Structure joined by nickel brazing

Abstract

A multi-plate oil cooler with high joining strength with an inner fin while suppressing a usage amount of a nickel brazing filler, even when ferrite-based stainless steel with low wettability for a nickel brazing filler is used for a plate is provided. A plate made from a ferrite-based stainless steel plate and an inner fin made from a pure iron plate or a carbon steel plate are joined with a nickel brazing filler to form a multi-plate oil cooler. In general, a structure body is provided wherein a ferrite-based stainless steel and pure iron or a carbon steel are joined with a nickel brazing filler.

Claims

1. A multi-plate oil cooler having an oil flow path and a cooling water flow path arranged alternately and in which a ferrite-based stainless steel plate and an inner fin made from a carbon steel plate are joined with a nickel brazing filler and the inner fin is arranged in the oil flow path.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 illustrates an exploded perspective view of the oil cooler of the present invention.

(2) FIG. 2 illustrates a plan view of FIG. 1.

(3) FIG. 3 illustrates a III-III-arrow seen cross-section view of FIG. 2.

(4) FIG. 4 illustrates a IV-IV-arrow seen cross-section view of FIG. 2.

(5) FIG. 5 illustrates a partially enlarged view of FIG. 4.

DESCRIPTION OF EMBODIMENTS

(6) Next, embodiments of the present invention will be explained on the basis of the drawings.

(7) Note that the shape itself of this oil cooler belongs to the known technology disclosed as Japanese Patent Application Laid-Open Publication No. 2015-045427 (Patent Literature 1) by the present applicant. The present invention is characterized in the combination of the three, that is, the plate material, fin material and brazing material.

(8) [Structure of Oil Cooler]

(9) This oil cooler has a stacked body of a first plate 3 and a second plate 4 each made from a ferrite-based stainless steel, and an upper end plate 8 and a lower end plate 21 made from the similar material. Furthermore, the first plate 3 and the second plate 4 are stacked alternately to configure a core 7, an oil flow path 5 and a cooling water flow path 6 are formed for every other plate of both plates 4, 3, and the inner fin 10 made from a plate material of pure iron or carbon steel is arranged to the oil flow path 5.

(10) These first plate 3 and the second plate 4 are made of those obtained by press-molding a cold-rolled steel plate in a dish shape. For the ferrite-based stainless steel plate, SUS430, SUS444, SUS445J1 and the like in Japanese Industrial Standards (JIS) can be used.

(11) Moreover, as to a carbon steel plate configuring the inner fin 10, a corrugated fin and multi-entry type fin (offset fin) can be formed by bending, by press molding, a cold-rolled steel plate of SPCC, SPCD, SPCE, SPCF, SPCG or the like in JIS.

(12) As one example, a component composition of the SPCC is: 0.15 mass % or less of carbon, 0.60% or less of manganese, 0.100% or less of phosphorus, and 0.035% or less of sulfur.

(13) Further, a nickel brazing filler is used for a brazing material for joining the first plate 3 of a ferrite-based stainless steel and the inner fin 10 of a carbon steel. As the nickel brazing filler, for example, nickel brazing materials prescribed by standards such as JIS or AWS (American Welding Society) can be used.

(14) While interposing such nickel brazing material between the first plate 3 and the inner fin 10, respective parts are brazed in a furnace. According to an experiment, in a combination of a plate of a ferrite-based stainless steel, inner fin of a carbon steel and a nickel brazing filler, the spread of the brazing material resulted in near six times the spread of a nickel brazing filler interposed between ferrite-based stainless steel plates.

(15) Meanwhile, FIG. 1 illustrates an exploded perspective view of the oil cooler of the present invention, FIG. 2 illustrates a plan view thereof, FIG. 3 illustrates a III-III-arrow seen cross-section view of FIG. 2, FIG. 4 illustrates a IV-IV-arrow seen cross-section view of FIG. 2, and FIG. 5 illustrates a partially enlarged view of FIG. 4. Furthermore, in respective first plates 3 that have a dish shape made from a ferrite-based stainless steel and are arranged every other plate, the bottom surface is formed flat and the oil flow path 5 is formed on the inside of the dish. On the inside of the second plate 4 similarly having a dish shape, the cooling water flow path 6 is formed and, on the inner surface thereof, many dimples 23 by press molding project toward the inner surface side and are arranged in a dispersed state.

(16) Furthermore, to a respective pair of corner portions on a diagonal line of the even first plate 3, oil communicating holes 1 are respectively arranged, and in a pair of corner portions on the other diagonal line orthogonal thereto, annular evaginating portions 2a respectively project, to which a pair of cooling water communicating holes 2 are arranged. In the second plate 4 having many dimples 23, in positions on a diagonal line inverse to that in the first plate 3, an annular evaginating portion 1a and the oil communicating hole 1 are arranged to a pair of respective corner portions, and in positions on the diagonal line orthogonal thereto, a pair of cooling water communication holes 2 are formed. Furthermore, the oil communicating hole 1 in the first plate 3 and the oil communicating hole 1 in the second plate 4 are connected to each other. Moreover, the tip of many dimples 23 in the second plate 4 abuts on the bottom surface of the first plate 3.

(17) In the inside of the first plate 3 and the inside of the second plate 4, which are stacked every other plate, the oil flow path 5 and the cooling water flow path 6 are formed alternately. In the oil flow path 5, the inner fin 10 is interposed, and in the cooling water flow path 6, the dimple 23 exists. Furthermore, the stacked body of the first plate 3, the second plate 4 and the inner fin 10 forms the core 7, and to each of plates 3, 4 and the inner fin 10, a powdery nickel brazing filler is applied via a binder. At this time, as to the inner fin 10, the nickel brazing filler is applied to both surfaces in the thickness direction thereof. To the upper end of the core 7, the upper end plate 8 is arranged, and to the lower end, the lower end plate 21 is arranged. Moreover, in both corners on the diagonal line of the upper end plate 8, a pair of convex portions 11 are arranged, projecting to the front surface side.

(18) Such oil cooler formed of an assembly of the first plate 3, the second plate 4 and the inner fin 10 is brazed and fixed integrally in a furnace at high temperatures. Then spaces between peripheral edges of the first plate 3 and the second plate 4, and between these and the inner fin 10 are joined, and spaces between periphery edge portions of the first plate 3 and the second plate 4, and between the dimple 23 on the second plate 4 and the bottom surface of the first plate 3 are joined.

(19) At this time, the brazing area in the oil flow path 5 is extremely large as compared with the brazing area of the cooling water flow path 6. The reason is that contact areas between the inner fin 10 and the first plate 3, the second plate 4 are large. Therefore, it is necessary to make the spread of the nickel brazing filler in the oil flow path 5 larger than that in the cooling water flow path 6. Since the inner fin 10 made from a carbon steel plate is arranged between the first plate 3 and the second plate 4 in the oil flow path 5, the spread of the nickel brazing filler becomes extremely larger than the spread in the cooling water flow path 6.

(20) This oil cooler is arranged, as shown in FIGS. 3 and 4 as an example, on a base portion 22. Then cooling water 20 circulates from one pipe 14 to the other pipe 14 through respective cooling water flow paths 6. Moreover, oil 19 circulates from an oil inlet 15 in the base portion 22 into respective oil flow paths 5. Then a heat exchanger is performed between the cooling water 20 and the oil 19.

(21) The characteristic of Example is that a ferrite-based stainless steel plate is used for plates 3, 4, low carbon steel such as SPCC is used for the inner fin 10, and both are joined with a nickel-based brazing material.

(22) Consequently, even when a ferrite-based stainless steel plate is used as a plate, it becomes possible to provide a multi-plate oil cooler etc. that have high joining strength and are free from clogging and inexpensive, with a small usage amount of a nickel brazing filler.

(23) Meanwhile, in respective drawings, a similar nickel brazing filler joins cooling water flow paths 6 lying between the first plate 3 and the second plate 4. Since a portion to be brazed between the first plate 3 and the second plate 4 in the cooling water flow path 6 is small, a small consumption amount of a nickel brazing filler will suffice.

Other Examples

(24) In the above Example, both the first plate 3 and the second plate 4 are formed from a ferrite-based stainless steel plate. In place of it, it is also possible to set the first plate 3 alone to a ferrite-based stainless steel plate, and to set the second plate 4 to an austenite-based stainless steel plate. Even then, for the inner fin 10 of the oil flow path 5, a cold-rolled steel plate such as SPCC, SPCD, SPCE, SPCF or SPCG, which are carbon steel plates, is used. When an austenite-based stainless steel plate is used as a raw material of the second plate 4, the spread of a nickel brazing filler in brazing becomes large, even in the cooling water flow path 6.

(25) Note that, needless to say, the present invention is not limited to above-described Examples of oil coolers, but may be utilized suitably for various multi-plate oil coolers, and additionally can be utilized for various heat exchangers such as heat exchangers for ventilation and heat sinks. Moreover, brazing may be performed in any of vacuum furnaces and furnaces of various atmospheres.

INDUSTRIAL APPLICABILITY

(26) The present invention can be utilized for heat exchangers that are optimum for oil coolers, and can also be utilized for heat exchangers for ventilation and heat sinks.

REFERENCE SIGNS LIST

(27) 1 oil communicating hole 1a annular evaginating portion 2 cooling water communicating hole 2a annular evaginating portion 3 plate 4 plate 5 oil flow path 6 cooling water flow path 7 core 8 upper end plate 10 inner fin 10a inner fin hole 11 convex portion 14 pipe 15 oil inlet 16 oil outlet 19 oil 20 cooling water 21 lower end plate 22 base portion 23 dimple