Exhaust gas heat exchanger
A tube is constituted by a pair of plates which are fitted with each other in such a manner as to put an inner fin between the plates. Differences in level are formed between the two plates, which differences in level is compensated by either a tapered wall or a stepped wall, whereby the outer wall surface of the tube is made substantially level thereover. A gap which is formed between the outer wall surface of the tube and a core plate, when the tube is passed through the core plate, can be as small as possible whereby the brazing properties can be improved.
This application is a divisional of U.S. patent application Ser. No. 10/189,612 filed on 07/03/2002. This application claims the benefit of JP 2001-215822, filed 01/16/2001. The disclosure of the above applications are incorporated herein by reference.
BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention relates to an exhaust gas heat exchanger, for performing heat exchange between exhaust gases produced when fuel is burnt in an engine and a cooling fluid such as water and, more particularly, to an exhaust gas heat exchanger for cooling exhaust gases for an EGR (exhaust gas recirculation) system (hereinafter referred to as an “EGR-gas heat exchanger”).
2. Description of the Related Art
As a conventional EGR-gas heat exchanger, an EGR-gas heat exchanger is described, for example, in Japanese Unexamined Patent Publication No. 2001-33187 (Kokai). The heat exchanger is constituted by a plurality of stacked tubes which are received in the interior of a tank. The tank is closed with end plates (core plates) and the tubes are secured to the core plates. Connected to the tank are an coolant inlet pipe and an coolant outlet pipe, whereby coolant flows into the tank to remove heat from exhaust gases which pass through the tubes.
It is generally known, as one of means for improving the heat exchange capacity of a heat exchanger, to provide inner fins in tubes of the heat exchanger. Known generally, as a method for producing such a tube, is a method comprising the steps of, for example, inserting an inner fin in a welded tube, bringing the tube into close contact with the inner fin by applying an external force to the tube, and brazing the inner fin to the tube.
Incidentally, with an EGR-gas heat exchanger, an Ni system brazing material is used to braze respective members in order to prevent corrosion caused by condensate produced when exhaust gases are cooled. In general, a brazing material in a paste form is used as the Ni system brazing material and is thinly applied to portions to be joined together.
Thus, in the event that the aforesaid production method is used, in which the inner fins are inserted into the tubes, the applied brazing material is stripped off when the inner fin is inserted, leading to a possibility that sufficient brazing material cannot be provided between the tube and the inner fin.
To cope with this problem, the inventor, et al. produced, by way of a trial, and studied a tube 1, as shown in
Since the tube shown in
An object of the invention is to obtain good brazing properties for an EGR-gas heat exchanger using therein tubes which are each constructed by a pair of plates adapted to fit with each other.
With a view to attaining the object,. the invention adopts the following technical means. According to a first aspect of the invention, the tube has first and second plates which each have a substantially U-shaped cross section and which are caused to fit with each other in such a manner as to face each other and an inner fin disposed in the interior of the tube for promoting heat exchange between exhaust gases and coolant. The second plate fits in the first plate in such a manner that the former is disposed in the inside of the latter, and a difference in level is formed at each of fitting portions of the second plate over which the first plate fits which difference in level is substantially equal in height to the thickness of the first plate and protrudes inwardly in the tube.
According to the first aspect of the invention, as the difference in level is formed on each side of the second plate which is substantially equal in height to the thickness of the first plate and which protrudes inwardly in the tube, no difference in level is formed between the fitting portion where the second plate fits in the first plate and an external wall surface of the second plate, and an external wall surface of the tube becomes substantially level thereover. Due to this, a gap generated between the external wall surface of the tube and an edge of an opening in the core plate can be made small, whereby the implementation of brazing can be ensured.
In addition, according to a second aspect of the invention, the tube has first and second plates which each have a substantially U-shaped cross section and which are caused to fit with each other in such a manner as to face each other and an inner fin disposed in the interior of the tube for promoting heat exchange between exhaust gases and coolant. The first plate fits on the outside of the second plate, and side edge portions of the first plate which fit on the second plate are configured so as to follow bent portions of the second plate which result from bending corresponding portions of the second plate.
According to the second aspect of the invention, as the portions of the first plate where the first plate fits on the second plate are configured so as to follow the bent portions of the second plate which result from bending the corresponding portions of the second plate, there is formed no difference in level between the fitting portions where the second plate fits in the first plate and an external wall surface of the second plate, an external wall surface of the tube becomes substantially level thereover. Due to this, a gap generated between the external wall surface of the tube and an edge of an opening in the core plate can be made small, whereby the implementation of brazing can be ensured.
According to a third aspect of the invention, the number of components can be reduced by making the first and second plates identical to each other in configuration.
According to a fourth aspect of the invention, as portions of the second plate on which the first plate fits are bent upwardly, even if exhaust gases are cooled to produce a condensate that remains within the tube, as the condensate so remaining does not reach to contact the fitting portions where the first and the second plates are brazed to each other, the generation of corrosion that would result from the remaining condensate can be suppressed, the resistance to corrosion thereby being improved.
According to a fifth aspect of the invention, in a case where the invention is applied to an exhaust gas heat exchanger in which the inner fin and the tube are brazed to each other using a brazing material of an Ni system applied to joining portions between the inner fin and the tube, the stripping off of the brazing material at a stage of preliminary assembling prior to brazing can be prevented by constructing the tube such that the inner fin is put between the first and second plates, thereby making it possible to reduce a risk of failure in brazing.
The present invention may be more fully understood from the description of preferred embodiments of the invention set forth below, together with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGSIn the drawings:
Firstly, a first embodiment of the invention will be described. Hereinafter, embodiments of the invention will be described as an exhaust gas heat exchanging device according to the invention being applied to an EGR-gas cooling system for a diesel engine (an internal combustion engine).
Reference numeral 220 denotes a known EGR valve disposed at an intermediate position along the length of the exhaust gas recirculation pipe 210 for regulating the volume of EGR gases according to the operating conditions of the engine 200. The EGR-gas heat exchanger 100 is disposed between an exhaust side of the engine 200 and the EGR valve 220 for implementing heat exchange between EGR gases and engine coolant (hereinafter, simply referred to as “coolant”) to thereby cool the EGR gases.
Next, the construction of the EGR-gas heat exchanger 100 will be described.
Reference numeral 102 denotes a tubular tank which has a substantially rectangular cross section. Tubes 101 are stacked in such a manner that they become parallel to each other and are accommodated in the interior of the tank 102 in such a manner that the longitudinal direction of the tubes 101 and the longitudinal direction of the tank 102 coincide with each other, whereby a heat exchange core 110 is constructed.
The tank 102 is closed at the ends thereof by core plates 103. Openings 103a are formed in the core plates 103 and the ends of the respective tubes 101 which are accommodated in the interior of the tank 102 are passed through the openings 103a in the core plates 103.
A coolant inlet pipe 104 is connected to the tank 102 at a position in the vicinity of the core plate 103 on which the upstream ends of the tubes 101 are supported, and coolant flows into the interior of the tank 102 via this coolant inlet pipe 104. A coolant outlet pipe 105 is connected to the tank 102 at a position in the vicinity of the other end of the tank 102 through which coolant is allowed to flow to the outside of the tank. Thus, internal coolant passages are formed. The main stream of the coolant flows in the interior of the tank 102 in substantially the same direction as that of flows of exhaust gases which pass through the tubes 101.
Bonnets 106, 107 are connected to the longitudinal ends of the tank 102 which are opposite to the heat exchange core 110, and the core plates 103 are bent in directions opposite to the heat exchange core 110 in such a manner as to cover the circumferences of the bonnets 106, 107 and are joined thereto. An exhaust gas inlet 106a is formed in an end of the bonnet 106 disposed at the end of the tank 102 where the coolant inlet pipe 104 is connected for introducing exhaust gases into the bonnet 106, whereas an exhaust gas outlet 107a is formed in an end of the bonnet 107 disposed at the end of the tank 102 where the coolant outlet pipe 105 is connected for guiding exhaust gases to the outside of the bonnet 107. The bonnets 106, 107 each have a substantially quadrangular pyramid-like configuration in which the area of the flow path thereof gradually increases as they approach the heat exchange core 110, respectively, whereby exhaust gases are distributed to the respective tubes 101 properly.
In the EGR-gas heat exchanger 100, exhaust gases introduced from the exhaust gas inlet 106a pass through the bonnet 106 and then pass through the interior of the respective tubes 101. Exhaust gases cooled by coolant flowing around the tubes 101 then pass through the bonnet 107 and are discharged from the exhaust gas outlet 107a. On the other hand, coolant flows into the interior of the tank 102 via the coolant inlet pipe 104. In the interior of the tank 102, the coolant cools the exhaust gases passing through the tubes, and then flows to the outside of the tank 102 via the coolant outlet pipe 105.
Next, the construction of the tubes 101 will be described, the tubes 101 being a crucial portion of the invention.
The inner fin 101b is formed into a substantially rectangular wave shape, and top portions of respective rectangular waves are brazed to an inner wall surface of the tube 101.
The respective plates 111a, 111b are bent at side edge portions thereof and each have a substantially U-shaped cross section. The side edge portions of the plates 111a, 111b are bent such that they overlap each other when the plates 111a, 111b fit on and in each other and constitute fitting portions 101c. An Ni brazing material in a paste form is thinly applied to the fitting portions, each constituting a joint portion by the brazing material. A difference in level 111c is formed at each of the fitting portions of the second plate which difference in level is substantially equal in height to the thickness of the first plate 111a and protrudes inwardly in the tube 101.
In addition, a paste-like brazing material of an Ni system, which has superior resistance to corrosion, is thinly applied to locations on the inner wall surfaces of the plates 111a, 111b to which the inner fin 101b is brazed, as well as to locations on the outer wall surface of the tube 101 which are brazed to the core plates 103.
Next, a method for producing the EGR-gas heat exchanger will be described.
The first and second plates 111a, 111b are caused to fit with each other in such a manner as to put the inner fin 101b between the plate 111a and the plate 111b to thereby fabricate the tube 101. As this occurs, the second plate 111b is fitted in the first plate 111a in such a manner that the second plate 111b is disposed inside the first plate 111a and that the plates face each other in a vertical direction. The tubes 101 are stacked in such a manner that the ribs 108 are brought into abutment with each other and are accommodated in the interior of the tank 102. The ends of the tubes 101 are passed through the core plates 103 and the core plates 103 are assembled to the tank 102 in such a manner as to close the tank 102 at the ends thereof. Following this, the bonnets 106, 107 are assembled to the core plates 103, respectively, and then the coolant inlet pipe 104 and the coolant outlet pipe 105 are assembled to the tank 102. Thus, after the respective members have been assembled together, brazing is implemented on the heat exchanger 100.
According to the embodiment, as the tube 101 is constructed by the first and second plates 111a, 111b which are fitted in each other in such a manner as to put the inner fin 101b between the first plate 111a and the second plate 111b, a risk of the brazing material being stripped off can be prevented when the inner fin 101b, and the first and second plates 111a, 111b are assembled together.
In addition, as the difference in level which protrudes inwardly is formed along each of the side edge portions of the second plate 111b, the fitting portions 101c become substantially as high as the outer wall surface of the second plate 111b, whereby the outer wall surface of the tube 101 can be a surface which is substantially level thereover. Due to this, when the tube 101 is passed through the core plates 103, only a minute gap is formed between an edge of the opening 103a in the core plate 103 and the outer wall surface of the tube 101. Thus, brazing of the tubes 101 to the core plates 103 can be ensured and a leakage resulting from a failure in brazing can be prevented from occurring between the coolant passage and the exhaust gas passages.
Furthermore, as the tube 101 is constructed by causing the first and second plates to fit with each other, the ribs 108 can be formed on both the first and second plates through press molding and no special process is required for forming the ribs 108.
In addition, the first and second plates 111a, 111b each have a U-shaped cross section and can be easily formed through press forming or the like.
Next, a second embodiment will be described. While the tube has been described in the aforesaid embodiment in which the plate disposed above is designed to fit inside, as shown in
The ends of the first plate 211a, adapted to fit outside, are bent downwardly whereas ends of the second plate 211b, adapted to fit inside, are bent upwardly. As this occurs, the ends of the respective plates are bent such that an angle at which the ends of the first plate are bent becomes greater than an angle at which the ends of the second plate are bent. Note that the bent portions of the respective plates 211a, 211b constitute fitting portions 201c when both the first and second plates are caused to fit with each other.
The bent portions of the second plate 211b protrude inwardly of the tube 201 and a difference in level 211c is formed at each of the bent portions which is substantially equal to the thickness of the first plate 211a. The ends of the second plate 211b each have a length which is equal to or longer than about one half the height of the tube 201 (a width in a vertical direction as viewed in
Both the first and second plates 211a, 211b are caused to fit with each other such that the first plate 211a is positioned above and outside whereas the second plate 211b is positioned below and inside with an inner fin 101b being bracketed therein, and the first plate 211a positioned above is clamped to partially wrap the second plate 211b.
As the differences in level 211c are formed on the second plate 211b which protrude inwardly, similarly to the first embodiment, the outer wall surface of the tube 201 can be made substantially level thereover, and good brazing properties can be provided when brazing the tube 201 to core plates 103.
Incidentally, when exhaust gases pass through the tube 201, as the exhaust gases are cooled by coolant, there is produced condensate and there may be a case where condensate so produced remains in the interior of the tube 201. In the event that condensate comes to contact brazing surfaces of the fitting portions 211c, there may be a possibility that the brazing surfaces are corroded by corroding constituents contained in the condensate. According to the embodiment of the invention, however, the end portions of the second plate 211b, which is disposed inside, extend upwardly, and even if the condensate remains in the interior of the tube 201, the condensate is not allowed to be in contact with the brazing surfaces of the fitting portions 211c. As a result, the corrosion of the fitting portions 211c can be suppressed, and the resistance to corrosion of the EGR-gas heat exchanger can be increased.
In addition, according to the second embodiment, as the tube 201 has an asymmetrical configuration as viewed vertically, an assembling error can be prevented that would otherwise occur when the tube is passed through core plates 103 when it is assembled to a tank.
Next, a third embodiment will be described. While in the aforesaid embodiment the differences in level are formed on the plate which is adapted to be fittingly positioned inside and the joint potions of the plate adapted to be fittingly positioned outside are located on the differences in level, respectively, even if ends of the joint portions of the plate which is fittingly positioned outside are collapsed to be clamped to wrap up the differences in level formed on the plate which is fittingly positioned inside, so that the ends of the joint portions are configured to follow the outer wall surface of the tube, advantages similar to those provided by the first and second embodiments can be obtained. Note that like reference numerals are used to describe constituent members similar to those described with respect to the first embodiment.
Next, a fourth embodiment will be described. While in the aforesaid embodiments the tubes are formed by causing the first and second plates which have the different configurations to fit with each other, even if the tube is constructed by causing plates each having an identical configuration to fit with each other, an advantage can be obtained which is identical to those provided by the first embodiment. Note that like reference numerals are used to describe constituent members similar to those described with reference to the first embodiment.
The end 411a of the plate 411 is fitted in the other end 411b of the other plate 411 to thereby form the tube 401. As this occurs, a state is created in which the end 411b is fitted in the difference in level 411c, whereby the outer wall surface of the tube 401 is made substantially level thereover. Owing to this, good brazing properties can be provided when brazing the tube 401 to core plates 103.
While the embodiments have been described as the tubes being stacked in a single row, tubes may be constructed such that they are stacked in a plurality of rows, and the numbers of tubes to be stacked and rows of stacked tubes are not limited to any specific numbers.
It goes without saying that the invention may be applied even if brazing materials other than brazing materials of an Ni system are used. In addition, even if a brazing material is sprayed or a brazing material in a sheet form is disposed as required instead of applying the paste-like brazing material, the same effect can be obtained.
While the invention has been described by reference to specific embodiments chosen for purposes of illustration, it should be apparent that numerous modifications could be made thereto by those skilled in the art without departing from the basic concept and scope of the invention.
Claims
1. An exhaust gas heat exchanger comprising:
- a tank defining a tank passage;
- a plurality of tubes disposed within the tank passage of the tank in such a manner as to be parallel with each other, each tube defining a tube passage;
- bonnets coupled to ends of said plurality of tubes in communication with the tube passages;
- core plates having openings through which ends of said plurality of tubes are passed, respectively, the core plates defining partitions between the tank passage and the tube passages;
- said tubes each comprise:
- a first plate having a bottom wall and two transverse side walls, each transverse side wall having a curved wall portion extending from the bottom wall;
- a second plate having a bottom wall and two transverse side walls, each of the two transverse side walls of the second plate extending over a respective transverse side wall of the first plate, each of the two transverse side walls of the second plate having a curved wall conforming to the curved wall of the respective transverse side wall of the first plate.
2. The exhaust gas heat exchanger according to claim 1 further comprising an inner fin disposed with at least one of the tube passages.
3. The exhaust gas heat exchanger according to claim 1 wherein the curved walls of the second plate each define a tapered region, which reduces a thickness of the second plate.
4. The exhaust gas heat exchanger according to claim 3 further comprising an inner fin disposed with at least one of the tube passages.
5. The exhaust gas heat exchanger according to claim 1 further comprising a stepped portion formed on the first plate, the stepped portion having a height substantially equal to thickness of the second plate.
6. The exhaust gas heat exchanger according to claim 5 further comprising an inner fin disposed with at least one of the tube passages.
7. An exhaust gas heat exchanger comprising:
- a tank defining a tank passage;
- a plurality of tubes disposed within the tank passage of the tank in such a manner as to be parallel with each other; each tube defining a tube passage;
- bonnets coupled to ends of said plurality of tubes in communication with the tube passages;
- core plates having openings through which ends of said plurality of tubes are passed, respectively, the core plates defining partitions between the tank passage and the tube passages;
- said tubes each comprise:
- a first plate having a first bottom wall and two side walls, each side wall of the first plate having a side portion extending transversely to the first bottom wall and a curved portion disposed between the side portion and the first bottom wall;
- a second plate having a second bottom wall and two side walls, each side wall of the second plate having a side portion extending transversely to the second bottom wall, a curved portion disposed between the side portion and the second bottom wall and a formed portion extending from the side portion, the formed portion following the contour of the curved portion of the first plate.
8. The exhaust gas heat exchanger according to claim 7 further comprising an inner fin disposed with at least one of the tube passages.
9. The exhaust gas heat exchanger according to claim 7 wherein the formed portion of the second plate each define a tapered region, which reduces a thickness of the second plate.
10. The exhaust gas heat exchanger according to claim 9 further comprising an inner fin disposed with at least one of the tube passages.
11. The exhaust gas heat exchanger according to claim 7 further comprising a stepped portion formed on the first plate, the stepped portion having a height substantially equal to thickness of the second plate.
12. The exhaust gas heat exchanger according to claim 11 further comprising an inner fin disposed with at least one of the tube passages.
Type: Application
Filed: Jun 9, 2006
Publication Date: Oct 12, 2006
Inventors: Kazuhiro Shibagaki (Kariya-city), Akihiro Maeda (Kariya-city)
Application Number: 11/450,924
International Classification: F28F 9/02 (20060101);