JP2005043039A - Evaporator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an evaporator capable of reducing a condensate amount staying on a top face of a lower tank. <P>SOLUTION: In this evaporator 1, two or more trains of heat exchanging tube groups 5 comprising a plurality of heat exchanging tubes 4 are provided longitudinal-directionally with a space, between a pair of an upper tank 2 and the lower tank 3 arranged vertical-directionally with a space, upper and lower both ends of the heat-exchanging tubes 4 are connected respectively to the both upper and lower tanks 2, 3, and fins 6 are arranged in air flow clearances among the adjacent heat exchanging tubes 4. The lower tank 3 has the top face 3a, both front and rear side faces 3b and a bottom face 3c. A groove 29 for a flow of the condensate is formed in a portion between the heat exchanging tubes in the both longitudinal-directional sides of the lower tank 3, to be extended respectively from a longitudinal-directional intermediate part of the top face 3a toward the both front and rear side faces 3b. A bottom face of the first portion existing in the top face 3a of the lower tank 3 in the groove 29 is gradually lowered from the longitudinal-directional intermediate part of the top face 3a toward both longitudinal-directional side edge parts. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an evaporator used for, for example, a car air conditioner, and more specifically, a heat exchange tube group including a plurality of heat exchange tubes arranged in parallel at intervals in the left-right direction is arranged in a plurality of rows. The heat exchange core part comprised by being performed, and the lower tank which is arrange | positioned at the lower end side of the heat exchange core part, and to which the lower end part of the heat exchange pipe | tube which comprises each heat exchange pipe group was connected was provided. It relates to the evaporator.

  In this specification and claims, the top, bottom, left and right in FIGS. 1 and 2 are respectively referred to as top and bottom and left and right, respectively, and the downstream side of the air flowing through the ventilation gap between adjacent heat exchange tubes of the heat exchange tube group ( The direction indicated by the arrow X in FIG. 1, the right side of FIG. 3) is the front, and the opposite side is the rear.

  In this specification, the term “aluminum” includes aluminum alloys in addition to pure aluminum.

  Conventionally, as a evaporator for a car air conditioner, a plurality of flat hollow bodies formed by brazing peripheral edges with a pair of plate-shaped plates facing each other are arranged in parallel, and a corrugated fin with a louver between adjacent flat hollow bodies A so-called laminated evaporator, in which the above is disposed and brazed to a flat hollow body, has been widely used. However, in recent years, there has been a demand for further reduction in size and weight and performance of the evaporator.

  As an evaporator that satisfies such a requirement, heat composed of a plurality of heat exchange tubes arranged in parallel in the left-right direction between a pair of upper and lower tanks spaced in the up-down direction. Two rows of exchange pipe groups are provided at intervals in the front-rear direction, and the upper and lower ends of the heat exchange pipes constituting each heat exchange pipe group are connected to the upper and lower tanks, respectively. Corrugated fins with louvers are arranged in the ventilation gap between them, and the top surface of the lower tank is a horizontal flat surface (see, for example, Patent Document 1), or the top surface of the lower tank is the middle in the front-rear direction There has been proposed one that is formed so that the portion becomes the highest portion and gradually decreases from the highest portion toward the front and rear sides (for example, see Patent Document 2).

  Since the evaporators described in both patent documents are reduced in size, weight, and performance as compared with the stacked evaporator, the amount of condensed water generated with respect to the heat transfer area increases.

As a result, a relatively large amount of condensed water accumulates between the top surface of the lower tank and the lower end of the corrugated fins, and the condensed water tends to freeze, which may reduce the performance of the evaporator.
JP 2001-324290 A Japanese Patent Laid-Open No. 2003-75024

  An object of the present invention is to provide an evaporator that solves the above-described problems and can reduce the amount of condensed water accumulated on the top surface of the lower tank.

  In order to solve the above-mentioned problems, the present invention comprises the following aspects.

1) A heat exchange core section configured by arranging a plurality of heat exchange tube groups including a plurality of heat exchange tubes arranged in parallel at intervals in the left-right direction, and heat exchange. In an evaporator provided with a lower tank disposed on the lower end side of the core portion and connected to the lower end portion of the heat exchange pipe constituting each heat exchange pipe group,
The lower tank has a top surface, both front and rear side surfaces, and a bottom surface. Between the heat exchange pipes adjacent in the left and right direction in the front and rear side portions of the lower tank, the front and rear side surfaces from the front and rear intermediate portions respectively. The evaporator is formed with a groove that extends in the direction of flowing condensed water.

  2) The evaporator according to 1) above, wherein each groove has a capillary effect of sucking condensed water on the surface of the lower tank.

  3) The above 1) or 2), wherein the bottom surface of the first portion existing on the top surface of the lower tank of each groove is gradually lowered from the front-rear direction middle portion of the lower tank top surface toward the front and rear side edges. The evaporator.

  4) The top surface of the lower tank is formed so that the middle part in the front-rear direction is the highest part and gradually decreases from the highest part toward the front and rear sides, and each groove is the highest on the top face of the lower tank. The evaporator according to any one of 1) to 3), wherein the evaporator is formed from both front and rear side portions of the lower portion to both front and rear side surfaces of the lower tank.

  5) The evaporator according to 4) above, wherein the depth of the first portion existing on the top surface of the lower tank of each groove is equal over the entire length.

  6) The evaporator according to 4) above, wherein the depth of the first portion existing on the top surface of the lower tank of each groove is gradually increased from the highest portion side of the top surface toward both front and rear sides.

  7) The evaporator according to any one of 4) to 6) above, wherein the depth of the first portion existing on the top surface of the lower tank of each groove is 0.5 to 2.0 mm.

  8) The evaporator according to any one of 4) to 7), wherein the groove width of the first portion existing on the top surface of the lower tank of each groove gradually widens from the groove bottom toward the opening.

  9) The evaporator according to 8) above, wherein the ratio L1 / L2 between the groove bottom width L1 of the first portion of each groove and the opening width L2 is 0.067 to 0.33.

  10) The evaporator according to any one of 1) to 3), wherein the top surface of the lower tank is formed to be a horizontal flat surface.

  11) The evaporator according to 10), wherein the groove width of the first portion existing on the top surface of the lower tank in each groove gradually increases from the groove bottom toward the opening.

  12) The evaporator according to any one of 1) to 11) above, wherein the bottom surface of each groove is a flat surface.

  13) The evaporator according to any one of the above items 1) to 11), wherein the shape of the bottom surface of each groove is an arc shape recessed toward the center in the width direction of the groove bottom in the cross section of each groove.

  14) The evaporator according to 13) above, wherein the radius of curvature of the bottom surface of each groove is ½ of the groove bottom width.

  15) The ratio W2 / W1 of the linear distance W2 between the front and rear ends of the first portion existing on the top surface of the lower tank in each groove and the total width W1 in the front-rear direction of the lower tank is 0.16 to 0.47. The evaporator according to any one of 1) to 14) above.

  16) Any one of 1) to 15) above, wherein the bottom surface of the second portion existing at the connecting portion between the top surface of the lower tank and the front and rear side surfaces in each groove is inclined downward toward the outside in the front-rear direction. The evaporator according to crab.

  17) The evaporator according to 16) above, wherein an inclination angle of the bottom surface of the second portion of each groove with respect to a vertical plane is 20 to 50 degrees.

  18) In the vertical cross section of each groove, the shape of the bottom surface of the first portion existing on the top surface of the lower tank of each groove is an arc shape curved downward from the highest part of the top surface of the lower tank toward the outside in the front-rear direction. The evaporator according to 16) or 17), wherein an inclination angle with respect to a vertical surface of a straight line connecting front and rear ends of the bottom surface of the first portion is smaller than an inclination angle with respect to the vertical surface on the bottom surface of the second portion. .

  19) The evaporator according to any one of 1) to 18) above, wherein the bottom surfaces of the third portions existing on both front and rear side surfaces of the lower tank in each groove are vertical.

  20) The evaporator according to any one of 1) to 19) above, wherein the depth of the third portion existing on both front and rear side surfaces of the lower tank in each groove is 0.3 to 0.8 mm.

  21) The evaporator according to 19) or 20) above, wherein the width of the third portion of each groove is the same from the groove bottom to the opening.

  22) The evaporator according to 21) above, wherein the width of the third portion of each groove is 0.5 to 1.5 mm.

23) A heat exchange core unit configured by arranging a plurality of rows of heat exchange tubes arranged in parallel in the front-rear direction, with a plurality of heat exchange tubes arranged in parallel at intervals in the left-right direction, and heat exchange In an evaporator provided with a lower tank disposed on the lower end side of the core portion and connected to the lower end portion of the heat exchange pipe constituting each heat exchange pipe group,
The lower tank has a top surface, both front and rear side surfaces, and a bottom surface, and the top surface of the lower tank gradually decreases from the highest portion toward the front and rear sides while the middle portion in the front and rear direction is the highest portion. The evaporator is formed as described above, and a groove through which condensed water flows is formed in the connecting portion between the top surface of the lower tank and both front and rear side surfaces.

  24) The evaporator according to 23) above, wherein each groove has a capillary effect of sucking condensed water on the surface of the lower tank.

  25) The evaporator according to 23) or 24), wherein the bottom surface of each groove is inclined downward toward the outer side in the front-rear direction.

  26) The evaporator according to 25) above, wherein an inclination angle of the bottom surface of each groove with respect to a vertical surface is 20 to 50 degrees.

  27) The evaporator according to any one of the above 23) to 26), wherein the width of each groove gradually increases from the groove bottom toward the opening.

  28) The evaporator according to 27) above, wherein the ratio L1 / L2 between the groove bottom width L1 and the opening width L2 of each groove is 0.067 to 0.33.

  29) The evaporator according to any one of the above 23) to 28), wherein the depth of each groove is 0.5 to 2.0 mm.

  30) The evaporator according to any one of the above 23) to 29), wherein the bottom surface of each groove is a flat surface.

  31) The evaporator according to any one of the above 23) to 29), wherein the shape of the bottom surface of each groove is an arc shape recessed toward the center in the width direction of the groove bottom in the cross section of each groove.

  32) The evaporator according to 31) above, wherein the radius of curvature of the bottom surface of each groove is ½ of the groove bottom width.

33) a heat exchange core part having a plurality of heat exchange pipes arranged at intervals in the left-right direction; a lower tank arranged on the lower end side of the heat exchange core part and connected to the lower end part of the heat exchange pipe; In an evaporator equipped with
The lower tank has a top surface, front and rear side surfaces, and a bottom surface, and at least one of the front and rear side surfaces of the lower tank has a plurality of grooves extending vertically and allowing condensed water to flow in the left-right direction. The evaporator is formed.

  34) The evaporator according to the above 33), wherein grooves are formed on both front and rear sides of the lower tank.

  35) The evaporator according to the above 33) or 34), wherein at least a portion close to both front and rear side edges of the entire top surface of the lower tank is provided with a portion that is lowered downward in the front-rear direction.

  36) Among the above 33) to 35), the top surface of the lower tank is formed such that the middle part in the front-rear direction is the highest part and gradually decreases from the highest part toward the front and rear sides. Evaporator in any one.

  37) The evaporator according to any one of the above 33) to 36), wherein each groove has a capillary effect of sucking condensed water on the surface of the lower tank.

  38) The evaporator according to any one of the above 33) to 37), wherein the bottom surface of each groove is vertical.

  39) The evaporator according to any one of the above 33) to 38), wherein the depth of each groove is 0.3 to 0.8 mm.

  40) The evaporator according to any one of the above 33) to 39), wherein the width of each groove is the same from the groove bottom to the opening.

  41) The evaporator according to 40) above, wherein the width of each groove is 0.5 to 1.5 mm.

  42) The evaporator according to any one of the above 33) to 41), wherein the bottom surface of each groove is a flat surface.

  43) The evaporator according to any one of the above items 33) to 41), wherein in the cross section of each groove, the shape of the bottom surface of each groove is an arc shape recessed toward the center in the width direction of the groove bottom.

  44) The evaporator according to 43) above, wherein the radius of curvature of the bottom surface of each groove is ½ of the groove bottom width.

  45) A refrigeration cycle comprising a compressor, a condenser, and an evaporator, wherein the evaporator is the evaporator according to any one of 1) to 44) above.

  46) A vehicle on which the refrigeration cycle described in 45) above is mounted as an air conditioner.

  According to the evaporator of 1) above, when condensed water is generated on the surface of the corrugated fins, the condensed water that has flowed down to the top surface of the lower tank enters the groove and flows in the groove on both the front and rear side surfaces of the lower tank. It falls from the lower end of the existing part to the lower part of the lower tank. In this way, freezing of the condensed water caused by the accumulation of a large amount of condensed water between the top surface of the lower tank and the lower end of the corrugated fin is prevented, and as a result, the performance of the evaporator is prevented from deteriorating.

  According to the evaporator of 2) above, the condensed water on the top surface of the lower tank enters the groove due to the capillary effect, so that it easily enters the groove, and as a result, the drainage effect of the condensed water is improved.

  According to the evaporator of 3) above, the condensed water that has entered the first portion of the groove can easily flow.

  According to the evaporators 4) to 6), the condensed water that has flowed down to the top surface of the lower tank also flows along the top surface of the tank, and enters the first portion of the groove by the capillary effect during the flow down. It flows through and falls from the lower end of the part existing on both front and rear sides of the lower tank to the lower part of the lower tank. In this way, freezing of the condensed water caused by the accumulation of a large amount of condensed water between the top surface of the lower tank and the lower end of the corrugated fin is prevented, and as a result, the performance of the evaporator is prevented from deteriorating.

  According to the evaporator of the above 7), the condensed water that has entered the groove can easily flow along the groove.

  According to the evaporators 8) and 9), the condensed water collected on the top surface of the lower tank is likely to enter the groove.

  According to the evaporator of the above 10), when condensed water is generated on the surface of the corrugated fin, the condensed water reaching the top surface of the lower tank enters the first portion of the groove due to the capillary effect and flows in the groove. It falls to the lower part of the lower tank from the lower end of the part existing on both front and rear sides of the lower tank. In this way, freezing of the condensed water caused by the accumulation of a large amount of condensed water between the top surface of the lower tank and the lower end of the corrugated fin is prevented, and as a result, the performance of the evaporator is prevented from deteriorating.

  According to the evaporator of the above 11), the condensed water collected on the top surface of the lower tank can easily enter the groove.

  According to the evaporator of the above 12), a corner is formed at the connecting portion between the bottom surface and both side surfaces of the groove, so that the capillary effect is obtained by this corner, and condensed water easily enters the groove.

  According to the evaporators 13) and 14), the capillary effect is obtained by the bottom surface of the arc-shaped groove, and the condensed water easily enters the groove.

  According to the evaporators 16) to 18), the condensed water in the first portion of the groove quickly flows into the second portion by the capillary effect, and passes through the portions present on the front and rear side surfaces of the lower tank of the groove. Drained.

  According to the evaporators of the above 19) to 22), it is possible to efficiently drop the condensed water from the groove below the lower tank.

  According to the evaporator of 23) above, when condensed water is generated on the surface of the corrugated fin, the condensed water that has reached the top surface of the lower tank flows into the groove on the front and rear side edges, and enters the groove. Flows down from both the front and rear sides of the lower tank. In this way, freezing of the condensed water caused by the accumulation of a large amount of condensed water between the top surface of the lower tank and the lower end of the corrugated fin is prevented, and as a result, the performance of the evaporator is prevented from deteriorating.

  According to the evaporator of 24), the condensed water flowing on the top surface of the lower tank enters the groove due to the capillary effect, so that it easily enters the groove, and as a result, the drainage effect of the condensed water is improved.

  According to the evaporator of 25), the condensed water that has entered the groove can easily flow.

  According to the evaporator of the above 26), the condensed water that has flowed through the top surface of the lower tank quickly flows into the groove due to the capillary effect, flows along the groove, and falls downward from both the front and rear side surfaces of the lower tank. .

  According to the evaporators 27) and 28), the condensed water flowing on the top surface of the lower tank easily enters the groove.

  According to the evaporator of 29), the condensed water that has entered the groove can easily flow along the groove.

  According to the evaporator of 30), a corner is formed at the connecting portion between the bottom surface and both side surfaces of the groove, and this corner provides a capillary effect, and condensed water easily enters the groove.

  According to the evaporators 31) and 32), the capillary effect is obtained by the bottom surface of the arc-shaped groove, and the condensed water easily enters the groove.

  According to the evaporator of the above 33) and 34), when condensed water is generated on the surface of the corrugated fin, the condensed water that reaches the top surface of the lower tank enters the groove, flows in the groove, and flows under the lower tank. Fall to. In this way, freezing of the condensed water caused by the accumulation of a large amount of condensed water between the top surface of the lower tank and the lower end of the corrugated fin is prevented, and as a result, the performance of the evaporator is prevented from deteriorating.

  According to the evaporators of 35) and 36) above, when condensed water is generated on the surface of the corrugated fins, the condensed water that reaches the top surface of the lower tank flows on the top surface to both the front and rear side edges and enters the groove. Then, it flows in the groove and falls below the lower tank. In this way, freezing of the condensed water caused by the accumulation of a large amount of condensed water between the top surface of the lower tank and the lower end of the corrugated fin is prevented, and as a result, the performance of the evaporator is prevented from deteriorating.

  According to the evaporator 37), the condensed water flowing on the top surface of the lower tank enters the groove due to the capillary effect, and therefore easily enters the groove. As a result, the drainage effect of the condensed water is improved.

  According to the evaporators 38) to 41), it is possible to efficiently drop the condensed water from the groove below the lower tank.

  According to the evaporator of the above 42), a corner is formed at the connecting portion between the bottom surface and both side surfaces of the groove, so that the capillary effect is obtained by this corner and the condensed water easily enters the groove.

  According to the evaporators 43) and 44), the capillary effect is obtained by the bottom surface of the arc-shaped groove, and the condensed water easily enters the groove.

  Embodiments of the present invention will be described below with reference to the drawings.

  1 to 3 show the overall configuration of the evaporator according to the present invention, FIGS. 4 to 8 show the configuration of the main part, and FIG. 9 shows how the refrigerant flows in the evaporator according to the present invention.

  1 to 3, the evaporator (1) is arranged in parallel between the pair of upper and lower aluminum tanks (2) and (3) spaced apart in the vertical direction. The heat exchange tube group (5) composed of a plurality of aluminum heat exchange tubes (4) is provided in two or more rows in the front-rear direction, here two rows, and each heat exchange tube group (5) is configured. The upper and lower ends of the heat exchange pipe (4) are connected to the upper and lower tanks (2) and (3), respectively, and aluminum is installed in the ventilation gap between adjacent heat exchange pipes (4) in the heat exchange pipe group (5). Corrugated fins (6) made by this are arranged and brazed to the heat exchange pipe (4). Here, the heat exchange core section (10) is constituted by the two heat exchange pipe groups (5) and the corrugated fins (6). Aluminum corrugated fins (6) are also arranged outside the heat exchange tubes (4) at both the left and right ends of the heat exchange tube group (5) and brazed to the heat exchange tubes (4). The aluminum side plate (7) is disposed outside the metal plate and is brazed to the corrugated fin (6).

  The upper tank (2) includes an upper member (8) made of a bare material formed of an aluminum extruded profile, and a plate-shaped lower member (9) formed of an aluminum brazing sheet and brazed to the upper member (8). ) And aluminum caps (11) and (12) for closing the left and right end openings.

  As shown in FIGS. 3 and 4, the upper member (8) has a substantially m-shaped cross section opened downward, and both front and rear walls (13) and (14) extending in the left-right direction, and both front and rear walls (13). (14) an intermediate wall (15) which is provided in the central portion between the two and extends in the left-right direction and partitions the upper tank (2) into two front and rear spaces, and both front and rear walls (13) (14) and intermediate walls (15 ) And two generally arcuate connecting walls (16) projecting upward to connect the upper ends of the two together. The lower end portions of the rear wall (14) and the intermediate wall (15) are integrally connected over the entire length by the drift prevention resistance plate (17). The drift prevention resistance plate (17) may be fixed to the rear wall (14) and the intermediate wall (15) separately from the rear wall (14) and the intermediate wall (15). A plurality of refrigerant passage holes (18) (18A) that are long in the left-right direction are formed in a penetrating manner at intervals in the left-right direction in the portion excluding the left and right end portions in the rear portion of the drift prevention resistance plate (17). Has been. The length of the refrigerant passage hole (18A) at the center in the left-right direction is shorter than the interval between the adjacent heat exchange tubes (4) in the rear heat exchange tube group (5), and the rear heat exchange tubes It is formed between two adjacent heat exchange tubes (4) at the center in the left-right direction of the group (5). Further, the length of the other refrigerant passage hole (18) is longer than the length of the refrigerant passage hole (18A) at the center. On the rear edge of the lower surface of the resistance plate for drift prevention (17), a protruding protrusion (17a) is integrally formed over the entire length, and protrudes downward on the lower edge of the inner surface of the front wall (13). The ridge (13a) is integrally formed over the entire length. The lower end of the intermediate wall (15) protrudes downward from the lower ends of both ridges (13a) (17a), and a plurality of protrusions (15a) protruding downward are integrally formed at the lower edge with a space in the left-right direction. Is formed. The protrusion (15a) is formed by cutting a predetermined portion of the intermediate wall (15).

  The lower member (9) has, on both front and rear side portions thereof, a curved portion (19) having an arc-shaped cross section with a small curvature and a central portion protruding downward. A plurality of pipe insertion holes (21) that are long in the front-rear direction are formed in each bending part (19) at intervals in the left-right direction. The pipe insertion holes (21) of the front and rear curved portions (19) are in the same position in the left-right direction. Rising walls (22) that engage with the ridges (13a) and (17a) of the upper member (8) are integrated with the front edge of the front curved portion (19) and the rear edge of the rear curved portion (19), respectively, over the entire length. Is formed. In addition, a plurality of through holes (24) into which the protrusions (15a) of the upper member (8) are fitted into the flat portion (23) between the curved portions (19) of the lower member (9) are spaced in the left-right direction. Formed.

  The upper and lower members (8) and (9) are caulked with the protrusions (15a) of the upper member (8) being inserted into the through holes (24), and the ridges (13a) (17a) of the upper member (8). ) And the rising wall (22) of the lower member (9) are brazed to each other, and the front side of the intermediate wall (15) of the upper member (8) is the refrigerant inflow side header ( 25) Similarly, the portion on the rear side of the intermediate wall (15) is the refrigerant outflow side header (26).

  Each cap (11) (12) is formed from bare material by pressing, forging or cutting, etc., and a recess is formed on the inner surface in the left-right direction to fit the left and right ends of the upper and lower members (8) (9). The upper and lower members (8) and (9) are brazed using a sheet-like brazing material. The right cap (12) communicates with the refrigerant inlet (12a) leading into the refrigerant inflow side header (25) and the portion above the drift prevention resistor plate (17) within the refrigerant outflow side header (26). A refrigerant outlet (12b) is formed. Also, an aluminum refrigerant inlet / outlet member (27) having a refrigerant inlet (27a) leading to the refrigerant inlet (12a) and a refrigerant outlet (27b) leading to the refrigerant outlet (12b) is brazed to the right cap (12). ing.

  As shown in FIGS. 3 and 5 to 8, the lower tank (3) has a top surface (3a), front and rear side surfaces (3b), and a bottom surface (3c). The top surface (3a) of the lower tank (3) crosses the whole so that the center in the front-rear direction becomes the highest part (28) and gradually decreases from the highest part (28) toward the front and rear sides. It is formed in a surface arc shape. A plurality of grooves (29) extending from the front and rear sides of the highest portion (28) of the top surface (3a) to the front and rear sides (3b) are formed on both front and rear sides of the lower tank (3) at intervals in the left and right direction. Has been. The bottom surface of each groove (29) is a flat surface.

  The depth of the first portion (29a) existing on the top surface (3a) of the lower tank (3) in each groove (29) is the same over its entire length. Both side surfaces of the first portion (29a) of each groove (29) are inclined outward in the left-right direction upward, and the groove width of the first portion (29a) of each groove (29) is the groove bottom. It gradually spreads toward the opening. At this time, the ratio L1 / L2 between the groove bottom width L1 and the opening width L2 is preferably 0.067 to 0.33 (see FIG. 5). When the ratio L1 / L2 is outside the range of 0.067 to 0.33, the capillary effect of the groove (29) is reduced, and the condensed water is less likely to enter the first portion (29a) of the groove (29). . The depth of the first portion (29a) of each groove (29) is preferably 0.5 to 2.0 mm. If this depth is less than 0.5 mm, a condensed water film may be formed on the top surface (3a) so as to cover the groove (29), and the condensed water may not easily enter the first portion (29a). If it exceeds 2.0 mm, condensed water may accumulate in the groove (29) and may freeze. The ratio W2 / W1 between the linear distance W2 between the front and rear ends of the first portion (29a) of each groove (29) and the full width W1 in the front-rear direction of the lower tank (3) is 0.16 to 0.47. It is preferable (see FIG. 3). Further, in the longitudinal section of each groove (29), the shape of the bottom surface of the first portion (29a) is from the highest part (28) side of the top surface (3a) of the lower tank (3) toward the outside in the front-rear direction. It has an arc shape curved downward (see FIG. 3). The radius of curvature of the bottom surface of the arc is preferably 18 to 54.5 mm.

  The bottom surface of the second part (29b) existing in the connecting part (3d) between the top surface (3a) of the lower tank (3) and the front and rear side surfaces (3b) in each groove (29) is directed outward in the front-rear direction. Inclined downward. The inclination angle α of the second portion (29b) with respect to the vertical plane of the inclined bottom surface is preferably 20 to 50 degrees (see FIG. 3). If the inclination angle is less than 20 degrees, the flow rate from the first part (29a) to the second part (29b) may be slow, and condensed water may accumulate in the first part (29a), exceeding 50 degrees. In addition, the flow from the first part (29a) to the second part (29b) may be intermittent rather than continuous. The bottom surface of the second portion (29b) is connected to the end of the bottom surface of the first portion (29a). The inclination angle with respect to the vertical plane of the straight line connecting the front and rear ends of the bottom surface of the first portion (29a) is preferably smaller than the inclination angle α with respect to the vertical surface of the bottom surface of the second portion (29b). Both side surfaces of the second portion (29b) are inclined outward in the left-right direction upward, and the groove width of the second portion (29b) gradually widens from the groove bottom toward the opening. . The ratio of the groove bottom width to the opening width is the same as that of the first portion (29a). The depth of the second portion (29b) is the same as that of the first portion (29a).

  The bottom surfaces of the third portions (29c) existing on the front and rear side surfaces (3b) of the lower tank (3) in each groove (29) are vertical. The depth of the third portion (29c) of each groove (29) is preferably 0.3 to 0.8 mm. The width of the third portion (29c) of each groove (29) is the same from the bottom of the groove (29) to the opening, and is preferably 0.5 to 1.5 mm. If the depth and width of the third portion (29c) are out of the above range, condensed water is difficult to enter the third portion (29c), and the flow down speed may be reduced and drainage performance may be reduced.

  The lower tank (3) includes a plate-like upper member (31) formed from an aluminum brazing sheet, a lower member (32) made of a bare material formed from an aluminum extruded profile, and aluminum that closes both left and right openings. And a cap (33).

  As shown in FIGS. 7 and 8, the upper member (31) has a circular cross-sectional shape with the center portion in the front-rear direction protruding upward, and the hanging walls (31a) are integrally formed over the entire length at both front and rear edges. Has been. The upper surface of the upper member (31) is the top surface (3a) of the lower tank (3), and the outer surface of the hanging wall (31a) is the front and rear side surfaces (3b) of the lower tank (3). On both the front and rear sides of the upper member (31), a groove (29) is formed from the highest position (28) at the center in the front-rear direction to the lower end of the hanging wall (31a). A long tube insertion hole (34) is formed in the front-rear direction between adjacent grooves (29) in both front and rear side portions excluding the highest position (28) at the front-rear center of the upper member (31). The front and rear tube insertion holes (34) are at the same position in the left-right direction. A plurality of through holes (35) are formed at intervals in the left-right direction at the highest position (28) at the center in the front-rear direction of the upper member (31). The upper member (31) is formed by simultaneously forming a hanging wall (31a), a groove (29), a tube insertion hole (34), and a through hole (35) by pressing an aluminum brazing sheet.

  The lower member (32) has a substantially w-shaped cross section that opens upward, and includes both front and rear walls (36) and (37) extending upward and outward in the front-rear direction, and the lower tank (3). A vertical intermediate wall (38) that divides the wall into two front and rear spaces, and two connecting walls (39) that connect the lower ends of both the front and rear walls (36) and (37) and the intermediate wall (38) together. Become. Each of the connecting walls (39) and the intermediate wall (38) are integrally connected via a curved portion that curves upward inward in the front-rear direction. The outer surface of the connecting wall (39) and the outer surface of the curved portion are the bottom surface (3c) of the lower tank (3), and the outer surfaces of the front and rear walls (36) and (37) are the front and rear side surfaces (3b) and the bottom surface (3c). It is a connecting part (3e). On the inner edge in the front-rear direction on the upper end surfaces of the front and rear walls (36) and (37), protruding ridges (36a) and (37a) respectively projecting upward are integrally formed over the entire length. The upper end of the intermediate wall (38) protrudes upward from the upper ends of both the front and rear walls (36) and (37), and protrudes upward at its upper edge and is fitted into the through hole (35) of the upper member (31). The plurality of protrusions (38a) to be formed are integrally formed at intervals in the left-right direction. Further, a coolant passage notch (38b) is formed from the upper edge of the intermediate wall (38) between adjacent projections (38a). The protrusion (38a) and the notch (38b) are formed by cutting a predetermined portion of the intermediate wall (38).

  The upper and lower members (31), (32) are caulked with the projections (38a) of the lower member (32) being inserted into the through holes (35), and the lower wall (31a) of the upper member (31). The protrusions (36a) (37a) of the member (32) are brazed to each other in an engaged state, and the front side of the intermediate wall (38) of the lower member (32) is the refrigerant inflow side header ( 41) Similarly, a portion on the rear side of the intermediate wall (38) is a refrigerant outflow side header (42). The refrigerant inflow side header (41) and the refrigerant outflow side header (42) communicate with each other by a notch (38b).

  Each cap (33) is formed from a bare material by pressing, forging or cutting, and a recess is formed on the inner surface in the left-right direction so that the left and right ends of the upper and lower members (31) (32) can be fitted. The upper and lower members (31) and (32) are brazed using a sheet-like brazing material.

  The heat exchange pipes (4) constituting the front and rear heat exchange pipe groups (5) are made of a bare material formed of an aluminum extruded profile, and are wide and flat in the front-rear direction, and extend in the length direction inside thereof. The refrigerant passages (4a) are formed in parallel. In addition, the front and rear end walls of the heat exchange pipe (4) have an arc shape protruding outward. The heat exchange pipe (4) of the front heat exchange pipe group (5) and the heat exchange pipe (4) of the rear heat exchange pipe group (5) are arranged to be at the same position in the left-right direction. Yes.

  Here, the tube height which is the thickness in the left-right direction of the heat exchange tube (4) is 0.75 to 1.5 mm, the tube width which is the width in the front-rear direction is 12 to 18 mm, and the wall thickness of the peripheral wall is 0.175 to 0.275 mm, the thickness of the partition wall partitioning the refrigerant passages (4a) is 0.175 to 0.275 mm, the pitch of the partition wall is 0.5 to 3.0 mm, and the curvature radius of the outer surfaces of the front and rear end walls is 0. It is preferable that it is 35-0.75 mm.

  As the heat exchange pipe (4), instead of the one made of an aluminum extruded shape, one in which a plurality of refrigerant passages are formed by inserting inner fins into an aluminum electric sewing pipe may be used. . Also, two flat wall forming parts formed by rolling an aluminum brazing sheet having a brazing filler metal layer on both sides and connected via connecting parts, and the opposite side of the connecting part in each flat wall forming part A side wall forming portion integrally formed in a protruding shape from the side edges of the flat wall forming portion, and a plurality of partition wall forming portions integrally formed in a protruding shape from the two flat wall forming portions at a predetermined interval in the width direction of the flat wall forming portion. It is also possible to use a plate having a partition wall formed by bending a plate with a hairpin shape at the connecting portion, butting the side wall forming portions with each other and brazing each other. In this case, a corrugated fin made of a bare material is used.

  The corrugated fin (6) is formed in a corrugated shape using an aluminum brazing sheet having a brazing filler metal layer on both sides, and a plurality of parallel portions in the front-rear direction are connected to a connecting portion that connects the wave head and the wave bottom. A louver (6a) is formed. The corrugated fin (6) is shared by both the front and rear heat exchange tube groups (5), and the width in the front and rear direction is the heat exchange tube (4) of the front heat exchange tube group (5) and the rear side heat exchange. The distance between the rear edge of the heat exchange pipe (4) of the pipe group (5) is substantially equal. Here, the linear distance between the wave head and the wave bottom which is the fin height of the corrugated fin (6) is 7.0 mm to 10.0 mm, and the pitch of the connecting portion which is also the fin pitch is 1.3 to 1.8 mm. It is preferable that

  The evaporator (1) is manufactured by temporarily fastening a combination of the constituent members and brazing all the constituent members together.

  The evaporator (1) constitutes a refrigeration cycle together with a compressor and a condenser, and is mounted on a vehicle such as an automobile as a car air conditioner.

  In the evaporator (1) described above, as shown in FIG. 9, the gas-liquid mixed phase two-layer refrigerant that has passed through the compressor, the condenser, and the decompression means is supplied to the refrigerant inlet (27a) and the right cap (12 ) Enters the refrigerant inlet side header (25) of the upper tank (2) through the refrigerant inlet (12a). This refrigerant is divided and flows into the refrigerant passages (4a) of the heat exchange pipes (4) of the front heat exchange pipe group (5) and flows downward in the refrigerant passages (4a) to lower tank (3). Into the refrigerant inflow side header (41). Next, the refrigerant passes through the notch (38b) and enters the refrigerant outflow side header (42) and is divided into the refrigerant passage (4a) of the heat exchange pipe (4) of the rear heat exchange pipe group (5). The refrigerant flows in the refrigerant passage (4a) upward and enters the portion below the drift prevention resistor plate (17) in the refrigerant outflow side header (26) of the upper tank (2). Next, the refrigerant passes through the refrigerant passage holes (18) and (18A) of the drift prevention resistor plate (17) and enters the portion above the drift prevention resistor plate (17) in the refrigerant outflow side header (26), The refrigerant flows out through the refrigerant outlet (12b) of the cap (12) and the refrigerant outlet (27b) of the refrigerant inlet / outlet member (27). The refrigerant passes through the refrigerant passage (4a) of the heat exchange pipe (4) of the front heat exchange pipe group (5) and the refrigerant passage (4a) of the heat exchange pipe (4) of the rear heat exchange pipe group (5). During the flow, the ventilation gap exchanges heat with the air flowing in the direction indicated by the arrow X in FIG. In the refrigerant flow described above, the heat exchange pipes (5) of the front heat exchange pipe group (5) from the refrigerant inflow side header (25) of the upper tank (2) by the action of the drift prevention resistor plate (17) ( The diversion to 4) and the diversion from the refrigerant outflow side header (42) of the lower tank (3) to the heat exchange pipe (4) of the rear heat exchange pipe group (5) are made uniform.

  At this time, condensed water is generated on the surface of the corrugated fin (6), and this condensed water flows down to the top surface (3a) of the lower tank (3). The condensed water flowing down to the top surface (3a) of the lower tank (3) enters the first part (29a) of the groove (29) by the capillary effect, flows in the groove (29), and flows into the third part (29c). Falls from below the bottom of the lower tank (3). In this way, freezing of condensed water caused by accumulation of a large amount of condensed water between the top surface (3a) of the lower tank (3) and the lower end of the corrugated fin (6) is prevented, and as a result, the evaporator (1) Performance degradation is prevented.

  In the first embodiment, the bottom surface of each groove (29) is a flat surface. However, the present invention is not limited to this. In the cross section of each groove (29), the shape of the bottom surface is the bottom of the groove (29). It may be a circular arc surface that is recessed toward the center. In this case, the radius of curvature of the bottom surface of the groove (29) is preferably ½ of the groove bottom width. In this case, the depth of the groove (29) is the depth at the center of the groove bottom.

  Moreover, in the said 1st Embodiment, although each groove | channel (29) consists of 1st-3rd part (29a)-(29c), it is not restricted to this, The 2nd part (29b) is provided. The first portion (29a) may extend to the connecting portion (3d) between the top surface (3a) and the front and rear side surfaces (3b), and the third portion (29c) may be formed continuously to the tip. . That is, in the longitudinal section of each groove (29), the bottom surface has an arc shape that curves downward from the highest part (28) side of the top surface (3a) of the lower tank (3) downward in the front-rear direction. A third portion (29c) formed on both front and rear side surfaces (3b) of the lower tank (3) and having a vertical bottom surface may be provided directly to the tip of the first portion (29a). .

  FIG. 10 shows a second embodiment of the present invention.

  In the embodiment shown in FIG. 10, the top surface (3a) of the lower tank (3) is formed to be a horizontal flat surface. And it extends from the front-rear direction center of the top surface (3a) to the front and rear side surfaces (3b) on both front and rear sides of the lower tank (3), and the first portion (29a), second portion (29b) and A plurality of grooves (29) made of the third portion (29c) are formed at intervals in the left-right direction. Since the top surface (3a) of the lower tank (3) is a horizontal flat surface, the shape of the upper member (31) is also different from that of the first embodiment. Other configurations are the same as those of the first embodiment.

  FIG. 11 shows a third embodiment of the present invention.

  In the case of the embodiment shown in FIG. 11, the first portion (29a) present on the top surface (3a) of the lower tank (3) in each groove (29) is the highest portion (28) side of the top surface (3a). It gradually becomes deeper toward the front and rear side edges. Therefore, the length of the second portion (29b) existing at the connecting portion between the top surface (3a) of the lower tank (3) and the front and rear side surfaces (3b) is shortened. Other configurations are the same as those of the first embodiment.

  FIG. 12 shows a fourth embodiment of the present invention.

  In FIG. 12, a plurality of grooves (50) are formed in the connecting portion (3d) between the top surface (3a) of the lower tank (3) and the front and rear side surfaces (3b) at intervals in the left-right direction. The bottom surface of the groove (50) is inclined downward toward the outer side in the front-rear direction. That is, a groove (50) similar to the second portion (29b) of the first embodiment is formed in the connecting portion (3d) between the top surface (3a) of the lower tank (3) and the front and rear side surfaces (3b). Has been. Other configurations are the same as those of the first embodiment.

  FIG. 13 shows a fifth embodiment of the present invention.

  In FIG. 13, a plurality of grooves (51) extending in the vertical direction are formed at intervals in the horizontal direction on both front and rear side surfaces (3b) of the lower tank (3). The bottom surface of the groove (51) is vertical. That is, grooves (51) similar to those of the third portion (29c) of the first embodiment are formed on the front and rear side surfaces (3b) of the lower tank (3). The width and depth of the groove (51) are the same as those of the third portion (29c) of the first embodiment. Other configurations are the same as those of the first embodiment. The groove (51) may be formed at the same position as the heat exchange tube (4) in the left-right direction.

  FIG. 14 shows a sixth embodiment of the present invention.

  In FIG. 14, a plurality of grooves (52) are spaced in the left-right direction from the connecting portion (3d) between the top surface (3a) of the lower tank (3) and the front and rear side surfaces (3b) to the front and rear side surfaces (3b). Is formed. The bottom surface of the portion existing in the connecting portion (3d) between the top surface (3a) of the lower tank (3) and the front and rear side surfaces (3b) in the groove (52) is inclined downward toward the outer side in the front-rear direction. . Further, the bottom surfaces of the portions existing on the front and rear side surfaces (3b) of the lower tank (3) in the groove (52) are vertical. That is, a groove (52) similar to that formed by the second portion (29b) and the third portion (29c) of the groove (29) of the first embodiment is formed. Other configurations are the same as those of the first embodiment.

  In the first to sixth embodiments, one heat exchange tube group (5) is provided between the front and rear side portions of the upper and lower tanks (2) and (3). One or two or more heat exchange pipe groups (5) may be provided between the front and rear side portions of the tanks (2) and (3). In the first and third to sixth embodiments, the highest position (28) is located in the center of the lower tank (3) in the front-rear direction, but the present invention is not limited to this. It may be in a position off the central part in the front-rear direction of (3). Also in this case, one or two or more heat exchange tube groups may be provided on both the front and rear sides of the highest portion.

  Further, in the first to third, fifth, and sixth embodiments, grooves continuous with the grooves are formed on the outer surfaces of the front and rear walls (36) and (37) of the lower member (32) of the lower tank (3). May be.

It is a perspective view which shows the whole structure of the evaporator by this invention. It is a partially omitted vertical cross-sectional view as seen from the rear. It is an expanded sectional view which follows the AA line of FIG. It is a disassembled perspective view of an upper tank. FIG. 4 is a cross-sectional end view taken along line BB in FIG. 3. It is sectional drawing which follows the CC line of FIG. It is sectional drawing which abbreviate | omitted one part along the DD line | wire of FIG. It is a disassembled perspective view of a lower tank. It is a figure which shows how the refrigerant | coolant flows in the evaporator of FIG. It is sectional drawing equivalent to a part of FIG. 3 which shows 2nd Embodiment of the evaporator by this invention. It is sectional drawing equivalent to a part of FIG. 3 which shows 3rd Embodiment of the evaporator by this invention. It is sectional drawing equivalent to a part of FIG. 3 which shows 4th Embodiment of the evaporator by this invention. It is sectional drawing equivalent to a part of FIG. 3 which shows 5th Embodiment of the evaporator by this invention. It is sectional drawing equivalent to a part of FIG. 3 which shows 6th Embodiment of the evaporator by this invention.

Explanation of symbols

(1): Evaporator
(2): Upper tank
(3): Lower tank
(3a): Top surface
(3b): Front and rear sides
(3c): Bottom
(3d): Connection between the top surface and both front and rear sides
(4): Heat exchange pipe
(5): Heat exchange tube group
(6): Corrugated fin
(28): Highest part
(29): Groove
(29a): 1st part
(29b): Second part
(29c): Third part
(50) (51) (52): Groove

Claims (46)

A heat exchange core unit configured by arranging a plurality of rows of heat exchange tubes arranged in parallel in the front-rear direction and a plurality of heat exchange tube groups arranged in parallel in the left-right direction, and a heat exchange core unit In an evaporator provided with a lower tank, which is disposed on the lower end side of the heat exchanger tube and to which a lower end portion of a heat exchange tube constituting each heat exchange tube group is connected,
The lower tank has a top surface, both front and rear side surfaces, and a bottom surface. In the portion between the heat exchange pipes adjacent in the left and right direction in the front and rear side portions of the lower tank, the front and rear side surfaces from the middle portion in the front and rear direction, respectively. The evaporator is formed with a groove that extends in the direction of flowing condensed water. The evaporator according to claim 1, wherein each groove has a capillary effect for sucking condensed water on the surface of the lower tank. The evaporator according to claim 1 or 2, wherein the bottom surface of the first portion existing on the lower tank top surface of each groove is gradually lowered from the front-rear direction intermediate portion of the lower tank top surface toward the front and rear side edges. The top surface of the lower tank is formed so that the middle part in the front-rear direction is the highest part and gradually decreases from the highest part toward the front and rear sides, and each groove is the highest part on the top surface of the lower tank The evaporator according to any one of claims 1 to 3, wherein the evaporator is formed from both front and rear side portions to front and rear side surfaces of the lower tank. The evaporator according to claim 4, wherein the depth of the first portion existing on the top surface of the lower tank of each groove is equal over the entire length thereof. The evaporator according to claim 4, wherein the depth of the first portion existing on the top surface of the lower tank of each groove gradually increases from the highest portion side of the top surface toward both front and rear sides. The evaporator according to any one of claims 4 to 6, wherein the depth of the first portion existing on the top surface of the lower tank of each groove is 0.5 to 2.0 mm. The evaporator according to any one of claims 4 to 7, wherein the groove width of the first portion existing on the top surface of the lower tank of each groove gradually increases from the groove bottom toward the opening. The evaporator according to claim 8, wherein a ratio L1 / L2 between the groove bottom width L1 of the first portion of each groove and the opening width L2 is 0.067 to 0.33. The evaporator in any one of Claims 1-3 currently formed so that the top surface of a lower tank may become a horizontal flat surface shape. The evaporator according to claim 10, wherein the groove width of the first portion existing on the top surface of the lower tank in each groove gradually increases from the groove bottom toward the opening. The evaporator according to claim 1, wherein the bottom surface of each groove is a flat surface. The evaporator according to any one of claims 1 to 11, wherein a shape of a bottom surface of each groove is an arc shape recessed toward a center portion in the width direction of the groove bottom in a cross section of each groove. The evaporator according to claim 13, wherein the radius of curvature of the bottom surface of each groove is ½ of the groove bottom width. The ratio W2 / W1 between the linear distance W2 between the front and rear ends of the first portion existing on the top surface of the lower tank in each groove and the full width W1 in the front-rear direction of the lower tank is 0.16 to 0.47. The evaporator in any one of 1-14. The bottom surface of the 2nd part which exists in the connection part of the top surface of the lower tank in each groove | channel and both front-and-back both sides inclines below toward the front-back direction outer side. The evaporator. The evaporator according to claim 16, wherein an inclination angle of the bottom surface of the second portion of each groove with respect to a vertical plane is 20 to 50 degrees. In the longitudinal section of each groove, the shape of the bottom surface of the first portion existing on the top surface of the lower tank of each groove is an arc shape that curves downward from the highest portion side of the top surface of the lower tank toward the outside in the front-rear direction. The evaporator according to claim 16 or 17, wherein an inclination angle with respect to a vertical plane of a straight line connecting front and rear ends of the bottom surface of the first portion is smaller than an inclination angle with respect to the vertical surface on the bottom surface of the second portion. The evaporator according to any one of claims 1 to 18, wherein a bottom surface of a third portion existing on both front and rear side surfaces of the lower tank in each groove is vertical. The evaporator according to any one of claims 1 to 19, wherein the depth of the third portion existing on both front and rear side surfaces of the lower tank in each groove is 0.3 to 0.8 mm. The evaporator according to claim 19 or 20, wherein the width of the third portion of each groove is the same from the groove bottom to the opening. The evaporator according to claim 21, wherein the width of the third portion of each groove is 0.5 to 1.5 mm. A heat exchange core unit configured by arranging a plurality of rows of heat exchange tubes arranged in parallel in the front-rear direction and a plurality of heat exchange tube groups arranged in parallel in the left-right direction, and a heat exchange core unit In an evaporator provided with a lower tank, which is disposed on the lower end side of the heat exchange pipe and is connected to the lower end of the heat exchange pipe constituting each heat exchange pipe group,
The lower tank has a top surface, both front and rear side surfaces, and a bottom surface, and the top surface of the lower tank gradually decreases from the highest portion toward the front and rear sides while the middle portion in the front and rear direction is the highest portion. The evaporator is formed as described above, and a groove through which condensed water flows is formed in the connecting portion between the top surface of the lower tank and both front and rear side surfaces. 24. The evaporator according to claim 23, wherein each groove has a capillary effect for sucking condensed water on the surface of the lower tank. The evaporator according to claim 23 or 24, wherein the bottom surface of each groove is inclined downward toward the outside in the front-rear direction. The evaporator according to claim 25, wherein an inclination angle of the bottom surface of each groove with respect to a vertical surface is 20 to 50 degrees. 27. The evaporator according to claim 23, wherein the width of each groove gradually increases from the groove bottom toward the opening. 28. The evaporator according to claim 27, wherein a ratio L1 / L2 between the groove bottom width L1 and the opening width L2 of each groove is 0.067 to 0.33. The evaporator according to any one of claims 23 to 28, wherein the depth of each groove is 0.5 to 2.0 mm. The evaporator according to any one of claims 23 to 29, wherein a bottom surface of each groove is a flat surface. The evaporator according to any one of claims 23 to 29, wherein a shape of a bottom surface of each groove is an arc shape recessed toward a center portion in a width direction of the groove bottom in a cross section of each groove. 32. The evaporator according to claim 31, wherein the curvature radius of the bottom surface of each groove is ½ of the groove bottom width. A heat exchange core part having a plurality of heat exchange pipes arranged at intervals in the left-right direction; and a lower tank arranged on the lower end side of the heat exchange core part and connected to the lower end part of the heat exchange pipe In the evaporator
The lower tank has a top surface, front and rear side surfaces, and a bottom surface, and at least one of the front and rear side surfaces of the lower tank has a plurality of grooves extending vertically and allowing condensed water to flow in the left-right direction. The evaporator is formed. 34. The evaporator according to claim 33, wherein grooves are formed on both front and rear side surfaces of the lower tank. 35. The evaporator according to claim 33 or 34, wherein at least a portion near the front and rear side edges of the entire top surface of the lower tank is provided with a portion that is lowered downward in the front-rear direction. 36. The top surface of the lower tank is formed such that an intermediate portion in the front-rear direction is the highest portion and is gradually lowered from the highest portion toward the front and rear sides. The described evaporator. 37. The evaporator according to any one of claims 33 to 36, wherein each groove has a capillary effect for sucking condensed water on the surface of the lower tank. The evaporator according to any one of claims 33 to 37, wherein a bottom surface of each groove is vertical. The evaporator according to any one of claims 33 to 38, wherein the depth of each groove is 0.3 to 0.8 mm. The evaporator according to any one of claims 33 to 39, wherein the width of each groove is the same from the groove bottom to the opening. 41. The evaporator according to claim 40, wherein the width of each groove is 0.5 to 1.5 mm. The evaporator according to any one of claims 33 to 41, wherein a bottom surface of each groove is a flat surface. The evaporator according to any one of claims 33 to 41, wherein in the cross section of each groove, the shape of the bottom surface of each groove is an arc shape recessed toward the center portion in the width direction of the groove bottom. 44. The evaporator according to claim 43, wherein the radius of curvature of the bottom surface of each groove is ½ of the groove bottom width. 45. A refrigeration cycle comprising a compressor, a condenser, and an evaporator, wherein the evaporator comprises the evaporator according to any one of claims 1 to 44. The vehicle in which the refrigeration cycle according to claim 45 is mounted as an air conditioner.

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