

  As shown in FIGS. 3 and 4, the drainage guide member 14 has a substantially rectangular plate-like base portion 18 and a claw portion 19 extending in the width direction b of the evaporator 13 in a plane substantially parallel to the evaporator 13. , The pillar portion 20, the contact portion 21, the protruding portion 22, the elastic member 23, and the like. In this example, the portions other than the elastic member 23 are integrally formed of a resin material. In addition, the nail | claw part 19 and the pillar part 20 correspond to the holding | maintenance part in this invention.

  The claw portion 19 of the drainage guide member 14 is formed so as to protrude toward the evaporator 13 at both ends in the longitudinal direction (left-right direction in FIG. 3) of the base portion 18. The two column portions 20 are formed so as to protrude from the base portion 18 toward the evaporator 13, and two column portions 20 are arranged in the longitudinal direction of the base portion 18.

  Thus, when the drainage guide member 14 is attached to the evaporator 13 from the side perpendicular to the air inflow surface 13e of the evaporator 13 (the surface side of the paper surface in FIG. 3), the claw portion 19 and the column portion 20 cause the evaporator 13 is fixed.

  Specifically, a triangular engagement portion 19a that protrudes toward the evaporator 13 is formed on the claw portion 19, and as shown in FIGS. 5 and 6, the engagement portion 19a is formed in the lower tank. It engages with the recess 24 on the side surface of the portion 13b.

  Further, as shown in FIG. 7, the column portion 20 is inserted into a gap between the lower tank portion 13 b and the fins 17 adjacent to the lower tank portion 13 b, and is formed in the column portion 20. The saw-toothed sawtooth portion 20 a is engaged with the louver portion 17 a of the fin 17.

  In addition, insertion of the column part 20 is made easy by forming the front-end | tip part of the column part 20 in a taper shape. Further, the tip projection 20b formed on the tip of the column 20 and on the back side of the surface on which the sawtooth 20a is formed contacts the lower tank portion 13b, so that the sawtooth 20a is finned. It is sure to be pressed against.

  A contact portion 21 that protrudes in a plate shape toward the evaporator 13 is formed on the upper end portion of the base portion 18 in the inclination direction a over almost the entire length of the base portion 18. A large number of insertion portions 21 a protruding in a triangular shape are formed at the tip of the contact portion 21. As shown in FIG. 8, the insertion portion 21 a is inserted into the gap between the tube 16 and the fin 17 of the evaporator 13.

  Specifically, the insertion portion 21a is inserted into a gap formed on the back side of the fin 17 with which the column portion 20 abuts. As a result, as shown by the arrow e in FIG. 9, the condensed water accumulated in the gap portion flows out of the gap portion through the insertion portion 21 a, and the condensed water that has flowed out of the gap portion travels down through the contact portion 21. It has come to flow.

  Further, the linear tip surface 21b of the contact portion 21 (that is, the tip surface other than the insertion portion 21a) abuts on the tube 16 of the heat exchanging portion 13a, so that air is passed between the drainage guide member 14 and the evaporator 13. Is controlled to pass.

  A plurality of abutting portions 25 having a predetermined height h are formed in a shape extending in a streak pattern along the inclination direction a on the flat surface portion of the base portion 18 facing the evaporator 13 side. As shown in FIG. 6, the contact portion 25 contacts the lower tank portion 13b of the evaporator 13, so that a predetermined dimension h is provided between the base portion 18 of the drainage guide member 14 and the lower tank portion 13b. A gap 26 is secured.

  As a result, the condensed water flowing along the contact portion 21 flows through the gap 26 as indicated by the arrow f in FIG. 9 and falls into the drainage space 27 described later. In this example, the predetermined dimension h is set to about 1 mm.

  A large number of rectangular through holes 28 are formed in the longitudinal direction of the base portion 18 corresponding to the insertion portions 21 a of the contact portion 21 at the base portion of the contact portion 21 at the upper end portion in the inclination direction a of the base portion 18. They are arranged side by side.

  Further, a projecting portion 22 that projects in a triangular shape facing the bottom surface 11c side of the cases 11a and 11b penetrates the lower surface of the base portion 18, that is, the surface opposite to the side on which the contact portion 21 is formed. A large number of holes are formed in the width direction of the base portion 18 corresponding to the holes 28.

  Thereby, a part of the condensed water that flows along the contact portion 21 passes through the through hole 28 as indicated by an arrow g, flows along the protruding portion 22, and falls downward. .

  Further, an elastic member 23 formed in a prismatic shape with elastic urethane foam or the like is attached to the lower surface of the base portion 18 with a double-sided tape or the like.

  As shown in FIG.1 and FIG.9, the rib part 29 which protrudes upwards is arrange | positioned at the bottom face 11c of case 11a, 11b. The rib portion 29 has a plate-like shape extending over the entire region in the width direction of the evaporator 13, and the left rib portion 29a formed integrally with the left divided case 11a and the right side formed integrally with the right divided case 11b. It is comprised by the rib part 29b.

  When the evaporator 13 is accommodated in the lower portion of the cases 11a and 11b, the elastic member 23 attached to the base portion 18 is pressed against the upper end surface of the rib portion 29 and is compressed and deformed. Thereby, the clearance gap between the base part 18 and the rib part 29 is sealed, and it can prevent that ventilation air passes between the base part 18 and the rib part 29. FIG.

  Therefore, the lower space 15 of the evaporator 13 includes the air blowing space 30 upstream of the drainage guide member 14 and the rib portion 29 (the upper side in the inclination direction a of the evaporator 13), the drainage guide member 14 and the rib. It is partitioned into a drainage space 27 on the downstream side of the air flow from the portion 29.

  The drainage space 27 plays a role of collecting condensed water. A drainage port 31 is opened in the drainage space 27, and the condensed water can be discharged out of the passenger compartment through the drainage port 31.

  A notch 29 c is formed at the base of the rib 29. Specifically, the notch 29c is formed on the joint surface between the left rib 29a and the right rib 29b, and the area of the notch 29c is substantially the same as the area of the drain port 31.

  For this reason, the condensed water (arrow g) that has flowed down through the through hole 28 and the protrusion 22 passes through the notch 29c and flows to the drain port 31 side.

  In addition, a sealing mechanism for preventing condensed water from leaking from the case coupling surface to the outside of the coupling surface of the left divided case 11a and the right divided case 11b is disposed below the evaporator 13. Yes.

  Specifically, a seal member (not shown) formed of an elastic material in a substantially cylindrical shape is disposed in the seal groove 32 formed integrally with one of the divided cases. The seal member is compressed by a projection (not shown) formed integrally with the other divided case, thereby exhibiting a sealing property on the case coupling surface.

  By the way, since the moisture in the air is condensed by the cooling action in the heat exchange section 13a of the evaporator 13, condensed water is generated on the surfaces of the tubes 16 and the fins 17 of the heat exchange section 13a. Since the blown air passes from below to above in the gap between the tubes 16 and the fins 17 of the heat exchange unit 13a, upward wind pressure acts on the condensed water on the surface of the heat exchange unit 13a.

  For this reason, most of the condensed water on the surface of the heat exchanging portion 13a does not immediately drop downward, but toward the tank portion 13b side of the inclined lower end portion of the evaporator 13 along the surface of the tube 16 of the heat exchanging portion 13a as indicated by an arrow j. Moving. That is, since the longitudinal direction of the tube 16 of the heat exchanging portion 13a faces the inclination direction a of the evaporator 13, most of the condensed water moves along the surface of the tube 16 to the inclined lower end side of the evaporator 13.

  Then, condensed water accumulates in the gap between the tube 16 and the fin 17 at the inclined lower end portion of the evaporator 13, and a condensed water concentration portion 33 is formed. In the condensed water concentration portion 33, the insertion portion 21 a of the contact portion 21 of the drainage guide member 14 is inserted.

  For this reason, the condensed water of the condensed water concentration part 33 tends to flow out of the gap part along the insertion part 21a of the contact part 21 as indicated by an arrow e. The condensed water that has flowed out through the insertion portion 21a flows downward along the surface of the contact portion 21, and further flows through the gap 26 as indicated by the arrow f and falls into the drainage space 27 at the lowest part of the cases 11a and 11b.

  That is, by inserting the insertion portion 21a into the condensed water concentration portion 33, the fall of the condensed water accumulated in the condensed water concentration portion 33 is promoted as compared with the case where the contact portion 21 is simply brought into contact with the surface of the heat exchange portion 13a. can do.

  And since the condensed water which fell to the drainage space 27 is drained from the drainage port 31 to the case exterior, it can drain smoothly.

  Further, a part of the condensed water that flows out of the gap portion by the insertion portion 21a and flows along the surface of the contact portion 21 passes through the through hole 28 as shown by an arrow g and is collected at the tip portion of the protruding portion 22 to form a water droplet. And falls downward. The condensed water dropped from the front end of the protrusion 22 passes through the notch 29c formed in the joint surface between the left rib portion 29a and the right rib portion 29b, and flows into the drain space 27 and the drain port 31. Drained outside.

  That is, if the gap 26 is set to be large, the flow rate of air passing through the gap 26 increases and hinders drainage. In this example, the gap 26 is set within a predetermined dimension h. For this reason, when the amount of condensed water generated is large, such as when the air humidity is high, if the condensed water is drained only from the gap 26, it cannot be drained sufficiently.

  Therefore, in this example, since the condensed water is drained not only from the gap 26 but also from the through hole 28, it can be smoothly drained even when the amount of condensed water generated is large.

  Further, the contact portion 21 of the drainage guide member 14 is in contact with the tube 16 of the heat exchanging portion 13 a of the evaporator 13, and the elastic member 23 attached to the drainage guide member 14 is pressed against the upper end surface of the rib portion 29. Since it is compressed and deformed, the flow of the blown air to the drainage space 27 is blocked.

  For this reason, the condensed water about to fall into the drainage space 27 as shown by the arrow f can be drained more smoothly without being blown up and pushed back by the wind pressure of the blown air.

  Further, since the contact portion 21 of the drainage guide member 14 is formed at the upper end portion in the inclination direction a of the base portion 18, the claw portion 19 and the column portion 20 are arranged below the contact portion 21 in the inclination direction a. can do.

  For this reason, since the nail | claw part 19 and the column part 20 are not exposed in the ventilation space 30, and the claw part 19 and the column part 20 do not block the flow of blowing air, the claw part 19 and the column part 20 are provided. As a result, it is possible to avoid a decrease in the flow rate of the air passing through the heat exchanging portion 13a of the evaporator 13.

  Next, a procedure for assembling the evaporator 13 and the drainage guide member 14 will be described.

  First, when the drainage guide member 14 is attached to the evaporator 13 from the side perpendicular to the air inflow surface 13 e of the evaporator 13, the drainage guide member 14 is fixed to the evaporator 13 by the claw portion 19 and the column portion 20.

  Next, the evaporator 13 to which the drainage guide member 14 is fixed is inserted into either the left divided case 11a or the right divided case 11b in a direction perpendicular to the case dividing surface. Then, both the cases 11a and 11b are fastened together so that the other divided case is placed on the evaporator 13 from the direction perpendicular to the case dividing surface.

  Thus, in this embodiment, since the drainage guide member 14 is directly fixed to the evaporator 13, the arrangement position of the drainage guide member 14 with respect to the evaporator 13 is determined only by the accuracy of the evaporator 13 and the drainage guide member 14 itself. Is done.

  In other words, since it can be avoided that the position of the drainage guide member 14 relative to the evaporator 13 is determined by the molding accuracy of the cases 11a and 11b, the displacement of the position of the drainage guide member 14 relative to the evaporator 13 can be avoided. Can be suppressed.

  As a result, the contact portion 21 of the drainage guide member 14 can be reliably brought into contact with the tube 16 of the heat exchanging portion 13a of the evaporator 13 without being affected by the molding accuracy of both cases 11a and 11b. Thus, the insertion portion 21 a of 21 can be reliably inserted into the gap of the heat exchange portion 13 a of the evaporator 13.

  Further, when the evaporator 13 is disposed in both cases 11a and 11b, the drainage guide member 14 comes into contact with the rib portion 29, so that an external force is applied to the drainage guide member 14 from the rib portion 29. The member 14 is securely fixed to the evaporator 13 by the claw portion 19 and the column portion 20.

  For this reason, since it can prevent that the position of the drainage guide member 14 shifts | deviates by the external force from the rib part 29, the contact part 21 of the drainage guide member 14 is maintained in the state which contacted the tube 16 of the heat exchange part 13a of the evaporator 13. FIG. can do.

  On the other hand, the vertical displacement of the position of the evaporator 13 with respect to the rib portions 29 on the case 11a, 11b side is absorbed by the elastic member 23. In other words, the elastic elastic member 23 having elasticity is crushed in the vertical direction between the base portion 18 and the rib portion 29, so that the displacement of the arrangement position of the evaporator 13 in the vertical direction with respect to the rib portion 29 can be absorbed.

  By the way, if the molding accuracy of the cases 11a and 11b cannot be sufficiently ensured due to the molding convenience of the cases 11a and 11b, the displacement of the arrangement position of the evaporator 13 in the vertical direction becomes large.

  Therefore, in this example, since the elastic member 23 has a simple prismatic shape, it is possible to increase the collapse allowance of the elastic member 23 by increasing the thickness of the elastic member 23. When the displacement of the arrangement position of the evaporator 13 in the vertical direction becomes large, the displacement can be easily made by setting a large space between the base portion 18 and the rib portion 29 and setting a large collapse allowance for the elastic member 23. Can be absorbed into.

  In addition, since the drainage guide member 14 is directly assembled to the evaporator 13 and then the evaporator 13 is assembled to the cases 11a and 11b, the evaporator 13 is attached to either the case 11a or 11b in a direction perpendicular to the dividing surface. When inserting and when the other split case is put on the evaporator 13 from the direction perpendicular to the split surface, the surface of the evaporator 13 and the contact portion 21 of the drainage guide member 14 are prevented from sliding. it can.

  For this reason, since the unevenness | corrugation on the surface of the evaporator 13 (the unevenness | corrugation of the tube 16 and the fin 17) can be prevented from being caught on the contact part 21 of the drainage guide member 14, the assembly | attachment of the drainage guide member 14 is easy.

  Furthermore, since sliding of the surface of the evaporator 13 and the contact portion 21 of the drainage guide member 14 can be avoided, an insertion portion 21 a protruding into the gap portion of the evaporator 13 is formed at the tip of the contact portion 21. It is possible to improve the drainage of condensed water.

  On the other hand, when the evaporator 13 is inserted into one of the cases 11a and 11b in the direction perpendicular to the dividing surface, and when the other dividing case is placed over the evaporator 13 in the direction perpendicular to the dividing surface. The elastic member 23 slides against the rib portion 29 while being pressed against the rib portion 29.

  In this embodiment, the elastic member 23 is affixed and fixed to the drainage guide member 14. Further, since the sliding surface on the rib portion 29 side is a smooth surface without unevenness, the elastic member 23 can slide smoothly with the rib portion 29 in the horizontal direction. For this reason, it is possible to avoid the elastic member 23 from being detached from the base portion 18 by sliding with the rib portion 29.

  For this reason, in the case structure of right and left division, the assembling property of the condensed water drainage structure can be improved.

(Second Embodiment)
In the said 1st Embodiment, although the insertion part 21a of the contact part 21 of the drainage guide member 14 is inserted in the space | gap part of the heat exchange part 13a, the condensed water of the condensed water concentration part 33 is sucked out. In the embodiment, as shown in FIG. 10, the insertion portion 21a of the contact portion 21 is abolished, and the contact portion 21 formed of an elastic material is brought into close contact with the heat exchange portion 13a and inserted into the gap portion of the heat exchange portion 13a. The condensed water of the condensed water concentration part 33 is sucked out by this.

  FIG. 10 is an enlarged cross-sectional view of a main part of the indoor air conditioning unit 10 according to the present embodiment, FIG. 11A is an enlarged view of a single drainage guide member 14 in the present embodiment, and FIG. Fig. 11 (a) is an arrow view in the H direction, and Fig. 11 (c) is an arrow view in the J direction in Fig. 4 (a).

  In the present embodiment, the contact portion 21 of the drainage guide member 14 is formed of an elastic elastomer and the insertion portion 21a is eliminated. In this example, the drainage guide member 14 other than the elastic member 23 is integrally formed by forming the contact portion 21 integrally with the resin base portion 18, the claw portion 19, the column portion 20, etc. by two-color molding. ing.

  Moreover, the length in the protrusion direction of the contact part 21 is set to the length which the contact part 21 whole closely_contact | adheres to the heat exchange part 13a.

  As a result, as shown in FIG. 10, a portion of the contact portion 21 that directly contacts the tube 16 of the heat exchange portion 13a is elastically deformed, and a portion that does not directly contact the tube 16 is inserted into the gap portion of the heat exchange portion 13a. Is done.

  For this reason, since the condensed water of the condensed water concentration part 33 can flow out of the space | gap part of the heat exchange part 13a along the contact part 21, the effect similar to the said 1st Embodiment can be acquired.

(Other embodiments)
In each of the above embodiments, the air conditioning case 11 is divided in the left-right direction, but the air conditioning case 11 may be divided in the up-down direction. In this case, as an assembling procedure of the evaporator 13 and the drainage guide member 14, after fixing the drainage guide member 14 to the evaporator 13, the evaporator 13 may be inserted vertically with respect to the case.

  For this reason, since the elastic member 23 does not slide in the horizontal direction with the rib portion 29 during assembly, the assembly of the evaporator 13 and the drainage guide member 14 is further facilitated.

  Moreover, in each said embodiment, the nail | claw part 19 and the pillar part 20 are formed in the drainage guide member 14, and the drainage guide member 14 is fixed to the evaporator 13 by the nail | claw part 19 and the pillar part 20. FIG. However, only one of the claw portion 19 and the column portion 20 is formed on the drainage guide member 14, and the drainage guide member 14 is fixed to the evaporator 13 by only one of the claw portion 19 and the column portion 20. May be.

  Further, in each of the above embodiments, the condensed water is drained by flowing through the gap 26 between the base portion 18 of the drainage guide member 14 and the lower tank portion 13b, the through hole 28 of the base portion 18, and the protruding portion 22. However, the through hole 28 and the protruding portion 22 may be eliminated, and the condensed water may flow through only the gap 26 and be drained.

  Moreover, in each said embodiment, although the nail | claw part 19, the column part 20, and the contact part 21 are integrally shape | molded so that it may couple | bond together via the base part 18, the base part 18 is abolished and the nail | claw part 19 is abolished. The column part 20 and the contact part 21 may be integrally formed so as to be directly coupled. That is, the claw portions 19 may be disposed at both ends of the contact portion 21 and molded so that the column portion 20 protrudes from the intermediate portion of the contact portion 21.

  When the base portion 18 is abolished in this way, the elastic member 23 is attached to the tip end surface on the rib portion 29 side of the contact portion 21, and the tip end surface of the contact portion 21 on the rib portion 29 side and the rib portion 29. What is necessary is just to make it contact with a front-end | tip surface via the elastic member 23.

  In each of the above embodiments, the rib portion 29 protruding upward is arranged on the bottom surface 11c of the case 11a, 11b, and the elastic member 23 attached to the base portion 18 is pressed against the upper end surface of the rib portion 29. By compressing and deforming, the lower space 15 of the evaporator 13 is partitioned into the blower space 30 and the drainage space 27, but the evaporator 13 is disposed close to the bottom surface 11c of the cases 11a and 11b. In this case, the rib portion 29 is abolished, and the elastic member 23 attached to the base portion 18 is directly pressed against the bottom surface 11c of the cases 11a and 11b so as to be compressed and deformed. The lower space 15 may be partitioned into a blower space 30 and a drainage space 27.

It is principal part sectional drawing of the indoor air conditioning unit by 1st Embodiment of this invention. It is a typical perspective view which shows the division structure of the case of the indoor air-conditioning unit in FIG. It is a partial expanded front view of the evaporator in which the drain plate member in a 1st embodiment is arranged. (A) is the single-piece | unit enlarged view of the waste_water | drain guide member 14 in 1st Embodiment, (b) is an A direction arrow directional view in (a), (c) is a B directional arrow directional view in (a). It is. It is a D direction expansion arrow line view in FIG. It is EE expanded sectional drawing in FIG. It is FF expanded sectional drawing in FIG. It is a typical perspective view of the evaporator in which the drain plate member in 1st Embodiment is arrange | positioned. It is the G section enlarged view in FIG. It is a principal part expanded sectional view of the indoor air-conditioning unit by 2nd Embodiment of this invention. (A) is an enlarged view of a single drainage plate member in the second embodiment, (b) is an arrow view in the H direction in (a), and (c) is an arrow view in the J direction in (a). .

Explanation of symbols

11 ... Air-conditioning case (case), 11a, 11b ... Split case, 11c ... Bottom surface,
13 ... Evaporator (cooling heat exchanger), 13a ... Heat exchange part, 13e ... Air inflow surface,
14 ... Drainage guide member, 15 ... Lower space, 18 ... Base part, 19 ... Claw part (holding part),
20 ... pillar part (holding part), 21 ... contact part, 21a ... insertion part, 22 ... protrusion part,
23 ... Elastic member, 25 ... Contact part, 26 ... Gap, 27 ... Drainage space, 28 ... Through-hole,
29 ... rib part, 30 ... ventilation space, a ... inclination direction, b ... direction orthogonal to inclination direction.

Claims (17)

A case (11) that forms an air passage through which air flows toward the passenger compartment;
Cooling that is arranged in the case (11) so as to be inclined with respect to a horizontal plane, introduces the air from the lower space (15) to the heat exchange part (13a), cools it, and guides the cooled air upward. Heat exchanger (13),
The cooling heat exchanger (13) is disposed between the bottom surface (11c) of the case (11) located below the cooling heat exchanger (13) and the cooling heat exchanger (13). And a drainage guide member (14) for guiding drainage of condensed water of
The drainage guide member (14) has a longitudinal direction in a direction (b) perpendicular to the inclined direction (a) of the cooling heat exchanger (13),
Condensed water generated in the cooling heat exchanger (13) is drained into the drainage space (27) below the drainage guide member (14) in the inclined direction (a) of the lower space (15). Is supposed to be
The drainage guide member (14) is in contact with the surface (13e) on the upstream side of the air flow of the cooling heat exchanger (13), and the contact portion (21) on the upstream side of the air flow. Holding portions (19, 20) for holding and fixing to the cooling heat exchanger (13) in a state of being in contact with the surface (13e),
After the drainage guide member (14) is fixedly disposed on the cooling heat exchanger (13), the cooling heat exchanger (13) is disposed in the case (11), and the drainage guide member ( 14) comes into contact with the bottom (11c) side portion of the case (11) ,
The contact portion (21) is formed to extend in the orthogonal direction (b),
An air conditioner characterized in that a protruding insertion portion (21a) to be inserted into a gap portion of the heat exchange portion (13a) is formed at a tip portion of the contact portion (21) . The lower space (15) is, by the drainage guide member (14), the drainage space (27) and an air blowing space through which the air flows in the inclined direction (a) above the drainage space (27). (30) is divided into
The cooling heat exchanger (13) is configured to introduce the air from the blower space (30) into the heat exchange part (13a) in the lower space (15). The air conditioner according to claim 1. A rib portion (29) having a protruding shape protruding from the bottom surface (11c) toward the drainage guide member (14) is formed integrally with the bottom surface (11c),
The rib portion (29) has a longitudinal direction substantially parallel to the longitudinal direction of the drainage guide member (14),
The air conditioner according to claim 1, wherein the drainage guide member (14) is configured to come into contact with the rib portion (29) in the bottom surface (11c) side portion. The lower space (15) is above the drainage space (27) and the drainage space (27) in the inclined direction (a) by the rib portion (29) and the drainage guide member (14). And is divided into a ventilation space (30) through which the air flows,
The cooling heat exchanger (13) is configured to introduce the air from the blower space (30) into the heat exchange part (13a) in the lower space (15). The air conditioner according to claim 3. The drainage guide member (14) includes a base portion (18) extending in the orthogonal direction (b) between the cooling heat exchanger (13) and the rib portion (29),
The air conditioner according to claim 3 or 4, wherein the base part (18) is formed integrally with the contact part (21) and the holding part (19, 20). The base portion (18) is disposed over the entire length of the cooling heat exchanger (13) in the orthogonal direction (b),
The holding portion is constituted by a claw portion (19) protruding from the both end portions in the orthogonal direction (b) of the base portion (18) to the cooling heat exchanger (13) side,
The air conditioner according to claim 5, wherein the claw portion (19) is adapted to engage with an outer surface of the cooling heat exchanger (13) on the orthogonal direction (b) side. apparatus. The base portion (18) is disposed at least between the rib portion (29) and the heat exchange portion (13a) in the inclined direction (a),
The holding part is constituted by a pillar part (20) protruding from the part facing the heat exchange part (13a) in the base part (18) toward the heat exchange part (13a),
The air conditioner according to claim 5, wherein the column part (20) is inserted and held in a gap part of the heat exchange part (13a). The base portion (18) is disposed over the entire length of the cooling heat exchanger (13) in the orthogonal direction (b), and at least the rib portion (29) and the heat in the inclined direction (a). It is arranged between the exchange part (13a),
The holding portion includes a claw portion (19) projecting from the both end portions in the orthogonal direction (b) of the base portion (18) to the cooling heat exchanger (13) side, and the base portion (18). Among them, it is constituted by a column part (20) protruding from the part facing the heat exchange part (13a) to the heat exchange part (13a) side,
The claw portion (19) is adapted to engage with an outer surface on the orthogonal direction (b) side of the cooling heat exchanger (13),
Furthermore, the said column part (20) is inserted and hold | maintained in the space | gap part of the said heat exchange part (13a), The air conditioner of Claim 5 characterized by the above-mentioned. The contact portion (21) protrudes from the upper end portion in the inclined direction (a) of the base portion (18) toward the heat exchange portion (13a), and the air inflow surface (13e) of the heat exchange portion (13a). The air conditioner according to any one of claims 5 to 8, wherein the air conditioner is in contact with the air conditioner. A protruding contact portion (25) that contacts the cooling heat exchanger (13) is integrally formed at a portion of the base portion (18) facing the cooling heat exchanger (13). ,
The air conditioner according to claim 9, wherein a gap (26) is formed between the base portion (18) and the cooling heat exchanger (13) by the contact portion (25). . A through hole (28) penetrating from the cooling heat exchanger (13) side to the rib portion (29) side is formed at the base portion of the contact portion (21) of the base portion (18). The air conditioner according to claim 10. The air conditioning according to claim 11, wherein a peripheral portion on the rib portion (29) side of the through hole (28) is provided with a protruding portion (22) protruding toward the bottom surface (11c) side. apparatus. The drainage guide member (14) is molded of resin,
The air conditioner according to any one of claims 9 to 12, wherein the insertion portion (21a) is integrally formed at a distal end portion of the contact portion (21). In the drainage guide member (14), the base portion (18) and the holding portion (19, 20) made of resin and the contact portion (21) made of an elastically deformable elastic material are integrally formed,
A portion of the contact portion (21) that directly contacts the heat exchange portion (13a) is elastically deformed,
The part of the contact part (21) that is not in direct contact with the heat exchange part (13a) is inserted into the gap of the heat exchange part (13a). The air conditioner described in 1. The drainage guide member (14) includes an elastic member (23) made of an elastically deformable elastic material,
The elastic member (23) is fixed to the rib portion (29) side portion of the base portion (18), and is in close contact with the distal end surface of the rib portion (29) to be elastically deformed. The air conditioner according to any one of claims 3 to 14, characterized in that The drainage guide member (14) includes an elastic member (23) made of an elastically deformable elastic material,
The elastic member (23) is fixed to the portion of the drainage guide member (14) that contacts the bottom surface (11c) side portion of the case (11), and the bottom surface (11c) of the case (11). The air conditioner according to claim 1 or 2, wherein the air conditioner is in close contact with the side portion and elastically deforms. The case (11) is configured to integrally fasten a plurality of divided cases (11a, 11b),
The air conditioner according to any one of claims 1 to 16, wherein a coupling surface of the plurality of divided cases (11a, 11b) extends in a substantially vertical direction.

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