KR100768590B1 - Water-cooled oil cooler - Google Patents

Abstract

A water cooled oil cooler is provided to improve the durability by reducing corrosion of a cooling water discharge opening bonding bead section with preventing the rotation between the cooling water flow side plate and the oil flow side plate. A water cooled oil cooler includes a cooling water flow side plate and an oil flow side plate(400). The oil flow side plate is assembled in the cooling water flow side plate and is brazed to the cooling water flow side plate. A rotation preventing protrusion(100) and a rotation preventing recess(200) are formed in at least one of the cooling water flow side plate and the oil flow side plate. The rotation preventing protrusion and the rotation preventing recess are alternately disposed vertically when the oil flow side plate and the cooling water flow side plate are stacked and assembled.

Description

Water-cooled oil cooler {WATER-COOLED OIL COOLER}

Figure 1a is a cross-sectional view showing a cooling water outlet portion of the water-cooled oil cooler according to the prior art.

Figure 1b is a perspective view of the oil flow side plate of the water-cooled oil cooler according to the prior art.

Figure 2 is a perspective view of a water-cooled oil cooler according to the present invention.

Figure 3a is a combined perspective view of the oil flow side plate and the coolant flow side plate coupled to the water-cooled oil cooler according to the present invention.

Figure 3b is an exploded perspective view of the oil flow side plate and the coolant flow side plate of Figure 3a exploded.

4 is a cross-sectional view showing a cooling water outlet of the water-cooled oil cooler according to the present invention.

<Code Description of Main Parts of Drawing>

100: anti-rotation protrusion 200: anti-rotation groove

300: cooling water flow side plate 310: cooling water outlet

400: oil flow side plate 410: oil outlet

500: bonded bead

The present invention relates to a water-cooled oil cooler, which forms an anti-rotation groove and an anti-rotation protrusion fixed to the oil flow side plate and the cooling water flow side plate to prevent rotation between these parts, and the vertical height of the bonding bead portion of the cooling water outlet. It relates to a water-cooled oil cooler to limit the product to within 0.2 ~ 0.5mm to improve the product durability due to the corrosion of the bonding bead portion.

In general, the oil cooler cools the oil lubricating the power transmission system of the vehicle to prevent mechanical friction and abrasion due to a decrease in oil viscosity due to temperature rise. In particular, the water-cooled oil cooler is configured to increase the heat transfer efficiency between the two fluids by allowing the two fluids to flow through the flow path formed in the housing to increase the heat exchange efficiency between the cooling fluid (cooling water) and the fluid to be cooled (oil).

Hereinafter, a conventional water-cooled oil cooler will be described with reference to the accompanying drawings.

Figure 1a is a cross-sectional view showing a cooling water outlet portion of the water-cooled oil cooler according to the prior art, Figure 1b is a perspective view of the oil flow side plate of the water-cooled oil cooler.

As shown in FIGS. 1A and 1B, the conventional water-cooled oil cooler has an oil flowing on the oil flow side plate 10 in a state in which the oil flow side plate 10 and the coolant flow side plate 20 are alternately stacked. A line is formed, and a coolant line through which coolant flows is formed on the coolant flow side plate 20.

An oil inlet 10a and a cooling water outlet 20a are formed at the oil flow side plate 10 and the coolant flow side plate 20, respectively, and the oil outlet 10a and the coolant outlet 20a are respectively formed. At the edge portion, bending portions 10b and 20b are formed to which the oil flow side plate 20 and the coolant flow side plate 10 abut each other. The bending parts 10b and 20b are brazed by welding when the oil flow side plate 20 and the coolant flow side plate 10 are joined using clad materials.

The oil flow side plate 10 is formed with a plurality of dimples 11 of a shape recessed toward the coolant flow side plate 10 located below, and a heat radiation fin is disposed on the upper portion. On the contrary, the oil flow side plate 10 is directly disposed on the coolant flow side plate 20 without a heat radiation fin. Accordingly, the engine oil flowing through the oil line of the oil flow side plate 10 may be cooled by the coolant flowing through the coolant line of the coolant flow side plate 20 at the same time as heat is radiated by the heat radiation fins.

However, in the conventional oil cooler having such a configuration, when a plurality of cooling water flow side plates and oil flow side plates are alternately laminated and assembled, adjacent cooling water flow side plates and oil flow side plates are not properly secured and assembled between them. There was a problem that the product quality is degraded due to defects.

In addition, a bead is formed in the bending part which is conventionally brazed and joined to the oil flow side plate and the coolant flow side plate, and is formed by a flow of the coolant passing through the coolant inlet and outlet. In the bead), there may be a problem in which erosion may occur, and this erosion may cause serious leakage of the oil cooler.

SUMMARY OF THE INVENTION An object of the present invention is to solve the problems of the prior art described above, and to prevent rotation between the coolant flow side plate and the oil flow side plate assembled therein, and to reduce the occurrence of the erosion in the beads of the coolant outlet. To provide an oil cooler.

In order to achieve the above object, the present invention, in a water-cooled oil cooler, includes a coolant flow side plate and an oil flow side plate laminated and assembled to the coolant flow side plate, the oil flow side plate and the coolant flow At least one selected side plate is formed with an anti-rotation protrusion protruding from one side of the corresponding edge, and an anti-rotation groove portion into which the anti-rotation protrusion is inserted is formed at another one of the oil flow side plate and the coolant flow side plate. do.

In this case, at least one of the cooling water or the oil flow side plate may be formed with a rotation preventing protrusion projecting outwardly on one side of the edge and a rotation preventing groove having a groove formed so that the rotation preventing protrusion is inserted and fixed to the other side of the edge. Can be. The anti-rotation protrusion and the anti-rotation groove may be alternately disposed in a vertical direction when the oil flow side plate and the coolant flow side plate are stacked and assembled, and the anti-rotation protrusion may be chamfered at the protruding end edge thereof. Preferably, the anti-rotation protrusion protrudes 1 mm or more from the anti-rotation groove when the fixing unit is inserted into the anti-rotation groove.

In addition, the coolant flow side plate and the oil flow side plate assembled therein are formed with an oil inlet and a coolant outlet, respectively, through which the joint bead protruding from the coolant outlet is 0.2-0.5. It can be formed extending in the range of mm, in particular, the joining bead portion applied to the present invention is preferably composed of the corresponding vertical height from the cooling water outlet inlet is 0.3mm.

An embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a view showing a perspective view of a water-cooled oil cooler according to the present invention, Figure 3a is a view showing a perspective view of the oil flow side plate and the coolant flow side plate coupled to the water-cooled oil cooler, Figure 3b is the oil flow side of Figure 3a The perspective view which exploded plate and the coolant flow side plate is exploded.

2 to 3B, the water-cooled oil cooler according to the present invention alternately stacks the oil flow side plate 400 through which the engine oil flows and the coolant flow side plate 300 through which the coolant flows. It is installed and mutually joined by brazing in a laminated state. In particular, the cooling water flow side plate 300 and the oil flow side plate 400 which are alternately stacked are formed with the anti-rotation protrusion 100 and the anti-rotation groove 200 which can prevent the rotation between them. That is, any one selected from the oil flow side plate 400 and the coolant flow side plate 300 is formed with a rotation preventing protrusion 100 protruding from one side of the edge, the other is not selected the anti-rotation protrusion ( An anti-rotation groove 200 into which 100 is inserted is formed.

For example, when the anti-rotation protrusion part 100 is formed at one side of the edge of the cooling water flow side plate 300, the anti-rotation groove part 200 ′ is formed at one side of the edge of the oil flow side plate 400. When the anti-rotation groove 200 is formed at one side of the edge of the coolant flow side plate 300, the anti-rotation protrusion 100 ′ may be formed at one side of the edge of the oil flow side plate 400 which is stacked and assembled. have.

The water-cooled oil cooler according to the present embodiment has a coolant flow side plate 300 having anti-rotation protrusions 100 and anti-rotation grooves 200 formed at one side and the other side of the edge, and the anti-rotation protrusions 100 and anti-rotation grooves. It is configured to include an oil flow side plate 400, the anti-rotation groove 200 'and the anti-rotation protrusion 100' formed on one side and the other side of the edge to correspond to the (200).

The anti-rotation protrusion part 100 is inserted into and fixed to the anti-rotation groove part 200 of the oil flow side plate 400 that is stacked and assembled from the bottom, so that the coolant flow side plate 400 of the upper part and the oil flow side plate of the lower part ( When the 400 are assembled together, the rotation between them is prevented.

To this end, the anti-rotation protrusion 100 is formed by cutting to have a predetermined width at one side of the edge of the coolant flow side plate 300 and then bending outward from the edge.

At this time, the corner of the anti-rotation protrusion 100 is preferably chamfered, the anti-rotation protrusion 100 is the anti-rotation groove 200 'when it is seated in the anti-rotation groove 200' of the oil flow side plate 400 It is preferable to extend so as to protrude more than 1mm to the outside of the). This prevents the assembly error that the anti-rotation protrusion 100 is separated from the anti-rotation groove 200.

The anti-rotation groove part 200 into which the anti-rotation protrusion part 100 is inserted and fixed forms a recess 210 in which the anti-rotation protrusion part 100 is seated in a state where the anti-rotation protrusion part 100 protrudes to the other side of the edge of the coolant flow side plate 300. .

In particular, when the anti-rotation protrusion 100 is seated in the groove 210, the distance between the groove 210 and the anti-rotation protrusion 100 is configured to maintain a separation distance of 0.5 mm or more, but with the coolant flow side plate 300 The present purpose for preventing rotation between the oil flow side plate 400 can be adjusted within a range that does not impair.

The anti-rotation protrusion 100 and the anti-rotation groove 200 having the above configuration are positioned to face each other on the circumference of the coolant flow side plate 300 having a circular shape, and the upper portion of the coolant flow side plate 300. It is preferable that the anti-rotation protrusion part 100 'and the anti-rotation groove part 200' of the oil flow side plate 400 respectively assembled to the lower part are disposed on the same vertical line.

As a variant, although not shown, a plurality of anti-rotation protrusions 100 may be formed on one side of the cooling water flow side plate 300, or a plurality of anti-rotation grooves 200 may be formed on the other side thereof. The configuration of the anti-rotation protrusion 100 and the anti-rotation groove 200 is applied in common to the above description.

At this time, the oil flow side plate 400 is assembled to the upper and lower portions of the coolant flow side plate 300 and the anti-rotation projection portion 100 and the anti-rotation groove portion 200 'corresponding to the anti-rotation groove portion 200 and Of course, the anti-rotation protrusions 100 'are formed.

Hereinafter, the anti-rotation groove 200 'and the anti-rotation protrusion 100' formed on the oil flow side plate 400 may include the anti-rotation groove 200 and the anti-rotation protrusion of the cooling water flow side plate 300 described above. Since the description of 100 is duplicated, a description thereof will be omitted.

4 is a vertical cross-sectional view of the water-cooled oil cooler coolant outlet.

As shown in FIG. 4, when the cooling water flow side plate 300 and the oil flow side plate 400 are laminated and assembled, an oil inlet 410 and a cooling water outlet in which oil and coolant flow through the water-cooled oil cooler 310 is penetrated in the vertical direction, in particular, the bonding bead portion 500 is bent at the edge portion of the cooling water outlet 310.

The bonding bead 500 is opposed to the edge of the cooling water inlet 310 edge welding so that the welding edge of the cooling water flow side plate 300 and the oil flow side plate 400 is smoothly welded to the edge of the cooling water outlet 310. It is preferably formed at an angle bending in the direction, the vertical height (h) is bent is preferably designed in the range 0.2 ~ 0.5mm.

In this case, when the vertical height h of the bonding bead part 500 is smaller than 0.2 mm, the effect of smoothing the edge of the cooling water outlet 310 may be reduced, and the vertical direction of the bonding bead part 500 may be insignificant. If the height h is greater than 0.5 mm, the material cost may be further increased depending on the extension length of the bonding bead portion 500.

Bonding bead portion 500 according to the present embodiment is limited to the vertical height (h) protruding into the coolant outlet inlet 310 to 0.3mm, compared to the conventional bead portion consisting of a vertical height of 1.0mm in the cooling water It is possible to reduce the erosion caused by, and it is possible to prevent the leakage phenomenon by reducing the erosion.

While the invention has been shown and described with respect to specific embodiments thereof, it will be appreciated that the invention can be variously modified and varied without departing from the spirit or scope of the invention as provided by the following claims. It will be obvious to those of ordinary skill.

As described above, according to the present invention, the anti-rotation protrusion and the anti-rotation groove are formed on the coolant flow side plate and the oil flow side plate, respectively, so that assembly and welding between adjacent parts are easy, and thus the product quality is improved. There is an advantage.

In addition, the present invention by reducing the vertical height of the junction bead portion of the cooling water outlet formed in the cooling water flow side plate and the oil flow side plate to within 0.2 ~ 0.5mm to reduce the leakage caused by the flow of the cooling water, the reduction of the emulsion of the junction bead portion There is an advantage to improve the product durability.

Claims (7)

delete delete In water-cooled oil cooler, Coolant flow side plate, An oil flow side plate laminated on the cooling water flow side plate and brazed; Any one selected from the oil flow side plate and the coolant flow side plate is formed with an anti-rotation protrusion formed to protrude outward on one side of the corresponding edge, The other one of the oil flow side plate and the coolant flow side plate is not selected, the rotation prevention groove is formed with a groove to insert the rotation prevention projection, At least one of the cooling water or the oil flow side plate The anti-rotation protrusion is formed on one side of the edge, The anti-rotation groove is formed on the other side of the edge, The anti-rotation protrusion and the anti-rotation groove, The water-cooled oil cooler, characterized in that the oil flow side plate and the coolant flow side plate is alternately arranged in the vertical direction. In water-cooled oil cooler, Coolant flow side plate, An oil flow side plate laminated on the cooling water flow side plate and brazed; Any one selected from the oil flow side plate and the coolant flow side plate is formed with an anti-rotation protrusion formed to protrude outward on one side of the corresponding edge, The other one of the oil flow side plate and the coolant flow side plate is not selected, the rotation prevention groove is formed with a groove to insert the rotation prevention projection, At least one of the cooling water or the oil flow side plate The anti-rotation protrusion is formed on one side of the edge, The anti-rotation groove is formed on the other side of the edge, The anti-rotation protrusion is A water-cooled oil cooler, characterized in that the projecting end edge is chamfered. In water-cooled oil cooler, Coolant flow side plate, An oil flow side plate laminated on the cooling water flow side plate and brazed; Any one selected from the oil flow side plate and the coolant flow side plate is formed with an anti-rotation protrusion formed to protrude outward on one side of the corresponding edge, The other one of the oil flow side plate and the coolant flow side plate is not selected, the rotation prevention groove is formed with a groove to insert the rotation prevention projection, At least one of the cooling water or the oil flow side plate The anti-rotation protrusion is formed on one side of the edge, The anti-rotation groove is formed on the other side of the edge, The anti-rotation protrusion is Water-cooled oil cooler, characterized in that protruding more than 1mm from the rotation preventing groove when fixed to the rotation preventing groove. delete delete

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