EP0193142A1 - Engine-braking system for an internal-combustion engine - Google Patents

Abstract

1. An engine-braking system for an internal combustion engine, especially for a normally aspirated or a supercharged diesel engine, the engine having at least one combustion chamber (1) communicating via an outlet valve (2) with an exhaust flue (3) fitted with a butterfly valve (9) which is closed during braking, in which the combustion chamber (1) also communicates with the exhaust flue (3) via a further flue (4) which due to the size of its cross-section relative to that of the outlet valve (2) acts as a throttle and which is opened for the duration of braking but gastightly closed during normal engine operation by a valve (8) actuatable by an adjusting device, characterized in that the gas pressure prevailing in the exhaust flue (3) is arranged to act on the adjusting device (19) in such a way that it actuates the valve (8) which opens the further flue (4) if the butterfly valve (9) is closed.

Description

The invention relates to an engine brake device for an internal combustion engine according to the preamble of claim 1.

CH-PS 310 325 describes an engine brake device for an internal combustion engine, in which the combustion chamber is connected to the exhaust duct via a further lockable gas duct, which increases the engine braking power by means of a blow-off and throttling effect. A valve is arranged in the gas duct, which can be actuated simultaneously via a linkage with a throttle valve in the exhaust duct. If the throttle valve is closed, the linkage simultaneously opens the valve in the gas duct and vice versa. In another embodiment, according to CH-PS 310 325, the gas channel can also be formed by an annular gap between the valve plate and valve seat.

The disadvantage is the complicated and complex control of the engine brake device by means of a linkage, which takes up special attachment points and space in the internal combustion engine and, despite regular lubrication, tends to show signs of failure during extended operation.

The object of the invention is to provide an engine braking device which automatically adjusts itself to normal or braking operation.

Because the gas pressure in the exhaust duct acts on an actuating device which opens the additional gas duct when the throttle valve is closed, the engine brake device can automatically adjust itself to normal or braking operation.

In an advantageous embodiment, this is achieved by an actuating device having a valve in the gas channel, the valve consisting of a piston which is spring-loaded in the closed position of the valve, the effective piston area of which acts on the effective piston area in the opening direction of the valve against the force of the spring by the gas pressure prevailing in the exhaust channel in front of the throttle valve is.

The force of the spring on the piston surface must be dimensioned such that the valve assigned to the gas channel always remains closed when the throttle valve is open, i.e. that the maximum ignition pressure in the combustion chamber cannot open the valve. In contrast, the piston surface facing away from the spring must be chosen so large that the gas pressure in the exhaust duct can move the piston when the throttle valve is closed and thus open the valve.

The valve is expediently located close to the combustion chamber, so in normal operation, i.e. When the throttle valve is open, no dead volume affects the function of the engine.

In a further advantageous embodiment, the gas channel is created by an annular gap formed in the rest position of the exhaust valve between the valve plate and the valve seat of the exhaust valve, the adjusting device being integrated in an oil circuit of the internal combustion engine and the setting of the annular gap, controlled by the gas pressure in the exhaust gas channel, being carried out automatically hydraulically.

With this hydraulic setting, the annular gap between the valve plate and the valve seat of the exhaust valve, which has a throttle characteristic in relation to the cross section of the exhaust valve, can be defined in a defined manner.

A pressure chamber, which can be closed on the one hand by a counter pressure valve and on the other hand by a control piston, is expediently arranged in an oil line to the rocker arm chamber or valve chamber, the one limiting side of which forms a piston which is movably sealed in a cylinder in its axial direction. The back pressure valve advantageously consists of a spring-loaded ball arranged in the pressure chamber, which is pressed in the closed position of the back pressure valve by the oil pressure in the pressure chamber onto the inlet of the oil line in the pressure chamber and closes the pressure chamber.

The control piston is advantageously connected at its end facing away from the pressure chamber to a membrane which is acted upon by the gas pressure in the exhaust duct against a spring force, such that the gas pressure in braking operation of the internal combustion engine shifts the membrane with the control piston against the spring force and the control piston unilaterally the pressure chamber closes.

The piston expediently sets the rest position of the exhaust valve, which position forms an end position, via an adjusting device, and the adjusting device consists of an auxiliary rocker arm, one end of which cooperates with the piston and the other end of which cooperates with the valve stem.

So that the annular gap between the valve plate and the valve seat of the exhaust valve can be adjusted in a defined manner, the auxiliary rocker arm can advantageously be adjusted in its axial position.

• Fig. 1 eine erfindungsgemäße Motorbremsvorrichtung als Schnitt durch einen Zylinderkopf mit angrenzendem Zylinderrohr,
• Fig. 2 einen Schnitt durch einen Zylinderkopf mit einer erfindungsgemäßen Motorbremsvorrichtung, wobei der Gaskanal aus einem Ringspalt zwichen einem Ventil teller und Ventilsitz gebildet ist.

Further features of the invention result from the description and the drawings, which show two embodiments of the invention and are described in more detail below. It shows:

• 1 shows an engine brake device according to the invention as a section through a cylinder head with an adjacent cylinder tube,
• Fig. 2 shows a section through a cylinder head with an engine brake device according to the invention, wherein the gas channel is formed from an annular gap between a valve plate and valve seat.

1 shows an engine brake device according to the invention as a section through a cylinder head 5 with an adjoining cylinder tube 11. The combustion chamber 1 is delimited by the cylinder tube 11, by the cylinder head 5 and by a piston (not shown): the cylinder tube 11 is opposite to the cylinder head 5 by a groove 29 in the cylinder head 5 arranged sealing ring sealed. In the cylinder head 5 there is the exhaust duct 3, the connection to the combustion chamber 1 is controlled by an exhaust valve 2 moved by a rocker arm 13. The valve plate 6 is conical and sits in a correspondingly designed valve seat 7. The valve stem 15 is guided in a valve guide 14 which is fastened in the cylinder head 5. At the upper end of the valve stem 15, a spring plate 28 is attached, via which a valve spring 16 loads the valve in the closed position. Via a rocker arm 13 driven by a camshaft, the valve stem 15 is moved axially against the force of the valve spring 16 in time with the internal combustion engine and the outlet valve 2 is opened, which is closed again by the valve spring 16 when the rocker arm 13 returns.

The combustion chamber 1 is connected to the exhaust gas duct 3 via a second gas duct 4 provided in the cylinder head 5 and controlled by a valve 8.

The valve stem 17 of the valve 8 protrudes through the gas channel 3 and is parallel to the valve stem of the exhaust valve 2. Its lower end is conical as a valve plate 18 and sits in the associated valve seat 12. The through bore of the valve seat leads into the gas channel 4, which in the Combustion chamber 1 opens.

• Der Ventilschaft 17 des Ventils 8 ragt in eine Stellvorrichtung 19. Diese bildet mit dem Ventilstößel 17 eine Baueinheit und kann als Ganzes dichtend in den Zylinderkopf 5 eingesetzt werden. Dazu sind im Zylinderkopf entsprechende Gewindebohrungen angebracht.

The blow-off cross section of the gas channel 4 has a throttle characteristic in comparison to the effective outlet cross section of the exhaust valve. The blow-off cross section compared to the outlet valve is preferably less than 1: 3 in diameter ratio or less than 1:10 in area ratio:

• The valve stem 17 of the valve 8 protrudes into an adjusting device 19. This forms a structural unit with the valve tappet 17 and can be inserted as a whole into the cylinder head 5 in a sealing manner. Appropriate threaded holes are made in the cylinder head for this purpose.

An advantage of the arrangement described is that these bores can serve as an assembly lead-through for the installation or machining of the valve seat 17 as long as the structural unit of the actuating device has not yet been used.

The valve stem 17 is guided in the lower part 20 of the actuating device and is connected to the piston 10, which has three grooves or piston rings 24 on its running surface and divides the interior of the upper part 22 into two subspaces. The side of the piston 10 facing away from the gas channel 4 is through a spring 26 loaded. The spring chamber communicates with the atmosphere through a bore 27; the side of the piston 10 opposite the spring 26 is connected to the exhaust duct 3 via a bore 21.

In the direction of flow of the exhaust gas duct 3, behind the mouth of the gas duct 4 and the bore 21, there is a remotely operable throttle valve 9, usually arranged centrally for several cylinders in the exhaust gas manifold (not shown).

If the throttle valve 9 is closed, an excess pressure builds up in the exhaust duct 3 after a few working cycles of the piston. Through the bore 21, this overpressure is also on the side of the piston 10 facing the gas channel 4. The effective piston surface is selected so that the overpressure displaces the piston 10 against the force of the spring 26 and thus raises the valve stem 17, as a result of which the gas channel 4 is opened.

At the beginning of the compression cycle, the pressure in the combustion chamber 1 is lower than in the exhaust gas duct 3. As a result, gas flows through the open gas duct 4 into the combustion chamber and increases the charge there. During the subsequent compression, the piston has to do additional work and is thereby braked. In the further course of the compression stroke, when the pressure in the combustion chamber 1 is higher than that in the exhaust pipe 3, gas flows out of the combustion chamber 1 through the gas channel 4. As a result, the compression end pressure is lower than in normal operation with closed gas channel 4; however, irreversible labor losses have arisen from the leak. In the subsequent expansion stroke, this throttled amount of gas can no longer affect the piston. In these two work cycles "compress and expanding "the gas in the internal combustion engine, the engine must therefore perform a considerable braking work.

This has the same order of magnitude as the braking power with throttle valve without gas channel in the two work cycles "pushing out and priming" and is added to this.

In a further embodiment, the gas channel 4 is replaced by an annular gap 4 ′ formed in the closed position of the outlet valve 2 between the valve plate 6 and the valve seat 7 of the outlet valve (shown in broken lines). An advantage of this design is that no additional gas channel is required in the cylinder head.

Fig. 2 shows this advantageous embodiment, which is explained below.

An arranged in the cylinder head 5 exhaust valve 2 (see. Fig. 1) extends with its valve stem 15 through an exhaust duct 3 and sits with its valve plate 6 in a valve seat 7. On the side of the spring plate 28 facing away from the valve spring 16 is a ring 30a with a cylindrical Extension 30b is placed on the valve stem 15, which is acted upon by a rocker arm 13, which is only shown schematically, and which displaces the valve stem 15 and thus the valve disk 6 in the open position of the exhaust valve 2. The rocker arm 13 is actuated by a camshaft 31, the camshaft 31 being connected to the rocker arm 13 via a tappet 43.

Parallel to the valve stem 15, a rod 44 is arranged in the cylinder head 5, which is screwed into the cylinder head 5 at one end. The rod 44 serves as a fastening for an auxiliary rocker arm 42 which is on the rod 44 is put on. At the end facing away from the cylinder head 5, the rod 44 has two nuts 45 which, together with an abutment 45a, serve as a stop for the auxiliary rocker arm 42. The auxiliary rocker arm 42 is pressed against the nuts 45 by a spring 46 which coaxially surrounds the rod 44. The auxiliary rocker arm 42 is in the manner of a balance beam and also elastically supported by the spring 46. An arm 48 of the auxiliary rocker arm 42 is U-shaped and rests on the ring 30a, which rests on the end face of the valve stem 15. A spherical pin 47 of the rocker arm 13 is arranged within the U-shaped arm 48 of the auxiliary rocker arm 42 and acts on the cylindrical extension 30b of the ring 30a.

The arm of the auxiliary rocker arm 42 opposite the U-shaped arm 48 rests on a piston 37, which is movably sealingly guided in its axial direction in a cylindrical bore in the cylinder head 5. The movement of the piston 37 is limited by a stop 49. The bottom of the piston 37 facing the exhaust duct 3 forms one side of a pressure chamber 36 in the cylinder head 5, the pressure chamber 36 having an inlet 39 and an outlet 40. The inlet 39 is formed by an oil line 34 of the internal combustion engine, which is integrated in the oil circuit of the internal combustion engine. In the direction of flow in front of the pressure chamber 36, a throttle 32 is arranged in the oil line 34, which throttles the flow of oil through the oil opening 34: The outlet 40 of the pressure chamber 36 merges into a bore 50 arranged parallel to the valve stem 15, which on the one hand connects with the valve chamber or Rocker arm space is connected and on the other hand merges into a spring space 51. A membrane 41 is arranged in the spring chamber 51 divides the spring chamber 51 from an adjacent gas chamber 52. Both spaces are separated from one another by the membrane 41 in a gastight manner. A cylindrical control piston 35 is attached to the diaphragm 41, which extends through the spring chamber 51 and projects into the bore 50. The control piston 35 is coupled to the movement of the membrane 41 and seals the outlet 40 of the pressure chamber 36 when the membrane 41 extends in the direction of the spring chamber 51. In the spring chamber 51, a compression spring 53 is arranged coaxially around the control piston 35, which applies force to the diaphragm 41 in the direction of the gas chamber 52: the gas chamber 52 is connected to the exhaust duct 3 through a bore 54.

In the pressure chamber 36, a counter pressure valve is arranged, which consists of a spring-loaded ball 38 which, in the closed position of the counter pressure valve, is pressed by the oil pressure in the pressure chamber 36 onto the inlet 39 of the oil line 34 into the pressure chamber 36 and shoots it. So that the ball 38 only performs a defined axial change in position, it is held by a conically shaped spring 55. The spring 55 is supported on the one hand on a U-shaped bracket 56 in the pressure chamber 36 and on the other hand on the ball 38.

In normal operation of the internal combustion engine, the throttle valve 9 in the exhaust gas duct 3 is opened, so that no high gas pressure builds up in the exhaust gas duct 3. The gas pressure in the exhaust duct 3, which acts on the diaphragm 41 via the bore 54, is not sufficient to bulge it against the force of the compression spring 53 in the direction of the spring chamber 51. The control piston 35 does not thereby close the outlet 40 of the pressure chamber 36, so that the oil flowing through the oil line 34 passes unhindered through the pressure chamber 36 into the valve or rocker arm chamber:

If the oil pressure in the oil line 34 in the direction of flow behind the throttle 32 is large enough, despite the open outlet 40, the piston 37 can yield to the oil pressure when the outlet valve 2 is open and change its position in the direction of the stop 49, and raise the auxiliary rocker arm 42 such that the U-shaped arm 48 of the auxiliary rocker arm 42 is deflected in the direction of the valve seat 7. If the outlet valve 2 returns to the closed position, the auxiliary rocker arm 42 immediately returns to its original position, since the piston 37 presses the oil in the pressure chamber 36 through the outlet 40 into the valve chamber or rocker arm chamber. However, this process is of subordinate importance for the mode of operation of the engine brake device according to the invention and can also be avoided by suitable adjustment of the size of the outlet 40 in connection with the throttle 32. According to the invention it is important that the movement of the exhaust valve 2 is unaffected in normal operation.

In braking operation, the throttle valve 9 in the exhaust duct 3 is closed, and the gas pressure in the exhaust duct 3 is sufficient to bulge the membrane 41 with the control piston 37 attached thereto in the direction of the spring chamber 51 against the force of the compression spring 53. The control piston 37 then closes the outlet 40 of the pressure chamber 36. If the outlet valve 2 is just in the open position, oil flows from the oil line 34 into the pressure chamber 36 and pushes the piston 37 up to a stop 49. If the outlet valve 2 returns to the closed position , so the ring 30a, which returns to the rest position, lifts the U-shaped arm 48 of the auxiliary rocker arm 42 on the valve stem 15 and thereby presses the opposite arm onto the piston 37. As a result, a pressure builds up in the pressure chamber 36, which pressures the inlet 39 by means of of the back pressure valve closes when the pressure in the pressure chamber 36 is greater than in the oil line 34. As a result, the auxiliary rocker arm 42 can no longer return to its rest position, so that the outlet valve 2 also remains in a certain deflected end position. The end position of the exhaust valve 2 is selected so that the annular gap 4 'between the valve plate 6 and the valve seat 7 of the exhaust valve 2 has a throttle characteristic in relation to the cross section of the exhaust valve 2.

The setting of the annular gap 4 'is accordingly carried out automatically by hydraulic means, controlled by the gas pressure in the exhaust gas duct. Furthermore, because of the incompressibility of the oil, the annular gap 4 ′ that determines the throttle cross section can be precisely defined. The nuts 45 on the rod 44 allow the axial position of the auxiliary rocker arm 42 and thus the throttle cross section of the ring channel 4 'to be determined or corrected even after the internal combustion engine has been installed:

Claims (9)

_1st Engine brake device for an internal combustion engine, in particular for a self-priming or supercharged diesel engine with at least one combustion chamber (1), which is connected via an exhaust valve (2) to an exhaust gas duct (3) in which a throttle valve (9) which is closed during braking operation is arranged, wherein the combustion chamber (1) is connected to the exhaust gas duct (3) via a further gas duct (4), which has a throttle characteristic in relation to the cross section of the exhaust valve (2), is open for the duration of the braking operation and is sealed gas-tight for the duration of the normal operation is
characterized in that the gas pressure in the exhaust duct (3) acts on an actuating device which opens the additional gas duct (4) when the throttle valve (9) is closed. 2. Engine brake device according to claim 1, characterized in that the adjusting device has a valve (8) in the gas channel (4), the valve (8) from a in the closed position of the valve (8) spring-loaded piston (10), the effective one Piston surface in the opening direction of the valve (8) against the force of the spring (26) is acted upon by the gas pressure prevailing in the exhaust duct (3) in front of the throttle valve (9). 3. Engine brake device according to claim 1, wherein the gas channel (4) by an in the rest position of the exhaust valve (2) formed annular gap (4 ') between the valve plate (6) and valve seat (7) of the exhaust valve (2), characterized in that the adjusting device is integrated in an oil circuit of the internal combustion engine and the setting of the annular gap (4 '), controlled by the gas pressure in the exhaust gas duct (3), is carried out automatically and hydraulically. 4. Engine brake device according to claim 3, characterized in that in an oil line (34) to the rocker arm or valve chamber a pressure chamber (36) which is closable on the one hand by a counter pressure valve and on the other hand by a control piston (35) is arranged, the one limiting side of which is a piston ( 37), which is movably sealed in a cylinder in its axial direction: 5. Engine brake device according to claim 4, characterized in that the back pressure valve consists of a spring-loaded ball (38) arranged in the pressure chamber (36), which in the closed position of the back pressure valve from the oil pressure in the pressure chamber (36) to the inlet (39) of the oil line (34 ) is pressed into the pressure chamber (36) and closes it. 6. Engine brake device according to claim 4, characterized in that the control piston (35) is connected at its end facing away from the pressure chamber (36) with a membrane (41) which is acted upon by the gas pressure in the exhaust gas duct (3) against a spring force, such that that the gas pressure in braking operation of the internal combustion engine displaces the diaphragm (41) with the control piston (35) against the spring force and the control piston (35) closes the pressure chamber (36) on one side. 7. Engine braking device according to one of claims 4 to 6, characterized in that the piston (37) via an actuating device defines the rest position of the exhaust valve (2) forming an end position. 8. Engine braking device according to one of claims 3 to 7, with a valve stem (15) which is connected to the valve plate (6) of the exhaust valve (2),
characterized in that the adjusting device consists of an auxiliary rocker arm (42), one end of which cooperates with the piston (37) and the other end of which cooperates with the valve stem (15). 9. Engine brake device according to claim 8, characterized in that the auxiliary rocker arm (42) is adjustable in its axial position.

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