1. Field of the Invention
The present invention relates to an oil cooler that is contained in a radiator tank and used for a motor vehicle or the like.
2. Description of the Related Art
A conventional oil cooler contained in a radiator tank is disclosed in Japanese patents laying-open publication No. 2001-272195, No. 2002-195783, and No. (Tokkaihei) 11-211378, and Japanese Patent No. 3245739. The oil cooler is provided with a heat exchange part for cooling oil flowing therethrough, two connecting pipes each for connecting a top portion of a communicating passage of the heat exchange part and a vehicle-side device, and two patch plates each for fluidically plugging a bottom portion of the communicating passage.
The heat exchange part includes a plurality of elements, each of which has coupled shell members containing an inner fin and are piled up. The two communicating passages are formed vertically at the both side portions of the elements so as to fluidically communicate interior portions of the elements with each other.
The top portions of the communicating passages are fluidically connected with the connecting pipes, respectively, by using a cylindrical pipe connector which is inserted into a pipe connecting hole formed on the radiator tank. In general, the connecting pipes are screwed together with the pipe connecters with a seal member arranged therebetween.
This conventional oil cooler, however, encounters the following problems in production management, causing high manufacturing costs and others. Specifically, it takes some trouble with tightening torque management when screwing a nut to the pipe connecter to fix the connecting pipe, and seal-member extrusion-or-intrusion preventing management. In addition, various diameter types of pipe connectors are required so as to fit different diameters of the connecting pipes, which increases its design and manufacturing costs. Further, the heat exchange part and the radiator tank are fixed with each other by using an additional member, which also increases the number of parts and increases the manufacturing costs because of necessity for high accurate temporary assembly of the pipe connectors, the heat exchange part, and the radiator tank in order to avoid bad brazing and oil leak.
On the other hand, the bottom portions of the communicating passages are plugged by using the patch plates.
Referring to
Referring to
However, the oil cooler of the former requires the seat member S in order to firmly fix the patch plate 013 to the undermost element 05b by brazing, which increases the number of parts and its manufacturing process and costs. The oil cooler of the latter requires different shaped elements, increasing the number of parts and its manufacturing process and costs.
It is, therefore, an object of the present invention to provide an oil cooler which overcomes the foregoing drawbacks and can decrease the number of parts and its manufacturing process and costs.
According to a first aspect of the present invention there is provided an oil cooler contained in a radiator tank, the oil cooler comprising a connecting pipe having an enlarged diameter portion, a heat exchange part having a plurality of elements which are piled up and flow oil through interior portions thereof, and a pipe connector. The elements are formed with a communicating passage for fluidically communicating with the interior portions of the elements. The pipe connector formed with a first retaining portion that is seated on one side of a wall portion of the radiator tank to contain and fix at least a part of the enlarged diameter portion of the connecting pipe by caulking, and a second retaining portion that is inserted through a through-hole of the wall portion and an one end portion of the communicating passage to fix the heat exchanger part and the wall portion at the other side of the wall portion by caulking.
Therefore, the number of parts of the oil cooler and its manufacturing costs can be decreased.
Preferably, the first retaining portion is a large-diameter cylindrical portion having notches, and the second retaining portion is a small-diameter cylindrical portion.
Therefore, the pipe connector can be easily formed and caulked.
Preferably, the small-diameter cylindrical portion is formed smaller in thickness than the large-diameter cylindrical portion.
Therefore, the through-hole of the wall portion can be set small in diameter, ensuring a high stiffness of the wall portion.
Preferably, the elements include an upper shell member having a cylindrical portion projecting outwardly and a lower shell member having a cylindrical portion projecting outwardly and having an outer diameter smaller than an inner diameter of the cylindrical portion of the upper shell member, the cylindrical portion of the lower shell member is fixed by caulking to the cylindrical portion of the upper shell portion of an adjacent element thereof to form the communicating passage by the cylindrical portions of the upper and lower shell members.
Therefore, the heat exchange part can be manufactured at low costs.
Preferably, the communicating passage is fluidically plugged at the other end portion thereof by a patch plate having a seat portion contactable to an outer surface of the lower shell member, a cylindrical portion for fixing the lower shell member of an outermost element by caulking, and an annular groove formed between the seat portion and the cylindrical portion to receive the cylindrical portion of the lower shell member of the outermost element.
Therefore, the other end portion of the communicating passage can be easily and surely plugged, and all the elements can be set to have the same shapes and constructions, decreasing the manufacturing process and costs.
Preferably, the cylindrical portion of the patch plate is formed to have a thickness that becomes smaller with a height thereof.
Therefore, the cylindrical portion of the patch plate can be easily caulked.
According to a second aspect of the present invention there is provided an oil cooler contained in a radiator tank, the oil cooler comprising a 5 connecting pipe having an enlarged diameter portion, a heat exchange part having a plurality of elements which are piled up and flow oil through interior portions thereof, and a patch plate. The elements includes an upper shell member having a cylindrical portion projecting outwardly and a lower shell member having a cylindrical portion projecting outwardly and having an outer diameter smaller than an inner diameter of the cylindrical portion of the upper shell member, the cylindrical portion of the lower shell member is fixed by caulking to the cylindrical portion of the upper shell portion of an adjacent element thereof to form the communicating passage by the cylindrical portions of the upper and lower shell members. The patch plate has a seat portion contactable to an outer surface of the lower shell member, a cylindrical portion for fixing the lower shell member of an outermost element by caulking, and an annular groove formed between the seat portion and the cylindrical portion to receive the cylindrical portion of the lower shell member of the outermost element so as to fluidically plug an end portion of the communicating passage.
Therefore, the end portion of the communicating passage can be easily plugged by the patch plate, using the same shaped elements. This can decrease its manufacturing process and costs.
Preferably, all parts of the oil cooler and the wall portion of the radiator tank are made of aluminum and blazed.
Therefore, its manufacturing process and costs can be decreased.
The objects, features and advantages of the present invention will become apparent as the description proceeds when taken in conjunction with the accompanying drawings, in which:
Throughout the following detailed description, similar reference characters and numbers refer to similar elements in all figures of the drawings, and their descriptions are omitted for eliminating duplication.
Referring to FIGS. 1 to 3, there is shown an oil cooler OC of an embodiment according to the present invention.
The oil cooler OC is used for cooling oil of an automatic transmission mounted on a motor vehicle for example, and arranged in a lower radiator tank of a not-shown radiator, so that radiator coolant flows around the oil cooler OC to draw heat from the oil after the radiator coolant is cooled by a radiator core of the radiator.
The oil cooler OC includes a heat exchange part 1 having a plurality of elements 5a, 5 and 5b fluidically connected by left and right communicating passages R1 formed at their left and right portions, two connecting pipes 2 each for connecting a top portion of the communicating passage R1 and a vehicle-side device, and two patch plates 13 and 13 each for fluidically plugging a bottom portion of the communicating passages R1.
The heat exchange part 1 has the five elements, consisting of an uppermost element 5a, three intermediate elements 5 and an undermost element 5b, and annular seat members S1 each arranged between the adjacent elements 5a and 5, 5 and 5 and 5 and 5b. Specifically, the elements 5a, 5 and 5b and the seat members S1 are alternatively piled up so that the coolant can pass through gaps formed between the adjacent elements 5a and 5, 5 and 5, and 5 and 5b so as to exchange heat between the oil and the radiator coolant.
The elements 5a, 5 and 5b have each an upper shell member 6 and a lower shell member 7 which are coupled with each other to contain an inner fin 8.
As shown in
A right communicating passage is formed at the right end portions of the elements 5a, 5 and 5b by right cylindrical portions of the upper and lower shell members 6 and 7 similarly to and in symmetrical with respect to the left communicating passage R1, although they are not shown in the accompanying drawings. The left and right communicating passage R1 correspond to a communicating passage of the present invention. Between the left and right communicating passages R1, the upper and lower shell members 6 and 7 are provided with a plurality of protrusions 9 projecting in the upside and downside directions, respectively, along their longitudinal direction. The protrusions 9 of the adjacent upper and lower shell members 6 and 7 are contactable with each other to have a total vertical height having the same thickness as that of the seat member S1 so as to keep the space between the adjacent elements 5a and 5, 5 and 5, and 5 and 5b.
The upper and lower shell members 6 and 7 are also provided with a plurality of dimpled grooves 10 on their inner surfaces along the longitudinal direction in order to suppress deformation of the elements 5a, 5 and 5b in a brazing process of the oil cooler OC.
As shown in
On the uppermost element 5a, the connecting pipes 2 and an top wall portion 3 of the lower radiator tank are fixed by using a connecting member 11, a seat plate 12 and a pipe connector 4 so that the connecting pipes 2 can be fluidically communicated with the top portions of the left and right communicating passages R1, respectively. The top wall portion 3 corresponds to a wall portion of the present invention, and the lower radiator tank corresponds to a radiator tank of the present invention.
On the other hand, on the lowermost element 5b, the patch plates 13b are fixed to fluidically plug the bottom portions of the left and right communicating passages R1, respectively.
As shown in
As shown in
An inner diameter of the large-diameter cylindrical portion 4a is set larger than an outer diameter of an enlarged diameter portion 2a formed at a lower portion of the connecting pipe 2, so that the large-diameter cylindrical portion 4a can partially embrace and fix the enlarged diameter portion 2a by inwardly caulking the large-diameter cylindrical portion 4a. An outer diameter of the small-diameter cylindrical portion 4b is set smaller than a diameter of a through-hole 3a of the top wall portion 3 of the lower radiator tank and a hole-diameter of the upper annular portion 12a of the seat plate 12 so that the small-diameter cylindrical portion 4b and the annular portion 4d of the pipe connector 4 can clamp and fix the top wall portion 3 and the upper annular portion 12a by outwardly caulking the small-diameter cylindrical portion 4b. Incidentally, the annular portion 4d is set larger in diameter than the through-hole 3a and smaller in thickness than the large-diameter cylindrical portion 4a so as to decrease the diameter of the through-hole 3a formed on the top wall portion 3 for ensuring its high stiffness.
The large-diameter cylindrical portion 4a of the pipe connector 4 corresponds to a first retaining portion of the present invention, and the small-diameter cylindrical portion 4b corresponds to a second retaining portion of the present invention.
As shown in FIGS. 10 to 12, the patch plate 13 to be fixed to the lowermost element 5b has a disc portion 13d, a large-diameter annular portion 13a projecting outwardly in its radial direction from a lower outer periphery of the disc portion 13d, and a small-diameter annular portion 13b projecting upwardly from an upper outer periphery of the disc portion 13d. An annular groove 13c is formed between the large-diameter annular portion 13a and the small-diameter annular portion 13b so that it can receive the cylindrical portion 7a of the lower shell member 7 of the lowermost element 5b. The small-diameter annular portion 13b is formed as a tapered sectional shape having a height higher than that of the large-diameter annular portion 13a and a thickness which becomes smaller with its height.
The large-diameter annular portion 13a corresponds to a seat portion of the present invention, and the small-diameter annular portion 13b corresponds to a cylindrical portion of the present invention.
All parts of the oil cooler OC of the embodiment and the top wall portion 3 of the lower radiator tank are made of aluminum.
The oil cooler OC is assembled as follows.
First, the oil cooler OC is temporarily assembled. Specifically, as shown in
These elements, five elements 5a, 5 and 5b in this embodiment, and the seat members S1 are alternately piled up with each other to form the heat exchange part 1 of the oil cooler OC.
Next, as shown in
Then, as shown in
Then, the projections 11b of the connecting members 11 are inwardly caulked to clamp the lower annular portion 12a of the seat plate 12, and its cylindrical portions 11a are outwardly caulked to be fixed to the inner peripheries of the cylindrical portion 6a formed on the upper shell portion 6 of the uppermost element 5a of the heat exchange part 1.
The heat exchange part 1 including the seat plate 12 is brought, as indicated by a downward large arrow in
On the other hand, the pipe connector 4 is brought, as indicated by an upward large arrow in
Then, as shown in
In addition, as shown in
Thus-temporarily-assembled oil cooler OC is located into a not-shown heating furnace, where it is heated so that its parts to be connected with each other are joined by brazing. Incidentally, in this brazing, at least one side of contacted portions of the parts may be coated by blazing filler metal after the oil cooler OC is temporarily assembled.
Next, as shown in
The operation of the oil cooler OC will be described.
The radiator coolant in the radiator flows through tubes of the radiator core to be cooled. Then, the radiator coolant flows through the tubes into the lower radiator tank 15, where it draws heat from the oil in the heat exchange part 1 through the upper and lower shell members 6 and 7 and the inner fin 8 while the oil passes through the elements 5a, 5 and 5b and the communicating passages R1. The cooled radiator coolant goes to the engine, and the cooled oil goes to the automatic transmission.
The oil cooler OC of the embodiment has the following advantages.
The oil cooler has the connecting pipe 2 with the enlarged diameter portion 2a and the pipe connector 4 with the large-diameter cylindrical portion 4a and the small diameter cylindrical portion 4b, where the large-diameter cylindrical portion 4a contains at least a part of the enlarged diameter portion 2a and is caulked thereon to fix each other, and the small diameter cylindrical portion 4b is caulked on the top wall portion 3 of the lower radiator tank 15 to fix each other. This enables the connecting pipes 2 having different diameters to be easily connected with the heat exchange part 1 of the oil cooler OC and the top wall portion 3 of the lower radiator tank 15 without an additional member. This can decrease its manufacturing process and costs.
The oil cooler OC has the elements 5a, 5 and 5b with the communicating passages R1 whose bottom portions are closed by the patch plates 13. The elements 5 and 5b include the upper shell member 6 and the lower shell member 7 fixed with the upper shell member 7 by caulking. The patch plates 13 are formed with the large-diameter annular portion 13a contactable with the outer surface of the lower shell member 7 of the lowermost element 5b, the annular groove 13c receiving its cylindrical portion 7a, and the small-diameter annular portion 13b caulked to be fixed to the heat exchange part 1. Therefore, all the elements 5a, 5 and 5b can be formed in the same shapes, and the patch plate 13 can be easily fixed to the lowermost element 5b. This decreases its manufacturing process and costs.
All parts of the oil cooler OC and the top wall portion 3 are made of aluminum, and their temporarily assembly is blazed, thereby eliminating a post-process for fixing the connecting pipe 2 to the heat exchange part 1. This can also decrease its manufacturing process and cost.
The pipe connector 4 has no screw, which can prevent deformation and/or pinching of the seat plate 12.
While there have been particularly shown and described with reference to preferred embodiments thereof, it will be understood that various modifications may be made therein, and it is intended to cover in the appended claims all such modifications as fall within the true spirit and scope of the invention.
The number of the elements may be set arbitrarily according to a demand for coolability of an oil cooler.
The pipe connector 4 and the connecting pipe 2 may be fixed with a seat plate between them, but it is not necessary.
The caulking process of the elements 5a, 5 and 5b may be separated from that of the patch plates 13 and the lowermost element 5b, where a different tool may be used for caulking.
Blazing of the heat exchange part 1, the top wall portion 3 and the connecting pipe 2 and blazing of the top wall portion 3 and the boxy wall portion 14 may be implemented at the same time.
The oil cooler OC may be arranged in any type of radiator as long as it can be cooled by its coolant. For example, although the oil cooler OC is arranged in the lower radiator tank, it may be arranged in an upper radiator tank in a radiator in which the radiator coolant flows through the lower radiator tank toward the upper radiator tank.
The oil cooler OC is not limited for an automatic transmission, and may be used for other device.
The entire contents of Japanese Patent Applications No. 2005-0180174 filed Jun. 21, 2005 and No. 2005-180173 filed Jun. 21, 2005 are incorporated herein by reference.
Number | Date | Country | Kind |
---|---|---|---|
2005-180173 | Jun 2005 | JP | national |
2005-180174 | Jun 2005 | JP | national |