EP2786084A1

EP2786084A1 - Heat exchanger for gas, particularly for engine exhaust gases

Info

Publication number: EP2786084A1
Application number: EP12794337.1A
Authority: EP
Inventors: Carlos Rodrigo Marco; Juan Carlos De Francisco Moreno; Eva Tomas Herrero; Serafin URZAY EJEA
Original assignee: Valeo Termico SA
Current assignee: Valeo Termico SA
Priority date: 2011-12-01
Filing date: 2012-11-30
Publication date: 2014-10-08
Also published as: US20140345839A1; WO2013079656A1; ES2406184A2; ES2406184B1; ES2406184R1; KR20140106610A

Abstract

Heat exchanger (1) for gas, particularly for engine exhaust gases, which comprises a plurality of parallel tubes (2) arranged inside a header (3) and through which the gases to be cooled by exchange of heat with a coolant flow, and fins (9) that disturb the flow of the gas and that are arranged inside each tube (2). The tubes (2) and the header (3) comprise a plurality of protrusions (10) and (11) respectively, the distribution pattern and dimensions of which are defined according to the dimensions of the tubes (2) and of the header (3) and which are able to guarantee suitable distribution of the compression between the header (3), the tubes (2) and the fins (9) relative to one another while the heat exchanger (1) is being assembled and brazed in the furnace. Perfect distribution of the compression between the assembled components and good furnace-soldering of the exchanger are thereby achieved.

Description

HEAT EXCHANGER FOR GASES, ESPECIALLY FOR EXHAUST GASES FROM AN ENGINE

The present invention relates to a heat exchanger for gas, in particular for the exhaust gases of an engine.

The invention is particularly applicable in heat exchangers of engine exhaust gas recirculation (EGRC).

BACKGROUND OF THE INVENTION

In some heat exchangers for gas cooling, for example those used in exhaust gas recirculation systems to the inlet of an internal combustion engine, the two heat exchanging media are separated by a wall.

The basic principle in a heat exchanger is the exchange of heat between two fluids at different temperatures. The hot fluid and the cold fluid usually flow through independent circuits located as close as possible to one another. The efficiency of the exchange depends on the mass flow rate, the speed, the specific heat and the temperature of each fluid relative to each other. The design of each circuit, the design of the separation wall and the raw materials are also important.

The current configuration of EGR exchangers on the market is a metal heat exchanger typically made of stainless steel or aluminum.

The heat exchanger itself may have various configurations: for example, it may consist of a housing inside which are arranged a series of parallel conduits for the passage of gases, the cooling fluid circulating in the housing, to the outside ducts; in another embodiment, the exchanger consists of a series of parallel plates which constitute the heat exchange surfaces, so that the exhaust gases and the cooling fluid circulating between two plates in alternating layers .

In the case of duct heat exchangers, the connection between the ducts and the housing can be of different types. Generally, the conduits are fixed at their ends between two support plates connected to each end of the housing, the two support plates having a plurality of orifices for the placement of the respective ducts. These support plates are in turn attached to connecting means to the recirculation line.

These connection means may consist of a V-shaped connection or a peripheral flange connection or flange, depending on the design of the recirculation pipe where is assembled the heat exchanger. In some cases, the support plate is made in one piece with the connecting means and forms a single connecting flange. The connection means may also consist of a gas reservoir disposed at one end of the housing or both.

In both types of EGR exchangers, most of their components are metallic, so that they are assembled by mechanical means and then oven-welded or arc-welded or laser-welded to ensure the proper sealing required this application. In some cases, they may also include some plastic components, which may have a single function or several functions integrated in one piece.

In tabular exchangers, the use of fins or corrugations inside the heat exchange circuits is known, since they contribute to improving the heat exchange as well as the mechanical strength of the heat exchanger.

The corrugations or fins help to guide the fluid so that it can properly fill the entire circuit, promote heat exchange and improve the mechanical resistance to an increase in pressure in the circuit.

The patent application ES 2331218 of the same holder as the present application describes a tabular heat exchanger with a housing which comprises a series of protuberances stamped on its surface and directed towards the inside thereof, so that said protuberances are arranged to a predetermined distance from the set of tubes, thereby ensuring a controlled expansion of the tubes in case of pressure increase.

JP20010130114 discloses a heat exchanger which comprises a gas tube bundle of rectangular section inside which it has fins of cross-section crenellated, the smooth portions which form the ridge and the valley are in contact with the inner surface of the tube, and a plurality of protuberances disposed in the walls of the tube in opposition to said smooth parts of the fins. This provision of the protuberances allows the correct placement of the fin inside the tube and prevents it from dislodging. Patent DE19961054368 discloses a heat exchanger which comprises a bundle of gas tubes of rectangular section disposed inside a housing. The tubes include outwardly directed protuberances which determine the distance between adjacent tubes and with respect to the interior surface of the housing.

It is known that during assembly, successful integration of the fins into the tubes is achieved only if the fins can be fully brazed to the tubes. In the opposite case, the mechanical strength and the increase in thermal efficiency can not be guaranteed.

The process of furnace brazing of the assembly constituted by the tubes, the housing and the fins is carried out after an overall assembly of the various components of the exchanger. However, the quality of the final furnace weld will be appropriate provided that complete component contact is ensured during the furnace brazing process. DESCRIPTION OF THE INVENTION

The purpose of the gas heat exchanger, in particular the exhaust gases of an engine, according to the present invention is to solve the disadvantages of exchangers known in the art, by offering a perfect distribution of the compression between the assembled components, as well as a good oven welding of the exchanger.

The gas heat exchanger, in particular the exhaust gas of an engine, object of the present invention is of the type which comprises a plurality of parallel tubes arranged inside a housing, through which the gases circulate. cooling by heat exchange with a coolant, and fins disrupting the flow of gas disposed within each tube, and is characterized in that the tubes and the housing respectively comprise a plurality of protuberances whose pattern of distribution and dimensions are defined according to the dimensions of the tubes and the housing, which are able to guarantee a good distribution of the compression between the housing, the tubes and the fins vis-à-vis each other during the brazing of the exchanger.

The invention is therefore based on a particular pattern and dimensions of the protuberances disposed on the surface of the housing and the tubes.

In this way, the tubes are optimally designed to obtain a good baking of the fins used. At the same time, the design improves the robustness of the mechanical resistance during the lifetime of the exchanger. The advantages obtained thanks to the design of the protuberances according to the invention are described below:

- The heat exchanger housing compresses the tubes and fins at the same time.

- The tubes, after assembly, can compress the fins to ensure good contact with the tubes.

- The contact of the housing and the tubes is ensured by the contact of the protuberances. These protuberances allow at the same time the distribution of cooling fluid and the contact between the components.

- The housing and tubes have the same pattern of protuberances to compress the components at the same time.

- The pattern and the dimension of the protuberances make it possible to obtain a perfect distribution of the compression and finally a good soldering of the exchanger.

Preferably, the protrusions are made by stamping, each protuberance comprising a substantially planar and circular projecting contact surface and a frustoconical side defined by an embossing angle and fitting radii with respect to said contact surface and to the surface. of the tube or housing where the protuberance is stamped.

Advantageously, the dimensions of the protuberances respectively of the tubes and the housing are defined by their diameter and height, the stamping angle and the connecting radii of the frustoconical side.

Advantageously, the pattern of distribution of the protuberances on the tubes is defined according to the thickness, the width and the length of the tube itself, the tubes, of substantially rectangular cross-section, being provided with two wider flat opposed sides. that high.

Preferably, the protuberances are disposed on the two opposite flat sides of the tubes, oriented towards the outside of the tube and distributed in one or more longitudinal rows depending on the width of the tube.

According to a first embodiment for the tubes, the protuberances of the same row on the tubes are spaced apart by a predetermined distance defined by the length of the tube and the first protrusion of the corresponding row is arranged relative to a end of the tube at a distance predetermined also defined by the length of the tube.

According to a second embodiment for the tubes, the protuberances on the tubes are distributed in two longitudinal rows parallel to each other, equidistant from a longitudinal axis of symmetry and spaced apart by a predetermined distance defined according to the width of the tube.

Preferably, between the two rows of protuberances on the tubes there are two reinforcing end protuberances each located with respect to one end of the tube at a predetermined distance defined by the length of the tube.

Advantageously, the pattern of distribution of the protuberances on the housing is defined according to the width of the tube and the thickness, the width and the length of the housing, the housing having a substantially rectangular cross section.

Preferably, the protuberances are disposed on at least one side of the housing, directed towards the inside of the housing and distributed in one or more groups of two longitudinal rows depending on the width of the housing.

According to a first embodiment for the housing, the protuberances of the same row on the housing are spaced apart by a predetermined distance defined by the length of the housing and the first protrusion of the corresponding row is arranged with respect to a end of the housing at a predetermined distance also defined by the length of the housing.

According to a second embodiment for the housing, the protuberances on the housing are divided into two groups of two longitudinal rows, parallel to each other and spaced apart by a predetermined distance defined as a function of the width of the housing, and both Groups of two rows are equidistant from a longitudinal axis of symmetry.

Preferably, between the two rows of protuberances of each group there are two end protrusions in reinforcement each located with respect to an end of the housing at a predetermined distance defined by the length of the housing.

Advantageously, the protuberances may have different shapes such as, inter alia, circular, cross, diamond or linear.

BRIEF DESCRIPTION OF THE DRAWINGS

To facilitate the description of what we have explained before, we enclose drawings on which, schematically and only by way of non-limiting example, are represented various practical cases of embodiment of the exchanger thermal device for gases, in particular for the exhaust gases of an engine, according to the invention, among which:

Figure 1 is a perspective view of a known heat exchanger with protuberances on the housing;

Figure 2 is a perspective view of the heat exchanger of the

Figure 1, without the gas tanks and in a longitudinal section of the housing to show the set of parallel tubes housed inside thereof;

Figure 3 is a cross-sectional view of a tube showing the fins housed therein and the protuberances of the invention;

Figure 4 is a perspective view of a tube with a single row of protuberances, according to a first embodiment of the invention;

Figure 5 is an elevational view of the tube of Figure 4; Figure 6 is a plan view of the tube of Figure 4;

Figure 7 is a detailed cross section of a protuberance of the tube along line VII-VII of Figure 6;

Figure 8 is a plan view of the housing with a group of two rows of protuberances, according to the first embodiment of the invention;

Figure 9 is a detailed cross-section of a protrusion of the housing along the line IX-IX of Figure 8;

Figure 10 is a perspective view of a tube with two rows of protuberances, according to a second embodiment of the invention;

Figure 11 is an elevational view of the tube of Figure 10;

Figure 12 is a plan view of the tube of Figure 10; Fig. 13 is a detailed cross section of a protrusion of the tube along the line XIII-XIII of Fig. 12;

Figure 14 is a plan view of the housing with two groups of two rows of protuberances, according to the second embodiment of the invention;

Figure 15 is a detailed cross section of a housing protrusion along the line XV-XV of Figure 14;

Figures 16a to 16e are plan views of five protuberances having different shapes and orientations;

Figure 17 is a diagram concerning the sensitivity of the position of the protuberances; and

Fig. 18 is a diagram relating to the sensitivity of the thickness of the solder material. DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring to Figures 1 to 3, the heat exchanger 1 for gas, in particular for the exhaust gas of an engine, comprises a set of parallel tubes 2 which in this example are flat and of rectangular section, intended the circulation of gases with heat exchange with a cooling fluid. Said set of parallel conduits 2 is housed inside a housing 3 which in this case is also of rectangular section.

Figure 2 shows the housing 3 longitudinally sectioned to show inside thereof the set of parallel tubes 2. The two ends of the set of parallel ducts 2 are each fixed on a support plate 4 which has a plurality of orifices for the introduction of the respective conduits 2. Each support plate 4 is assembled at the corresponding end of the housing 3.

In this embodiment, the housing 3 comprises at each of its two ends a gas reservoir 5 assembled to the gas recirculation pipe, although a connection flange and a gas tank could also be used. Also, the housing 3 comprises an inlet duct 6 and an outlet duct 7 of the cooling circuit.

To improve the heat exchange and the mechanical strength of the exchanger 1, fins 9 are used inside the tubes 2 as can be seen in FIG. 3.

The process of brazing of the assembly formed by the tubes 2, the housing 3 and the fins 9 after the overall assembly of the different components of the exchanger 1 is carried out. The quality of the final oven-welding will be appropriate provided to ensure complete component contact during the oven brazing process.

Similarly, the tubes 2 and the housing 3 comprise a plurality of protuberances, respectively 10 and 11, whose distribution pattern and dimensions are defined according to the dimensions of the tubes 2 and the housing 3 and which are capable of guaranteeing a distribution. appropriate compression between the housing 3, the tubes 2 and the fins 9 relative to each other during assembly and brazing of the exchanger 1.

Hereinafter two embodiments of protrusion patterns are described respectively on the tubes 2 and on the housing 3. In these cases, the protuberances 10, 11 are made by stamping and have a circular configuration. Each protrusion 10, 11 comprises a contact surface 12 projecting substantially planar and circular and a frustoconical side defined by an embossing angle A and RR connecting radii with respect to said contact surface 12 and the surface of the tube 2 or the housing 3 which is embossed the protrusion 10, 11.

The dimensions of the protuberances 10, 11 respectively of the tubes 2 and the housing 3 are defined by their diameter D and height H, the stamping angle A and the RR connecting radii of the frustoconical side.

According to a first embodiment for the tube 2 illustrated in FIGS. 4 to 7, there is shown a tube 2 with a single row of protuberances 10.

The definition of the pattern of protuberances 10 is determined by the following geometric relationships:

H = (1 to 4) x Tl

D = (0.1 to 0.5) x W1 and / or D = (0.06 to 0.4) x DD

RR = (0.5 to 2) x Tl and / or RR = (0, 1 to 0.6) x H

45 ° <A <75 °

DD = (0.05 to 0.6) x L1

DDE = (0.05 to 0.6) x L1

Row position of protuberances 10 carried by the longitudinal symmetry line of the tube + / - 10 mm

Protrusions distributed over a row if: 10 <Wl <30 mm

Protrusions distributed in two rows if: 26 <Wl <45 mm where:

H: Height of the protuberance 10.

D: Diameter of the contact surface 12 of the protuberance 10.

RR: Radius of connection to the contact surface 12 and to the surface of the tube

2.

A: Angle of stamping of the protuberance 10.

Tl: Thickness of the tube 2.

Wl: Width of the tube 2.

Ll: Length of the tube 2.

DD: Distance between protuberances 10 of the same row.

DDE: Distance between the center of the first protrusion 10 of a row and a end of the tube 2.

According to a first embodiment for the housing 3 illustrated in FIGS. 8 and 9, there is shown a housing 3 with a single group of two rows of protuberances 11.

The definition of the pattern of protuberances 11 is determined by the following geometrical relations:

P = (1 to 4) x T2

D = (0.1 to 0.5) x Wl

RR = (0.5 to 2) x T2 and / or RR = (0, 1 to 0.6) x H

DD = (0.05 to 0.6) x L2

DDE = (0.05 to 0.6) x L2

Position of a row of protuberances 11 centered on the longitudinal axis of symmetry of the housing +/- 10 mm where:

P: Depth of the protuberance 11.

H: Height of the protuberance 11.

D: Diameter of the contact surface 12 of the protuberance 11.

RR: Connection radius with respect to the contact surface 12.

T2: Case thickness 3.

Wl: Width of the tube 2.

L2: Length of housing 3.

DD: Distance between protuberances 11 of the same row.

DDE: Distance between the center of the first protrusion 11 of a row and one end of the housing 3.

According to a second embodiment for the tube 2 illustrated in Figures 10 to 13, there is shown a tube 2 with two rows of protuberances 10 parallel to each other.

Also, between the two rows of protuberances 10 on the tubes 2 there are two protruding end protrusions 10a having a rectangular configuration with two half-circles at the smallest opposite ends.

The definition of the protuberance pattern 10 is determined by the following geometric relationships:

H = (1 to 4) x Tl

D = (0.1 to 0.5) x W1 and / or D = (0.06 to 0.4) x DD

RR = (0.5 to 2) x Tl and / or RR = (0, 1 to 0.6) x H

45 ° <A <75 °

Protrusions distributed over a row if: 10 <Wl <30 mm

Protrusions distributed in two rows if: 26 <Wl <45 mm

Number of protuberances: at least 1 protrusion per 100 to 600 mm ²

DDH = (0.05 to 0.6) x L1

DDV = (0.2 to 0.8) x Wl

DDE = (0.05 to 0.6) x L1

DDEIA = (0.05 to 0.6) x L1

DDE1B = (0.05 to 0.6) x L1 where:

H: Height of the protuberance 10.

D: Diameter of the contact surface 12 of the protuberance 10.

RR: Radius of connection with respect to the contact surface 12 and the surface of the tube 2.

A: Angle of stamping of the protuberance 10.

Tl: Thickness of the tube 2.

Wl: Width of the tube 2.

Ll: Length of the tube 2.

DDH: Distance between protuberances 10 of the same row.

DDV: Distance between rows.

DDE: Distance between the first protuberance 10 of a row and an end of the tube 2.

DDEIA: Distance between a first center of an end protrusion 10a and an end of the tube 2.

DDE1B: Distance between a second center of an end protrusion 10a and an end of the tube 2.

According to a second embodiment for the housing 3 illustrated in FIGS. 14 and 15, there is shown a housing 3 with two groups of two rows of protuberances 11 parallel to each other.

Also, between the two rows of protuberances 11 of each group there are two protruding end projections 11a, in this case circular.

P = (1 to 4) x T2

D = (0.1 to 0.5) x Wl

RR = (0.5 to 2) x T2 and / or RR

DDH = (0.05 to 0.6) x L2

DDV = (0.2 to 0.8) x W2

DDE = (0.05 to 0.6) x L1

DDE1 = (0.05 to 0.6) x L1 where:

P: Depth of the protuberance 11.

H: Height of the protuberance 11.

D: Diameter of the contact surface 12 of the protuberance 11.

RR: Connection radius with respect to the contact surface 12.

T2: Case thickness 3.

Wl: Width of the tube 2.

W2: Width of the housing 3.

L2: Length of housing 3.

DDH: Distance between protuberances 11 of the same row.

DDV: Distance between the rows of the same group.

DDE1: Distance between the center of an end protrusion l ia and one end of the housing 3.

It should be emphasized that, although there are shown protuberances 10, 11 having a circular configuration, they may also have other shapes, such as elongated with different orientations (see Figures 16a to 16c), cross-shaped (Figure 16d) or diamond-shaped (Figure 16e), among others.

Similarly, tests with prototypes were carried out to analyze the relationship between the thickness of the weld material and the distance of the protuberances from the gap in the weld joint.

The results of a first test can be observed on the graph of Figure 17, which shows the sensitivity of the position of the protuberances 10, 11, establishing a ratio between the distance between the protuberances and the gap existing in the seal. assembly when the fin 9 is introduced into the tube 2.

The results indicate that if the distance between protuberances is reduced, the deformations during the assembly process are avoided (deformation of the tube 2), whereby a smaller size of the gap between the tubes 2 and the fins 9 is obtained. The maximum permissible gap in this technology is 0.15 mm, which corresponds to a distance between protuberances of 40 mm. The larger the gap size, the larger the furnace soldering defects and the lower the mechanical strength.

The results of a second test can be seen in the graph of Figure 18, which shows the sensitivity of the thickness of the solder material, by establishing a relationship between the thickness of the solder material and the gap in the weld material. assembly joint when the fin 9 is introduced into the tube 2.

The results indicate that the larger the gap size, the greater the thickness of the solder material required and therefore the more expensive the product. The maximum permissible gap in this technology is 0.15 mm, which corresponds to a solder thickness of 50 microns.

Claims

A heat exchanger (1) for gases, in particular for the exhaust gases of an engine, which comprises a plurality of parallel tubes (2) arranged inside a housing (3) and through which the gas to be cooled by heat exchange with a cooling fluid, and fins (9) disturbing the flow of gas arranged inside each tube (2), characterized in that the tubes (2) and the housing ( 3) comprise a plurality of protuberances (10) and (11) respectively, whose distribution scheme and dimensions are defined according to the dimensions of the tubes (2) and the housing (3), which are capable of ensuring an appropriate distribution compression between the housing (3), the tubes (2) and the fins

(9) vis-à-vis each other during the brazing of the exchanger (1).

2. Exchanger (1) according to claim 1, wherein the protuberances (10, 11) are formed by stamping, each protrusion (10, 11) comprising a contact surface (12) projecting substantially flat and circular and a frustoconical side defined by an embossing angle (A) and connecting radii (RR) with respect to said contact surface (12) and the surface of the tube (2) or housing (3) where the protuberance (10) is stamped. , 11).

3. Exchanger (1) according to claim 2, wherein the dimensions of the protuberances (10, 11) respectively of the tubes (2) and the housing (3) are defined by their diameter (D) and their height (H) and the stamping angle (A) and the connecting radii (RR) of the frusto-conical side.

4. Exchanger (1) according to claim 1 or 2, wherein the pattern of distribution of the protuberances (10) on the tubes (2) is defined according to the thickness (T1), the width (W1) and the length (Ll) of the pipe (2) itself, the tubes (2) being of substantially rectangular cross section and having two flat opposed sides wider (Wl) than high.

5. Exchanger (1) according to claim 4, wherein the protuberances

(10) are arranged on the two opposite flat sides of the tubes (2), directed towards the outside of the tube (2) and distributed over one or more longitudinal rows according to the width (W1) of the tube (2).

6. Exchanger (1) according to claim 5, wherein the protuberances (10) of the same row on the tubes (2) are spaced apart by a predetermined distance (DD, DDH) defined by the length (Ll) of the tube (2) and the first protuberance (10) of the corresponding row is disposed with respect to an end of the tube (2) at a predetermined distance (DDE) also defined by the length (Ll) of the tube (2).

7. Exchanger (1) according to claim 5, wherein the protuberances (10) on the tubes (2) are distributed in two parallel longitudinal rows, equidistant from a longitudinal axis of symmetry and spaced apart by a predetermined distance (DDV) defined according to the width (W1) of the tube (2).

8. Exchanger (1) according to claim 7, wherein between the two rows of protuberances (10) on the tubes (2) there are two protruding end protrusions (10a) each located relative to the opposite ends of the tube ( 2) at a predetermined distance (DDE1, DDE2) defined by the length (L1) of the tube (2).

9. Exchanger (1) according to claim 1, characterized in that the distribution pattern of the protuberances (11) on the housing (3) is defined according to the width

(W1) of the tube (2), and the thickness (T2), the width (W2) and the length (L2) of the housing (3), the housing (3) having a substantially rectangular cross section.

10. Exchanger (1) according to claim 9, wherein the protuberances (11) are arranged on at least one side of the housing (3), directed towards the inside of the housing.

(3) and distributed in one or more groups of two longitudinal rows depending on the width (W2) of the housing (3).

11. Exchanger (1) according to claim 10, wherein the protuberances (11) of the same row are spaced apart by a predetermined distance (DD, DDH) defined by the length (L2) of the housing (3) and the first protuberance (11) of the corresponding row is disposed with respect to an end of the housing (3) at a predetermined distance (DDE) also defined by the length (L2) of the housing (3).

12. Exchanger (1) according to claim 10, wherein the protuberances (11) are divided into two groups of two parallel longitudinal rows and spaced apart by a predetermined distance (DDV) defined according to the width (W2) of housing (3) and the two groups of two rows are arranged equidistant from the longitudinal axis of symmetry.

13. Exchanger (1) according to claim 12, wherein, between the two rows of protuberances (11) of each group there are two protuberances (l ia) end reinforced each relative to the opposite ends of the housing (3). ) at a predetermined distance (DDE1) defined by the length (L2) of the housing (3).

14. Exchanger (1) according to claim 1, wherein the protuberances (10, 11) may have different shapes such as among others circular, cross, diamond or linear.