The present invention relates to a combustion engine for a vehicle, comprising a compressor to which charged air is to be supplied for supercharging, wherein the engine is provided with a device for venting exhaust gases from the crankcase of the engine to the compressor, which device comprises a throttle element for securing a desired pressure level in the crankcase.
In a supercharged combustion engine, a certain amount of leakage of fully or partly combusted exhaust gases always occur between the piston rings and the cylinder wall to the crankcase during the compression steps of the combustion engine. This exhaust gas leakage is generally referred to as blow-by, even though the gases also contain condensate from the engine oil in the crankcase. To prevent unfiltered exhaust gases from being discharged directly to the environment, these exhaust gases are ventilated to the intake system of the engine for combustion in the cylinders. This principle is generally referred to as PCV, Positive Crankcase Ventilation.
The blow-by gases are supplied directly from the crankcase, via a hose or the like, to the inlet in the air duct between the turbo compressor and the air filter. Alternatively, the exhaust gases are first supplied to the cylinder head cover (which is in fluid communication with the crankcase via the transmission between the crankshaft and the camshaft(s)). The underpressure that prevails upstream the compressor provide for this blow-by gas ventilation.
During driving situations when the engine works hard, a powerful suction is created upstream the compressor. To avoid a too large underpressure in the crankcase, which can result in an increased blow-by, a throttle element is arranged in the hose.
It forms a flow resistance in the hose which can be adapted for adjusting the evacuated amounts of exhaust gases as desired.
One example of this known PCV-principle is shown in
The combustion engine is provided with a PCV-device 21 (shown with dashed lines), which is intended to ventilate the exhaust gases from the crankcase. A throttle element 23 is arranged in the PCV-device and serves to control the amount of blow-by gases that are ventilated from the crankcase. During the operation of the engine, the underpressure that prevails just upstream the compressor will draw air from the environment via the air filter 17, but also from the crankcase via the PCV-device 21. In driving situations when the compressor 9 works hard (and thus creates a more powerful suction just upstream the compressor), the throttle element 23 will provide an efficient flow resistance in the PCV-device 21 preventing the pressure from decreasing too much in the crank case, which could result in an increased blow-by. During wintertime driving, or during other cold conditions, condensate is easily formed in the crankcase which can be transformed into ice. A particular critical place is as mentioned before the throttle element 23 in the PCV-device 21.
However, during some driving conditions the water content in the blow-by gases creates large amounts of condensation water, e.g. during wintertime or during frequent starts and stops of the engine. This formation of condensate can cause great problems if freezed to ice. A particularly critical place is the throttle element in the hose, and since an underpressure prevails, ice may also be formed at temperatures of several degrees above zero. Besides that the crankcase ventilation can be blocked by an ice plug leading to drainage of engine oil, the ice plug may also when it finally melts loose the grip and join the blow-by gas flow into the compressor, which can lead to damages of the compressor wheel.
U.S. Pat. Nos. 6,412,479 and 6,390,080 both use different types of PCV-systems. To avoid the formation of ice, they use a heat pipe for leading heat from e.g. the cooling liquid or the exhaust gas system for heating the PCV-system.
U.S. Pat. No. 6,044,829 discloses an electrical heating element for preventing ice formation in the PCV-system. The disadvantage with such a heating principle is that it requires an electrical current as well as some form of control equipment for preventing over heating.
U.S. Pat. No. 4,768,493 uses a separate circuit for circulating a cooling liquid around a PCV-valve. This separate circuit implies the use of extra pipes.
The systems described above are bulky and expensive.
An object of the present invention is to prevent the formation of ice in the throttle element included in the PCV-system in a simple way.
This object is achieved by means of a combustion engine as initially defined and which is characterised in that the throttle element is arranged in thermal cooperation with the compressor. Hereby, the formation of ice will not arise. Since the formation of ice only arises after a moment's driving, the compressor material have time to get heated by the heat generated during the compression, as well as get distributed via the compressor material to the throttle element.
Preferably, the compressor comprises an intake to which the device is connected, and which intake is in fluid communication with the inlet of the compressor, whereby the throttle element is arranged in the intake. Hereby the nearness to the heat source is short.
Suitably, the intake forms a recess in the compressor housing. Hereby is achieved a robust and stabile construction, and the throttle element is well protected from exterior stresses. Robust constructions are advantageous when emission related constructions are to be concerned, since national laws regulating emissions and the like often put great demands on stability and robustness.
Preferably, the recess extends in radial direction with reference to the longitudinal direction of the inlet. Hereby is achieved that connections to the recess will not interfere with connections to the air inlet of the compressor.
Suitably, the throttle element constitutes a contraction of the cross section of the recess, and preferably the recess has a section with a first diameter and a second section with a second, smaller diameter. Hereby a simple and robust design of the throttle element will be allowed. Furthermore, it will be simple to modify the compressor.
The invention will now be described with reference to accompanying drawings, on which:
The engine according to
During operation of the engine, the underpressure which is created just upstream the compressor will draw air from the environment via the air filter 47, but also from the crankcase via the PCV-device 51. During those driving situations when the compressor 39 works hard (and thus creates a more powerful suction upstream the compressor), the throttle element 53 will offer an efficient flow resistance in the PCV-device 51 which prevents the pressure from decreasing too much in the crankcase which thereby could result in an increased blow-by.
The PCV-device according to
In
During operation of the engine, the heat that is generated by the work of the compressor 39 will be distributed in the whole compressor housing and thus also to the area that surrounds the recess 65, i.e. also to the throttle element 53. It is not unusual that the compressor reaches a temperature, at the inlet nose, of several tens of centigrade, which is more than enough for avoiding the formation of ice.
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0401105 | Apr 2004 | SE | national |
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Number | Date | Country | |
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20050241310 A1 | Nov 2005 | US |