JP7001917B2 - Heat exchanger with heat transfer tube unit - Google Patents

Description

The present invention relates to a heat exchanger having a heat transfer tube unit.

Some heat exchangers used in air conditioners and the like have a heat transfer tube for flowing a refrigerant and a heat transfer tube unit in which fins for heat exchange are formed as an integral member. The heat exchanger disclosed in Patent Document 1 (Japanese Unexamined Patent Publication No. 2006-105489) has a plurality of such heat transfer tube units. Multiple heat transfer tube units are connected to a common header.

In order to improve the heat transfer performance between the air and the refrigerant, in a heat exchanger, a plurality of heat transfer tube units are usually arranged at a narrow interval. When the air flow passes through the gap of such a heat transfer tube unit, the air flow receives resistance, so that the amount of air passing is reduced, and as a result, the heat transfer performance may not be improved as intended. On the other hand, if the heat transfer tube units are arranged at wide intervals, a part of the air flow passes through the heat exchanger without contacting the heat transfer unit, so that the heat transfer performance is not improved.

An object of the present invention is to improve the heat transfer performance of the heat exchanger.

The heat exchanger according to the first aspect of the present invention includes a plurality of heat transfer tube units having a plurality of fins and a plurality of heat transfer tubes. The plurality of heat transfer tube units are arranged at intervals in the heat transfer tube unit arrangement direction. In each heat transfer tube unit, the plurality of heat transfer tubes extend in the heat transfer tube extension direction perpendicular to the heat transfer tube unit arrangement direction. In each heat transfer tube unit, the fins and the heat transfer tubes are alternately arranged in the heat transfer tube unit arrangement direction and the heat transfer tube separation direction perpendicular to the heat transfer tube extension direction. The plurality of fins of each heat transfer tube unit have a first inclined portion that is inclined by a positive acute angle with respect to the heat transfer tube separation direction, and a second inclined portion that is inclined by a negative acute angle with respect to the heat transfer tube separation direction, respectively. Including at least one of.

According to this configuration, the airflow flowing along the heat transfer tube unit meanders according to the change in the inclination of the fins. As a result, the probability that the air flow will come into contact with the fins increases. Therefore, the heat transfer performance of the heat exchanger is improved.

In the heat exchanger according to the second aspect of the present invention, in the heat exchanger according to the first aspect, a plurality of heat transfer tube units have at least one of a first heat transfer tube unit and a second heat transfer tube unit. The plurality of fins of the first heat transfer tube unit are either a first fin having only a first inclined portion and a second fin having only a second inclined portion, respectively. The plurality of fins of the second heat transfer tube unit includes a third fin having both a first inclined portion and a second inclined portion.

According to this configuration, a specific embodiment in which a plurality of fins form a meandering shape is presented. Since the heat transfer tube is located at the apex of the meandering of the first heat transfer tube unit, it is easy to confirm the shape. Since the heat transfer tube is not located at the apex of the meandering of the second heat transfer tube unit, the space occupied by the second heat transfer tube unit is small.

In the heat exchanger according to the third aspect of the present invention, in the heat exchanger according to the second aspect, a plurality of heat transfer tube units have both a first heat transfer tube unit and a second heat transfer tube unit.

According to this configuration, the heat exchanger has two types of heat transfer tube units. Therefore, by appropriately arranging the two types of heat transfer tube units, it is possible to improve the heat transfer performance while reducing the air resistance.

The heat exchanger according to the fourth aspect of the present invention is the heat exchanger according to the third aspect, and the heat transfer tube belonging to the first heat transfer tube unit is the second heat transfer tube unit from the viewpoint of facing the heat transfer tube unit arrangement direction. It is located between adjacent heat transfer tubes to which it belongs.

According to this configuration, the heat transfer tubes belonging to the respective heat transfer tube units are not close to each other at the positions where the first heat transfer tube unit and the second heat transfer tube unit are adjacent to each other. Therefore, air resistance due to the proximity of the heat transfer tube is unlikely to occur at that location.

In the heat exchanger according to the fifth aspect of the present invention, in the heat exchanger according to the third aspect or the fourth aspect, the first heat transfer tube unit and the second heat transfer tube unit are alternately arranged in the heat transfer tube unit arrangement direction. ing.

According to this configuration, since the first heat transfer tube unit and the second heat transfer tube unit are alternately arranged, the heat transfer tubes belonging to the adjacent heat transfer tube units are not close to each other. Therefore, air resistance due to the proximity of the heat transfer tube is less likely to occur.

In the heat exchanger according to the sixth aspect of the present invention, in the heat exchanger according to any one of the second to fifth aspects, a plurality of fins of the first heat transfer tube unit are alternately arranged in the heat transfer tube separation direction. The first fin and the second fin are arranged.

According to this configuration, the inclinations of the fins of the first heat transfer tube unit are alternately reversed. Therefore, a meandering shape with a small pitch can be formed.

The heat exchanger according to the seventh aspect of the present invention is the heat exchanger according to any one of the second to fifth aspects, in which a plurality of fins of the first heat transfer tube unit have two fins in the heat transfer tube separating direction. The first fin and the second fin are arranged alternately one by one.

According to this configuration, the inclination of the fins of the first heat transfer tube unit is reversed every other one or more. Therefore, a meandering shape with a large pitch can be formed.

In the heat exchanger according to the eighth aspect of the present invention, in the heat exchanger according to any one of the second to sixth aspects, the plurality of fins of the second heat transfer tube unit are alternately different in the protruding direction. It is a third fin arranged in the heat transfer tube separation direction.

According to this configuration, the inclinations of the fins of the second heat transfer tube unit are alternately reversed. Therefore, a meandering shape with a small pitch can be formed.

The heat exchanger according to the ninth aspect of the present invention is the second heat transfer tube unit in the heat exchanger according to any one of the second aspect, the third aspect, the fourth aspect, the fifth aspect and the seventh aspect. The plurality of fins include the first fin, the second fin, and the third fin, and at least one first fin or second fin is arranged between the two third fins.

According to this configuration, the inclination of the fins of the second heat transfer tube unit is reversed every other one or more. Therefore, a meandering shape with a large pitch can be formed.

The heat exchanger according to the tenth aspect of the present invention is the heat exchanger according to any one of the first aspect to the ninth aspect, and the plurality of fins are curved surfaces.

According to this configuration, the fins having a plurality of curved surfaces form a smooth meandering shape and guide the air flow smoothly. Therefore, the air resistance can be further reduced.

According to the heat exchanger according to the first aspect and the second aspect of the present invention, the heat transfer performance of the heat exchanger is improved.

According to the heat exchanger according to the third aspect, the fourth aspect, the fifth aspect, and the tenth aspect of the present invention, the air resistance is lowered while improving the heat transfer performance.

The heat exchanger according to the sixth, seventh, eighth, and ninth aspects of the present invention provides variations in the meandering pitch of the fins of the heat transfer tube unit, and it is possible to select one suitable for the application. can.

It is a schematic diagram which shows the outer shape of a heat exchanger 10. It is a schematic diagram which shows the outer shape of a heat transfer tube unit 30. It is a schematic diagram of the heat transfer tube unit group 35A of the heat exchanger 10 which concerns on 1st Embodiment. It is a schematic diagram of the heat transfer tube unit group 35A'of the heat exchanger 10 which concerns on the modification 1A of 1st Embodiment. It is a schematic diagram which shows the outer shape of the heat exchanger 10 which concerns on modification 1B of 1st Embodiment. It is a schematic diagram which shows the outer shape of the heat transfer tube unit 30 of the heat exchanger 10 which concerns on modification 1B of 1st Embodiment. It is a schematic diagram of the heat transfer tube unit group 35B of the heat exchanger 10 which concerns on 2nd Embodiment. It is a schematic diagram of the heat transfer tube unit group 35C of the heat exchanger 10 which concerns on 3rd Embodiment. It is a schematic diagram of the heat transfer tube unit group 35D of the heat exchanger 10 which concerns on 4th Embodiment. It is a schematic diagram of the heat transfer tube unit group 35E of the heat exchanger 10 which concerns on 5th Embodiment. It is a schematic diagram of the heat transfer tube unit group 35F of the heat exchanger 10 which concerns on 6th Embodiment. It is a figure which shows the flat tube for heat exchange.

<First Embodiment>
(1) Overall Configuration FIG. 1 shows the heat exchanger 10 according to the first embodiment of the present invention. The heat exchanger 10 is used, for example, in an air conditioner or the like, and is for exchanging heat between a refrigerant and air. The heat exchanger 10 has a first pipe 41, a second pipe 42, a first header 21, a second header 22, and a heat transfer tube unit group 35. The heat transfer tube unit group 35 includes a plurality of heat transfer tube units 30.

(2) Configuration of each part (2-1) Header and piping The first piping 41 and the second piping 42 are for passing the refrigerant. Both the first pipe 41 and the second pipe 42 can function as an inlet and an outlet for a refrigerant that can take various states such as gas, liquid, and gas-liquid two-phase. The first pipe 41 is connected to the first header 21 so that the refrigerant can be exchanged with the first header 21. The second pipe 42 is connected to the second header 22 so that the refrigerant can be exchanged with the second header 22. Both the first header 21 and the second header 22 have a heat transfer tube unit connecting surface 23. The first header 21 and the second header 22 are arranged so that the heat transfer tube unit connecting surfaces 23 face each other or substantially face each other.

(2-2) Heat Transfer Tube Unit Group The plurality of heat transfer tube units 30 constituting the heat transfer tube unit group 35 are arranged at intervals in the heat transfer tube unit arrangement direction x. Each heat transfer tube unit 30 is connected to the first header 21 and the second header on the respective heat transfer tube unit connection surface 23. The heat transfer tube unit 30 is integrally composed of, for example, aluminum or an aluminum alloy.

FIG. 2 shows one heat transfer tube unit 30. The heat transfer tube unit 30 has a plurality of heat transfer tubes 31 and a plurality of fins 32. The number of heat transfer tubes 31 provided in the heat transfer tube unit 30 is, for example, 6 or more, but the number is not limited to this.

The heat transfer tube 31 is for moving the refrigerant between the first header 21 and the second header 22. Both ends of each heat transfer tube 31 are connected to the heat transfer tube unit connection surface 23 of the first header 21 and the second header 22. Each heat transfer tube 31 has at least a portion extending in the heat transfer tube extension direction z, and is preferably linear. The plurality of heat transfer tubes 31 are generally arranged in the heat transfer tube separation direction y, ignoring the offset in the heat transfer tube unit arrangement direction x. The inner diameter of each heat transfer tube 31 is, for example, 1.5 mm or less, preferably 0.8 mm or less.

The fin 32 is for exchanging heat between the refrigerant flowing through the adjacent heat transfer tube 31 and the surrounding air. Each fin 32 is arranged between two adjacent heat transfer tubes 31. Further fins 32 may be arranged on the outer side of the outermost heat transfer tube 31 of the heat transfer tube unit 30. The fins 32 and the heat transfer tube 31 are generally arranged alternately in the heat transfer tube separation direction y, ignoring the offset portion in the heat transfer tube unit arrangement direction x. The air is configured to flow in a direction parallel to the yz plane by a fan (not shown) or the like. The direction of the air flow may coincide with the heat transfer tube separation direction y.

The heat transfer tube unit arrangement direction x, the heat transfer tube separation direction y, and the heat transfer tube extension direction z intersect each other. For example, the heat transfer tube unit arrangement direction x, the heat transfer tube separation direction y, and the heat transfer tube extension direction z are perpendicular to each other. The heat transfer tube unit arrangement direction x and the heat transfer tube separation direction y may be horizontal, and the heat transfer tube extension direction z may be vertical.

(3) Detailed Configuration of Heat Transfer Tube Unit 30 FIG. 3 is a schematic view of the heat transfer tube unit group 35A of the heat exchanger 10 according to the first embodiment of the present invention. Among the plurality of fins 32, a first inclined portion S1 that is inclined by a positive acute angle with respect to the heat transfer tube separation direction y and a second inclined portion S1 that is inclined by a negative acute angle with respect to the heat transfer tube separation direction y. There is an acute angle portion S2. In this embodiment, all fins 32 are configured as flat surfaces. The absolute values of positive and negative acute angles are set, for example, substantially equal.

The plurality of heat transfer tube units 30 constituting the heat transfer tube unit group 35A are all first heat transfer tube units 30A. Here, the first heat transfer tube unit 30A is either the first fin 32A in which the plurality of fins 32 have only the first inclined portion S1 or the second fin 32B having only the second inclined portion S2. It means something.

In the first embodiment, the plurality of fins 32 included in the first heat transfer tube unit 30A are generally arranged alternately in the heat transfer tube separation direction y and the first fins 32A, ignoring the offset of the heat transfer tube unit arrangement direction x. The second fin 32B.

(4) Features (4-1)
The air flow flowing along the heat transfer tube unit 30 meanders according to the change in the inclination of the fin 32. As a result, the probability that the air flow will come into contact with the fin 32 increases. Therefore, the heat transfer performance of the heat exchanger 10 is improved.

(4-2)
Since the heat transfer tube 31 is located at the apex of the meandering of the first heat transfer tube unit 30A, it is easy to confirm the shape, for example, in the manufacturing process.

(4-3)
The inclinations of the fins 32 of the first heat transfer tube unit 30A are alternately reversed. Therefore, since a meandering shape with a small pitch can be formed, the contact frequency between the air flow and the fin 32 is increased, which contributes to the improvement of heat transfer performance.

(5) Modification Example A modification of the present embodiment will be described below. A plurality of modification examples may be combined.

(5-1) Modification 1A
FIG. 4 is a schematic view of the heat transfer tube unit group 35A'of the heat exchanger 10 according to the modified example 1A of the first embodiment of the present invention. Unlike the heat transfer tube unit group 35 according to the first embodiment, in the first heat transfer tube unit 30A of the heat transfer tube unit group 35A'according to the modified example 1A, all the fins 32 are configured as curved surfaces. Due to this curved surface, the first heat transfer tube unit 30A as a whole has a cross section in the shape of, for example, a sinusoidal wave.

According to this configuration, the fins having a plurality of curved surfaces form a smooth meandering shape and guide the air flow smoothly. Therefore, the air resistance can be further reduced.

(5-2) Modification 1B
FIG. 5 is a heat exchanger 10 according to a modification 1B of the first embodiment of the present invention. In this heat exchanger 10, the first header 21 and the second header 22 are arranged on the same side with respect to the heat transfer tube unit group 35A''. The first header 21 and the second header 22 are connected to the first pipe 41 and the second pipe 42, respectively.

FIG. 6 shows one of a plurality of heat transfer tube units 30 constituting the heat transfer tube unit group 35A ″ of the heat exchanger 10. The heat transfer tube unit 30 has a plurality of heat transfer tubes 31 and a plurality of fins 32. Each heat transfer tube 31 has at least a portion extending in the heat transfer tube extension direction z, and is preferably linear. The plurality of heat transfer tubes 31 are arranged in the heat transfer tube separation direction y. Further, the adjacent heat transfer tubes 31 are connected by a curved connecting tube 31c. That is, the heat transfer tube unit 30 has one refrigerant path composed of the heat transfer tube 31 and the connecting tube 31c. This refrigerant path moves the refrigerant between the first header 21 and the second header 22. The end of the heat transfer tube 31 is connected to the heat transfer tube unit connection surface 23 of either the first header 21 or the second header 22.

The heat transfer tube unit 30 has fins 32 between adjacent heat transfer tubes 31. Further fins 32 may be arranged on the outer side of the outermost heat transfer tube 31 of the heat transfer tube unit 30. A plurality of fins 32 may be connected at the upper end or the lower end of the heat transfer tube unit 30. The fin 32 has a side extending in the heat transfer tube extension direction z, and is joined to the heat transfer tube 31 at that side. The fins 32 and the heat transfer tubes 31 are alternately arranged in the heat transfer tube separation direction y. The direction of the air flow is set to be at least parallel to the yz plane and preferably to coincide with the heat transfer tube separation direction y. The heat transfer tube unit 30 may be manufactured by a method other than extrusion molding of a metal material.

According to this configuration, since three of the four sides of the heat transfer tube unit 30 are open to the surrounding space, the condensed water is more easily discharged.

(5-3) Modification 1C
In the above-described embodiment, as an example of the arrangement, the configuration in which the heat transfer tube unit arrangement direction x and the heat transfer tube separation direction y are horizontal directions and the heat transfer tube extension direction z is the vertical direction is referred to. Instead of this, the heat exchanger 10 may be arranged in another direction. For example, the heat transfer tube separation direction y and the heat transfer tube extension direction z may be horizontal, and the heat transfer tube unit arrangement direction x may be vertical.

<Second Embodiment>
(1) Configuration FIG. 7 is a schematic diagram of a heat transfer tube unit group 35B of the heat exchanger 10 according to the second embodiment of the present invention.

Similar to the heat transfer tube unit group 35A according to the first embodiment, the plurality of heat transfer tube units 30 constituting the heat transfer tube unit group 35B according to the second embodiment are all the first heat transfer tube units 30A. As described in the first embodiment, the plurality of fins 32 included in the first heat transfer tube unit 30A each have a first fin 32A having only the first inclined portion S1 and a second having only the second inclined portion S2. One of the fins 32B. The plurality of fins 32 included in the first heat transfer tube unit 30A are generally arranged alternately in the heat transfer tube separation direction y, ignoring the offset in the heat transfer tube unit arrangement direction x.

However, unlike the heat transfer tube unit group 35A according to the first embodiment, in the heat transfer tube unit group 35B according to the second embodiment, the first fin 32A and the second fin 32B included in the first heat transfer tube unit 30A are two. They are arranged alternately one by one.

Also in this embodiment, all the fins 32 are configured as a flat surface. Other elements not mentioned are the same as those in the first embodiment.

(2) Features Since the inclination of the fins 32 of the first heat transfer tube unit 30A is inverted every other one or more, a meandering shape with a large pitch is formed. As a result, the resistance of the air flow is reduced, and the distance between the adjacent first heat transfer tube units 30A may be designed to be small according to the reduced amount. As a result, the heat transfer performance may be improved.

(3) Modification Example (3-1) Number of Fins Arranged Alternately The first fins 32A and the second fins 32B arranged alternately in the heat transfer tube separation direction y are not limited to two each. For example, the first fins 32A and the second fins 32B may be arranged alternately by three or more sheets.

According to this configuration, the spatial length of the meandering cycle of the heat transfer tube unit 30 can be increased. Therefore, the air flow is less susceptible to resistance.

(3-2) Other Modifications of the first embodiment may be applied to the second embodiment.

<Third Embodiment>
(1) Configuration FIG. 8 is a schematic diagram of a heat transfer tube unit group 35C of the heat exchanger 10 according to the third embodiment of the present invention. Similar to the heat transfer tube unit group 35A according to the first embodiment, in the heat transfer tube unit group 35C according to the third embodiment, only a positive acute angle with respect to the heat transfer tube separation direction y is included in the plurality of fins 32. There is a first inclined portion S1 that is inclined and a second inclined portion S2 that is inclined by a negative acute angle with respect to the heat transfer tube separation direction y. Also in this embodiment, all the fins 32 are configured as a flat surface.

Unlike the heat transfer tube unit group 35A according to the first embodiment, the plurality of heat transfer tube units 30 constituting the heat transfer tube unit group 35C according to the third embodiment are all the second heat transfer tube units 30B. Here, the second heat transfer tube unit 30B means that the third fin 32C having both the first inclined portion S1 and the second inclined portion S2 is included in the plurality of fins 32. In the present embodiment, the plurality of fins 32 included in the second heat transfer tube unit 30B are all the third fins 32C.

In the third embodiment, the plurality of fins 32 included in the second heat transfer tube unit 30B are generally arranged in the heat transfer tube separation direction y, ignoring the offset in the heat transfer tube unit arrangement direction x. The boundary between the first inclined portion S1 and the second inclined portion S2 in each fin 32 projects in either the positive direction or the negative direction of the heat transfer tube unit arrangement direction x. The plurality of fins 32, which are generally arranged in the heat transfer tube separation direction y, have different projecting directions alternately.

Other elements not mentioned are the same as those in the first embodiment.

(2) Features (2-1)
The fins 32 of the second heat transfer tube unit 30B are all the third fins 32C, and the protruding directions of the third fins 32C are alternately reversed. Therefore, since a meandering shape with a small pitch can be formed, the contact frequency between the air flow and the fin 32 is increased, which contributes to the improvement of heat transfer performance.

(2-2)
Since the heat transfer tube 31 is not located at the apex of the meandering of the second heat transfer tube unit 30B, the space occupied by the second heat transfer tube unit 30B is small. Therefore, the resistance of the air flow can be reduced, which may improve the heat transfer performance.

(3) Modified Example A modified example of the previous embodiment may be applied to the third embodiment.

<Fourth Embodiment>
(1) Configuration Figure 9 is a schematic diagram of the heat transfer tube unit group 35D of the heat exchanger 10 according to the fourth embodiment of the present invention.

Similar to the heat transfer tube unit group 35C according to the third embodiment, the plurality of heat transfer tube units 30 constituting the heat transfer tube unit group 35D according to the fourth embodiment are all the second heat transfer tube units 30B. As described in the third embodiment, the second heat transfer tube unit 30B includes a third fin 32C having both a first inclined portion S1 and a second inclined portion S2 in a plurality of fins 32. To say. However, unlike the third embodiment, the plurality of fins 32 of the second heat transfer tube unit 30B adopted in the fourth embodiment are not only the third fin 32C but also the first fin 32A described in the first embodiment. And the second fin 32B is also included.

The plurality of fins 32 included in the second heat transfer tube unit 30B according to the fourth embodiment are generally arranged alternately in the heat transfer tube separation direction y, ignoring the offset in the heat transfer tube unit arrangement direction x. The plurality of fins 32 include a plurality of third fins 32C arranged so that the protruding directions are alternately different. Further, the first fin 32A and the second fin 32B are alternately arranged at a plurality of locations sandwiched between the adjacent third fins.

Also in this embodiment, all the fins 32 are configured as a flat surface. Other elements not mentioned are the same as those in the first embodiment.

(2) Features According to this configuration, the inclination of the fins 32 of the second heat transfer tube unit 30B is inverted every other one or more. Therefore, since a meandering shape with a large pitch can be formed, the resistance of the air flow can be reduced, which may improve the heat transfer performance.

(3) Modification example (3-1) Number of fins arranged alternately The number of first fins 32A and second fins 32B alternately arranged at a plurality of locations sandwiched between adjacent third fins 32C is limited to one. I can't. For example, two or more first fins 32A and second fins 32B may be arranged alternately.

According to this configuration, the pitch of the meandering shape of the heat transfer tube unit 30 can be increased, so that the air flow is less likely to receive resistance. Therefore, as in the second embodiment, the heat transfer performance may be improved.

(3-2) Others Modifications of the previous embodiments may be applied to the fourth embodiment.

<Fifth Embodiment>
(1) Configuration FIG. 10 is a schematic diagram of a heat transfer tube unit group 35E of the heat exchanger 10 according to the fifth embodiment of the present invention. Similar to the heat transfer tube unit group 35A according to the first embodiment, in the heat transfer tube unit group 35E according to the fifth embodiment, only a positive acute angle with respect to the heat transfer tube separation direction y is included in the plurality of fins 32. There is a first inclined portion S1 that is inclined and a second inclined portion S2 that is inclined by a negative acute angle with respect to the heat transfer tube separation direction y. Also in this embodiment, all the fins 32 are configured as a flat surface.

The plurality of heat transfer tube units 30 constituting the heat transfer tube unit group 35E are the first heat transfer tube unit 30A used in the first embodiment and the second heat transfer tube unit 30B used in the third embodiment. Since the structures of the first heat transfer tube unit 30A and the second heat transfer tube unit 30B have already been described, the description thereof will be omitted here. In the heat transfer tube unit group 35E, the first heat transfer tube unit 30A and the second heat transfer tube unit 30B are alternately arranged in the heat transfer tube unit arrangement direction x. As a result, the heat transfer tube 31 belonging to the first heat transfer tube unit 30A is located between the adjacent heat transfer tubes 31 belonging to the second heat transfer tube unit 30B from the viewpoint of facing the heat transfer tube unit arrangement direction x.

Other elements not mentioned are the same as those in the first embodiment.

(2) Features (2-1)
The heat exchanger 10 has two types of heat transfer tube units, that is, a first heat transfer tube unit 30A and a second heat transfer tube unit 30B. Therefore, by appropriately arranging the two types of heat transfer tube units, it is possible to improve the heat transfer performance while reducing the air resistance.

(2-2)
At locations where the first heat transfer tube unit 30A and the second heat transfer tube unit 30B are adjacent to each other, the heat transfer tubes 31 belonging to the respective heat transfer tube units are not in close proximity to each other. Therefore, air resistance due to the proximity of the heat transfer tube 31 is unlikely to occur at that location.

(2-3)
Since the first heat transfer tube unit 30A and the second heat transfer tube unit 30B are arranged alternately, there are few places where the heat transfer tubes 31 belonging to the adjacent heat transfer tube units are close to each other. Therefore, air resistance due to the proximity of the heat transfer tube 31 is less likely to occur.

(3) Modification example (3-1) Types of heat transfer tube units The plurality of heat transfer tube units 30 constituting the heat transfer tube unit group 35E are not limited to two types, the first heat transfer tube unit 30A and the second heat transfer tube unit 30B. There may be three or more types. For example, the heat transfer tube unit group 35E may be configured by preparing three types of heat transfer tube units in which the positions of the heat transfer tubes are deviated by 1/3 of the fin width and arranging them regularly.

According to this configuration, for example, when it is allowed to design a large fin width, it is difficult to increase the air resistance even if the distance between the heat transfer tube units in the heat transfer tube unit arrangement direction x is set short. Therefore, the heat transfer performance of the heat exchanger may be improved.

(3-2) Others Modifications of the previous embodiments may be applied to the fifth embodiment.

<Sixth Embodiment>
(1) Configuration FIG. 11 is a schematic diagram of a heat transfer tube unit group 35F of the heat exchanger 10 according to the sixth embodiment of the present invention. Similar to the heat transfer tube unit group 35A according to the first embodiment, in the heat transfer tube unit group 35F according to the sixth embodiment, only a positive acute angle with respect to the heat transfer tube separation direction y is included in the plurality of fins 32. There is a first inclined portion S1 that is inclined and a second inclined portion S2 that is inclined by a negative acute angle with respect to the heat transfer tube separation direction y. Also in this embodiment, all the fins 32 are configured as a flat surface.

The plurality of heat transfer tube units 30 constituting the heat transfer tube unit group 35F are the first heat transfer tube unit 30A used in the second embodiment and the second heat transfer tube unit 30B used in the fourth embodiment. Since the structures of the first heat transfer tube unit 30A and the second heat transfer tube unit 30B have already been described, the description thereof will be omitted here. In the heat transfer tube unit group 35F, the first heat transfer tube unit 30A and the second heat transfer tube unit 30B are alternately arranged in the heat transfer tube unit arrangement direction x. As a result, the heat transfer tube 31 belonging to the first heat transfer tube unit 30A is located between the adjacent heat transfer tubes 31 belonging to the second heat transfer tube unit 30B from the viewpoint of facing the heat transfer tube unit arrangement direction x.

Other elements not mentioned are the same as those in the first embodiment.

(2) Features (2-1)
At locations where the first heat transfer tube unit 30A and the second heat transfer tube unit 30B are adjacent to each other, the heat transfer tubes 31 belonging to the respective heat transfer tube units are not in close proximity to each other. Therefore, air resistance due to the proximity of the heat transfer tube 31 is unlikely to occur at that location.

(2-2)
In both the first heat transfer tube unit 30A and the second heat transfer tube unit 30B, the inclination of the fins 32 is reversed every other one or more. Therefore, since a meandering shape with a large pitch can be formed, the resistance of the air flow can be reduced.

(3) Modification Example (3-1) Types of Heat Transfer Tube Units Similar to the modification of the fifth embodiment, the plurality of heat transfer tube units 30 constituting the heat transfer tube unit group 35F are the first heat transfer tube unit 30A and the first heat transfer tube unit 30A. 2 Not only two types of heat transfer tube unit 30B but also three or more types may be used.

According to this configuration, as described with respect to the modified example of the fifth embodiment, the heat transfer performance of the heat exchanger may be improved.

(3-2) Number of Fins Arranged Alternately With respect to the first heat transfer tube unit 30A, the first fins 32A and the second fins 32B arranged alternately in the heat transfer tube separation direction y are not limited to two each. For example, three or more first fins 32A and second fins 32B may be arranged alternately.

With respect to the second heat transfer tube unit 30B, the number of the first fins 32A and the second fins 32B alternately arranged in the plurality of gaps defined by the adjacent third fins is not limited to one. For example, two or more first fins 32A and second fins 32B may be arranged alternately.

(3-3) Others Modifications of the previous embodiments may be applied to the sixth embodiment.

<Conclusion>
Although the embodiments of the present disclosure have been described above, it will be understood that various modifications of the embodiments and details are possible without departing from the spirit and scope of the present disclosure.

For example, the above-mentioned configuration of the heat transfer tube unit may be applied to a flat tube for heat exchange. The heat exchange flat tube is a member used in, for example, a microchannel heat exchanger. In this case, the flat tube for heat exchange has a meandering shape as shown in FIG. The heat exchange flat tube has heat transfer tubes 31 and fins 32 that are alternately arranged in the heat transfer tube separation direction y.

10 Heat exchanger 21 1st header 22 2nd header 23 Heat transfer tube unit connection surface 30 Heat transfer tube unit 30A 1st heat transfer tube unit 30B 2nd heat transfer tube unit 31 Heat transfer tube 32 fin 32A 1st fin 32B 2nd fin 32C 3rd Fin 41 1st pipe 42 2nd pipe S1 1st slope S2 2nd slope

Japanese Unexamined Patent Publication No. 2006-105489

Claims (8)

A heat transfer tube unit (30) having a plurality of fins (32) and a plurality of heat transfer tubes (31),
With multiple
The plurality of heat transfer tube units are arranged at intervals in the heat transfer tube unit arrangement direction (x).
In each heat transfer tube unit
The plurality of heat transfer tubes extend in the heat transfer tube extension direction (z) perpendicular to the heat transfer tube unit arrangement direction (x).
The fins and the heat transfer tubes are alternately arranged in the heat transfer tube separation direction (y) perpendicular to the heat transfer tube unit arrangement direction (x) and the heat transfer tube extension direction (z).
The plurality of fins of each heat transfer tube unit are respectively.
The first inclined portion (S1) that is inclined by a positive acute angle with respect to the heat transfer tube separation direction (y), and
The second inclined portion (S2), which is inclined by a negative acute angle with respect to the heat transfer tube separation direction (y),
Including at least one of
The plurality of heat transfer tube units have at least one of a first heat transfer tube unit (30A) and a second heat transfer tube unit (30B).
The plurality of fins of the first heat transfer tube unit (30A) are respectively.
The first fin (32A) having only the first inclined portion (S1), and
The second fin (32B) having only the second inclined portion (S2),
Is one of
The plurality of fins of the second heat transfer tube unit (30B) are
A third fin (32C) having both the first inclined portion (S1) and the second inclined portion (S2),
Including
The plurality of heat transfer tube units include both the first heat transfer tube unit (30A) and the second heat transfer tube unit (30B).
Heat exchanger (10). The heat transfer tube belonging to the first heat transfer tube unit (30A) is located between the adjacent heat transfer tubes belonging to the second heat transfer tube unit (30B) from the viewpoint facing the heat transfer tube unit arrangement direction (x). do,
The heat exchanger according to claim 1 . The first heat transfer tube unit and the second heat transfer tube unit are alternately arranged in the heat transfer tube unit arrangement direction (x).
The heat exchanger according to claim 1 or 2 . The plurality of fins of the first heat transfer tube unit are the first fin and the second fin alternately arranged in the heat transfer tube separation direction (y).
The heat exchanger according to any one of claims 1 to 3 . The plurality of fins of the first heat transfer tube unit are the first fin and the second fin, which are alternately arranged by two or more in the heat transfer tube separation direction (y).
The heat exchanger according to any one of claims 1 to 3 . A heat transfer tube unit (30) having a plurality of fins (32) and a plurality of heat transfer tubes (31),
With multiple
The plurality of heat transfer tube units are arranged at intervals in the heat transfer tube unit arrangement direction (x).
In each heat transfer tube unit
The plurality of heat transfer tubes extend in the heat transfer tube extension direction (z) perpendicular to the heat transfer tube unit arrangement direction (x).
The fins and the heat transfer tubes are alternately arranged in the heat transfer tube separation direction (y) perpendicular to the heat transfer tube unit arrangement direction (x) and the heat transfer tube extension direction (z).
The plurality of fins of each heat transfer tube unit are respectively.
The first inclined portion (S1) that is inclined by a positive acute angle with respect to the heat transfer tube separation direction (y), and
The second inclined portion (S2), which is inclined by a negative acute angle with respect to the heat transfer tube separation direction (y),
Including at least one of
The plurality of heat transfer tube units have at least one of a first heat transfer tube unit (30A) and a second heat transfer tube unit (30B).
The plurality of fins of the first heat transfer tube unit (30A) are respectively.
The first fin (32A) having only the first inclined portion (S1), and
The second fin (32B) having only the second inclined portion (S2),
Is one of
The plurality of fins of the second heat transfer tube unit (30B) are
A third fin (32C) having both the first inclined portion (S1) and the second inclined portion (S2),
Including
The plurality of fins of the second heat transfer tube unit are the third fins arranged in the heat transfer tube separation direction (y) so that the protruding directions are alternately different.
Heat exchanger (10) . A heat transfer tube unit (30) having a plurality of fins (32) and a plurality of heat transfer tubes (31),
With multiple
The plurality of heat transfer tube units are arranged at intervals in the heat transfer tube unit arrangement direction (x).
In each heat transfer tube unit
The plurality of heat transfer tubes extend in the heat transfer tube extension direction (z) perpendicular to the heat transfer tube unit arrangement direction (x).
The fins and the heat transfer tubes are alternately arranged in the heat transfer tube separation direction (y) perpendicular to the heat transfer tube unit arrangement direction (x) and the heat transfer tube extension direction (z).
The plurality of fins of each heat transfer tube unit are respectively.
The first inclined portion (S1) that is inclined by a positive acute angle with respect to the heat transfer tube separation direction (y), and
The second inclined portion (S2), which is inclined by a negative acute angle with respect to the heat transfer tube separation direction (y),
Including at least one of
The plurality of heat transfer tube units have at least one of a first heat transfer tube unit (30A) and a second heat transfer tube unit (30B).
The plurality of fins of the first heat transfer tube unit (30A) are respectively.
The first fin (32A) having only the first inclined portion (S1), and
The second fin (32B) having only the second inclined portion (S2),
Is one of
The plurality of fins of the second heat transfer tube unit (30B) are
A third fin (32C) having both the first inclined portion (S1) and the second inclined portion (S2),
Including
The plurality of fins of the second heat transfer tube unit include the first fin, the second fin, and the third fin, and at least one of the first fins is between the two third fins. One fin or the second fin is arranged,
Heat exchanger (10) . The plurality of fins are curved surfaces.
The heat exchanger according to any one of claims 1 to 7 .

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