FR2920706A1 - MULTIFUNCTIONAL MODULE FOR INTERNAL COMBUSTION ENGINE - Google Patents

Abstract

The subject of the present invention is a multifunctional module for an internal combustion engine, forming a structural unit and incorporating the functions of cooling the exhaust gases, regulating the re-injection of the exhaust gases and regulating, at least partially, the flow of circulation in the cooling circuit of said engine, said structural assembly being in the form of a constructive and functional unit (1), intended to be mounted on the engine block and integrating at least part of a circuit of recirculation of exhaust gas, a heat exchanger (2) for cooling said gases and at least part of the engine cooling circuit, integrating at least the water outlet housing.Module characterized in that the part of the circuit of the exhaust gas recirculation and the part of the engine cooling circuit are integrated into separate structural elements.

Description

DESCRIPTION

The present invention relates to the field of motor vehicle parts and equipment, more particularly the peripheral or accessory systems of internal combustion engines of such vehicles, and relates to a multifunctional module.

Currently, the space available under the bonnet of vehicles is increasingly restricted, especially around the engine block, and pushes to promote the integration of functions to achieve to reduce congestion, while maintaining the maintenance of their quality and durability of execution, on which depends the reliability of operation of the vehicle. Furthermore, in terms of the development and manufacture of internal combustion engine vehicles, the current trend is to reason, no longer in terms of isolated elements, ie components or parts, but in terms of assemblies. , units or modules, each fulfilling a global function or several interdependent functions. Moreover, to achieve a compact assembly, requiring no particular support structure for its maintenance under the hood of the vehicle, it would be interesting to fix such a unit directly on the engine block.

Finally, it is also advantageous, for economic reasons, to make at least some of the constituent parts of such a unit of a plastic material, the latter must however be protected against too high temperatures. The present invention aims to meet at least some of the expectations expressed above. For this purpose, the subject of the present invention is a multifunctional module for an internal combustion engine, forming a structural assembly and incorporating the functions of cooling the exhaust gases, regulating the re-injection of the exhaust gases and regulating the less partial, circulation flows in the cooling circuit of said engine, said structural assembly being made in the form of a constructive and functional unit, intended to be mounted on the engine block and incorporating at least part of a circuit exhaust gas recirculation system, a heat exchanger for cooling said gases and at least part of the engine cooling circuit, integrating at least the water outlet housing, characterized in that the part of the circuit of the exhaust gas recirculation and the part of the engine cooling circuit are integrated in structural elements distinct from the constructive and functional unit. The invention will be better understood, thanks to the following description, which relates to a preferred embodiment, given by way of non-limiting example, and explained with reference to the appended diagrammatic drawings, in which: FIGS. 2 are perspective views from two different angles of a multifunctional module according to the invention, FIG. 3 is a view similar to that of FIG. 2, more particularly showing the circulation of the cooling liquid in the multifunctional module according to FIG. FIG. 4 is a diagram showing the circulation circuit of the exhaust gases in the functional module according to the invention, FIG. 5 is a view similar to that of FIG. 1, more particularly representing the non-gas circulation circuit. 20 cooled by the heat exchanger according to the invention, Figure 6 is a view similar to that of Figure 1 showing more particularly the circuit circulation of gases cooled by the heat exchanger and the tube bundle thereof, Figure 7 is a view similar to that of Figure 1 representing the multifunctional module according to the invention during assembly of the heat exchanger , and Figure 8 is a view similar to that of Figure 1 showing the multifunctional module according to the invention during assembly of the vacuum reserve module on the tank of the heat exchanger. As represented in FIGS. 1 and 2, the multifunctional module for an internal combustion engine according to the invention, forming a structural assembly and incorporating the functions of cooling the exhaust gases, regulating the reinjection of the exhaust gases and of At least partial control of the circulation flows 35 in the cooling circuit of said engine is realized in the form of a constructive and functional unit 1 intended to be mounted on the engine block and integrates at least a part of the engine. an exhaust gas recirculation circuit, a heat exchanger 2 for cooling said gases and at least part of the engine cooling circuit, integrating at least the water outlet housing 3. This multifunctional module 1 characterized in that the part of the exhaust gas recirculation circuit and the part of the engine cooling circuit are integrated into structure elements 4, 3, 5, 6 separate from said constructive and functional unit 1. Thanks to the invention, a multifunctional module forming a constructive and functional unit 1 integrating, on the one hand, the functions of cooling and regulating reinjection exhaust gas and, secondly, the function of regulating the flow of circulation in the cooling circuit of said engine can be realized. This multifunctional module 1 has a limited size and can be directly mounted on the engine, as will be explained later. In addition, the recirculation circuits of the exhaust gas and cooling are dissociated and integrated in different structural elements, so that the latter can be made of different materials. For this purpose, and according to the invention, the part of the exhaust gas recirculation circuit can be integrated in a central element 4, made of metal, of the constructive and functional unit 1 and the part of the cooling circuit of the exhaust gas or engine can be made of a thermoplastic synthetic material and be mounted on said central element 4. The metal used for the manufacture of the central element 4 may be stainless steel, for example. The use of a synthetic material for the production of part of the cooling circuit makes it possible to obtain a mass gain of the constructive and functional unit 1 on the one hand and, on the other hand, to reduce it manufacturing costs, as well as to increase flexibility, which is particularly advantageous for the assembly together of the elements forming said constructive and functional unit 1. According to a first non-represented embodiment of the invention, the part of the engine cooling circuit can be made in the form of a structural subassembly 3, 5, 6 in one piece formed by the assembly of two parts made by injection molding of thermoplastic synthetic material. According to a second variant, the part of the engine cooling circuit can be made by assembling at least two parts 3, 5, 6. As shown in the accompanying figures, the parts 3, 5, 6 can be made in the form of tubular elements or ducts possibly interconnected by vibration welding. In addition, the arrangement of these forms the water outlet housing 3. It is apparent from the accompanying figures that the constructive and functional unit 1 may be substantially elongate and consist essentially of the assembly of three elements, namely: - the central element 4 formed in one piece, on a first side of which is mounted the portion 3, 5, 6 of the engine cooling circuit, and including in particular, on the other side, an opening of inlet 7 of the coolant and an inlet opening 8 of the exhaust gas respectively connected to the engine cooling circuit and the gas recirculation circuit for the direct mounting of the module 1 on the engine block, - the heat exchanger 2, and a gas flow regulating member 9, the heat exchanger 2 and the gas flow regulating member 9 being oppositely mounted each at a mounting end thereof. the central element 4. This structure in distinct elements makes it possible to simplify the manufacture of such a multifunctional module 1 and thus to reduce the costs thereof. In addition, the presence of the inlet openings 7 of the coolant 25 and exhaust gas inlet 8 allows direct mounting on the engine. Typically, and as is more particularly apparent from FIG. 3, the heat exchanger 2 can be made in the form of a metal tank 16 having a coolant inlet opening 30 and an outlet opening 11 of the coolant, tank 16 in which is mounted and positioned a bundle 13 of tubes 14 in which the exhaust gas circulates. Here again, stainless steel can be used in the embodiment of the tank 16. This figure also shows the circulation of the cooling liquid in the multifunctional module 1 by means of arrows. The arrows represented by a thicker line correspond to the flow of liquid having passed through the tank 16, and which has thus recovered part of the calories of the exhaust gases in the heat exchanger 2, so that it presents a higher temperature at the outlet of the heat exchanger 2 at the inlet of the latter. The heat exchanger 2 is preferably positioned close to the inlet opening 8 of the gases, so that the hot exhaust gases do not pass through the multifunctional module 1 over a long distance, thereby avoiding a rise in excessive temperature due to the exhaust gases from the motor directly admitted into said multifunctional module 1.

To further reduce the volume occupied by the constructive and functional unit 1 according to the invention, a module 15 forming a vacuum reserve, made of a thermoplastic synthetic material and which can be used for the control or supply of power or pneumatic energy. a regulating member 9 and / or a bypass member 17 of the pneumatic or electropneumatic type gas flow can be mounted on the tank 16 of the heat exchanger 2. The need for integration of a vacuum tank specific, in the engine bonnet, through specific fastening devices, is avoided. The module 15 forming a vacuum reserve can be made in a generally U-shaped shape, the internal faces of the wings and of the core comprise elements or projection 21 bearing on the corresponding faces of the tank 16 of the heat exchanger 2 in mounting position of said module 15. As shown in Figure 7, these projecting elements 21 may be made in the form of ribs. The latter make it possible to achieve thermal insulation between the metal tank 16 of the heat exchanger 2 and the module 15 of synthetic material by creating insulating air blades between the walls of the latter. According to the invention, the inlet opening 7 of the cooling liquid can be fluidly connected to the water outlet housing 3 via a duct 12 formed in and passing through the central element 4 in a manner perpendicular to its longitudinal axis and the water outlet housing 3 can be connected to the inlet opening 10 of the tank 16 of the heat exchanger 2 via a conduit 5, formed in the subassembly 3 , 5, 6 in one piece constituting the part of the engine cooling circuit or corresponding to one of the parts 3, 5, 6 assembled to realize the part of the engine cooling circuit. In the same way, a duct 6 formed in the subassembly 3, 5, 6 in one piece constituting the part of the engine cooling circuit or corresponding to one of the parts 3, 5, 6 assemblies to realize the part of the engine cooling circuit, can be connected to the outlet opening 11 of the tank 16 of the heat exchanger 2 for the evacuation of water leaving said tank 16. Considering present heat exchanger 2, the latter may comprise a bundle 13 of tubes 14 mounted in the tank 16 of the heat exchanger 2 by means of a support body 20 sealing at the assembly interface between the tank 16 and the central element 4 and closing said tank 16 of the heat exchanger 2, and the bundle 13 of tubes 14 can form a U-shaped circulation path for the exhaust gases in the tank 16 and be constituted by a first group of tubes 14 to go, in which the exhaust gases circulate from the first end 14 'of the tubes 14 located at the opening of the tank 16 and the support body 20 towards the second end 14 "of the tubes 14 located at the bottom of the tank 16, and by a second group of return tubes 14, in which the exhaust gases flow from the second end 14 "of the tubes 14 located at the bottom of the tank 16 towards the first end 14 'of the tubes 14 located at the opening of the tank 6 and the support body 20. The second ends 14 "of the tubes 14 can lead into a common volume ensuring the fluid communication between the first group and the second group of tubes 14, said volume being constituted for example by a shell closed by a plate, said plate being traversed by the second ends 14 "of the tubes 14. Of course, the tubes 14 of the heat exchanger 2 can be made in one piece and bent U or be each constituted by two portions of straight tubes interconnected by a curved tube portion. According to the invention, the inlet opening 8 of the exhaust gas can be in fluidic relation with the inlet ends of the tubes 14 via a channel formed in the central element 4 and with a gas outlet opening 19 located on the central element 4 via a channel 18 for the passage of gases, also produced in the central element 4 and a gas flow bypass member 17 can be mounted in the inlet opening 8 of the gases. In this way, the exhaust gases entering the inlet opening 8 are directed either towards the tank 16 or towards the outlet opening 19. FIG. 4 represents in continuous lines the situation in which the exhaust gases are directed to the tank 16 of the heat exchanger 2 to achieve cooling thereof. The flow of these gases is also shown in FIG. 6 in which the arrows with a thicker line represent the exhaust gases before they pass through the heat exchanger 2. The multifunctional module 1 makes it possible to obtain, while not cooling, the exhaust gases, a rapid heating of the engine after a cold start. Under these conditions, the circuit taken by the exhaust gas corresponds to that indicated by the arrows shown in Figure 5. In the circuit of Figure 4, the path taken is that shown in dashed lines.

Advantageously, the outlet opening 19 can be arranged at the level of the constructive and functional unit 1 so that when the latter is mounted on a motor, said outlet opening 19 is in position for direct mounting on the intake manifold of the latter.

According to the invention, the multifunctional module 1 may comprise a thermostatic regulator for the flow of liquid in the water outlet housing 3. This member can thus regulate the circulation of the cooling liquid between the circuit of the multifunctional module 1, 1 'cockpit exchanger and radiator.

Thanks to the invention, it is possible to produce a multifunctional module whose manufacturing cost is reduced by the use of certain elements of the latter in a thermoplastic synthetic material while achieving maximum optimization of the space occupied under the bonnet. as the multifunctional module 1 encloses part of the exhaust gas recirculation circuit as well as part of the engine cooling circuit. Of course, the invention is not limited to the embodiment described and shown in the accompanying drawings. Modifications are possible, particularly from the point of view of the constitution of the various elements or by substitution of technical equivalents, without departing from the scope of protection of the invention.

Claims (15)

1. Multifunctional module for internal combustion engine, forming a structural assembly and integrating the functions of cooling the exhaust gas, regulating the re-injection of the exhaust gas and regulating, at least partially, the flow of circulation in the engine. cooling circuit of said motor, said structural assembly being constructed as a constructive and functional unit (1), to be mounted on the engine block and incorporating at least a part of a gas recirculation circuit; exhaust, a heat exchanger (2) for cooling said gases and at least part of the engine cooling circuit, integrating at least the water outlet housing (3), characterized in that the part of the recirculation circuit of the exhaust gas and the part of the engine cooling circuit are integrated in structural elements (4, 5, 6) separate from said constructive unit and function nelle (1). 2. Module according to claim 1, characterized in that the part of the exhaust gas recirculation circuit is integrated in a central element (4), made of metal, of the constructive and functional unit (1) and in that part of the engine cooling circuit is made of a thermoplastic synthetic material and is mounted on said central element (4). 3. Module according to claim 2, characterized in that the part of the engine cooling circuit is in the form of a structural subassembly (3, 5, 6) in one piece formed by the assembly. two parts made by injection molding of thermoplastic synthetic material. 4. Module according to claim 2, characterized in that the portion of the engine cooling circuit is formed by assembling at least two parts (3, 5, 6). 5. Module according to any one of claims 2, 3 and 4, characterized in that the constructive and functional unit (1) is substantially of elongated form and consists essentially of the assembly of three elements, namely: The central element (4) formed in one piece, on a first side of which the part (3, 5, 6) of the engine cooling circuit, and comprising in particular, on the other side, an inlet opening (7) of the coolant and an inlet opening (8) of the exhaust gas respectively connected to the engine cooling circuit. engine cooling and gas recirculation circuit for direct mounting of the module (1) on the engine block, - the heat exchanger (2), and - a gas flow regulating member (9), heat exchanger (2) and the gas flow regulating member (9) being oppositely mounted each at a mounting end of the central member (4). 6. Module according to claim 5, characterized in that the heat exchanger (2) is in the form of a tank (16) made of metal having an inlet opening (10) of the coolant and an opening outlet (11) of the coolant, tank (16) in which is mounted and positioned a bundle (13) of tubes (14) in which the exhaust gas flows. 7. Module according to claim 6, characterized in that a module (15) forming a vacuum reserve, made of a thermoplastic synthetic material and can be used for controlling or supplying power or pneumatic energy to an organ control device (9) and / or a bypass member (17) of the pneumatic or electropneumatic type gas flow is mounted on the tank (16) of the heat exchanger (2). 8. Module according to claim 7, characterized in that the module (15) is formed in a generally U-shaped, the inner faces of the wings and the core comprise elements or projection (21) bearing on the faces corresponding to the tank (16) of the heat exchanger (2) in the mounting position of said module (15). 9. Module according to any one of claims 6 to 8, as far as it relates to claim 3 or 4, characterized in that the inlet opening (7) of the coolant is fluidly connected to the water outlet housing (3) via a duct (12) formed in and passing through the central element (4) perpendicularly to its longitudinal axis and in that the water outlet housing (4) 3) is connected to the inlet opening (10) of the tank (16) of the heat exchanger (2) via a conduit (5) formed in the sub-- The unit (3, 5, 6) in one piece constituting the part of the engine cooling circuit or corresponding to one (5) of the parts (3, 5, 6) assembled to produce the part of the engine cooling circuit; engine cooling. 10. Module according to claim 9, characterized in that a duct (6) formed in the subset (3, 5, 6) in one piece constituting the part of the engine cooling circuit or corresponding to one (6) of the parts (3, 5, 6) assembled to perform the part of the engine cooling circuit, is connected to the outlet opening (11) of the tank (16) of the heat exchanger ( 2) for the evacuation of water leaving said tank (16). 11. Module according to any one of claims 6 to 10, characterized in that the bundle (13) of tubes (14) is mounted in the tank (16) of the heat exchanger (2) by means of a supporting body (20) sealing at the assembly interface between the tank (16) and the central element (4) and closing said tank (16) of the heat exchanger (2), and the bundle (13) of tubes (14) forms a U-shaped circulation path for the exhaust gases in the tank (16) and is constituted by a first group of tubes (14) to wherein the exhaust gas flows from the first end (14 ') of the tubes (14) at the opening of the vessel (16) and the support body (20) to the second end (14 ") of the tubes (14) located at the bottom of the tank (16), and by a second group of tubes (14) return, wherein the exhaust gas flows from the second end (14 ") of the tubes (14) located at the nive at the bottom of the tank (16) to the first end (14 ') of the tubes (14) located at the opening of the tank (6) and the support body (20). 12. Module according to claim 11, characterized in that the second ends (14 ") of the tubes (14) open into a common volume providing fluid communication between the first group and the second group of tubes (14), said volume being constituted for example by a shell closed by a plate, said plate being traversed by the second ends (14 ") of the tubes (14). 13. Module according to any one of claims 7 to 12, characterized in that the inlet opening (8) of the exhaust gas is in fluid relation with the inlet ends of the tubes (14) by the intermediate of a channel formed in the central element (4) and with an outlet opening (19) of gases located on the central element (4) via a channel (18) of gas passage, also realized in the central element (4) and in that a member (17) for bypassing the gas flow is mounted in the inlet opening (8) of the gases. 14. Module according to claim 13, characterized in that the outlet opening (19) is arranged at the level of the constructive and functional unit (1) so that when the latter is mounted on a motor, said opening outlet (19) is in position for direct mounting on the inlet manifold of the latter. 15. Module according to any one of claims 1 to 14, characterized in that it comprises a thermostatic regulating member of the liquid flow in the water outlet housing (3).