JP2011226722A - Egr (exhaust gas recirculation) cooler - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an EGR cooler that includes a plurality of heat transmission pipes, that can reliably cool peripheral part of each heat transmission pipe and that can reliably prevent thermal deformation of the heat transmission pipes.SOLUTION: The EGR cooler includes: the plurality of heat transmission pipes 5, inside which an EGR gas circulates; a casing 2 that houses each of the heat transmission pipes 5; and end plates 3, 4 that support each of the pipes 5 at both ends in the casing 2. In the EGR cooler 1, a flow path for a cooling water is formed by the casing 2 and both end plates 3, 4. In the end plate 3, a cooling water groove 7 is formed to circulate the cooling water in thickness of the end plate 3.

Description

  The present invention relates to an EGR cooler technique used for exhaust gas recirculation of an engine.

In recent years, exhaust gas recirculation (hereinafter referred to as “Exhaust Gas Recirculation”) is an effective technique for reducing nitrogen oxides (NOx) and particulate matter (PM) contained in exhaust gas discharged from an engine and improving fuel efficiency of the engine. A technique referred to as EGR) has been widely adopted.
In a system for realizing EGR, an EGR cooler that is a device for cooling exhaust gas to be recirculated (hereinafter referred to as EGR gas) is used.

Since the exhaust gas introduced into the EGR cooler is very high temperature, if the exhaust gas is not properly cooled by the EGR cooler, the EGR cooler is locally heated to cause heat deformation of the heat transfer pipe, etc. There is a case. Such thermal deformation of the heat transfer pipe is not preferable because it causes damage to the heat transfer pipe or a decrease in cooling efficiency due to increased pressure loss of the heat transfer pipe.
Therefore, in Patent Document 1 shown below, a technique for avoiding local increase in temperature of the heat transfer pipe constituting the EGR cooler is disclosed and publicly known.

  In the prior art disclosed in Patent Document 1, a part of the cooling water introduced from the cooling water inlet is placed at a position facing the cooling water inlet on one end side in the axial direction of the shell (housing) in the diametrical direction. By providing a bypass outlet for extraction and introducing cooling water from the cooling water inlet into the shell, a part of the introduced cooling water is extracted from the bypass outlet, so that the cooling water at one end in the axial direction of the shell Cooling water does not stagnate at a position facing the inlet in the diametrical direction, and a local high temperature of the heat transfer pipe is avoided.

Further, conventionally, an EGR cooler that employs a heat transfer pipe having a flat shape as a heat transfer pipe constituting the heat exchanger part in order to increase the heat transfer area and improve the heat exchange efficiency is known, for example, The technique is disclosed in Patent Document 2 and the like shown below and is publicly known.
In the EGR cooler that employs a heat transfer pipe having a flat shape, it is necessary to ensure a higher degree of dimensional accuracy than a circular heat transfer pipe, so the adverse effects of heat deformation of the heat transfer pipe are more pronounced. It is known to appear.
For this reason, in the EGR cooler which employ | adopted the heat-transfer pipe which has a flat shape, it is necessary to avoid the local high temperature of a heat-transfer pipe more reliably.

JP 2001-74380 A JP 2007-64606 A

It is known that the local increase in temperature of the heat transfer pipe is likely to occur in the vicinity of the support portion where the end plate for supporting the heat transfer pipe contacts the heat transfer pipe.
However, in the related art according to Patent Document 1, it is difficult to reliably cool the periphery of the support portion where the end plate and the heat transfer pipe abut, and it is possible to reliably prevent local high temperature of the EGR cooler. It was difficult.

  The present invention has been made in view of such current problems, and in an EGR cooler having a plurality of heat transfer pipes, the periphery of the support portion of each heat transfer pipe can be reliably cooled. An object of the present invention is to provide an EGR cooler that can reliably prevent thermal deformation.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  That is, in claim 1, a plurality of heat transfer pipes through which EGR gas circulates, a housing incorporating the plurality of heat transfer pipes, and the plurality of heat transfer pipes in the housing are long. A pair of support plates that are members for supporting at both ends in the vertical direction, and a cooling water flow path is formed by the housing and the pair of support plates. A cooling water passage is formed in the plate for circulating the cooling water within the thickness of the support plate.

  According to a second aspect of the present invention, the heat transfer pipe has a flat shape.

  According to a third aspect of the present invention, the cooling water channel is formed on one of the support plates for supporting each end of the plurality of heat transfer pipes on the inflow side of the EGR gas.

  5. The cooling water channel according to claim 4, wherein the cooling water channel is formed within the thickness of the support plate, and is an inlet portion formed on the upstream side in the flow direction of the cooling water, and the downstream side in the flow direction of the cooling water. And an outlet portion that is a hole formed in the communication portion, and a communication hole that is a hole that communicates the inlet portion and the outlet portion.

  According to a fifth aspect of the present invention, the cooling water passage formed by the casing and the pair of support plates includes a first guide member that is a resistance portion for guiding the cooling water to the inlet portion. is there.

  According to a sixth aspect of the present invention, the first guide member is a wall-shaped protrusion that protrudes from the outer peripheral surface of the heat transfer pipe.

  According to a seventh aspect of the present invention, the first guide member is a plurality of substantially columnar protrusions protruding from the outer peripheral surface of the heat transfer pipe.

  In Claim 8, In the flow path of the cooling water formed by the casing and the pair of support plates, the cooling water flowing out from the outlet portion is guided to the downstream area of the first guide member. A second guide member that is a resistance portion is provided.

  As effects of the present invention, the following effects can be obtained.

  In claim 1, the periphery of the support portion of the heat transfer pipe by the support plate can be cooled.

  According to the second aspect of the present invention, the periphery of the support portion by the support plate of the heat transfer pipe having a flat shape can be cooled.

  In Claim 3, the heat deformation of the heat transfer pipe can be prevented with a simple configuration.

  According to the fourth aspect of the present invention, the periphery of the support portion by the support plate of the heat transfer pipe can be reliably cooled.

  According to the fifth aspect, the periphery of the support portion of the heat transfer pipe by the support plate can be cooled more reliably.

  According to the sixth aspect of the present invention, it is possible to easily form a resistance portion for guiding the cooling water to the inlet portion.

  According to the seventh aspect of the present invention, it is possible to easily form the resistance portion for guiding the cooling water to the inlet portion without causing stagnation of the cooling water in the downstream area of the resistance portion.

  In Claim 8, it can prevent that the stagnation of cooling water arises in the downstream area of a resistance part.

The side surface cross-sectional schematic diagram which shows the whole structure of the EGR cooler which concerns on 1st embodiment of this invention. The perspective schematic diagram which shows the support state of the heat-transfer pipe by an end plate. The schematic diagram which shows the end plate which comprises the EGR cooler which concerns on 1st embodiment of this invention, (a) The front and side schematic diagram which shows the end plate arrange | positioned upstream of EGR gas, (b) EGR gas downstream The front and side schematic diagram which shows the end plate arrange | positioned at the side. The schematic diagram which shows the assembly | attachment state of the end plate in the EGR cooler which concerns on 1st embodiment of this invention, (a) Whole cross-sectional schematic diagram, (b) Partial cross-sectional schematic diagram. The schematic diagram which shows the distribution | circulation state of the cooling water in the EGR cooler which concerns on 1st embodiment of this invention, (a) The partial cross section schematic diagram in side view, (b) The partial cross section schematic diagram in planar view. The side surface cross-section schematic diagram which shows the whole structure of the EGR cooler which concerns on 2nd embodiment of this invention. The schematic diagram which shows the end plate arrange | positioned in the EGR gas upstream which comprises the EGR cooler which concerns on 2nd embodiment of this invention, (a) Front schematic diagram, (b) AA cross-sectional schematic diagram, (c ) BB cross-sectional schematic diagram. The schematic diagram which shows the assembly | attachment state of the end plate in the EGR cooler which concerns on 2nd embodiment of this invention, (a) Whole cross-sectional schematic diagram, (b) Partial cross-sectional schematic diagram. The schematic diagram which shows the distribution | circulation condition of the cooling water in the EGR cooler which concerns on 2nd embodiment of this invention, (a) The partial cross section schematic diagram in side view, (b) The partial cross section schematic diagram in planar view. The schematic diagram which shows the distribution | circulation condition of the cooling water in the EGR cooler which concerns on 2nd embodiment of this invention, (a) The partial cross section schematic diagram in the planar view in the case of providing an outflow guide, (b) The inflow guide which concerns on another embodiment The partial cross section schematic diagram in planar view in the case of providing. The schematic diagram which shows the other aspect of the EGR cooler which concerns on this invention, (a) The front schematic diagram which shows the end plate in the EGR cooler which concerns on 3rd embodiment of this invention, (b) 4th embodiment of this invention The front schematic diagram which shows the end plate in the EGR cooler which concerns on.

Next, embodiments of the invention will be described.
First, the EGR cooler according to the first embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 1, an EGR cooler 1 according to a first embodiment of the present invention is a so-called shell and tube type heat exchanger used for cooling EGR gas. 4. It is constituted by a plurality of heat transfer pipes 5, 5,.

  The casing 2 is a case-like member for forming a part of a flow path of a fluid (here, EGR gas and cooling water) to be subjected to heat exchange, and allows EGR gas to flow into the casing 2. An EGR gas inlet 2a that is an opening for the EGR gas, an EGR gas outlet 2b that is an opening for allowing the EGR gas to flow out of the casing 2, and a cooling water inlet 2c that is an opening for allowing the cooling water to flow into the casing 2 In addition, a cooling water outlet 2d, which is an opening for allowing cooling water to flow out of the casing 2, is formed.

  As shown in FIGS. 1 and 2, each end plate 3, 4 is a plate-like member for isolating each flow path of EGR gas and cooling water in the casing 2, and a plurality of heat transfer in the casing 2. This is a member for supporting the pipes 5.

The end plate 3 is a member for supporting each end of the heat transfer pipes 5, 5... Upstream of the EGR gas flow direction.
2 and 3A, the end plate 3 corresponds to a cross-sectional shape by a plane orthogonal to the axial direction of the heat transfer pipe 5, and a hole portion to be fitted with the heat transfer pipe 5. A plurality of fitting holes 3a, 3a, ... are formed.

As shown in FIGS. 1 and 2, the end plate 4 is a member for supporting each end portion of each heat transfer pipe 5, 5... On the downstream side in the EGR gas flow direction.
As shown in FIGS. 2 and 3B, the end plate 4 corresponds to a cross-sectional shape by a plane orthogonal to the axial direction of the heat transfer pipe 5 in the same manner as the end plate 3, and the heat transfer pipe 5 A plurality of fitting holes 4a, 4a,... Corresponding to the fitting holes 3a, 3a,.

Then, as shown in FIG. 1, by fixing the end plates 3, 4 in the casing 2, a cooling water flow path is formed in a region sandwiched between the end plates 3, 4 of the casing 2, In other areas of the casing 2, an EGR gas flow path is formed.
For this reason, the flow path of the EGR gas is separated into the upstream side and the downstream side by the end plates 3 and 4.

As shown in FIGS. 1 and 2, the heat transfer pipe 5 is a tubular member that is formed into a flat shape by crushing a substantially cylindrical pipe in a direction orthogonal to the axial direction. The cross-sectional shape orthogonal to the shape substantially matches the shape of the corresponding fitting holes 3a and 4a.
The heat transfer pipe 5 is brazed by being fitted into the fitting hole 3 a of the end plate 3 and the fitting hole 4 a of the end plate 4 corresponding thereto, and is supported in the casing 2 by the end plates 3 and 4. Has been.
With such a configuration, the EGR gas flow paths separated from the upstream side and the downstream side are communicated with each other by the plurality of heat transfer pipes 5, 5... To form a series of EGR gas flow paths. .

That is, in the EGR cooler 1, the EGR gas inlet 2a and the EGR gas outlet 2b are communicated by the heat transfer pipes 5, 5... To form an EGR gas flow path and the end plate 3 in the casing 2. 4, and the EGR gas inlet 2 a and the EGR gas outlet 2 b are separated from each other, and a space between the end plates 3 and 4 in the casing 2 forms a cooling water flow path.
In addition, since the EGR cooler 1 shown by this embodiment is a structure provided with six heat-transfer pipes 5,5 ... laminated | stacked at a fixed space | interval in the height direction, about each end plate 3,4, Although the case of forming each of the fitting holes 3a, 3a,... And the fitting holes 4a, 4a, etc. at six locations is illustrated, the number of heat transfer pipes constituting the EGR cooler according to the present invention is shown. However, the present invention is not limited to this.

  In the EGR cooler 1, the EGR gas is circulated inside the heat transfer pipes 5, 5... And the cooling water is circulated outside the heat transfer pipes 5, 5. The EGR gas is cooled by performing heat exchange between the EGR gas and the cooling water via the heat pipes 5. That is, the EGR gas that has flowed into the EGR cooler 1 from the EGR gas inlet 2a is cooled and flows out of the EGR gas outlet 2b, and the cooling water that has flowed into the EGR cooler 1 from the cooling water inlet 2c is heated to the cooling water outlet. Out of 2d.

Further, as shown in FIG. 3 (a), the end plate 3 is formed with cooling water grooves 7, 7... That are a plurality of groove portions on the surface in contact with the cooling water.
The cooling water grooves 7, 7... Are boundaries between the fitting holes 3 a, 3 a, and are boundary portions that form the support portions of the heat transfer pipes 5, 5. 3b, 3b, and adjacent portions 3c, 3d, which are portions adjacent to the fitting holes 3a, 3a, and form the support portions of the heat transfer pipes 5, 5 ... by the end plate 3. Are parallel to the respective fitting holes 3a, 3a, and in a range equal to or larger than the width of the respective fitting holes 3a, 3a,.
In addition, the formation position, depth, formation range, etc. of the cooling water groove 7 are appropriately set in consideration of the strength necessary for supporting the heat transfer pipes 5, 5,.

4 (a) and 4 (b), in the EGR cooler 1, the end plate 3 is provided with the cooling water grooves 7, 7... Facing the cooling water flow path side.
With such a configuration, in the EGR cooler 1, as shown in FIGS. 5 (a) and 5 (b), the cooling water flowing through the casing 2 (cooling water flow path) is supplied to the cooling water grooves 7, 7,. The boundary portions 3b, 3b,... And the adjacent portions 3c, 3d can be cooled by the cooling water.

  Thus, in the EGR cooler 1, the cooling water flowing through the casing 2 also flows through the cooling water grooves 7, 7... Formed within the thickness of the end plate 3. It is possible to cool the support portions (that is, the boundary portions 3b, 3b,... And the adjacent portions 3c, 3d) of the heat transfer pipes 5, 5,.

On the other hand, as shown in FIG. 3B, the end plate 4 is not formed with a cooling water groove at a portion adjacent to each fitting hole 4a, and is different from the end plate 3 in this respect.
That is, in the EGR cooler 1, the end plate 4 on the downstream side of the EGR gas is lower in temperature and is less likely to be locally heated than the end plate 3 on the upstream side of the EGR gas. It has a simple structure.

Next, an EGR cooler according to a second embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 6, the EGR cooler 11 according to the second embodiment of the present invention includes a pair of end plates 13, 14 and a plurality of heat transfer pipes 15, 15. In that respect, it differs from the EGR cooler 1, and the configuration of other parts is the same as that of the EGR cooler 1.

  Each of the end plates 13 and 14 is a plate-like member for isolating each flow path of the EGR gas and the cooling water in the casing 2 in the same manner as each of the end plates 3 and 4 described above. Is a member for supporting the heat transfer pipes 15.

Like the end plate 3 described above, the end plate 13 is a member for supporting each end of the heat transfer pipes 15, 15... Upstream of the EGR gas flow direction. Like the end plate 4 described above, the heat transfer pipes 15, 15... Are members for supporting the end portions on the downstream side in the EGR gas flow direction.
Further, as shown in FIGS. 7A, 7B and 7C, the end plate 13 corresponds to a cross-sectional shape by a plane orthogonal to the axial direction of the heat transfer pipe 15, and is fitted to the heat transfer pipe 15. A plurality of fitting holes 13a, 13a,.

  The end plate 14 is a member common to the above-described end plate 4, corresponds to a cross-sectional shape by a plane orthogonal to the axial direction of the heat transfer pipe 15, and is a hole that fits the heat transfer pipe 15. A plurality of fitting holes 14a, 14a, ... corresponding to the fitting holes 13a, 13a, ... are formed (see Fig. 3B).

Then, by fixing the end plates 13 and 14 in the casing 2, the cooling water in the region sandwiched between the end plates 13 and 14 of the casing 2 in the same manner as the end plates 3 and 4 described above. A flow path is formed, and an EGR gas flow path is formed in the other region of the casing 2.
For this reason, the flow path of the EGR gas is separated into the upstream side and the downstream side by the end plates 13 and 14.

As shown in FIG. 6, the heat transfer pipe 15 is a tubular member formed into a flat shape by crushing a substantially cylindrical pipe in a direction orthogonal to the axial direction, and orthogonal to the axial direction. The cross-sectional shape substantially matches the shape of the corresponding fitting holes 13a and 14a.
The heat transfer pipe 15 is brazed by being fitted into the fitting hole 13a of the end plate 13 and the fitting hole 14a of the end plate 14 corresponding thereto, and is supported in the casing 2 by the end plates 13 and 14. Has been.
With such a configuration, the EGR gas flow paths separated from the upstream side and the downstream side are communicated by the plurality of heat transfer pipes 15, 15... To form a series of EGR gas flow paths. .

  That is, in the EGR cooler 11, the EGR gas inlet 2a and the EGR gas outlet 2b are communicated by the heat transfer pipes 15, 15... To form an EGR gas flow path, and the end plate 13 in the casing 2. The space between the EGR gas inlet 2a and the EGR gas outlet 2b is isolated from the space sandwiched between the two, and the space between the end plates 13 and 14 in the casing 2 forms a cooling water flow path.

  In the EGR cooler 11, the EGR gas is circulated inside each heat transfer pipe 15, 15... And the cooling water is circulated outside each heat transfer pipe 15, 15. The EGR gas and the cooling water are subjected to heat exchange via the heat pipes 15, 15... To cool the EGR gas. That is, the EGR gas that has flowed into the EGR cooler 11 from the EGR gas inlet 2a is cooled and flows out of the EGR gas outlet 2b, and the cooling water that has flowed into the EGR cooler 11 from the cooling water inlet 2c is heated to the cooling water outlet. Out of 2d.

Further, as shown in FIGS. 7A, 7B, and 7C, the end plate 13 is opened at a surface on the side in contact with the cooling water, and is a cooling that is a plurality of holes communicating with the flow path of the cooling water. Water holes 17, 17... Are formed.
The cooling water hole 17 is a hole portion drilled within the thickness of the end plate 13, and an inlet portion 17a that is a hole that opens to the upstream side of the cooling water and an outlet portion 17b that is a hole that opens to the downstream side of the cooling water. And a communication hole 17c that communicates the inlet portion 17a and the outlet portion 17b.

Further, the cooling water holes 17, 17... Are portions between the fitting holes 13 a, 13 a, and form support portions of the heat transfer pipes 15, 15. , And adjacent portions 13c that are portions adjacent to the fitting holes 13a, 13a,... And that form the support portions of the heat transfer pipes 15, 15,. -In 13d, it forms in parallel with each fitting hole 13a, 13a ..., and the range more than the width | variety of each fitting hole 13a, 13a ....
The formation position, hole diameter, formation range, and the like of the cooling water holes 17 are appropriately set in consideration of the strength necessary for supporting the heat transfer pipes 15, 15.

8 (a) and 8 (b), in the EGR cooler 11, the end plate 13 is connected to the inlet portions 17a, 17a,... And the outlet portions 17b, 17b,. It is arranged to open toward the.
With such a configuration, in the EGR cooler 11, as shown in FIGS. 9A and 9B, a part of the cooling water flowing in the casing 2 is branched and distributed in the cooling water holes 17 and 17. The boundary portions 13b, 13b... And the adjacent portions 13c and 13d can be cooled by the cooling water.

  As described above, in the EGR cooler 11, the cooling water flowing in the casing 2 also flows in the cooling water holes 17, 17... Formed in the thickness of the end plate 13, so that it has been difficult to cool conventionally. It is possible to cool the support portions (that is, the boundary portions 13b, 13b,... And the adjacent portions 13c, 13d) of the heat transfer pipes 15, 15,.

Further, in the EGR cooler 1 according to the first embodiment of the present invention, the cooling water groove 7 formed in the end plate 3 has no fixed inlet and outlet for the cooling water. There arises a problem that the access is not stable.
On the other hand, in the EGR cooler 11 according to the second embodiment of the present invention, the cooling water hole 17 formed in the end plate 13 has an inlet portion 17a and an outlet portion 17b, and cooling water flows from the inlet portion 17a. Then, the flow of the cooling water in the cooling water hole 17 is more stable, such as flowing out from the outlet portion 17b, so that the EGR cooler 11 is superior to the EGR cooler 1 in terms of the stability of the cooling performance. ing.

That is, in the EGR cooler 11 according to the second embodiment of the present invention, the cooling water hole 17 is an inlet portion 17a which is a hole formed in the upstream side of the cooling water that is formed within the thickness of the end plate 13. And an outlet portion 17b which is a hole formed on the downstream side of the cooling water, and a communication hole 17c which is a hole which communicates the inlet portion 17a and the outlet portion 17b.
With such a configuration, it is possible to reliably cool the periphery of the support portion of each heat transfer pipe 15, 15.

Further, as shown in FIG. 3B, the end plate 14 is not formed with a cooling water groove in a portion adjacent to each fitting hole 14a as in the end plate 4 described above. It is different from the end plate 13.
That is, in the EGR cooler 11, as with the EGR cooler 1 described above, the end plate 14 on the downstream side of the EGR gas is lower in temperature than the end plate 13 on the upstream side of the EGR gas and is less likely to be locally heated. In addition, a simple configuration that does not form a cooling water groove or the like is adopted.

That is, the EGR coolers 1 and 11 according to the first and second embodiments of the present invention include the cooling water groove 7 and the cooling water hole 17, the heat transfer pipes 5,..., Or the heat transfer pipes. Are formed on the end plate 3 and the end plate 13 which are one support plate for supporting each end of the EGR gas inflow side.
With such a configuration, it is possible to prevent thermal deformation of the heat transfer pipes 5, 5... And the heat transfer pipes 15, 15.

Further, when the cooling water hole 17 is formed in the end plate 3, there is a concern that the cooling water does not flow through the cooling water hole 17.
Therefore, in the EGR cooler 11, as shown in FIG. 8B, the cooling water flowing through the casing 2 is guided to the inlets 17a, 17a,... The inflow guides 18, 18...

  The inflow guide 18 is a wall-shaped part projecting from the outer peripheral surface forming the flat portion of the heat transfer pipe 15, and provides resistance to the cooling water flowing between the adjacent heat transfer pipes 15 and 15. And it plays the role which changes the flow direction of a part of cooling water to the direction along the opening direction of the inlet part 17a.

The inflow guide 18 is a wall-shaped protrusion formed by projecting toward the outside of the pipe by press molding at the same time when the heat transfer pipe 15 is formed into a flat shape by press molding. The structure which forms an integral wall-shaped resistance part in the flow path of the cooling water between adjacent heat-transfer pipes 15 and 15 by abutting the tops of the inflow guides 18 and 18 of 15 and 15 It is said.
In this embodiment, the protrusions 18a and 18b corresponding to the inflow guides 18 and 18 formed in the heat transfer pipes 15 and 15 arranged on the outermost side are arranged on the inner peripheral surface of the casing 2. ing.
The formation position, inclination, width, and the like of the inflow guide 18 are appropriately set according to the formation position and hole diameter of the inlet portion 17a in the cooling water hole 17, the desired cooling capacity, and the like.
In addition, the shape of the inflow guide 18 is not limited to the case where the inflow guide 18 is formed as a straight wall portion as shown in the present embodiment, but may be formed as a curved wall portion as appropriate according to a desired flow situation. is there.

  In the present embodiment, the inflow guide 18 is formed by press molding at the same time as the heat transfer pipe 15 is press-molded. However, the inflow guide is not limited to the one formed by press molding. A wall-shaped member prepared as a separate member may be fixed to the outer peripheral surface of the heat transfer pipe by welding or the like to form an inflow guide.

  9 (a) and 9 (b), the EGR cooler 11 is provided with the inflow guides 18, 18,..., So that a part of the cooling water flowing in the casing 2 is allowed to flow through the inlet portion 17a. Therefore, the cooling water can be reliably guided into the cooling water hole 17.

That is, the EGR cooler 11 according to the second embodiment of the present invention includes a resistance portion for guiding the cooling water to the inlet portion 17a in the cooling water flow path formed by the casing 2 and the end plates 13 and 14. Are inflow guides 18, 18.
With such a configuration, the periphery of the support portion of each heat transfer pipe 15, 15.

Further, in the EGR cooler 11 according to the second embodiment of the present invention, the guide member is an inflow guide 18 which is a wall-like protrusion protruding from the outer peripheral surface of each heat transfer pipe 15. 18...
With such a configuration, it is possible to easily form a resistance portion for guiding the cooling water to the inlet portion 17a.

As shown in FIG. 10A, in the EGR cooler 11 having the inflow guides 18, 18..., The flow of the cooling water is drifted by the inflow guide 18. There is concern about the occurrence of stagnation.
Therefore, in the EGR cooler 11 according to the second embodiment of the present invention, when the inflow guides 18, 18... Are provided, the cooling water flowing out from the outlet portion 17 b is guided to the downstream area of the inflow guide 18. By providing the outflow guides 19, 19... Which are resistance portions, the stagnation of cooling water in the downstream area of the inflow guide 18 can be eliminated.

  The outflow guide 19 is a wall-shaped part projecting from the outer peripheral surface forming the flat portion of the heat transfer pipe 15, and provides resistance to the cooling water flowing between the adjacent heat transfer pipes 15 and 15. And it plays the role which changes the flow direction of a part of cooling water which flows out from the exit part 17b.

Similarly to the inflow guide 18, the outflow guide 19 is a wall-shaped protrusion formed by projecting toward the outside of the tube by press molding at the same time when the heat transfer pipe 15 is press-molded into a flat shape. Yes, by bringing the tops of the outflow guides 19 and 19 of the adjacent heat transfer pipes 15 and 15 into contact with each other, an integral wall shape is formed in the flow path of the cooling water between the adjacent heat transfer pipes 15 and 15. The resistance portion is formed.
The formation position, inclination, width, and the like of the outflow guide 19 are appropriately set according to the formation position, the hole diameter, and the like of the outlet portion 17b in the cooling water hole 17.

Thus, since the EGR cooler 11 includes the outflow guides 19, 19..., The flow of the cooling water flowing out from the outlet portion 17 b can be directed to the downstream area of the inflow guides 18, 18. Therefore, the stagnation of the cooling water can be surely prevented in the downstream area of the inflow guides 18.
In the present embodiment, an example in which the outflow guide 19 is simultaneously formed by press molding at the time of press molding of the heat transfer pipe 15 is illustrated, but the outflow guide is not limited to that formed by press molding. A wall-shaped member prepared as a separate member may be fixed to the outer peripheral surface of the heat transfer pipe by welding or the like to form an outflow guide.

That is, the EGR cooler 11 according to the second embodiment of the present invention is configured so that the cooling water flowing out from the outlet portion 17b is introduced into the inflow guide in the cooling water passage formed by the casing 2 and the end plates 13 and 14. The outflow guide 19 which is a resistance part for guide | inducing to the downstream area of 18 is provided.
With such a configuration, it is possible to prevent the cooling water from stagnation in the downstream area of the inflow guide 18.

Further, the inflow guide as a resistance portion for guiding the cooling water flowing through the casing 2 to the respective inlet portions 17a, 17a,... Has the inflow guides 28, 28,. It is also possible to adopt the embodiment.
The inflow guide 28 is a substantially cylindrical portion projecting from the outer peripheral surface forming the flat portion of the heat transfer pipe 15 and imparts resistance to the cooling water flowing between the adjacent heat transfer pipes 15 and 15. And it plays the role which changes the flow direction of a part of cooling water to the direction along the opening direction of the inlet part 17a.

The inflow guide 28 is a substantially cylindrical protrusion formed by projecting toward the outside of the pipe by press molding at the same time when the heat transfer pipe 15 is press molded into a flat shape. By bringing the top portions of the inflow guides 28, 28,... Of the pipes 15, 15 into contact with each other, a substantially cylindrical resistance integrated in the flow path of the cooling water between the adjacent heat transfer pipes 15, 15. It is set as the structure which forms a part.
The formation positions, the number of arrangements, and the like of the inflow guides 28, 28,...

As described above, if the EGR cooler 11 is configured to include the inflow guides 28, 28,..., A part of the cooling water flowing through the casing 2 can be reliably circulated through the cooling water hole 17.
Further, in the configuration including the inflow guides 28, 28,..., Cooling water can flow between the inflow guides 28, 28, so that the cooling is performed in the downstream area of the inflow guides 28, 28,. No water stagnation occurs.
In the present embodiment, an example in which the inflow guide 28 is simultaneously formed by press molding at the time of press molding of the heat transfer pipe 15 is illustrated, but the inflow guide is not limited to that formed by press molding, for example, A substantially cylindrical member prepared as a separate member may be fixed to the outer peripheral surface of the heat transfer pipe by welding or the like to form the inflow guide.

That is, in the EGR cooler 11 according to the second embodiment of the present invention, the guide member is an inflow that is a plurality of substantially cylindrical protrusions protruding from the outer peripheral surface of each heat transfer pipe 15. Guides 28, 28,...
With such a configuration, it is possible to easily form a resistance portion for guiding the cooling water to the inlet portion 17a without causing stagnation of the cooling water in the downstream area of the inflow guides 28,.

  In the present embodiment, the EGR cooler 11 has a configuration including the inflow guides 18 and 28 and the outflow guide 19, but the EGR cooler 1 includes the inflow guides 18 and 28 and the outflow guide 19. It is also possible.

Next, the structure of the EGR cooler according to the present invention when a circular heat transfer pipe is employed will be described with reference to FIG.
In each EGR cooler 1 * 11 which concerns on 1st and 2nd embodiment of this invention, although the case where each heat-transfer pipe 5 * 15 is an aspect which has a flat shape is illustrated and demonstrated, this invention The heat transfer pipe that constitutes the EGR cooler according to the present invention does not necessarily have a flat shape, and may employ a generally used circular heat transfer pipe.

  That is, according to the third embodiment of the present invention, the heat transfer pipe 5 having a flat shape in the EGR cooler 1 according to the first embodiment of the present invention is replaced with a plurality of circular heat transfer pipes. An EGR cooler (not shown) can be configured. The EGR cooler according to the third embodiment of the present invention can be configured using an end plate 23 as shown in FIG.

The end plate 23 is a member for supporting each end of the circular heat transfer pipe (not shown) on the upstream side in the EGR gas flow direction. The end plate 23 includes an axial direction of the heat transfer pipe. A plurality of fitting holes 23a, 23a,..., Which correspond to a cross-sectional shape by planes orthogonal to each other and are holes to be fitted to the heat transfer pipe, are formed.
The plurality of fitting holes 23a, 23a,... Formed in the end plate 23 are formed by replacing one flat fitting hole 3a (see FIG. 3) in the end plate 3 with 15 circular fitting holes. It is set as the aspect replaced by 23a * 23a ....

In the end plate 23, like the end plate 3, cooling water grooves 27, 27..., Which are a plurality of groove portions similar to the cooling water groove 7, are formed on the surface in contact with the cooling water. .
The cooling water grooves 27, 27,... Are boundaries between the fitting holes 23a, 23a,... And boundary portions 23b, 23b,. Are formed in adjacent portions 23c and 23d which are portions adjacent to the respective fitting holes 23a, 23a,.

  Further, the EGR cooler according to the third embodiment of the present invention has a shape corresponding to the end plate 23 and does not include the cooling water grooves 27, 27,... Disposed on the downstream side of the EGR gas. A pair of end plates (not shown) are used.

  Further, by replacing the heat transfer pipe 15 having a flat shape in the EGR cooler 11 according to the second embodiment of the present invention with a plurality of circular heat transfer pipes, according to the fourth embodiment of the present invention. An EGR cooler (not shown) can be configured. The EGR cooler according to the fourth embodiment of the present invention can be configured using an end plate 33 as shown in FIG.

The end plate 33 is a member for supporting each end of the circular heat transfer pipe (not shown) on the upstream side in the EGR gas flow direction. The end plate 33 includes an axial direction of the heat transfer pipe. A plurality of fitting holes 33a, 33a,..., Which correspond to a cross-sectional shape by planes orthogonal to each other and are holes to be fitted to the heat transfer pipe, are formed.
The plurality of fitting holes 33a, 33a... Formed in the end plate 33 are formed by replacing one flat fitting hole 13a (see FIG. 7) in the end plate 13 with 15 circular fitting holes. It is set as the aspect which replaces with 33a * 33a ....

In the end plate 33, like the end plate 13, a plurality of cooling water holes 37, 37..., Which are holes similar to the cooling water holes 17, are formed on the surface in contact with the cooling water. Yes.
The cooling water holes 37, 37,... Are portions between the fitting holes 33a, 33a, and the boundary portions 33b, 33b,. Are formed in adjacent portions 33c and 33d that are portions adjacent to the respective fitting holes 33a, 33a, ... and that form the support portions of the heat transfer pipes by the end plate 33.

  Further, the EGR cooler according to the fourth embodiment of the present invention has a shape corresponding to the end plate 33 and does not include the respective cooling water holes 37, 37,... Disposed on the downstream side of the EGR gas. A pair of end plates (not shown) are used.

That is, each of the EGR coolers 1 and 11 according to the first to fourth embodiments of the present invention includes a plurality of heat transfer pipes 5, 5,. 15 ... or each tubular heat transfer pipe (not shown), and the casing 2 which is a housing containing the heat transfer pipes 5, 5 ... etc., and inside the casing 2, Each of the end plates 3, 13, 23, 33, etc., which are a pair of support plates that are members for supporting the heat transfer pipes 5, 5,. 14 and the like, and a flow path of the cooling water is formed by the casing 2, the end plates 3, 13, 23, and 33, and the end plates 4 and 14, and the like. Of each of the end plates 3 and 23 The cooling water channels 7 and 27, which are cooling water channels for circulating the cooling water in the interior, are formed, or the cooling water is circulated through the end plates 13 and 33 within the thickness of the end plates 13 and 33. The cooling water holes 17 and 37, which are cooling water passages for the purpose, are formed.
With such a configuration, the heat transfer pipes 5, 5,..., The heat transfer pipes 15, 15... And the circular heat transfer pipes are supported by the end plates 3, 13, 23, 33. The periphery of the part can be cooled.

In addition, in EGR coolers (for example, each EGR cooler 1 * 11 which concerns on 1st and 2nd embodiment) provided with the heat-transfer pipe which has a flat shape, EGR cooler (for example, 3rd) Compared with each EGR cooler according to the fourth embodiment), heat is likely to be generated at the support portion of the heat transfer pipe by the end plate, and therefore, it is necessary to reliably cool the support portion of each heat transfer pipe by the end plate. Becomes higher.
For this reason, in each EGR cooler 1 * 11 which concerns on 1st and 2nd embodiment of this invention, it enables reliable cooling to the inside of the thickness of each end plate 3 * 13, The effectiveness of the effect of the present invention that the support portions of the heat transfer pipes 5 and 15 can be reliably cooled is particularly high.

That is, in each EGR cooler 1 * 11 which concerns on 1st and 2nd embodiment of this invention, each heat-transfer pipe 5 * 15 has a flat shape.
With such a configuration, even each EGR cooler 1, 11 provided with each heat transfer pipe 5, 15 having a flat shape, each heat transfer pipe 5, 5... And each heat transfer pipe 15, 15,. The periphery of the support portion by the end plate 3 and the end plate 13 can be cooled.

1 EGR cooler (first embodiment)
2 Casing 3 End plate (EGR gas upstream side)
4 End plate (downstream of EGR gas)
5 Heat transfer pipe 7 Cooling water groove 11 EGR cooler (second embodiment)
13 End plate (EGR gas upstream side)
14 End plate (downstream of EGR gas)
15 Heat Transfer Pipe 17 Cooling Water Hole 18 Inflow Guide 19 Outflow Guide 28 Inflow Guide 23 End Plate 33 End Plate

Claims (8)

A plurality of heat transfer pipes through which EGR gas circulates;
A housing containing the plurality of heat transfer pipes;
Inside the housing, a pair of support plates that are members for supporting the plurality of heat transfer pipes at both ends in the length direction;
With
An EGR cooler that forms a flow path of cooling water by the housing and the pair of support plates,
In the support plate,
Forming a cooling water channel for circulating the cooling water within the thickness of the support plate;
An EGR cooler characterized by that. The heat transfer pipe is
Having a flat shape,
The EGR cooler according to claim 1. The cooling water channel,
Forming one end of the plurality of heat transfer pipes on the support plate for supporting each end of the inflow side of the EGR gas;
The EGR cooler according to claim 1 or 2, wherein the EGR cooler is provided. The cooling water channel,
An inlet portion which is a hole formed in the upstream side in the flow direction of the cooling water and is formed in the thickness of the support plate; and an outlet portion which is a hole formed in the downstream side in the flow direction of the cooling water; A communication hole that is a hole for communicating the inlet portion and the outlet portion;
The EGR cooler as described in any one of Claims 1-3 characterized by the above-mentioned. In the cooling water flow path formed by the casing and the pair of support plates,
A first guide member that is a resistance portion for guiding cooling water to the inlet portion;
The EGR cooler according to claim 4. The first guide member is
It is a wall-like protrusion protruding from the outer peripheral surface of the heat transfer pipe,
The EGR cooler according to claim 5. The first guide member is
A plurality of substantially cylindrical protrusions protruding from the outer peripheral surface of the heat transfer pipe,
The EGR cooler according to claim 5. In the cooling water flow path formed by the casing and the pair of support plates,
A second guide member that is a resistance portion for guiding the cooling water flowing out from the outlet portion to a downstream region of the first guide member;
The EGR cooler according to claim 5 or 6, wherein the EGR cooler is characterized.

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