SE521097C2 - Arrangement for supercharged internal combustion engine with closed crankcase ventilation - Google Patents

Abstract

Arrangement in supercharged combustion engine (2) with enclosed crankcase ventilation, whereby the arrangement serves to provide negative pressure in the engine's crankcase, while the engine's turbocompressor (16) driven by exhaust gases draws air in through an air filter (18) and feeds pressurized air to the engine's inlet pipe (8) via a charged air cooler (28). The feedback of crankcase gases to the inlet pipe (8) and the maintenance of negative pressure in the crankcase even during engine braking are catered for by a ventilation line (36) extending from the crankcase to a bifurcation point (40) in the air inlet duct (20) between the air filter and the compressor inlet (22). The ventilation line (36) incorporates in series a pressure regulator (44), provided with oil filter, and a two-way connection (42), one outlet (46) of which communicates with the bifurcation point (40) via the ventilation line (36), while the other outlet (48) communicates with the inlet pipe (8) via a check valve (52).

Description

In its simplest form, engine braking (i.e. braking action by means of the engine) is effected by the driver releasing the accelerator pedal, suitably in combination with a downshift to a lower gear. However, even more efficient engine braking can be achieved by using some type of exhaust brake (eg an adjustable throttle) which restricts the exhaust during the exhaust stroke, thereby giving rise to a back pressure (in the exhaust system) which each engine piston has to overcome during its exhaust stroke.

With the current system, the above-mentioned maintenance of negative pressure in the crankcase can be achieved by connecting the interior of the crankcase to the negative pressure prevailing in the air intake duct in the area between the air filter and the air inlet of the compressor. A pressure regulator connected in this connection is then used to produce substantially constant negative pressure in the crankcase.

However, this known type of system does not work when using the above-mentioned type of exhaust braking, because the negative pressure between the air filter and the compressor air inlet then becomes too small (due to the throttled exhaust flow to the turbocharger exhaust turbine) while the gas flow in the crankcase ventilation becomes large (due to increased blow-by). gas fl fate past the piston rings, turbo shaft seals and exhaust valve controls).

Object of the invention A main object of the present invention is to provide an arrangement which ensures negative pressure in the crankcase also during engine braking (exhaust braking) of a supercharged internal combustion engine with closed crankcase ventilation.

A related, further object is to offer a constructive solution which prevents oil-laden crankcase gas from being drawn into large parts of the inlet system, especially during exhaust braking when the flow of crankcase gas in the crankcase ventilation is particularly large. 10 15 20 to Un 30. ,. . Description of the invention The above-mentioned object is achieved, in an arrangement of the kind stated in the introduction, in that the arrangement has the features stated in the characterizing part of claim 1. Furthermore, further developments of the arrangement may exhibit the features set forth in claims 2-7.

Characteristic of the invention is thus that in order to ensure negative pressure in the crankcase also during engine braking, a return line is arranged for returning crankcase gases from the crankcase to the inlet pipe which extends from the interior of the crankcase to a connection point in the air intake duct between the air filter and the compressor air inlet. An oil trap, a pressure regulator and a two-way branch or two-way valve are connected in series in this ventilation line, one outlet / outlet port of which is connected to said connection point via the ventilation line, while its other outlet / outlet port is connected to the inlet pipe via a non-return valve.

If the pressure drop in the line between the valve and the air inlet to the engine has adapted pressure drop, it should not be necessary to have a two-way valve, but one can then be satisfied with a two-way branch, for example a T-pipe section. In such a case, it is convenient to arrange a non-return valve at the connection point in the air intake duct.

Especially when the engine braking takes place by activating a special exhaust brake downstream of the exhaust valves, it can be difficult and in some cases impossible to obtain sufficient negative pressure in the inlet pipe. However, this problem can be effectively solved by means of an adjustable damper which is connected in the charge air supply connection between the air outlet of the charge air cooler and the inlet pipe. This damper is then designed to be able to be closed during towing and exhaust braking. By activating this damper, a negative pressure can be ensured in the inlet pipe which is sufficient for the crankcase gases (blow-by-gases) to be able to be led directly to the inlet pipe via the two-way valve. A significant advantage of directing the crankcase gases directly into the cylinders in this way is that it is then effectively avoided that oil carried by the oil-laden crankcase gases accompanies them and is deposited in the compressor and in the subsequent charge air cooler. The oil trap connected in the ventilation duct upstream of the two-way valve 521 097 ïi§f; {¿¿¿} ß is preferably an oil separation filter, which is suitably assembled with the pressure regulator into a unit.

The proximal non-return valve in the connection between the second outlet port of the two-way valve and the inlet pipe may suitably comprise one or more resilient blade valves of the reed valve type. This or these non-return valves have the task of ensuring that no charge air leaks out of the inlet pipe to the ventilation line during normal operation of the motor, i.e. when no exhaust braking occurs. The arrangement according to the invention is useful with both supercharged diesel engines and supercharged otto engines.

Brief Description of the Drawing Figure An arrangement according to the invention will now be described in more detail below and further explained with reference to the accompanying drawing. In this case: Fig. 1 shows the only drawing figure very schematically how the components and units included in the arrangement are arranged and interconnected and connected to a four-cylinder internal combustion engine. Description of exemplary embodiments In Fig. 1, an overcharged internal combustion engine generally designated 2 is schematically shown in plan view. At one end of the engine 2 there is a cooling fan 4, and at the opposite end of the engine a flywheel housing 6. On one side of the engine there is an inlet manifold 8 through which air is supplied to the engine cylinders, and on the opposite side of the engine there is an exhaust manifold 10 which receives the exhaust gases from the cylinders and leads these on to the exhaust system of the engine not shown here. A larger or smaller part of the energy of the exhaust gases from the exhaust manifold 10 is utilized by forcing them to flow through the turbine part 12 of an exhaust-driven turbocharger 14, the compressor part of which is designated 16. The air supply system of the shown supercharged engine 2 comprises a air filter equipped with air purifier 18 through which air from the ambient atmosphere is sucked into the tubular air intake duct 20 of the air supply system, which is connected to the air inlet 22 of the compressor. the compressed and cooled charge air is then led through a supply pipe 32 to the inlet manifold 8 of the engine via a throttle damper 34 connected in the supply pipe. which is sufficient for the blow-by gases leaking in the engine crankcase from the cylinders to be able to be returned directly to the inlet manifold 8. In other words, the throttle damper 34 ensures that the pressure in the inlet manifold 8 will fluctuate around the atmospheric pressure. During exhaust braking, the pressure in the inlet manifold 8 is close to zero, and when the inlet valves of the cylinders open, a negative pressure arises which propagates in the inlet pipe. It is precisely this negative pressure which during exhaust braking can be used to "suck out" the crankcase exhaust gases from the crankcase through the ventilation line 36 which will now be described below.

To enable crankcase gases to be returned from the crankcase to the inlet manifold 8 and 20 to ensure negative pressure in the crankcase also during exhaust braking (engine braking), a ventilation duct 36 is provided extending from a crankcase outlet 38 to a connection point 40 in the air intake duct 20 between the air cleaner 14 ventilation inlet 22. This ventilation pipeline 36 includes, seen in the direction of flow, a pressure regulator coordinated with an oil trap and an adjustable two-way valve 42. The oil trap suitably designed as an oil separating filter is preferably assembled with said pressure regulator to a control unit 44.

The two-way valve 42 has a first outlet port 46 and a second outlet port 48. During normal operation (ie in case of inactivated exhaust braking or engine braking) the crankcase gases 30 are led via the control unit 44 and the subsequent two-way valve 42 from its outlet 46 to the connection point 40 of the ventilation pipeline 36. Via the second outlet port 48 of the valve 42, the crankcase gases coming from the crankcase gas outlet 38 can instead be returned directly to the inlet manifold 8 via a hose or pipe 50 whose downstream end is connected to the inlet manifold 8 through a non-return valve 52. that charge air in the inlet manifold 8 leaks out via the pipeline 50 during normal operation of the engine 2 when exhaust braking does not take place and the pressure in the inlet manifold 8 is significantly higher than the pressure of the crankcase gases inside the crankcase and thus in the ventilation pipeline 36. venti 42 to the interior of the inlet manifold 8, suitably comprises one or more prestressed spring valve type spring valve elements.

When the throttle 34 is closed, the two-way valve 42 is switched so that the crankcase gases are returned to the inlet manifold 8 via the line 50 and the non-return valve 52. via the valve 46 outlet 46 to the connection point 40 in the intake duct 20 of the compressor 16.

The invention can be modified and designed in other ways than those specified in the description example within the scope of the appended claims. For example, instead of being placed after the charge air cooler 28, the throttle damper 34 can be placed before the charge air cooler, which in the figure is indicated by a dashed throttle damper 34b.

The described non-return valve 52, or the line between the non-return valve 52 and the valve 42, may in a further developed embodiment be provided with a safety valve, in order to prevent charging air from entering the back path from the air inlet 8 to the ventilation line 26 in the event that the non-return valve 52 ceases. This safety valve can suitably be designed as a non-return valve.

If the pressure drop in the line 36 between the valve 42 and the air inlet 20 has adapted pressure drop, it should not be necessary to have a two-way valve, but one can then be satisfied with a two-way branch, for example a T-pipe section. In such a case, it is convenient to arrange a non-return valve at the connection point 40 in the air intake duct 20, which non-return valve is advantageously integrated with other parts included in the connection point 40.

Claims (9)

5 10 15 20 25 30 521 097 Patent claims An arrangement for a supercharged internal combustion engine (2) with closed crankcase ventilation, which arrangement serves to create a negative pressure in the engine crankcase, wherein a turbocharger (16) driven by the engine exhaust sucks air through an air filter (18) via an air inlet duct (20) and thus supplying pressurized air to the engine inlet pipe (8) via a charge air cooler (28), and that for returning crankcase gases from the crankcase to the inlet pipe (8) a ventilation duct (36) is provided extending from the interior of the crankcase (38) to a connection point ( 40) in the air intake duct (20) between the air filter (18) and the compressor air inlet (22), characterized in that to ensure negative pressure in the crankcase also during engine braking, an adjustable damper (34) is connected in a charge air supply connection (32) and in the ventilation line (36) an oil trap (44), a pressure regulator (44) and a two-way branch or two-way valve (42) are connected in series, one of which outlet ports (46) is connected lse with said connection point (40) via the ventilation line (36), while its second outlet port (48) is connected to the inlet pipe (8) via a non-return valve (52). Arrangement according to Claim 1, characterized in that the adjustable damper (34) is connected in a charge air supply connection (32) between the air outlet (30) of the charge air cooler (28) and the inlet pipe (8). Arrangement according to Claim 1, characterized in that the adjustable damper (34b) is connected in a pipeline (26) between the air outlet (24) of the compressor and the air inlet of the charge air cooler (28). Arrangement according to claim 1, 2 or 3, characterized in that the non-return valve in the connection (50) between the second outlet port (48) of the two-way valve (42) and the inlet pipe (8) consists of a valve unit (52) preferably comprising at least one resilient reed leaf valve valve type, which prevents charge air outflow from the inlet pipe (8) to the two-way valve (42). 521 097 Arrangement according to one of the preceding claims, characterized in that the oil trap in the ventilation line (36) from the crankcase consists of an oil separating filter, which is preferably assembled with the pressure regulator into a unit (44). 5 Arrangement according to Claim 2 or 3, characterized in that the damper is a servo-operated throttle valve (34, 34b) of the rotary damper type. Arrangement according to one of the preceding claims, characterized in that the two-way branch with two outlets (46, 48) used instead of the two-way valve (42) consists of a constantly open two-way connection in the form of a T-pipe section. Arrangement according to Claim 7, characterized in that a non-return valve is arranged in the connection between the two-way branch and the air intake duct (20), advantageously at the connection point (40). 15 Arrangement according to one of the preceding claims, characterized in that the internal combustion engine (2) is a four-stroke engine, preferably a diesel engine.