DE102007015531A1 - Heat transfer element and heat exchanger with this - Google Patents

Abstract

A heat transfer member (2) has a base wall (2a) having a base portion (2d) and angled portions (2c, 21c, 22c). The angled portions extend from opposite sides of the base portion with respect to a flow direction of a fluid. The angled portions are provided by portions which are cut from the base wall at opposite sides of the base portion and bent relative to the base wall.

Description

The The present invention relates to a heat exchange element and a heat exchangers with this.

One heat exchangers with ribs formed with louvers to improve heat exchange performance are known. For example, in a heat exchanger used in Japanese unaudited Patent publication No. 2005-121348 (US 2004/0206484 A1) discloses a rib angled pieces on her flat plate part. The angled pieces are from the flat plate part cut and angled. In other words, the extend angled pieces of base portions of the flat plate member and have L-shaped cross sections with the base sections. In this heat exchanger is an air flow through the angled pieces disturbed. Therefore, the heat transfer coefficient increases between the air and the ribs and thus improves the heat exchange performance.

each the angled pieces is formed on one side of the respective base portion. Therefore learn the base sections when bending the angled pieces of the flat plate part a moment in one direction. As a result become boundaries between the angled pieces and the base sections distorted or twisted. Further, since the flat plate part is plural has angled pieces, the flat plate part deformed overall. That's why it's difficult to stably provide the ribs with predetermined shapes.

The The present invention is made in view of the above thing and it is an object of the present invention to provide a heat transfer element to provide with a stable shape to shape.

It Another object of the present invention is a heat transfer element with a shape that can improve productivity, and one heat exchangers with the heat transfer element provided.

According to one Aspect of the present invention, a heat transfer element has a base wall with a base portion, a first angled portion and a second angled section extending from opposite sides of the base section. The first angled section, the second angled section and the base section see heat exchangers in front.

Of the first and second angled sections are made by cutting Dividing the base wall on the opposite sides of the base portion and bending the sections relative to the base wall. Since the first and the second angled portion on the opposite sides of the base section are bent to the base section when bending the first and second angled portions moments exercised in directions, who pick each other up.

Therefore It is less likely that borders between the first and the second angled portion and the base portion are twisted. Therefore, the accuracy of shaping the angled improves Sections. Accordingly, become the heat transfer elements with a desired Mold made stable. Furthermore, the productivity of the heat transfer elements improves. The heat transfer element For example, it is applied to a rib of a heat exchanger.

The Heat transfer element can have several heat exchangers to have. The heat transfer parts are in a flow direction a fluid arranged so that the first angled piece of each Heat transfer part on an upstream Side of the corresponding base section is arranged and the second angled piece the heat transfer part on a downstream side the corresponding base portion with respect to the flow direction the fluid is arranged.

To the Example can the first angled pieces and the second angled pieces the heat transfer parts the essentially same measure with respect to a Have direction perpendicular to the base wall. In this case, the Sizes of when bending the first and second angled portions on the Basic sections exercised Moments are essentially the same. Therefore, the base sections become prevented from twisting when the first and second angled ones Sections are bent.

alternative can the first angled portion and the second angled portion different dimensions in terms of have a direction perpendicular to the base wall. For example, have in some of the heat exchanges, which are arranged upstream of a reference point, the first angled pieces Dimensions larger than the dimensions the second angled pieces from that. In this case, the air flow in an upstream area of the Base wall further disturbed. Therefore, the heat transfer coefficient improves. Further, an increase in the pressure loss (flow resistance) due to excessive disturbance of the Air in a downstream Area of the base wall reduced.

Instead, the dimensions of some heat exchangers can be upstream of a reference point the base wall are arranged to be larger than the dimensions of the heat exchange parts, which are arranged downstream of the reference point. Also in this case, the air flow in the upstream area of the base wall is effectively disturbed and the heat transfer coefficient improves. Further, the increase in pressure loss is reduced by the excessive disturbance of the air in the downstream area of the base wall.

Further Objects, features and advantages of the present invention from the following detailed description with reference to the attached Drawings in which like parts are indicated by like reference numerals are better understood. Show:

1 a front view of a heat exchanger according to a first embodiment of the present invention;

2 a perspective view of a rib of the heat exchanger according to the first embodiment;

3 a perspective view of a part of the rib according to the first embodiment;

4 a cross-sectional view of the rib along a line IV-IV in 2 ;

5 an enlarged cross-sectional view of louvers of in 4 represented rib;

6 a schematic representation of a roll forming apparatus according to the first embodiment;

7 FIG. 12 is a graph showing a simulation result showing a relationship between an arrangement pitch of the louvers and a heat exchange performance according to the first embodiment; FIG.

8th FIG. 15 is a graph showing a simulation result showing a relationship between a height H of bent pieces of the rib and a heat exchange performance according to the first embodiment; FIG.

9 a cross-sectional view of upstream louvers of a rib according to second and third embodiments of the present invention;

10 a cross-sectional view of louvers of a rib according to a fourth embodiment of the present invention;

11 FIG. 12 is a graph showing a relationship between a ratio H1 / L of a height H1 of an upstream angled piece and the width L of a base piece of the fin and a heat exchange performance according to the fourth embodiment; FIG.

12 FIG. 12 is a graph showing a relationship between the ratio H1 / L and a pressure loss according to a fifth embodiment of the present invention; FIG.

13A to 13C Cross-sectional views of examples of louver shapes of a rib according to a fifth embodiment of the present invention; and

14A to 14C Cross-sectional views of examples of louver shapes of a rib according to the fifth embodiment.

(First embodiment)

A first embodiment will be referred to 1 to 8th described. In the first embodiment, an in 1 shown heat exchanger used for example as a radiator for a vehicle air conditioning.

To the Example is the cooler a high pressure side heat exchanger a vapor compression refrigeration cycle and radiates heat one output from a compressor of the vapor compression refrigeration cycle refrigerant from. The cooler is also called a refrigerant condenser designated. In a cooling circuit with carbon dioxide and the like as a refrigerant, when that of a refrigerant discharged from a compressor has a pressure lower than a critical pressure, the refrigerant in the cooler by condensing heat absorbed in an evaporator. If, on the other hand, the refrigerant discharged from the compressor is equal to or equal to pressure greater than has a critical pressure, the refrigerant in the cooler through Radiating the heat absorbed in the evaporator without condensing cooled.

As in 1 As shown, the radiator has a core part as a heat exchange part, header tank 3 and side plates (inserts) 4 , The core part contains pipes 1 and ribs 2 as heat transfer elements. The tubes define channels through which a refrigerant flows. Ribs 2 are connected to outer surfaces of the tubes for increasing a heat transfer surface with air, thereby facilitating heat exchange between the air and the refrigerant.

The distribution tanks 3 are at the longitudinal ends of the pipes 1 arranged and extending in a direction perpendicular to a longitudinal direction of the tubes 1 , The distribution containers 3 stand with the pipes 1 in connection. The side plates 4 are disposed at ends of the core member as a reinforcing member for reinforcing the core member.

The radiator further has a refrigerant inlet at one of the distribution tanks 3 and a refrigerant outlet at the other of the distribution tanks 3 , Alternatively, the radiator may configure the refrigerant inlet and the refrigerant outlet on the same header tank 3 to have. In the latter case, the other header tank 3 equipped with a separator, so that the refrigerant flows in a U-turn or in serpentine lines in the radiator.

For example, the aforementioned components such as the tubes 1 , Ribs 2 , Distribution tank 3 and side plates 4 made of a metal such as an aluminum alloy. Also, the aforementioned components are integrally connected, for example by soldering.

The rib 2 is a corrugated fin with plate sections 2a and end sections 2 B , the adjacent plate sections 2a position at predetermined intervals. Each of the plate sections 2a has a plate shape and provides surfaces that extend along a flow direction A1 of the air as an external fluid. The plate section 2a is for example a flat plate. Therefore, the plate section becomes 2a hereinafter also referred to as a flat plate section 2a designated.

Each of the end sections 2 B For example, has a flat plate shape with a width smaller than that of the flat portion 2a , The end section 2 B provides an outer surface that matches the outer surface (flat walls) of the pipe 1 connected so that heat is transferred between them. As in 2 shown are the plate section 2a and the end section 2 B perpendicular to each other and define a right-angled corner between them.

The width of the end section 2 B is very small. If the corners between the end section 2 B and the adjacent plate sections 2a define a radius, the end portion 2 B be recognized as a curved or bent section. Therefore, the end portion becomes 2 B also as a curved section 2 B designated. In this embodiment, the corrugated fin 2 for example, formed from a thin sheet metal by roll forming.

As in 4 shown, has the flat section 2a the rib angled pieces 2c , The angled pieces 2c are by cutting parts of the flat section 2a and moving or bending the cut parts relative to the remaining part of the flat portion 2a such that the cut parts are right angles with the flat section 2a form, shaped. Therefore, the flat section has 2a Openings as slots. Every angled piece 2c has a height that makes it real from the flat section 2a that has a base wall of the rib 2 forms, extends.

Here, the height of the angled piece corresponds 2c a measure in an up / down direction in 3 and 4 , This height of the angled piece 2c is also called a width of the angled piece 2c designated. The angled pieces 2c have the same height. An opening is formed by forming an H-shaped cut on the flat portion 2a and moving away portions of the cut relative to the flat portion 2a shaped as an opening. Therefore, there are two angled pieces 2c formed on opposite sides of an opening. The two angled pieces 2c an opening belong to different louvers (heat exchanger parts) 20 which will be described later. Also, an overall height of the two angled pieces 2c equal to a width of the opening.

Each of the angled pieces 2c has a rectangular shape with longitudinal sides in one direction along a direction in which a height of the rib 2 is measured. The angled piece 2c has a shape like a band. This is the height of the rib 2 in an up / down direction in 1 measured. The angled piece 2c extends in a direction having an air flow direction A1 in 2 cuts. In this embodiment, the angled piece extends 2c in a direction parallel to the direction in which the height of the rib 2 is measured, and in a direction perpendicular to the air flow direction A1.

Also, the length of the angled piece 2c essentially equal to the height of the rib 2 , That is, the angled piece 2c has a first end at a position adjacent to an end portion 2 B and a second end at a position adjacent to the opposite end portion 2 B of the flat section 2a , Therefore, the between the two angled pieces 2c defined opening has a length substantially equal to the height of the rib 2 ,

In this embodiment, the angled piece 2c at right angles with respect to the flat section 2a , The right angle is about 90 ° C.

In this rib, the air bumps with the angled pieces 2c together as it flows along the surface of the flat section. Therefore, the air flow is disturbed, so that a heat transfer coefficient between the rib 2 and the air is increased. Accordingly, the angled pieces serve 2c as collision walls to disturb the airflow.

Referring to 2 and 3 who the parts of the flat section 2a which are positioned between the openings as base sections (bases) 2d designated. The base section 2d is continuous with respect to the air flow direction A1 to two angled pieces 2c ,

In this embodiment, the two angled pieces 2c extending from opposite sides of the base section 2d extend, on the same side of the flat section 2a bent. That is, the two angled pieces 2c are on the same surface of the flat section 2a educated. Furthermore, the two angled pieces run 2c parallel to each other. In particular, in 3 a right angled piece 2c on a right side of a base piece 2d is positioned from the flat section 2a moved counterclockwise, and a left angled piece 2c on a left side of the base piece 2d is positioned from the flat section 2a moved in a clockwise direction.

Therefore have the base piece 2d and the two angled pieces 2c on both sides of the base piece 2d are positioned, a substantially U-shaped cross-section or a cross-section such as a clip, as in 5 shown. Below is this U-shaped section with the base piece 2d and the two angled pieces 2c that differ from the base piece 2d extend as the damper 20 designated. In this embodiment, all angled pieces run 2c a flat section 2a in the same direction.

Also have the angled pieces 2c a flat section 2a the same length, and the ends of the angled pieces 2c are in a longitudinal direction of the flat portion 2a , that is aligned in the air flow direction A1. Therefore, the strength of the flat section 2a improved on both sides. Therefore, the strength of the flat section 2a larger than that of the end section 2 B that does not have angled pieces 2c has. So can the end section 2 B relative to the flat section 2a be bent sharply.

The flat section 2a has several louvers 20 , The louvers 20 are arranged parallel to each other and in the air flow direction A1, so that the air in turn with the louvers 20 crashes. As in 4 shown, are the louvers 20 arranged symmetrically to a reference point C, which is positioned at a predetermined position with respect to the air flow direction A1.

In this embodiment, the reference point C is positioned substantially at a center position with respect to the air flow direction A1. The number of angled pieces 2c which are positioned upstream of the reference point C is equal to the number of the angled pieces 2c which are positioned downstream of the reference point C. Also all have angled pieces 2c the same height (hereinafter referred to as an elbow height H). In 4 Gr1 denotes a group of upstream louvers 20 and Gr2 denotes a group of downstream louvers 20 ,

In the above discussion, it is described that two angled pieces 2c on both sides of each base piece 2d are formed. The flat section 2a has two end walls at its upstream and downstream ends with respect to the air flow direction A1 and a center wall at the middle position. The end walls and middle wall are flat and wider than any base piece 2d with respect to the air flow direction A1. The end walls and middle wall also have angled pieces of the same shape as those of the base piece 2d extending angled pieces 2c ,

Looking at the above explanations, one can see that the angled pieces 2c are formed on both sides of the respective openings. That is, all openings have the angled pieces 2c on both sides. In other words, every base piece has 2d the two angled pieces 2c which extend in the same direction on both sides, regardless of the width of the base 2d ,

Next, a construction of a roll forming apparatus for forming the rib will be described 2 Referring to 6 described. As in 6 As shown, the roll forming apparatus generally includes a tensioning unit 12 , a roll forming unit 13 , a cutting unit 14 , a conveyor unit 15 , a forming unit, a brake unit and the like.

The clamping unit 12 exerts a predetermined tension on a fin material 11 having a thin plate shape and a roll of material (uncoiler) 10 is pulled. The clamping unit 12 has a weight clamping part 12a for applying a predetermined tension to the fin material 11 by gravity, one with the movement of the rib material 11 rotatable roller 12b and a roll tensioning part 12d that is a feather part 12c for applying a predetermined tension to the fin material 11 through the roller 12b contains. Here, the predetermined clamping force on the fin material 11 exerted to the height of the rib, which in the rib forming unit 13 is bent to keep at a constant level.

The rib forming unit 13 bends the rib material 11 in a wavy shape to the curved sections 2 B and the flat sections 2e and shapes the angled pieces 2c at Ab cut according to the flat sections 2a , The rib forming unit 13 contains a pair of profile rollers 13a , The rollers 13a have gear shapes with teeth 13b , The rollers 13a have cutting (not shown) on the teeth 13b for forming the angled portions 2c , The rib material 11 gets into the undulating shape along the teeth 13b bent and the angled pieces 2c are formed while rolling between the pair 13a be transported.

The cutting unit 14 cuts the rib material 11 in a predetermined length, so that a rib 12 a predetermined number of the curved portions 2 B Has. The rib material 11 that has been cut to the predetermined length, by the transport unit 15 transported to the forming unit.

The transport unit 15 has a pair of rollers 15a , The pair of rollers has gears with teeth that are substantially equal in reference intervals (distance) to the intervals of the adjacent curved sections 2 B in the rib forming unit 13 are formed, are arranged. Here, the intervals between the adjacent curved sections become 2 B the corrugated fin is generally referred to as a fin pitch Pf. The fin pitch Pf is twice the distance between the adjacent flat portions 2a , as in 4 shown.

If an angle of pressure of the profile rollers 13a is increased, the rib distance Pf of the rib 2 reduced in the final state. On the other hand, when the pressure angle of the profile rollers 13a is reduced, the rib distance Pf of the rib 2 enlarged in the final state. If a difference of the modules of the profile rollers 13a and the transport rollers 15a within 10%, the ribs will be without replacing the transport rollers 15a shaped.

The forming unit 16 forms the waviness of the curved sections 2 B by pressing the curved sections 2 B in a direction substantially perpendicular to the web of the curved sections 2 B back. The forming unit 16 contains a pair of forming rollers 16a . 16b , The forming rollers 16a . 16b are on opposite sides of the rib material 11 arranged and according to the movement of the rib material 11 rotatable. Next are the forming rollers 16a . 16b arranged so that one through the axes of rotation of the forming rollers 16a . 16b running line perpendicular to a conveying direction of the fin material 11 is.

The brake unit 17 contains a brake shoe 17c with a braking surface 17a and a plate element 17e with a braking surface 17b , The brake unit 17 is downstream of the forming unit 16 with respect to a conveying direction of the fin material 11 positioned. The brake unit 17 compresses the rib material 11 by a conveying force by the transport unit 15 is generated, and a friction caused by the braking surfaces 17a . 17b is generated so that the curved sections 2 B are in contact with each other.

Here is one end of the brake shoe 17c rotatably supported, and a spring element 17d is at the other end of the brake shoe 17c as a friction control device. This is how it works through the braking surfaces 17a . 17b generated friction by controlling a deflection of the spring element 17d controlled. The plate element 17e is made of a material having a sufficient rub resistance, for example of die steel.

Next, an operation of the profile forming apparatus will be described. First, the rib material 11 from the roll of material 10 pulled (drawing step). Then, the predetermined tension on the fin material 11 in the conveying direction of the fin material 11 in the clamping unit 12 exercised (tensioning step). Next are the curved sections 2 B and the angled pieces 2c on the rib material 11 shaped (rib forming step). The molded rib material 11 is cut in the cutting unit to a predetermined length (cutting step).

The fin stock of the predetermined length is passed through the transport unit 15 to the forming unit 16 transported (transport step). Then in the forming unit 16 the curved sections 2 B pressed, so the ripple of the rib material 11 to reform (forming step). Next is the rib material 11 in the brake unit 17 pulled together so that the adjacent curved sections 2 B in contact with each other (contraction step).

After the contraction step, the rib material expands 11 by its elasticity and has a predetermined fin pitch Pf. Then, a check such as a dimensional inspection is performed. In this way, the corrugated fins 2 produced.

In this embodiment, the angled pieces 2c on both sides of the bases 2d shaped and run in the same direction. Therefore, if the angled pieces 2c Shaping moments on the base piece 2d in opposite directions. Therefore, it is less likely to have a boundary between the base piece 2d and the angled piece 2c ie a base of the elbow 2c , is distorted. Accordingly, the accuracy of molding the louvers 20 improved. As a result, the louvers 20 right in the desired Molds shaped and the productivity of the ribs 2 is improved.

In this embodiment, all louvers 20 essentially the same height H. That's why in every base piece 2d that when bending the angled piece 2c moment on the upstream side, bending the angled piece 2c on its downstream side, the moment caused substantially the same. Therefore, it effectively prevents the bases of the elbows 2c when bending the angled pieces 2c be distorted. Accordingly, the accuracy of molding the angled pieces becomes 2c further improved. This will increase the productivity of the ribs 2 further improved.

Further, the louvers 20 arranged symmetrically to the reference point C. In the rib forming step, the bending forces are continuously applied to the rib material 11 in opposite directions. Therefore, it is less likely that the rib material 11 is deformed so that it is biased in one direction and collected when the angled pieces 2c be formed. Because the basic pieces 2d and the angled pieces 2c Being stably shaped will increase the productivity of the ribs 2 further improved.

Also, the louvers are 20 by bending the angled pieces 2c on both sides of the base piece 2d formed with respect to the air flow direction A1. The louvers 20 are formed at predetermined intervals without cutting or wasting the fin material. Therefore, a discharge rate of the fin material 11 improved.

Besides, there are the angled pieces 2c on both sides of the base piece 2d be formed, the distances between the adjacent louvers 20 without unduly increasing the elbow height H increased. Therefore, an effect of increasing the disturbance of the air is improved, suppressing an increase in the pressure loss (air flow resistance). This improves the heat transfer coefficient. Accordingly, the heat exchange performance is improved.

According to a study, it is preferable that the rib 2 has a thickness in a range between ≥ 0.01 mm and ≤ 0.1 mm. 7 shows a simulation result of the heat exchange performance against an air damper spacing P of the louvers 20 , 8th shows a simulation result of the heat exchange performance against the angle piece height H.

The louver distance P is a distance between the adjacent louvers 20 with respect to the air flow direction A1, as in 5 shown. The angle piece height H corresponds to a dimension (height) of the air flap 20 in a direction perpendicular to the air flow direction A1. Therefore, the elbow height H is also referred to as the air damper height. Also, the angle piece height and the damper height H include a thickness of the flat portion 2a , The heat exchange performance is determined based on the product of the heat exchange coefficient and a heat transfer area.

As in 7 and 8th 1, the heat exchange performance is improved when the damper pitch P is in a range between ≥ 0.04 mm and ≤ 0.75 mm and the damper height H is in a range between ≥ 0.02 mm and ≤ 0.4 mm.

Further is the heat exchange performance further improved when the air flap distance P in one area between ≥ 0.2 mm and ≤ 0.7 mm is located and the damper height H in a range between ≥ 0.1 mm and ≤ 0.35 mm. Furthermore, the heat exchange performance further improved when the air flap distance P in one area between ≥ 0.4 mm and ≤ 0.6 mm and if the damper height H is in a range between ≥ 0.2 mm and ≤ 0.3 mm.

Second Embodiment

A second embodiment will be referred to 9 described. Following the same components are given the same reference numerals and their description will not be repeated.

In every flat section 2a are the louvers 20 with respect to the air flow direction A1 arranged symmetrically relative to a predetermined reference point C. Therefore, the louvers are 20 the upstream group and the louvers 20 the downstream group arranged symmetrically. Below are the louvers 20 the upstream group referred to as upstream louvers. And the louvers 20 the downstream group are called downstream louvers 20 designated.

9 shows some of the upstream louvers 20 , In this embodiment, the angled pieces 2c the upstream louvers 20 a different length, as in 9 shown. In particular, the upstream air damper has 20 an upstream angled piece 21c on its upstream side and a downstream angled piece 22c on its downstream side with respect to the air flow direction A1. A height H1 of the upstream angled piece 21c is greater than a height H2 of the downstream angled piece 22c ,

Therefore, since the upstream louvers 20 the upstream angled pieces 21c have higher than those of other angled pieces 2c are the airflow in an upstream region of the flat section 2a more disturbed. This improves the heat transfer coefficient. Also, an increase in the pressure loss (air flow resistance) becomes in a downstream area of the flat portion 2a restricted due to excessive disturbance of the air.

If the upstream angled pieces 2c the downstream louvers 20 would be increased, the heat exchange performance would be deteriorated. Ie in this case, because of the number of other louvers 20 with respect to the air flow direction A1, the heat exchange amount is reduced by an increase in the pressure loss (air flow resistance) as compared with the increase of the heat exchange coefficient due to the disturbance.

In this embodiment, the upstream louvers have 20 and the downstream louvers 20 a symmetric relationship. Since the height H1 of the upstream angled pieces 21c the upstream louvers 20 enlarged, are the upstream louvers 20 and the downstream louvers 20 not perfectly symmetrical. The upstream louvers 20 however, the downstream louvers have the generally U-shaped cross-sections and therefore are substantially symmetrical. The above symmetrical relationship contains this substantially symmetrical relationship.

Also, in this embodiment, the number of the upstream louvers 20 equal to the number of downstream louvers 20 , However, the number of upstream louvers may be 20 also slightly different from the number of downstream louvers 20 (eg, around one). The above symmetric relationship also includes this case. Also in the first embodiment, the number of louvers 20 the upstream group Gr1 of the number of louvers 20 the downstream group Gr2 be different.

Also in this embodiment, since the louvers 20 are arranged in the symmetrical relationship with respect to the reference point C, the bending forces continuously on the fin material 11 in abutting directions in the rib forming step. Therefore, it is less likely that the rib material 11 when bending the angled pieces 2c is deformed so that it is biased in one direction. Therefore, the basic pieces 2d and the angled pieces 2c stable and evenly shaped. Accordingly, the productivity of the ribs becomes 2 further improved.

(Third Embodiment)

A third embodiment will be described. The third embodiment is also in 9 shown. Every flat section 2a has the upstream louvers 20 and the downstream louvers 20 , Here are the downstream louvers 20 the same shape as the louvers 20 of the first embodiment.

As in 9 shown, have the upstream louvers 20 the upstream angled pieces 21c and the downstream angled pieces 22c , and the height H1 of the upstream angled pieces 21c is higher than the height H2 of the downstream angled pieces 22c ,

In the downstream louvers 20 have the upstream angled pieces 2c and the downstream angled pieces 2c the same height H. Therefore have the upstream louvers 20 a higher altitude than the downstream louvers 20 , In this embodiment, the heights H, H1, H2 have the relationship H1>H> H2. Further, the height H and the height H2 may be substantially equal. Alternatively, the heights H, H1, H2 may have the relationship H1 + H2> 2 × H.

Therefore, since the air flow through the upstream angled pieces 21c with the higher altitude than the others is more disturbed, the heat transfer coefficient increases. Also, since it is less likely that the air flow will be in the downstream area of the shallow section 2a is excessively disturbed, the increase of the pressure loss (air flow resistance) is suppressed.

If the height of the upstream angled pieces 2c the downstream louvers 20 is increased, the heat exchange performance is reduced. Ie in this case, because of the number of remaining louvers 20 is small with respect to the air flow direction A1, the heat exchange amount is reduced by an increase in the pressure loss (air flow resistance) as compared to the increase of the heat exchange coefficient by the disturbance.

Also, only one or some of the upstream air dampers can 20 the upstream angled pieces 21c with the height H1 greater than the height H of the downstream louvers 20 to have. Further, the height of the upstream louvers 20 increased on average more than the height of the downstream louvers 20 ,

In this embodiment, since the upstream angled pieces 21c and the downstream angled pieces 22c the different heights have, the upstream louvers 20 and the downstream louvers 20 not exactly symmetrical. The upstream louvers 20 and the downstream louvers 20 however, similarly have the substantially U-shaped cross-sectional shape. Therefore, the upstream louvers have 20 and the downstream louvers 20 nor the symmetrical relationship.

Also, even if the number of upstream louvers 20 and the number of downstream louvers 20 may be slightly different, the upstream louvers 20 and the downstream louvers 20 nor the symmetrical relationship.

(Fourth Embodiment)

A fourth embodiment will be referred to 10 to 12 described. In this embodiment, the height H1 of the upstream angled piece is 21c in a range between ≥ 0.02 mm and ≤ 0.4 mm. The air flap spacing P is also in a range between ≥ 0.02 mm and ≦ 0.75 mm. Further, the height H2 of the downstream angled piece 22c equal to the height H1 of the upstream angled piece 21c ,

Because the angled pieces 2c from the flat section 2a are bent, the width L of the base varies 2d the air damper 20 corresponding to the height H1 of the upstream angled piece 21c and the air damper spacing P. 11 Fig. 10 shows a relationship between a louver ratio H1 / L and heat exchange performance. The damper ratio H1 / L is a ratio H1 of the upstream angled piece 21c to the width L of the base piece 2d , As in 11 That is, when the louver ratio H1 / L is in a range between 0.9 mm and ≤ 1.25 mm, the heat exchange performance is satisfactory.

12 shows a relationship between the air valve ratio H1 / L and the pressure loss. When the damper ratio H1 / L≤1.2, the pressure loss is reduced.

Under consideration the heat exchange performance and the pressure loss, it is preferable that the louver ratio H1 / L in the range ≥ 0.9 mm and ≤ 1.25 mm lies. More preferably, the louver ratio H1 / L is within a range between ≥ 0.95 mm and ≤ 1.2 mm. More preferably, the louver ratio H1 / L is in a range between ≥ 1.0 mm and ≦ 1.15 mm.

(Fifth Embodiment)

A fifth embodiment will be referred to 13A to 14C described. In the above embodiment, the angled pieces are 2c relative to the flat section 2a right-angled to improve heat exchange performance. The angle of the angled pieces 2c relative to the flat section 2a however, is not limited to the right angle, but may be modified as long as the air flow is disturbed.

In this embodiment, the angle of the angled pieces 2c relative to the flat section 2a modified in a range between ≥ 40 ° C and ≤ 140 ° C. Therefore, the cross-sectional shape of the louvers 20 not limited to the essentially U shape, but may have some shapes. Here is the angle of each angled piece 2c relative to the flat section 2a defined, ie relative to a state, before it from the flat section 2a is bent. Therefore, the angle is also referred to as a bending angle.

13A to 13C show examples where the angles of the angled pieces 2c modified in different ways. In 13A are the upstream and downstream angled pieces 2c each angled at about 40 ° C. In 13B are the upstream and downstream angled pieces 2c each angled at about 140 ° C. In 13C are the upstream angled pieces 21c angled at about 90 ° C and the downstream angled pieces 22c are angled at about 40 ° C.

The shape of the louvers 20 is further modified. 14A to 14C show examples of louvers 20 , In 14A are the angled piece 2c and a connecting portion between the angled piece 2c and the base piece 2d relative to the flat section 2a angulated. In 14B are the angled pieces 2c shaped so that the base piece 2d and the angled pieces 2c share a uniformly curved wall with an arcuate shape in cross section.

In 14C is an end of the upstream angled piece 21c bent to an upstream position with respect to the air flow direction A1 and an end of the downstream angled piece 22c is bent to a downstream position with respect to the air flow direction A1.

Accordingly, the shape of the louvers 20 not limited to the shapes shown, as long as the airflow along the flat section 2a is disturbed.

In the above Ausführungsbeisielen the present invention is in the radiator of the vehicle air conditioner Applied, but it can also be used in any other heat exchangers be used, for example, a heater core of a vehicle air conditioning, an evaporator or condenser of a vapor compression refrigeration cycle, a condenser for Cool of engine cooling water.

The shape of the ribs is not limited to the corrugated shape. Ribs 2 may also be other ribs, such as flat-walled panel ribs and pin-shaped ribbed ribs. The louvers 20 can be in multiple rows in each flat section 2a be arranged in the air flow direction A1. Next, the angled pieces 2c be inclined at a predetermined angle relative to a direction perpendicular to the air flow direction A1. In addition, the number of louvers 20 in several flat sections 2a to be different. Also, the flat section 2a only one air damper 20 to have. In addition, the above embodiments can be realized in variable combinations.

The exemplary embodiments The present invention is described above. The present However, the invention is not limited to the above exemplary embodiments limited, but can be realized in other ways without the scope of protection to leave the invention.

Claims (18)

Heat transfer element for transferring heat with a fluid, having a base wall ( 2a ) with a base section ( 2d ); a first angled section ( 2c . 21c ); and a second angled section ( 2c . 21c . 22c ), wherein the first angled portion and the second angled portion extend from opposite sides of the base portion and are angled relative to the base wall, and the first angled portion, the second angled portion, and the base portion are a heat exchange part (FIG. 20 ). Heat transfer element according to claim 1, wherein the heat exchange part ( 20 ) one of a plurality of heat exchange parts ( 20 ). A heat transfer element according to claim 2, wherein the first angled portions (16) 2 . 21c . 22c ) and the second angled sections ( 2c . 1c . 22c ) of the plurality of heat exchanging parts is substantially equal in dimension with respect to a direction perpendicular to the base wall ( 2a ) to have. Heat transfer element according to claim 2, wherein the plurality of heat exchanging parts ( 20 ) are arranged with respect to a flow direction of the fluid so that the first angled portions ( 2c . 21c ) upstream of the base sections ( 2d ) are positioned and the second angled portions ( 2c . 22c ) with respect to the flow direction of the fluid downstream of the base sections ( 2d ) and some of the plurality of heat exchangers upstream of a reference point of the base wall ( 2a ), and the first angled portions of the some of the plurality of heat exchanging parts have dimensions (H1) larger than dimensions (H2) of the second angled portions thereof with respect to a direction perpendicular to the base wall. Heat transfer element according to claim 2, wherein the plurality of heat exchanging parts ( 20 ) are arranged with respect to a flow direction of the fluid containing a plurality of heat exchanging parts upstream and downstream heat exchanging parts, wherein the upstream heat exchanging parts are arranged upstream of a reference point of the base wall with respect to the flow direction of the fluid and the downstream heat exchanging parts are located downstream of the reference point, and the upstream heat exchanging parts (H1, H2) greater than the dimensions (H) the downstream heat exchanges with respect to a direction perpendicular to the base wall ( 2a ) to have. A heat transfer element according to any one of claims 1 to 5, wherein at least one of said first and second angled portions (16) 2c . 21c . 22c ) relative to a surface of the base portion ( 2d ) is rectangular. A heat transfer member according to any one of claims 1 to 5, wherein each of said first and second angled portions (16) 2c . 21c . 22c ) in a range between at least 40 ° C and at most 140 ° C relative to a surface of the base wall ( 2a ) is angled. Heat transfer element according to one of claims 1 to 7, wherein the heat exchange part ( 20 ) one of several heat exchange parts ( 20 ), which are arranged in a row a plurality of heat exchanging parts and a symmetrical relationship relative to a reference point of the base wall ( 2a ) to have. Heat transfer element according to one of claims 1 to 8, wherein the heat exchange part ( 20 ) a height (H, H1, H2) in a direction perpendicular to the base wall ( 2a ) and a width (L) in a direction along the base section and perpendicular to the first and second angled sections, and a ratio of height to width is in a range between at least 0.9 and at most 1.25. Heat transfer element according to claim 9, wherein the ratio is in a range between at least 0.95 and at most 1,2 is located. Heat transfer element according to claim 10, wherein the ratio is in a range between at least 1.0 and at most 1.5 is located. Heat transfer element according to one of claims 1 to 11, wherein the heat exchange part ( 20 ) one of several heat exchange parts ( 20 ) arranged in a flow direction of the fluid at a predetermined distance (P), and each of the plurality of heat exchange parts has a dimension (H, H1, H2) in a direction perpendicular to the base wall in a range of at least 0.02 mm and at most 0.4 mm, and the predetermined distance (P) is in a range between at least 0.04 mm and at most 0.75 mm. Heat transfer element according to claim 12, wherein the dimension (H, H1, H2) of the heat exchange part ( 20 ) is in a range between at least 0.1 mm and at most 0.35 mm, and the predetermined distance (P) is in a range between at least 0.2 mm and at most 0.7 mm. Heat transfer element according to claim 13, wherein the dimension (H, H1, H2) of the heat exchange part ( 20 ) is in a range between at least 0.2 mm and at most 0.3 mm, and the predetermined distance (P) is in a range between at least 0.4 mm and at most 0.6 mm. Heat exchanger, with a pipe ( 1 ) defining a channel for flowing a heat medium therein; and a rib disposed on an outer surface of the pipe ( 2 ), wherein the rib contains the heat transfer element according to one of claims 1 to 14. Heat exchanger according to claim 15, in which the rib ( 2 ) has a thickness in a range between at least 0.01 mm and at most 0.1 mm. Heat exchanger according to Claim 15 or 16, in which the rib ( 2 ) has a corrugated shape. heat exchangers according to one of claims 15 to 17, in which the heat medium a refrigerant is.