DE10119484A1 - Liquid-cooled internal combustion engine has exhaust gas recirculation with feeder and discharge openings for exhaust gas and for coolant, and seal - Google Patents

Abstract

The exhaust gas recirculation system has an exhaust gas recirculation heat-exchanger (1) with an exhaust gas feeder (2) openng and an exhaust gas discharge (3) opening, a coolant feeder (4) and dsicharge (5) opening arranged on an assembly plane (11) and share a sealing element (6) in the form of a flat seal. The heat exchanger is fixed directly on the machine housinng of the internaal cobustion engine.

Description

The invention relates to a liquid-cooled internal combustion engine with an Ab gas recirculation system according to that mentioned in the preamble of claim 1 Art.

The invention is based on JP 11 237 192. In this is an EGR Heat exchanger (exhaust gas recirculation heat exchanger) described in a pipe shaped housing is arranged. There is a flange on each end face which the EGR heat exchanger is installed in the exhaust gas recirculation line. On The flange is used for exhaust gas supply and the other for exhaust gas discharge. On the outside A coolant is offset from the tubular housing by 180 ° to one another inlet connection and a coolant outlet connection arranged. The coolant is through a labyrinthine pipe system from the coolant inlet pipe through the tubular Housing directed to the coolant drain pipe. This pipe system is through Longitudinal tubes which are arranged parallel to the tubular housing therein; educated. The hot exhaust gas is led into the longitudinal tube and from which the Coolant rinsing longitudinal tubes cooled.

Furthermore, JP 11 082 186, particularly in FIG. 1, shows the installation of an EGR heat exchanger close to the internal combustion engine. The diverse connections for the coolant supply and the coolant discharge or the exhaust gas supply and exhaust gas discharge are clearly visible.

A disadvantage of such EGR heat exchangers is the large number of separa Connection points for the coolant supply and coolant discharge or the exhaust gas supply and exhaust gas discharge. When the internal combustion engine is operated for long periods leaks can occur at these connection points.

The object of the present invention is to ensure the permanent tightness of an EGR To increase heat exchanger, while at the same time cost-effective production.

This object is achieved by the features in the characterizing part of the patent spell 1 solved.

This special design makes additional coolant and exhaust gas and the connecting elements between the lines and the EGR Heat exchanger saved. Due to the reduction in components, the manufacturing costs for an internal combustion engine with an EGR heat exchanger significantly reduced ed.

According to claim 2, the number of sealing elements is also advantageous reduced, which further reduces the manufacturing costs.

By using a single, process-reliable, flat sheet Sick seal according to claims 3 and 4 instead of individual connections elements, the long-term tightness of the EGR heat exchanger is considerably improved sert. The product quality is significantly improved.

Due to the compact design according to claim 5, the EGR heat Exchanger can be connected very stiff to the cylinder head, making the long-term tightness is further improved.

According to claims 6 and 7 with the heat contained in the exhaust gas immediately after a cold start of the internal combustion engine, the passenger compartment of the engine vehicle are heated. This measure will be in the passenger compartment reaches comfortable temperatures much faster for the vehicle occupants, as well as the time for defrosting the panes.

In the following, the invention is based on a preferred exemplary embodiment les shown in a single figure.

Fig. 1 shows a view of an illustrated perspective EGR heat exchanger 1. The exhaust gas heat exchanger 1 is a liquid / gas heat exchanger. An assembly level 11 can be seen , in which an exhaust gas inlet opening 2 , an exhaust gas discharge opening 3 , a coolant inlet opening 4 and a coolant outlet opening 5 are arranged, which are surrounded by a common sealing element 6 , which lies flat on the assembly level 11 . In the Dichtungsbe area, mounting elements 9 , 9 ', here screws, are arranged in unrecognizable holes in the assembly level 11 and in the sealing element 6 . With the help of these mounting elements 11 , the EGR heat exchanger is mounted directly on a machine housing of an internal combustion engine, not shown here.

When the internal combustion engine is operating, exhaust gas is introduced into the EGR heat exchanger through the exhaust gas supply opening 2 . Inside the EGR heat exchanger are the exhaust gas channels 7 , 7 'through which the exhaust gas is passed on to the exhaust gas discharge opening 3 . The individual exhaust gas channels 7 , 7 'represent a direct connection from the exhaust gas supply opening 2 to the exhaust gas discharge opening 3 and are surrounded by coolant, which enters through the coolant supply opening 4 , is then conducted past the outer walls of the exhaust gas channels 7 , 7 ' and out of the coolant opening 5 emerges again. In other exemplary embodiments, the exhaust gas channels 7 , 7 'can also be curved or helical.

Perpendicular to the exhaust gas cooling channels 7, 7 'is a second coolant outflow opening formed on the housing of the EGR heat exchanger 1 10th By means of the second coolant discharge opening 10 , coolant can be heated by the exhaust gas passed through the exhaust gas channels 7 , 7 'during the warm-up of the internal combustion engine. The coolant preheated in this way is immediately available for heating the passenger compartment.

In further exemplary embodiments, the second coolant drain opening 10 can be arranged at any angle to the exhaust gas channels 7 , 7 '. The EGR heat exchanger and the second coolant drain opening 10 can be made in one piece, or can be connected to one another in a detachable or non-detachable manner.

The EGR heat exchanger 1 is preferably mounted directly on a cylinder head, not shown here, of the internal combustion engine, since in this area the hot exhaust gas can be removed directly from the outlet channels for cooling. The sealing element 6 is preferably a flat seal, in the present case it is a sheet metal bead seal. The areas radially around the exhaust gas feed opening 2 , the exhaust gas discharge opening 3 , the coolant inlet opening 4 and the coolant outlet opening 5 can be sealed by additional elastic beads running around the openings. In principle, all types of seals are possible that are correspondingly corrosion and temperature resistant.

The housing of the EGR heat exchanger 1 is preferably made in several pieces from a cast material, for example cast stainless steel, aluminum or brass. The exhaust gas channels 7 , 7 'are preferably made of sheet metal, preferably in a stainless steel version, in order to ensure the required corrosion and temperature resistance. These are introduced into the housing of the EGR heat exchanger 1 before final assembly. After the exhaust gas channels 7 , 7 'have been arranged in the housing of the EGR heat exchanger 1 , the latter is welded in a gas-tight and liquid-tight manner. Soldered or adhesive connections are also possible.

In a simplified embodiment, the second coolant drain opening 10 can be eliminated. Detachable machine elements, such as screws, are preferably used as mounting elements 9 , 9 '. Instead of the screw solution, solder or adhesive connections are also possible.

LIST OF REFERENCE NUMBERS

1

EGR heat exchanger

2

Abgaszuführöffnung

3

Abgasabführöffnung

4

Coolant inflow opening

5

Coolant drain opening.

6

sealing element

7

.

7

'' Exhaust cooling duct

8th

cooling surface

9

.

9

'' Assembly element

10

second coolant drain opening

11

mounting level

Claims (7)

1. Liquid-cooled internal combustion engine with an exhaust gas recirculation system with an EGR heat exchanger with an exhaust gas supply opening and an exhaust gas discharge opening, a coolant supply opening and a coolant discharge opening, characterized in that the exhaust gas supply opening ( 2 ), the exhaust gas discharge opening ( 3 ), the coolant supply opening ( 4 ) and the coolant drain opening ( 5 ) are arranged in an assembly level ( 11 ). 2. Liquid-cooled internal combustion engine according to claim 1, characterized in that the exhaust gas supply opening ( 2 ), the exhaust gas discharge opening ( 3 ), the coolant inlet opening ( 4 ) and the coolant outlet opening ( 5 ) is assigned a common sealing element ( 6 ). 3. Liquid-cooled internal combustion engine according to claim 1, characterized in that the common sealing element ( 6 ) is a flat seal. 4. Liquid-cooled internal combustion engine according to claim 1, characterized in that the common sealing element ( 6 ) is a sheet metal seal seal. 5. Liquid-cooled internal combustion engine according to at least one of the preceding claims, wherein a machine housing of the internal combustion engine has an exhaust gas inlet opening, an exhaust gas discharge opening, a coolant inlet opening and a coolant outlet opening, characterized in that the EGR heat exchanger ( 1 ) can be fastened directly to the machine housing. 6. Liquid-cooled internal combustion engine according to claim 1, wherein the internal combustion engine has a heating circuit, characterized in that a second coolant drain opening ( 10 ) is arranged on the EGR heat exchanger ( 1 ). 7. Liquid-cooled internal combustion engine according to claims 1 and 6, characterized in that the second coolant drain opening ( 10 ) is not arranged in the assembly plane ( 11 ).