The present invention relates to a corrugated fin for dissipating heat of a heat exchange medium in a heat exchanger such as a radiator, an oil cooler or an after-cooler. The invention also relates to the heat exchanger including the corrugated fin.
In an engine room of a work vehicle such as a hydraulic excavator or a bulldozer, an engine, a radiator, a cooling fan and others are placed in a predetermined pattern of locations. When driven, the cooling fan causes a flow of cooling air which passes through the radiator, thereby cooling engine cooling water circulating between the engine and the radiator.
The radiator is constructed mainly of a top tank, a bottom tank, a plurality of tubes and fins.
The top tank and the bottom tank are coupled through the plurality of tubes arranged at predetermined intervals. Thus, the engine cooling water coming from the engine is once stored in the top tank, then passes through the plurality of tubes to be stored in the bottom tank, and is then returned to the engine.
The fins are each disposed between the adjacent tubes and joined to the tubes by joining means such as brazing.
As an example of the above-described fin, there is a corrugated fin having flat plate sections and joining sections that are alternately formed into a corrugated shape by bending (refer to, for example, patent documents 1, 2 and 3). The flat plate sections of such a corrugated fin each has a pair of lateral sides facing each other and a pair of end sides facing each other, while the joining sections each connect with the lateral sides of the flat plate sections.
The corrugated fin is manufactured, for example, by undergoing a grooving process and a corrugating process.
The grooving process is a process of forming a plurality of grooves on a surface of a bandlike sheet by passing the bandlike sheet uncoiled from a sheet coil between a pair of grooving rollers or by press working using a press machine.
In the corrugating process, the bandlike sheet which has undergone the grooving process is passed through a pair of corrugating rollers for bending, whereby the flat plate sections and the joining sections form a corrugated shape in an alternating sequence.
Examples of the grooves formed in the bandlike sheet in the grooving process include grooves extending in a direction in which the pair of lateral sides of the flat plate section are arranged and grooves extending in a direction in which the pair of end sides of the flat plate section are arranged.
Providing the flat plate section with the grooves extending in the direction in which the pair of lateral sides are arranged can increase a section modulus of a section taken along the direction in which the pair of end sides are arranged. Accordingly, the flat plate section can have increased rigidity with respect to such a bending action as to bring the pair of lateral sides close to each other. However, in this case, a section taken along the direction in which the pair of lateral sides are arranged cannot have an increased section modulus, so that the flat plate section cannot have increased rigidity with respect to such a bending action as to bring the pair of end sides close to each other.
Providing the flat plate section with the grooves extending in the direction in which the pair of end sides are arranged can increase a section modulus of a section taken along the direction in which the pair of lateral sides are arranged. Accordingly, the flat plate section can have increased rigidity with respect to such the bending action as to bring the pair of end sides close to each other. However, in this case, a section taken along the direction in which the pair of end sides are arranged cannot have an increased section modulus, so that the flat plate section cannot have increased rigidity with respect to such the bending action as to bring the pair of lateral sides close to each other.
Therefore, during the production of the conventional corrugated fins or, more specifically, in the corrugating process, bending can possibly occur at an unexpected place, thereby problematically increasing a dimensional error.
For this reason, the dimensional errors of the corrugated fins accumulate when a radiator core is assembled by alternately stacking the corrugated fins and the tubes, which in turn may warp the radiator core, leaving a problem that product accuracy is difficult to improve. Correcting the dimensional error of the corrugated fin requires extra time and effort, while assembling such that the dimensional errors of the corrugated fins offset one another requires a high skill. In any case, the production problematically becomes difficult.
In view of the problems mentioned above, the present invention aims to provide a corrugated fin capable of reliably preventing bending at an unexpected place during production, thereby improving product accuracy and facilitating the production. The invention also aims to provide a heat exchanger including this corrugated fin.
To achieve the above object, a corrugated fin for a heat exchanger according to a first aspect of the present invention comprises a flat plate section and a joining section which are alternately formed into a corrugated shape by bending, said flat plate section having a pair of lateral sides facing each other and a pair of end sides facing each other, said joining section connecting with a lateral side of the pair of lateral sides of the flat plate section,
wherein said joining section has an even surface joined to a tube through which a heat exchange medium is circulated and
wherein said flat plate section has at least one recess or protrusion in an arbitrary section taken in two directions, the two directions being a direction in which the pair of lateral sides are arranged and a direction in which the pair of end sides are arranged.
According to a second aspect of the invention that is based on the first aspect, it is preferable that the even surface of the joining section is formed into a plane surface.
According to a third aspect of the invention that is based on the first aspect, it is preferable that the even surface of the joining section is formed into a curved surface.
According to a fourth aspect of the invention that is based on the first, second or third aspect, it is preferable that two or more recesses or protrusions are provided.
A heat exchanger according to a fifth aspect of the invention includes the corrugated fin of the first, second, third or fourth aspect.
In the corrugated fin of the first aspect of the invention, the flat plate section is provided with at least one recess or protrusion in the arbitrary section taken in the two directions, that is, the direction in which the pair of lateral sides are arranged and the direction in which the pair of end sides are arranged. Accordingly, the section taken along the direction in which the pair of end sides are arranged and the section taken along the direction in which the pair of lateral sides are arranged can have increased section moduli, respectively. For this reason, the flat plate section can have increased rigidity with respect to such a bending action as to bring the pair of lateral sides close to each other as well as with respect to such a bending action as to bring the pair of end sides close to each other.
The joining section is not provided with any recess or protrusion such as provided in the flat plate section. This allows a large difference in rigidity between the flat plate section and the joining section, thus enabling easy and reliable bending at a boundary between the flat plate section and the joining section.
In the corrugated fin of the first aspect of the invention, bending at an unexpected place can be prevented without fail during production of the corrugated fin, whereby the corrugated fin can have a reduced dimensional error.
Adopting the structure of the second aspect of the invention can increase an area joined to the tube and a thermal contact area, thus allowing stronger joining between the corrugated fin and the tube and enhancing a heat dissipation effect of the corrugated fin.
Adopting the structure of the third aspect of the invention can avoid stress concentration on a bent part.
Adopting the structure of the fourth aspect of the invention can further increase the rigidity of the flat plate section without fail and allows easier and more reliable bending at the boundary between the flat plate section and the joining section.
The heat exchanger of the fifth aspect of the invention has increased product accuracy and is thus easy to produce.
Concrete exemplary embodiments of a corrugated fin and a heat exchanger including the corrugated fin according to the present invention are demonstrated hereinafter with reference to the accompanying drawings. The following description is provided of an example in which the invention is applied to a radiator installed in an engine room of a work vehicle such as a hydraulic excavator or a bulldozer. However, it goes without saying that the invention is applicable to heat exchangers having the same basic structure as the radiator, such as an oil cooler and an after-cooler.
(Description of a Schematic Structure of the Radiator)
Radiator 1 shown in
This radiator 1 is constructed mainly of top tank 2, bottom tank 3, tubes 4 and corrugated fins 5.
Top tank 2 and bottom tank 3 are coupled through the plurality of tubes 4, thus allowing the engine cooling water coming from the engine to be once stored in top tank 2, then pass through the plurality of tubes 4 to be stored in bottom tank 3 and be returned to the engine thereafter.
Tubes 4 and corrugated fins 5 are alternately stacked to form radiator core 6.
(Description of the Tubes)
As shown in
The plurality of tubes 4 are arranged at predetermined pitch Pa along width direction RW of radiator 1 and at predetermined spacing S along depth direction RD of radiator 1.
(Brief Description of the Corrugated Fin)
Corrugated fin 5 is disposed between tubes 4 which are adjacent in width direction RW of radiator 1. Corrugated fin 5 has flat plate sections 5a and joining sections 5b that are alternately formed into a corrugated shape by bending.
(Brief Description of the Flat Plate Section)
Each flat plate section 5a is a rectangular plate section having a pair of lateral sides 11, 11′ facing each other in width direction RW of radiator 1 and a pair of end sides 12, 12′ facing each other in depth direction RD of radiator 1.
(Description of Groove-Shaped Recesses of the Flat Plate Section)
As shown in
Groove-shaped recesses 13 extend linearly in a direction from end side 12 toward end side 12′ while slanting in a direction from lateral side 11 toward lateral side 11′.
Pitch Pb for arranging groove-shaped recesses 13, an angle of inclination, length and width of each groove-shaped recess 13 and others are determined so that adjacent groove-shaped recesses 13 partly overlap each other when viewed in direction FW in which the pair of lateral sides 11, 11′ are arranged.
Providing the plurality of groove-shaped recesses 13 on the surface of flat plate section 5a causes a part between adjacent groove-shaped recesses 13 to become relatively stripe-shaped protrusion 14. In addition, providing groove-shaped recesses 13 on the surface of flat plate section 5a results in formation of corresponding stripe-shaped protrusions 15 (see
(Description of Recesses and Protrusions of the Flat Plate Section in Arbitrary Sections)
As shown in
As shown in
(Brief Description of the Joining Section)
As shown in
Conceptually, this even surface 20 has two implications, one of which is that surface 20 is a completely even surface free of undulation and the other of which is that surface 20 is a substantially even surface having, compared with groove-shaped recesses 13, extremely negligible shallow grooves (grooved remnants) which are formed inevitably when a grooving process is carried out to form groove-shaped recesses 13 in flat plate section 5a.
(Description of Joining Between the Corrugated Fin and the Tube)
Corrugated fin 5 and tube 4 are joined together by brazing using brazing filler metal 22 interposed between even surface 20 of joining section 5b and surface 21 of tube 4.
Because of being plane, even surface 20 of joining section 5b can have a larger area joined to tube 4 and a larger thermal contact area compared to cases where even surface 20 is a curved surface or an angular surface.
Obtaining the larger joining area between even surface 20 of joining section 5b and surface 21 of tube 4 enables stronger joining between corrugated fin 5 and tube 4.
Obtaining the larger thermal contact area between even surface 20 of joining section 5b and surface 21 of tube 4 enables efficient conduction of the heat of the engine cooling water, which flows through tube 4, from tube 4 to corrugated fin 5, thereby enhancing a heat dissipation effect of corrugated fin 5.
(Description of a Method of Manufacturing the Corrugated Fin)
A description is provided next of the method of manufacturing corrugated fin 5 with reference to
The manufacturing method of corrugated fin 5 includes the grooving process and a corrugating process.
(Description of the Grooving Process)
The grooving process is a process of forming the plurality of groove-shaped recesses 13 on a surface of bandlike sheet 30a, a corrugated fin material, by passing bandlike sheet 30a uncoiled from sheet coil 30 between a pair of first rollers 31, 31′.
The pair of first rollers 31, 31′ have a plurality of recesses and protrusions (not shown) on their outer peripheral surfaces to correspond to the plurality of groove-shaped recesses 13 to be formed in bandlike sheet 30a. As first rollers 31, 31′ are rotated in respective directions of arrows in the drawing, bandlike sheet 30a is sandwiched between these rollers 31, 31′ and then sent downstream. Here, the plurality of groove-shaped recesses 13 are formed on the surface of bandlike sheet 30a as a result of bandlike sheet 30a being sandwiched between the recesses of first roller 31 on one side and the protrusions of first roller 31′ on the other side.
It is to be noted that similar groove-shaped recesses 13 can be formed on the surface of bandlike sheet 30a by press working using a press machine.
(Description of the Corrugating Process)
The corrugating process is a bending process in which bandlike sheet 30a coming out from between the pair of first rollers 31, 31′ is passed through a pair of second rollers 32, 32′ disposed downstream of first rollers 31, 31′, whereby flat plate sections 5a and joining sections 5b form the corrugated shape in an alternating sequence.
The pair of second rollers 32, 32′ have a plurality of teeth (not shown) on their outer peripheral surfaces for bending bandlike sheet 30a, which has groove-shaped recesses 13 formed on its surface, into the corrugated shape. The teeth of roller 32 and the teeth of roller 32′ are formed to mesh together. As second rollers 32, 32′ are rotated in respective directions of arrows in the drawing, bandlike sheet 30a is sandwiched between these rollers 32, 32′ and then sent downstream. Here, bandlike sheet 30a is bent into the corrugated shape as a result of being sandwiched between a space between the teeth of second roller 32 and the tooth of second roller 32′.
As shown in
In this embodiment, even surface 20 is plane as shown in
Corrugated fin 5 which has undergone the corrugating process is thus sandwiched between adjacent tubes 4 and joined to those tubes 4 by brazing.
(Description of Effects of the First Embodiment)
In corrugated fin 5 of the first embodiment, flat plate section 5a is provided with, as shown in
Joining section 5b is not provided with recess 16 defined by groove-shaped recess 13 or protrusions 17, 18 defined by respective stripe-shaped protrusions 14, 15 such as provided at flat plate section 5a. This allows a large difference in rigidity between flat plate section 5a and joining section 5b, thus enabling easy and reliable bending at a boundary between flat plate section 5a and joining section 5b.
Consequently, bending at an unexpected place can be prevented without fail during the production of corrugated fin 5 or, more specifically, in the corrugating process, thus reducing a dimensional error of corrugated fin 5.
Radiator core 6 of radiator 1 of the first embodiment is assembled by alternately stacking tubes 4 and corrugated fins 5. Because the dimensional error of each corrugated fin 5 can be reduced, radiator core 6 does not warp, thereby increasing product accuracy. Moreover, no correction of the dimensional error of corrugated fin 5 and no high skill for offsetting the dimensional errors against one another are required, thus facilitating the production.
(Description of Variations of the First Embodiment)
Corrugated fin 5 of the first embodiment has, at its flat plate section 5a, at least one recess 16 defined by groove-shaped recess 13 in the arbitrary section taken along each of the two directions, that is, direction FW in which the pair of lateral sides 11, 11′ are arranged and direction FD in which the pair of end sides 12, 12′ are arranged. Appropriate variations can be made on this structure without departing from the spirit of this structure.
For example, groove-shaped recess 13 can be replaced by groove-shaped recess 13A having a greater groove width than recess 13 as shown in
As shown in
As shown in
As shown in
As shown in
While groove-shaped recesses 13 extend linearly in the direction from end side 12 of flat plate section 5a toward end side 12′, slanting in the direction from lateral side 11 toward lateral side 11′, groove-shaped recesses 13C shown in
Hereinafter, descriptions of corrugated fins 5A to 5G in accordance with the respective second through eighth exemplary embodiments of the present invention are provided one by one. In the following embodiments, elements similar to those in the first embodiment have the same reference marks in drawings, the detailed descriptions of those elements are omitted, and emphasis is placed on different features not seen in the first embodiment.
(Description of Groove-Shaped Recesses of a Flat Plate Section Shown in
As shown in
Each groove-shaped recess 40 is formed of first groove-shaped recess 40a and second groove-shaped recess 40b, and in the plan view with end side 12′ of flat plate section 5a being above the other end side 12, first and second groove-shaped recesses 40a, 40b connect in a V shape.
Starting from a middle point of direction FW in which a pair of lateral sides 11, 11′ of flat plate section 5a are arranged, first groove-shaped recess 40a extends linearly in a direction from end side 12 toward end side 12′ while slanting in a direction from lateral side 11 toward lateral side 11′.
Starting from the middle point of direction FW in which lateral sides 11, 11′ of flat plate section 5a are arranged, second groove-shaped recess 40b extends linearly in the direction from end side 12 toward end side 12′ while slanting in a direction from lateral side 11′ toward lateral side 11.
(Description of Recesses and Protrusions of the Flat Plate Section in Arbitrary Sections Shown in
As shown in
As shown in
(Description of Groove-Shaped Recesses of a Flat Plate Section Shown in
As shown in
Groove-shaped recesses 46 are recesses each bent into an arc shape, bulging toward end side 12 between lateral sides 11, 11′.
(Description of Recesses and Protrusions of the Flat Plate Section in Arbitrary Sections Shown in
As shown in
As shown in
(Description of Groove-Shaped Recesses of a Flat Plate Section Shown in
As shown in
Each groove-shaped recess 52 is formed of first groove-shaped recess 52a, second groove-shaped recess 52b, third groove-shaped recess 52c and fourth groove-shaped recess 52d, and in the plan view with end side 12′ of flat plate section 5a being above the other end side 12, those first through fourth groove-shaped recesses 52a, 52b, 52c, 52d connect in a W shape.
Starting from a point located in the middle between lateral side 11′ and a middle point of direction FW in which lateral sides 11, 11′ of flat plate section 5a are arranged, first groove-shaped recess 52a extends linearly in a direction from end side 12 toward end side 12′ while slanting in a direction from lateral side 11 toward lateral side 11′.
Starting from the point located in the middle between lateral side 11′ and the middle point of direction FW in which lateral sides 11, 11′ of flat plate section 5a are arranged, second groove-shaped recess 52b extends linearly in the direction from end side 12 toward end side 12′ while slanting in a direction from lateral side 11′ toward lateral side 11.
Starting from a point located in the middle between lateral side 11 and the middle point of direction FW in which lateral sides 11, 11′ of flat plate section 5a are arranged, third groove-shaped recess 52c extends linearly in the direction from end side 12 toward end side 12′ while slanting in the direction from lateral side 11 toward lateral side 11′.
Starting from the point located in the middle between lateral side 11 and the middle point of direction FW in which lateral sides 11, 11′ of flat plate section 5a are arranged, fourth groove-shaped recess 52d extends linearly in the direction from end side 12 toward end side 12′ while slanting in the direction from lateral side 11′ toward lateral side 11.
(Description of Recesses and Protrusions of the Flat Plate Section in Arbitrary Sections Shown in
As shown in
As shown in
(Description of Groove-Shaped Recesses of a Flat Plate Section Shown in
As shown in
Each groove-shaped recess 58 is formed of first groove-shaped recess 58a, second groove-shaped recess 58b, third groove-shaped recess 58c and fourth groove-shaped recess 58d, and in the plan view with lateral side 11′ of flat plate section 5a being above the other lateral side 11, those first through fourth groove-shaped recesses 58a, 58b, 58c, 58d connect in an M shape.
Starting from a point located in the middle between end side 12 and a middle point of direction FD in which a pair of end sides 12, 12′ of flat plate section 5a are arranged, first groove-shaped recess 58a extends linearly in a direction from end side 12′ toward end side 12 while slanting in a direction from lateral side 11′ toward lateral side 11.
Starting from the point located in the middle between end side 12 and the middle point of direction FD in which end sides 12, 12′ of flat plate section 5a are arranged, second groove-shaped recess 58b extends linearly in a direction from end side 12 toward end side 12′ while slanting in the direction from lateral side 11′ toward lateral side 11.
Starting from a point located in the middle between end side 12′ and the middle point of direction FD in which lateral sides 12, 12′ of flat plate section 5a are arranged, third groove-shaped recess 58c extends linearly in the direction from end side 12′ toward end side 12 while slanting in the direction from lateral side 11′ toward lateral side 11.
Starting from the point located in the middle between end side 12′ and the middle point of direction FD in which lateral sides 12, 12′ of flat plate section 5a are arranged, fourth groove-shaped recess 58d extends linearly in the direction from end side 12 toward end side 12′ while slanting in the direction from lateral side 11′ toward lateral side 11.
(Description of Recesses and Protrusions of the Flat Plate Section in Arbitrary Sections Shown in
As shown in
As shown in
(Description of Groove-Shaped Recesses of a Flat Plate Section Shown in
As shown in
Each first groove-shaped recess 64 extends linearly in a direction from end side 12 toward end side 12′ while slanting in a direction from lateral side 11 toward lateral side 11′.
Each second groove-shaped recess 65 extends linearly in the direction from end side 12 toward end side 12′ while slanting in a direction from lateral side 11′ toward lateral side 11.
First groove-shaped recesses 64 cross second groove-shaped recesses 65, thus forming a mesh-like pattern as a whole.
(Description of Recesses and Protrusions of the Flat Plate Section in Arbitrary Sections Shown in
As shown in
As shown in
(Description of Groove-Shaped Recesses of a Flat Plate Section Shown in
As shown in
First groove-shaped recess 71 extends linearly between a corner where lateral side 11 and end side 12′ meet and a corner where lateral side 11′ and end side 12 meet.
Second groove-shaped recess 72 extends linearly between a corner where lateral side 11 and end side 12 meet and a corner where lateral side 11′ and end side 12′ meet.
First groove-shaped recess 71 and second groove-shaped recess 72 cross each other, thus forming an X shape.
(Description of Recesses and Protrusions of the Flat Plate Section in Arbitrary Sections Shown in
As shown in
As shown in
(Description of Hemispheric Recesses of a Flat Plate Section Shown in
As shown in
Pitch Pk for arranging hemispheric recesses 79, a diameter of each hemispheric recess 79 and others are determined so that hemispheric recesses 79 adjacent in direction FD in which end sides 12, 12′ are arranged partly overlap each other when viewed in direction FW in which lateral sides 11, 11′ are arranged.
Pitch Pm for arranging hemispheric recesses 79, the diameter of each hemispheric recess 79 and others are determined so that hemispheric recesses 79 adjacent in direction FW in which lateral sides 11, 11′ are arranged partly overlap each other when viewed in direction FD in which end sides 12, 12′ are arranged.
(Description of Recesses and Protrusions of the Flat Plate Section in Arbitrary Sections Shown in
As shown in
As shown in
(Description of Effects of the Second through Eighth Embodiments)
Even in each of corrugated fins 5A, 5B, 5C, 5D, 5E, 5F, 5G of the second through eighth embodiments, flat plate section 5a is provided with at least one recess 41, 47, 53, 59, 66, 73 or 74 defined by groove-shaped recess 40, 46, 52, 58, 64, 65, 71 or 72 or at least one protrusion 44, 45, 50,51, 56, 57, 62, 63, 69, 70, 77 or 78 defined by stripe-shaped protrusion 42, 43, 48, 49, 54, 55, 60, 61, 67, 68, 75 or 76, or at least one recess 80 defined by hemispheric recess 79 or at least one protrusion 82 defined by hemispheric protrusion 81 in the arbitrary section taken along each of the two directions, that is, direction FW in which the pair of lateral sides 11, 11′ are arranged and direction FD in which the pair of end sides 12, 12′ are arranged. This can increase a section modulus of the section taken along direction FD in which end sides 12, 12′ are arranged as well as a section modulus of the section taken along direction FW in which lateral sides 11, 11′ are arranged. Therefore, corrugated fins 5A to 5G of the second through eighth embodiments can provide the same effects as corrugated fin 5 of the first embodiment. Similarly to radiator 1 of the first embodiment, radiators including such respective corrugated fins 5A to 5G have increased product accuracy, thus facilitating their production.
The embodiments and variations of the corrugated fin and the heat exchanger including the corrugated fin according to the present invention have been described above. However, the present invention is not limited to the structures described in the above embodiments and variations and allows appropriate variations on each of the structures without departing from the spirit of the invention, such as, appropriately combining the structures of the above-described embodiments and variations.
A corrugated fin and a heat exchanger including the corrugated fin according to the present invention have the characteristic of being capable of reliably preventing bending at an unexpected place during production, thereby improving product accuracy and facilitating the production, and therefore, are suitable for use in and as a radiator, an oil cooler, an after-cooler or the like.
Number | Date | Country | Kind |
---|---|---|---|
2010-040282 | Feb 2010 | JP | national |
The present application is a U.S. Continuation application of U.S. application Ser. No. 13/580,342, filed Aug. 21, 2012, which is a U.S. National Phase application of International Application No. PCT/JP2011/053840, filed Feb. 22, 2011, which claims priority from Japanese Application No. 2010-040282, filed Feb. 25, 2010, all of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | 13580342 | Aug 2012 | US |
Child | 15216299 | US |