EP3020935A2 - Dispositif de degazage du carter de vilebrequin - Google Patents

Dispositif de degazage du carter de vilebrequin Download PDF

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Publication number
EP3020935A2
EP3020935A2 EP15193730.7A EP15193730A EP3020935A2 EP 3020935 A2 EP3020935 A2 EP 3020935A2 EP 15193730 A EP15193730 A EP 15193730A EP 3020935 A2 EP3020935 A2 EP 3020935A2
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EP
European Patent Office
Prior art keywords
pressure
jet pump
suction jet
crankcase
control device
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
EP15193730.7A
Other languages
German (de)
English (en)
Other versions
EP3020935A3 (fr
EP3020935B1 (fr
Inventor
Dimitri An
Steve Beez
Armando COELHO
Alfred ELSÄSSER
Thomas Fallscheer
Christian Gramlich
Volker Kirschner
Thomas Riemay
Stefan Ruppel
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Mahle International GmbH
Original Assignee
Mahle International GmbH
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Filing date
Publication date
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Publication of EP3020935A2 publication Critical patent/EP3020935A2/fr
Publication of EP3020935A3 publication Critical patent/EP3020935A3/fr
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Publication of EP3020935B1 publication Critical patent/EP3020935B1/fr
Not-in-force legal-status Critical Current
Anticipated expiration legal-status Critical

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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02MSUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
    • F02M21/00Apparatus for supplying engines with non-liquid fuels, e.g. gaseous fuels stored in liquid form
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01MLUBRICATING OF MACHINES OR ENGINES IN GENERAL; LUBRICATING INTERNAL COMBUSTION ENGINES; CRANKCASE VENTILATING
    • F01M13/00Crankcase ventilating or breathing
    • F01M13/02Crankcase ventilating or breathing by means of additional source of positive or negative pressure
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01MLUBRICATING OF MACHINES OR ENGINES IN GENERAL; LUBRICATING INTERNAL COMBUSTION ENGINES; CRANKCASE VENTILATING
    • F01M13/00Crankcase ventilating or breathing
    • F01M13/04Crankcase ventilating or breathing having means for purifying air before leaving crankcase, e.g. removing oil
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01MLUBRICATING OF MACHINES OR ENGINES IN GENERAL; LUBRICATING INTERNAL COMBUSTION ENGINES; CRANKCASE VENTILATING
    • F01M13/00Crankcase ventilating or breathing
    • F01M2013/0038Layout of crankcase breathing systems
    • F01M2013/005Layout of crankcase breathing systems having one or more deoilers
    • F01M2013/0061Layout of crankcase breathing systems having one or more deoilers having a plurality of deoilers
    • F01M2013/0066Layout of crankcase breathing systems having one or more deoilers having a plurality of deoilers in parallel
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01MLUBRICATING OF MACHINES OR ENGINES IN GENERAL; LUBRICATING INTERNAL COMBUSTION ENGINES; CRANKCASE VENTILATING
    • F01M13/00Crankcase ventilating or breathing
    • F01M13/02Crankcase ventilating or breathing by means of additional source of positive or negative pressure
    • F01M13/021Crankcase ventilating or breathing by means of additional source of positive or negative pressure of negative pressure
    • F01M2013/026Crankcase ventilating or breathing by means of additional source of positive or negative pressure of negative pressure with pumps sucking air or blow-by gases from the crankcase
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01MLUBRICATING OF MACHINES OR ENGINES IN GENERAL; LUBRICATING INTERNAL COMBUSTION ENGINES; CRANKCASE VENTILATING
    • F01M13/00Crankcase ventilating or breathing
    • F01M13/04Crankcase ventilating or breathing having means for purifying air before leaving crankcase, e.g. removing oil
    • F01M2013/0433Crankcase ventilating or breathing having means for purifying air before leaving crankcase, e.g. removing oil with a deflection device, e.g. screen
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01MLUBRICATING OF MACHINES OR ENGINES IN GENERAL; LUBRICATING INTERNAL COMBUSTION ENGINES; CRANKCASE VENTILATING
    • F01M13/00Crankcase ventilating or breathing
    • F01M13/04Crankcase ventilating or breathing having means for purifying air before leaving crankcase, e.g. removing oil
    • F01M2013/0488Crankcase ventilating or breathing having means for purifying air before leaving crankcase, e.g. removing oil with oil trap in the return conduit to the crankcase
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F01MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
    • F01MLUBRICATING OF MACHINES OR ENGINES IN GENERAL; LUBRICATING INTERNAL COMBUSTION ENGINES; CRANKCASE VENTILATING
    • F01M13/00Crankcase ventilating or breathing
    • F01M13/04Crankcase ventilating or breathing having means for purifying air before leaving crankcase, e.g. removing oil
    • F01M2013/0488Crankcase ventilating or breathing having means for purifying air before leaving crankcase, e.g. removing oil with oil trap in the return conduit to the crankcase
    • F01M2013/0494Crankcase ventilating or breathing having means for purifying air before leaving crankcase, e.g. removing oil with oil trap in the return conduit to the crankcase using check valves

Definitions

  • the invention relates to a vehicle having an internal combustion engine having a crankcase and a supercharger with a crankcase ventilation device having an inertia-based oil separator having at least one inertia-based oil separator, a separated oil to the crankcase returning oil return and a suction jet pump driven with compressed air of the supercharger and which generates a negative pressure to drive blow-by gas. Furthermore, the invention relates to a method for controlling a crankcase ventilation device.
  • crankcase In the crankcase is a crankshaft, which is connected via connecting rods with pistons of the individual cylinders of the internal combustion engine. Leakages between the pistons and the associated cylinder walls result in a blow-by gas flow through which blow-by gas passes from the combustion chambers into the crankcase.
  • crankcase ventilation device To avoid undue overpressure in the crankcase, modern internal combustion engines are equipped with a crankcase ventilation device to remove the blow-by gases from the crankcase.
  • the blow-by gas is usually supplied to a fresh air system of the internal combustion engine using the crankcase ventilation device, which supplies the combustion chambers of the internal combustion engine with fresh air.
  • the crankcase ventilation device which supplies the combustion chambers of the internal combustion engine with fresh air.
  • the crankcase there is an oil mist, so that the blow-by gas carries oil with it.
  • This oil can act as oil droplets elements in the intake tract, such as a turbocharger, damage.
  • the crankcase breather usually has an oil separator, and preferably an oil return, which returns the separated oil to the crankcase.
  • passive systems can basically be distinguished from active systems. Passive systems use the pressure difference between the crankcase and the negative pressure in the fresh air system to drive the blow-by gas. Active systems additionally generate a negative pressure for the extraction of the blow-by gas from the crankcase. As a result, a higher pressure difference can be used in the oil separation, so that the deposition is improved.
  • a suction jet pump which is driven by the compressed air of the supercharger and thus generates a negative pressure, with the aid of which a higher differential pressure can be generated.
  • the response of the internal combustion engine, at part load or idle can significantly deteriorate because in the charger energy is withdrawn, if due to the low power of the engine anyway low energy is present.
  • crankcase ventilation device in which a negative pressure for venting the crankcase by means of a suction jet pump is generated.
  • the suction jet pump is driven by compressed air from a turbocharger.
  • the present invention has for its object to provide for a vehicle of the type mentioned an improved embodiment, which is characterized in particular by a better response of the internal combustion engine. At the same time, a high efficiency with regard to the oil separation effect should be realized.
  • the invention is based on the general idea of only driving the crankcase ventilation device by the suction jet pump when the internal combustion engine is operated at relatively high load, because then the charging device provides sufficiently large amounts of compressed air, from which parts can be diverted without significant performance losses, to operate the suction jet pump.
  • This is possible in particular at high powers of the internal combustion engine.
  • the flow rate of the blow-by gases is particularly high, so that in a very favorable manner then the support of the crankcase ventilation device takes place by the suction jet pump, although the largest flow rates are required.
  • the suction jet pump is regulated and / or controlled by a control device. As a result, the performance of the suction jet pump can be optimally adapted to the given conditions.
  • the suction jet pump can be operated when sufficient compressed air is present through the charging device and / or operated when the pressure in the crankcase increases too much.
  • the suction jet pump By supporting the suction jet pump, generally larger pressure differences can be provided for the oil separation device, so that the deposition rate of the oil separation device is improved.
  • negative pressure is understood to mean a pressure which is below the atmospheric ambient pressure.
  • control device is formed by an already existing control unit.
  • the engine control unit can take over the function of the control device. This is advantageous since the required information is already available to the engine control unit.
  • a separate control device for the control device may be provided.
  • a favorable solution provides that the control device regulates the suction jet pump by a pump control valve and / or controls and / or switches, which regulates the flow of compressed air through the suction jet pump and / or controls and / or switches.
  • the losses of the compressed air can be selectively influenced by the ejector, so that the response of the internal combustion engine, especially at idle or at part load, can be improved.
  • the pump control valve is an electrically controllable and / or controllable valve.
  • the control device can easily control the pump control valve and thus the suction jet pump by an electrical signal.
  • an electrically controllable valve may include a solenoid and a ferromagnetic material so that the valve may be controlled by current flowing through the solenoid coil.
  • an electrically controllable valve may include an electrical actuator that opens and closes the valve.
  • a particularly favorable solution provides that the pump control valve is a pneumatically controllable and / or controllable valve. This allows existing pneumatic systems to be used to control the pump control valve.
  • the pump control valve is a hydraulically controllable and / or controllable valve.
  • existing hydraulic systems can be used to control the pump control valve.
  • the pump control valve is switchable between two states, in particular between a closed position in which the pump control valve is closed and a passage position in which the pump control valve is completely open.
  • the suction jet pump can be switched on or off and thus the support of the crankcase ventilation by the suction jet pump on or off.
  • the pump control valve is a proportional valve, wherein the pump control valve continuously between a closed position in which the pump control valve is closed and a passage position in which the pump control valve is fully open, is adjustable.
  • the power of the ejector can be selectively controlled and / or controlled, so that the crankcase ventilation can be selectively controlled and / or regulated in order to achieve a good compromise between crankcase ventilation and spent compressed air of the charging device.
  • control device controls the Saugstrahlpumpe map-based and / or regulated.
  • Ie in the controller are stored for points of the maps of the internal combustion engine, control variables for the ejector.
  • the Steuereicardi can thus control the ejector pump based on the stored control variables such that a good crankcase ventilation is achieved with low energy loss.
  • a favorable variant provides that the control device controls the suction jet pump based on a speed of the internal combustion engine and / or regulates.
  • the amount of blow-by gas that accumulates in the crankcase is dependent on the speed.
  • the generation of compressed air by the charging device is dependent on the rotational speed of the internal combustion engine. Consequently, the control device based on the speed of the internal combustion engine determine when the support of the crankcase ventilation by the suction jet pump makes sense or not.
  • a further favorable variant provides that the control device controls and / or regulates the suction jet pump on the basis of the torque generated by the internal combustion engine.
  • the generated torque is in strong relation to the combustion pressure within the cylinders of the internal combustion engine. Consequently, the torque is also related to the blow-by gases flowing from the combustion chamber into the crankcase.
  • the control device can make a sensible decision as to whether the support by the ejector pump is required or not.
  • a particularly favorable variant provides that the control device controls and / or regulates the suction jet pump on the basis of the power generated by the internal combustion engine. Both the generated blow-by gases and the compressed air generated by the supercharger are in strong relation to that produced Performance of the internal combustion engine, so that the control device can decide based on the power generated by the internal combustion engine, whether the support of the crankcase ventilation by the suction jet pump is necessary or not.
  • control device controls the suction jet pump based on a throttle position and / or controls.
  • the throttle position of the internal combustion engine influences the performance of the internal combustion engine.
  • control device based on the throttle position determine whether the support of the crankcase ventilation by the suction jet pump makes sense or not.
  • a support of the crankcase ventilation by the suction jet pump makes sense if much compressed air is generated by the supercharger and when the volume flow of blow-by gas into the crankcase is large. This is especially the case when the internal combustion engine has a high rotational speed, generates a high torque, generates a high power and / or the throttle valve is wide open.
  • control device controls and / or controls the ejector pump according to a measured variable. In this way, the controller can respond to the real occurring values, and thus find an even better compromise between energy consumption by the ejector pump and improved crankcase ventilation.
  • control device controls the suction jet pump on the basis of the intake air quantity and / or regulates.
  • the sucked air quantity is a good measure of the power generated by the internal combustion engine.
  • the control device can then activate the suction jet pump precisely when the use of the suction jet pump is particularly favorable.
  • a further advantageous solution provides that the control device controls and / or regulates the suction jet pump on the basis of a boost pressure of the charging device. If the boost pressure is particularly high, the additional removal of compressed air from the charger leads to less power losses than when the boost pressure is already low anyway. In this way, therefore, the control device can ensure that the response of the internal combustion engine is less affected.
  • a particularly advantageous solution provides that the control device controls and / or regulates the suction jet pump according to the pressure applied in the crankcase.
  • the control device controls and / or regulates the suction jet pump according to the pressure applied in the crankcase.
  • the suction jet pump just turn on when the vent against the ambient pressure is not sufficient to dissipate the entire volume flow of blow-by gases from the crankcase. Consequently, thus exceeding an allowable pressure within the crankcase can be avoided.
  • control device controls and / or regulates the suction jet pump in such a way that the power of the suction jet pump is increased at an increased intake air quantity, that the power of the suction jet pump is increased at a high boost pressure of the supercharger, and / or that at an elevated pressure in the crankcase Power of the suction jet pump is increased.
  • the ⁇ labscheide driving has at least three working areas, wherein in a first working area, a flow cross-section of the ⁇ labscheide boots is constant, wherein in a second work area, the flow cross section of the ⁇ labscheide interests increases with increasing pressure difference between the inlet and outlet of the ⁇ labscheide listening and wherein in a third Working area of the flow cross section of the oil separator with increasing pressure difference increases less than in the second work area.
  • the volume flows through the ⁇ labscheide interests are low, so that the flow cross-section of the oil separator must also be low in order to have a sufficient pressure difference for the inertia-based oil separation available.
  • the second working area is provided, in which the flow cross-section of the oil separation device increases, so that even with increased volume flow of the blow-by gases sufficient crankcase ventilation can be ensured.
  • the enlargement of the flow cross-section is braked in comparison to the second working region, so that the pressure difference can increase.
  • This third working area is intended for operating conditions in which the suction jet pump provides an additional negative pressure for crankcase ventilation, so that even with an increased pressure difference ensures sufficient crankcase ventilation can be.
  • the increased pressure difference allows better separation of oil.
  • a further advantageous possibility provides that the inertia-based ⁇ labscheide worn has at least two inertia-based oil separator, and that the control device switches depending on the power of the ejector between the at least two oil separators.
  • one of the oil separators can be designed for low volume flows and low pressures, while the second oil separator is designed for larger pressure differences, which can be achieved when the ejector is switched on. In this way, better deposition rates can be achieved.
  • the one or more oil separators is or are formed by an impactor, and / or is formed by a cyclone or are.
  • An impactor and a cyclone are both inertia-based oil separators that achieve an improved separation rate with an increased pressure difference between inlet and outlet.
  • the effects of the suction jet pump can be optimally utilized.
  • the ⁇ labscheide leads comprises two oil separator, each having a spring-loaded poppet valve, which opens with increasing input-side pressure, that the poppet valve of one of the oil separator is a low pressure poppet valve, and that the poppet valve of the other oil separator is a high pressure poppet valve that the low pressure poppet valve opens at a lower pressure than the high pressure poppet valve.
  • the inertia-based oil separation device has an oil separator with a pressure / volume characteristic with at least three, preferably at least four, different regions.
  • the different regions differ in particular by the relation between pressure and volume, for example, the different regions of the pressure / volume characteristic correlate with the different working regions of the oil separator.
  • the oil separator has two springs which act on the poppet valve, wherein a first spring is biased in the closed state of the poppet valve and a second spring is tensioned only from a certain opening path of the poppet valve.
  • a first spring is biased in the closed state of the poppet valve
  • a second spring is tensioned only from a certain opening path of the poppet valve.
  • the impactor has a progressive spring, which acts on the poppet valve and which has a spring constant, which increases with increasing compression of the spring.
  • the behavior of the oil separator can be influenced in such a way that when connecting the ejector a greater pressure difference can be achieved, which allows a better ⁇ labscheiderate.
  • a further advantageous variant provides that the poppet valve is additionally acted upon by a reference pressure, which acts on the poppet valve in the closing direction. Also in this way can be achieved that the pressure difference between the inlet and outlet of the oil separator is increased in order to achieve a better oil separation.
  • the oil separator has a membrane against which the reference pressure is applied and through which the poppet valve of the oil separator is acted upon.
  • a force generated by the reference pressure can be applied to the poppet valve in a simple manner
  • the reference pressure is a boost pressure of the charging device or an input-side pressure of the suction jet pump.
  • the reference pressure is an ambient pressure, in particular an atmospheric ambient pressure.
  • the ambient pressure is substantially constant, so that a vacuum generated by the suction jet pump, which acts as a back pressure to the reference pressure on the membrane, can influence the poppet valve.
  • the negative pressure is lowered, so that less by the negative pressure strong opening forces act on the poppet valve. Consequently, with an increased output of the ejector, the opening area of the oil separator is reduced, so that the pressure difference across the oil separator can increase and thus the oil separation is improved.
  • crankcase ventilation device has a throttle valve, with which the blow-by gases can be throttled. If the negative pressure generated by the suction jet pump are too large, so that the pressure within the crankcase falls too far and there is a risk to suck oil from the crankcase, the throttle valve is closed, so that extraction of oil from the crankcase can be prevented.
  • a further particularly advantageous variant provides that the throttle valve is arranged in a flow path of the blow-by gases between the crankcase and the ⁇ labscheide worn, or that the throttle valve is disposed in a flow path of the blow-by gases between the oil separator and the suction jet pump , In these two positions, the throttle valve can effectively prevent too much suction of the blow-by gases.
  • the invention is also based on the general idea of providing a liquid separation device for separating liquid from a gas flow, in particular of oil from blow-by gas, which has at least one impactor, wherein the impactor has nozzles which are at least partially permanently open and through which the gas flow flows, the impactor has at least one baffle plate arranged opposite the nozzle, which deflects the gas flow and at which the liquid droplets precipitate, the impactor has a spring-loaded poppet valve which is arranged parallel to the nozzles in terms of flow, which opens with increasing pressure difference between valve inlet and valve outlet and forms a flow gap through which a part of the gas flow flows, and opposite to which a baffle plate is arranged, which deflects the gas flow and at which liquid droplets are deposited, wherein the liquid separation device has at least three working areas, wherein in a first working area a flow cross section of the liquid separation device is constant, increases in a second work area, the flow cross-section of the sosstechniksabborge founded with increasing pressure difference between
  • the liquid separator can be designed in such a way that it functions optimally under different operating conditions.
  • the liquid separator can ensure, for example, that at relatively low pressure differences, nevertheless a sufficiently high volume flow can flow through the diesstechniksabscheider adopted and at a higher pressure difference, which can be achieved for example by an additional conveyor, can achieve a better deposition rate.
  • a favorable variant provides that the flow cross section of the liquid separation device is the sum of the cross sections of the nozzles and the flow gaps of the poppet valves.
  • the flow cross-section of the diesstechniksabborge crafted the cross section through which the gas flow flows in order to achieve a sufficient flow rate for the inertia-based liquid separation.
  • a further favorable variant provides that the liquid separation device is at low pressure differences in the first working area, at medium pressure differences in the second working area and at high pressure differences in the third working area.
  • a particularly favorable variant provides that the impactor has two springs which act on the poppet valve, wherein a first spring is biased in the closed state of the poppet valve and a second spring is tensioned only from a certain opening stroke of the poppet valve. In this way, the three work areas can be achieved with the help of a single impactor.
  • the impactor has a progressive spring, which acts on the poppet valve and having a spring constant, which increases with increasing compression of the spring. In this way, the different working areas of the liquid separation device can be achieved with a single impactor, with the second and third working areas continuously merging.
  • a favorable possibility provides that the poppet valve is additionally acted upon by a reference pressure, which acts on the poppet valve in the closing direction of the poppet valve.
  • a reference pressure which acts on the poppet valve in the closing direction of the poppet valve.
  • a particularly advantageous solution provides that a charge pressure of a charging device of an internal combustion engine is used as the reference pressure, and / or an input-side pressure of a suction jet pump. These pressures are dependent on the load condition of an internal combustion engine, in which the diesstechniksabborge styles can be used. Thus, the separation behavior of the diesstechniksabscheide styles can be adapted to the operating conditions of the internal combustion engine.
  • the reference pressure is an ambient pressure, in particular an atmospheric ambient pressure.
  • the ambient pressure is substantially constant, so that a vacuum generated by the suction jet pump, which acts as a back pressure to the reference pressure on the membrane, can influence the poppet valve.
  • the vacuum is lowered with increasing power of the suction jet pump, so that less strong opening forces act on the poppet valve by the negative pressure. Consequently, with an increased output of the ejector, the opening area of the oil separator is reduced, so that the pressure difference across the oil separator can increase and thus the oil separation is improved.
  • a particularly advantageous solution provides that a common baffle plate is provided for the nozzles and the poppet valve, which is cylindrical and which radially surrounds the nozzles and the flow gap of the poppet valve. In this way, a particularly compact construction of the impactor and thus of the liquid separation device can be achieved.
  • the diesstiksabscheide Scotland comprises two impactors, each having a spring-loaded poppet valve, which opens with increasing input pressure, that the poppet valve of one of the impactors is a low pressure poppet valve and that the poppet valve of the other impactor is a high-pressure diaphragm valve, that Low pressure poppet valve opens at a lower pressure than the high pressure poppet valve.
  • Another particularly favorable solution provides that the high pressure poppet valve opens only at a pressure at which the low pressure poppet valve is already open to the maximum. In this way, the second working area and the third working area of the liquid separation device can be cleanly separated from one another, without creating an intermediate area in which the flow cross section of the liquid separation device increases more with increasing pressure difference than in the second working area.
  • the low pressure poppet valve is subjected to a reference pressure.
  • the low pressure poppet valve can be closed again when a particularly large pressure difference is available at the remplisstechniksabscheide worn available.
  • This can be achieved, for example, by supporting a conveying device, for example a suction jet pump.
  • a conveying device for example a suction jet pump.
  • the deposition rate of the liquid separation device can be improved particularly well.
  • crankcase ventilation device 10 has a remplisstechniksabscheide worn 11, hereinafter ⁇ labscheide worn 11th called by which blow-by gases are passed from a crankcase 14 to separate oil mist from the blow-by gas, a suction jet pump 16 which generates a negative pressure to drive the blow-by gases, and a pump control valve 18 which controls and / or regulates the suction power of the suction jet pump 16.
  • the crankcase ventilation device 10 is used for venting the crankcase 14 of an internal combustion engine 20, as used for example in a vehicle 22, in particular a motor vehicle.
  • crankcase ventilation device 10 In reciprocating engines, such as gasoline engines or diesel engines, due to the high pressure during combustion gases from the combustion chamber into the crankcase 14. The gases flow between the piston and cylinder wall in the crankcase 14. These gases are blow-by Called gases. The blow-by gases would accumulate in the crankcase 14 over time and build up considerable pressure. To prevent this, the crankcase ventilation device 10 is provided.
  • the blow-by gases which are vented from the crankcase 14, usually have oil mist, they are the intake manifold 13 of the engine 20 is supplied.
  • the oil separator 11 is provided in order not to burden the internal combustion engine 20 and possibly in the intake tract 13 befind Anlagen units, such as superchargers 24 with the oil mist.
  • the ⁇ labscheide worn 11 causes a pressure difference, or requires a certain pressure difference in order to achieve sufficiently high deposition rates. For this reason, for example, in pure suction internal combustion engines, the negative pressure in the intake tract 13 of the internal combustion engine 20 is utilized in order to provide a pressure difference for the oil separation device 11.
  • the suction jet pump 16 may be provided, which is driven by the compressed air 28 generated by the charging device 24, and generates a negative pressure.
  • a larger pressure difference between the crankcase 14 and the outlet of the oil separator 11 can be generated.
  • a better degree of separation can be achieved. This is particularly interesting because a maximum permissible pressure in the crankcase 14 should not be exceeded.
  • the response of the internal combustion engine 20 deteriorates, especially at low power.
  • the turbocharger 26 is at a low speed, thus producing only a low boost 30.
  • engine performance becomes high reduced.
  • the turbocharger 26 is at full speed and can generate sufficient compressed air 28 and a sufficiently high boost pressure 30, so that often even a Waist Gate is used to avoid impermissibly high speeds of the turbocharger. In such situations, the removal of compressed air 28 is harmless to the performance of the engine 20.
  • the pump control valve 18 is designed such that the suction jet pump 16 is operated just when sufficient boost pressure 30 so are sufficient amounts of compressed air 28 from the supercharger 24 are available. Accordingly, the power of the ejector 16 is throttled or the ejector 16 completely turned off when not enough boost pressure 30 or compressed air 28 is available, for example, at idle or in partial load ranges of the engine 20th
  • the assistance of the crankcase ventilation by the suction jet pump 16 takes place just when the internal combustion engine 20 outputs high power. So just then, even if a flow rate of blow-by gases in the crankcase 14 is particularly high. Viewed the other way around, the throttling of the suction jet pump 16 takes place precisely in operating states of the internal combustion engine 20, when anyway relatively small amounts of blow-by gas reach the crankcase 14.
  • the pump control valve 18 is configured such that the pump control valve 18 opens or closes depending on a pressure difference between a valve inlet 35 and a valve outlet 37. At low pressure differences, the pump control valve 18 is closed. At pressure differences above a threshold pressure difference opens the pump control valve 18 so that gases can flow through the pump control valve.
  • the pump control valve 18 On the input side, the pump control valve 18 is connected to the high-pressure side of the charging device 24, so that the boost pressure 30 of the charging device 24 is present on the input side of the pump control valve 18.
  • the pump control valve 18 thus opens when the boost pressure 30 of the charging device 24 exceeds the output pressure of the pump control valve 18, that is, the pressure at the inlet of the suction jet pump 16 by more than the threshold pressure difference.
  • the pump control valve 18 opens, if it is harmless to the performance of the engine 20.
  • the pump control valve 18 is designed such that it opens or closes depending on the input-side pressure. At low pressures up to a swelling pressure this is Pump control valve 18 closed. At pressures above the threshold pressure, the pump control valve 18 opens so that gases can pass through the pump control valve 18.
  • the pump control valve 18 On the input side, the pump control valve 18 is connected to the high-pressure side of the charging device 24, so that the boost pressure 30 of the charging device 24 is present on the input side of the pump control valve 18.
  • the pump control valve 18 thus opens when the boost pressure 30 of the charging device 24 is above the threshold pressure.
  • the pump control valve 18 opens, if it is harmless to the performance of the engine 20.
  • the pump control valve 18 has a valve seat 32 and a closure part 34, which is pressed against the force of the valve seat 32 and thus closes the pump control valve 18.
  • a seal 36 is arranged, against which the closure part 34 is pressed, and thus the pump control valve 18 closes.
  • the closure member 34 is arranged such that the input-side pressure exerts a force on the closure member 34, which lifts the closure member 34 from the valve seat 32.
  • the force with which the closure member 34 is acted upon against the valve seat 32 and the pressure force by the boost pressure 30 thus compete with each other.
  • the pressing force of the boost pressure 30 exceeds the force with which the shutter member 34 is urged against the valve seat 32, the shutter member 34 rises from the valve seat 32, so that the pump control valve 18 opens.
  • the pressure force by the boost pressure 30 is at the threshold pressure at which the pump control valve 18 opens approximately equal to the force with which the closure member 34 is acted upon against the valve seat 32.
  • a spring 38 may be provided, which is biased, so that the closure member 34 is acted upon by the spring force of the spring 38 against the valve seat 32.
  • the suction jet pump 16 is based on the Ventury effect.
  • a first medium is passed through a nozzle and directed into a larger tube. Due to the high flow rate of the medium at the nozzle, the surrounding medium is entrained, so that there is a negative pressure, which is utilized here in order to achieve a sufficient pressure difference at the ⁇ labscheide worn 11.
  • the oil separator 11 has an oil separator 12, which is an inertia-based oil separator.
  • oil separator 12 exploits the different densities of the oil droplets compared to the density of the blow-by gas to separate the oil droplets from the blow-by gas.
  • a gas flow is generated, which is deflected.
  • the oil droplets can not follow so well due to the higher density of the deflection, so that they are driven to the edge of the flow and possibly hit a plate on which they attach.
  • Such inertia-based oil separators 12 are, for example, impactors 40 or cyclones.
  • the oil separator 12 is designed as an impactor 40 and can also separate other liquids.
  • the gas flow to be cleaned is For example, the blow-by gas, passed through at least one nozzle 42, which is arranged opposite a baffle plate 44, so that the gas flow is deflected immediately after the nozzle.
  • the gas flow receives a high velocity, so that the liquid droplets, hereinafter called oil droplets, the deflection by the baffle plate can not follow and meet the baffle plate 44 and hang there and thus be separated from the gas flow.
  • the impactor 40 has a poppet valve 46 which is spring-loaded closed, wherein the poppet valve 46 opens when a pressure difference between the valve inlet 48 and valve outlet 50 is exceeded, which corresponds to a pressure difference between inlet 49 and outlet 51 of the oil separator 11.
  • the poppet valve 46 forms an annular flow gap 52, which also acts like a nozzle, and accelerates the flow of gas flowing through the impactor 40, for example the blow-by gas.
  • the annular flow gap 52 is surrounded by a cylindrical baffle plate 44, which deflects the gas flow, which has flowed through the annular flow gap 52, and thus also allows there a separation of oil droplets from the gas flow.
  • a flow cross-section 56 of the impactor 40 is increased and thus increases the flow cross-section of the oil separator 11.
  • the flow cross section 56 is composed of the cross section of all nozzles 42 and the flow area of the annular flow gap 52.
  • the poppet valve 46 is formed in such a way that the poppet valve 46 can be opened more easily via a first opening path than over a remaining opening path.
  • the poppet valve 46 has two springs which press a closure plate 58 against a valve seat, wherein when the poppet valve is closed, a first spring 60 is biased and a second spring 62 is not biased.
  • the second spring 62 is tensioned only when opening the poppet valve 46 when the first opening path of the poppet valve 46 is passed. In this way, the relevant for the poppet valve 46 spring constant in the first opening path is less than in the remaining opening stroke, since the spring constants of the first spring 60 and the second spring 62 are added.
  • the impactor 40 has three working areas.
  • a first working area 64 the poppet valve 46 is closed and the gas flow must flow through the nozzles 42.
  • a second work area 66 the poppet valve 46 is partially opened, with only the first spring 60 is tensioned, so that the poppet valve 46 can open against a small spring constant.
  • a third working area 68 the poppet valve 46 is opened so far that both the first spring 60 and the second spring 62 are tensioned, so that a further opening of the poppet valve 46 must be made against an increased spring force.
  • the working areas are preferably selected such that when the ejector pump 16 is switched off or operating at very low power, the impactor 40 operates in the first working range or in the second working range 66 and when the suction switching pump 16 is switched on, the impactor 40 operates in the third working range 68.
  • the impactor 40 has an input side inner cylinder 70 in which at a head end 72 of the inner cylinder 70, the nozzles 42 are arranged in the cylinder wall and are directed radially outward.
  • flow openings 74 are arranged for the poppet valve 46 through which the gas flow through the poppet valve 46 can flow and on the other hand, a central bore 76 in which a guide pin 78 of the poppet valve 46 is guided so that a closure plate 58 axially movable is mounted in the inner cylinder 70.
  • the shutter 58 abuts against the head end 72 of the inner cylinder 70 from the outside and thus closes the flow openings 74 when the poppet valve 46 is closed.
  • the shutter 58 is axially raised from the head end 72 of the inner cylinder 70 to expose the flow opening 74 when the poppet valve 46 is opened.
  • the springs 62, 60 are supported on an inner side of the inner cylinder 70 at the head end 72 of the inner cylinder 70 and thus press the plate-shaped closure member 58 in the direction of the valve inlet 48.
  • Radial outside the inner cylinder, the baffle plate 44 is cylindrical and arranged and can thus deflect the gas flow, which flows through the nozzles 42 or through the annular flow gap 52 and thus to separate liquid, such as oil, from the gas flow.
  • the impactor 40 has a liquid collecting region 80, in which the separated liquid, for example oil, is collected in order to then be able to return it to the crankcase 14 via an oil return 81.
  • the separated liquid for example oil
  • a throttle valve 15 is arranged, which can throttle the flow of the blow-by gases, if the pressure in the crankcase 14 would decrease too much, so that oil would be sucked out of the crankcase 14.
  • the throttle valve 15 may also be arranged fluidically between the oil separation device of the suction jet pump 16.
  • FIGS. 6 to 8 illustrated second embodiment of the crankcase ventilation device 10 differs from that in the FIGS. 1 to 5 illustrated first embodiment of the crankcase ventilation device 10 in that the poppet valve 46 of the impactor 40 has a progressive spring 82, with which the plate-shaped closure member 58 of the poppet valve 46 is subjected to force against the flow openings 74.
  • the second working area 66 and the third working area 68 of the impactor 40 continuously merge into one another, so that when the suction jet pump 16 is switched on, an increased pressure difference at the impactor 40 can be achieved.
  • FIGS. 6 to 8 illustrated second embodiment in terms of structure and function with in the FIGS. 1 to 5 illustrated first embodiment of the crankcase ventilation device 10, to the above description in this respect reference is made.
  • FIGS. 9 to 10 illustrated third embodiment of the crankcase ventilation device 10 differs from that in the FIGS. 1 to 5 illustrated first embodiment of the crankcase ventilation device 10 characterized in that the oil separator 11 has two oil separator 12, for example, two impactors 40 through which the oil separator 11 has a plurality, for example, three work areas.
  • the ⁇ labscheide worn 11 has a first poppet valve 84 and a second poppet valve 86, wherein both poppet valves each have only one spring.
  • the spring 88 of the first poppet valve 84 has a lower spring constant than the spring 90 of the second poppet valve 86.
  • the bias of the spring 90 of the second poppet valve 86 is such that the second poppet valve 86 opens only when the first poppet valve 84 already is open at most.
  • the first poppet valve 84 is also called the low pressure poppet valve 84
  • the second poppet valve 86 is also called the high pressure poppet valve 86.
  • the first working area 64 of the oil separation device 11 results, in which both the first poppet valve 84 and the second poppet valve 86 are closed, and the oil separation device 11 can flow through the gas flow only through the nozzles 42.
  • the second working area 66 is characterized in that the first poppet valve 84 is partially opened and the second poppet valve 86 is closed.
  • the third working area 68 is characterized in that the first poppet valve 84 is fully open and that the second poppet valve is at least partially open.
  • FIGS. 9 to 10 illustrated third embodiment of the crankcase ventilation device 10 in terms of design and function with in the FIGS. 1 to 5 illustrated first embodiment of the crankcase ventilation device 10, to the above description in this respect reference is made.
  • FIGS. 11 and 12 illustrated fourth embodiment of the crankcase ventilation device 10 differs from that in the FIGS. 1 to 5 illustrated first embodiment of the crankcase ventilation device 10 characterized in that the poppet valve 46 is additionally acted upon by a reference pressure 92 which presses the poppet valve 46 in a closed position.
  • the boost pressure 30 he charging device 24 can be used.
  • the suction power of the ejector 16 is particularly high, so that the oil separator 11, a high pressure difference for the oil separation can be provided.
  • the flow cross-section 56 of the oil separator 11 must not be too large. This is achieved by the reference pressure 92, since with larger boost pressures 30, the poppet valve 46 may be closed again, so that the flow cross-section 56 of the oil separation device 11 increases or even decreases less.
  • an input-side pressure 93 of the suction jet pump 16 is used as the reference pressure 92.
  • the input-side pressure of the ejector jet 16 16 is also a measure of the performance of the power of the ejector 16 by the pump control valve 18 Suction jet pump 16, so that the adaptation of the oil separation device 11 is particularly adapted to the actual available suction power of the suction jet pump 16.
  • an atmospheric ambient pressure is used as the reference pressure 92.
  • the ambient pressure is essentially constant and only subject to fluctuations due to the altitude above zero and the weather-related fluctuations.
  • the impactor 40 has in a free space above the closure plate 58 of the poppet valve 46 a closed by a membrane 94 pressure chamber in which the reference pressure 92 is introduced.
  • the diaphragm 94 presses driven by the reference pressure 92 on the shutter 58.
  • the shutter 58 is thereby additionally pressed onto the flow openings 74 of the poppet valve 46.
  • the pressure at the valve outlet 50 is applied to the membrane 94, which thus acts on the poppet valve 46 in the opening direction.
  • the outlet 51 of the oil separator 11 and thus the valve outlet 51 is sucked off by the suction jet pump 16 so that the vacuum generated by the suction jet pump 16 is applied to the valve outlet 51.
  • At high powers of the ejector 16 thus reduces the pressure that opens the poppet valve 46, so that when increasing the power of the ejector 16, the poppet valve 46 is acted upon more strongly in the closing direction. This also applies when using a substantially constant pressure as the reference pressure 92, such as the atmospheric pressure.
  • valve inlet 48 acts on the poppet valve 46 in the opening direction.
  • the pressure at the valve inlet 48 is in particular at the bottom of the
  • FIGS. 11 and 12 illustrated fourth embodiment of the crankcase ventilation device 10 in terms of design and function with in the FIGS. 1 to 5 illustrated first embodiment of the crankcase ventilation device 10, to the above description in this respect reference is made.
  • crankcase ventilation device 10 differs from that in the FIGS. 9 to 10 illustrated third embodiment of the crankcase ventilation device 10 characterized in that the first poppet valve 84, so the low pressure poppet valve 84, in addition to a reference pressure 92 is applied.
  • the boost pressure 30 of the charging device 24 can be used.
  • the first poppet valve 84 which is formed as a low pressure poppet valve 84, is depressed by the reference pressure 92 so that the low pressure poppet valve 84 opens less widely is or even closed. The liquid separation then takes place mainly through the high pressure poppet valve 86.
  • the first poppet valve 84 has in a free space above the closure plate 58 of the poppet valve 84 a closed by a membrane 94 pressure chamber in which the reference pressure 92 is introduced.
  • the diaphragm 94 is driven by the reference pressure 92 onto the closure plate 58.
  • the closure plate 58 is thereby additionally pressed onto the flow openings 74 of the poppet valve 84.
  • crankcase ventilation device 10 in terms of structure and function with in the FIGS. 9 to 10 represented third embodiment of the crankcase ventilation device 10, to the above description in this respect reference is made.
  • FIG. 15 illustrated sixth embodiment of the crankcase ventilation device 10 differs from that in the FIGS. 1 to 5 illustrated first embodiment of the crankcase ventilation device 10 in that the pump control valve 18 is controlled by a control device 96 and / or regulated.
  • the pump control valve 18 is designed to be controllable by a signal from the outside accordingly.
  • the pump control valve 18 is an electrically, magnetically, pneumatically or hydraulically controllable valve.
  • the pump control valve 18 can be switched back and forth between a closed position and an open position.
  • the pump control valve 18 is a proportional valve, which is continuously adjustable between the closed position and the passage position.
  • the control device 96 controls the pump control valve 18 and thus the power of the suction jet pump 16 such that the response of the internal combustion engine 20 is influenced as little as possible.
  • the pump control valve 18 is closed, in particular during idling operation and / or partial load range, so that the suction jet pump 16 does not draw off compressed air 28 from the charging device 24.
  • control device 96 decides whether the suction jet pump 16 is switched on or off.
  • control device can regulate and / or control the power of the suction jet pump 16 based on a map.
  • the control device 96 is, for example, the engine control of the internal combustion engine 20, so that the control device 96 has all the data of the engine control. These are in particular the rotational speed of the internal combustion engine 20, the torque generated by the internal combustion engine 20, the generated power of the internal combustion engine 20 or a throttle position. On the basis of these values, the control device 96 can estimate whether sufficient charge pressure 30 is present, so that the performance of the internal combustion engine 20 is not or only slightly influenced and if any support of the crankcase ventilation by the suction jet pump 16 is necessary.
  • controller 96 may regulate and / or control the ejector 16 in accordance with a measured amount.
  • a measured amount can, for example be the sucked air amount, the boost pressure 30 or the pressure in the crankcase 14.
  • the suction jet pump can respond to the conditions actually occurring in the crankcase 14 or behind the charging device 24, and control the ejector 16 accordingly.
  • a combination of map-based control and / or control and based on measured sizes is possible.
  • a value for the power of the suction jet pump can be determined on the basis of the characteristic diagrams and, if appropriate, readjusted on the basis of the measured variable.
  • FIG. 15 illustrated sixth embodiment of the crankcase ventilation device 10 in terms of design and function with in the FIGS. 1 to 5 illustrated first embodiment of the crankcase ventilation device 10, to the above description in this respect reference is made.
  • FIG. 16 illustrated seventh embodiment of the crankcase ventilation device 10 differs from that in the FIGS. 6 to 8 illustrated second embodiment of the crankcase ventilation device 10 characterized in that the pump control valve 18 is controlled by a control device 96.
  • the control and / or control of the pump control valve 18 by the control device 96 corresponds to the control and / or control according to the in FIG. 15 illustrated sixth embodiment of the crankcase ventilation device 10, the above description of which reference is made.
  • FIG. 16 illustrated seventh embodiment of the crankcase ventilation device 10 in structure and function with the in the FIGS. 6 to 8 illustrated second embodiment of the crankcase ventilation device 10 in terms of structure and function, to the above description in this respect reference is made.
  • FIG. 17 illustrated eighth embodiment of the crankcase ventilation device 10 differs from that in the FIGS. 9 to 10 illustrated third embodiment of the crankcase ventilation device 10 characterized in that the pump control valve 18 is controlled by a control device 96 and / or controlled.
  • the control and / or control of the pump control valve 18 by the control device 96 corresponds to the control and / or control according to the in FIG. 15 illustrated sixth embodiment of the crankcase ventilation device 10, the above description of which reference is made.
  • FIG. 17 illustrated eighth embodiment of the crankcase ventilation device 10 with respect to structure and function with the illustrated in Figures 9 to 10 third embodiment of the crankcase ventilation device 10, to the above description in this respect reference is made.
  • crankcase ventilation device 10 differs from the in FIG. 17 illustrated eighth embodiment of the crankcase ventilation device 10 in that the crankcase ventilation device 10 has a switching valve 100 which switches the blow-by gas flow between the two impactors of the oil separator 11.
  • the switching valve 100 is controlled by the controller 96.
  • the control device 96 switches the switching valve 100 according to that the impactor 40 is flowed through with the low-pressure plate valve 84 when the ejector 16 is turned off or only at very low power operates, and that the high-pressure fan valve 86 is flowed through when the ejector pump 16 is turned on or at least operates at high power.
  • the high pressure diaphragm valve 86 of the oil separator can be used, which indeed requires a higher differential pressure, but then also offers better oil separation.
  • controller 96 controls another valve 102 disposed between the impactor 40 with the low pressure poppet valve 84 and the intake manifold 13, and then closes when the switch valve 100 is switched to the impactor 40 with the high pressure poppet valve 86. In this way, backflow of gases through the impactor 40 with the low cell valve 84 can be avoided. In this case, the ⁇ labscheide worn 11 for both impactors each have their own outlet 53, 55 on.
  • FIG. 20 illustrated tenth embodiment of the crankcase ventilation device 10 differs from that in the FIGS. 11 and 12 illustrated fourth embodiment in that the pump control valve 18 is controlled by a control device 96.
  • the regulation and / or control of the pump control valve 18 by the control device 96 corresponds to the control and / or control according to the in FIG. 15 illustrated sixth embodiment of the crankcase ventilation device 10, the above description of which reference is made.
  • FIG. 20 illustrated tenth embodiment of the crankcase ventilation device 10 in terms of design and function with in the FIGS. 11 and 12 illustrated fourth embodiment of the crankcase ventilation device 10, to the above description, reference is made in this regard.
  • FIG. 21 illustrated eleventh embodiment of the crankcase ventilation device 10 differs from that in the Figures 13 and 14 illustrated fifth embodiment of the crankcase ventilation device 10, characterized in that the pump control valve 18 is controlled and / or regulated by a control device 96.
  • the control and / or control of the pump control valve 18 by the control device 96 corresponds to the control and / or control according to the in FIG. 15 illustrated sixth embodiment of the crankcase ventilation device 10, the above description of which reference is made.
  • FIG. 21 illustrated eleventh embodiment of the crankcase ventilation device 10 in terms of structure and function with in the Figures 13 and 14 illustrated fifth embodiment of the crankcase ventilation device 10, to the above description in this respect reference is made.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Lubrication Details And Ventilation Of Internal Combustion Engines (AREA)
EP15193730.7A 2014-11-14 2015-11-09 Dispositif de dégazage du carter de vilebrequin Not-in-force EP3020935B1 (fr)

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DE102014223288.0A DE102014223288A1 (de) 2014-11-14 2014-11-14 Kurbelgehäuseentlüftungseinrichtung

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WO2018073194A1 (fr) * 2016-10-21 2018-04-26 Elringklinger Ag Dispositif de séparation, dispositif moteur et procédé de séparation
CN108119205A (zh) * 2017-12-22 2018-06-05 江苏理工学院 一种曲轴箱通风清洁装置
FR3063304A1 (fr) * 2017-02-28 2018-08-31 Mgi Coutier Dispositif d’aspiration et de decantation d’un gaz de carter et installation associee
DE102017203877A1 (de) 2017-03-09 2018-09-13 Polytec Plastics Germany Gmbh & Co. Kg Geschaltete Saugstrahlpumpe

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DE102016209635B4 (de) * 2016-06-02 2024-04-25 Mahle International Gmbh Verfahren zum Betreiben einer Kurbelgehäuseentlüftungsanlage sowie nach diesem Verfahren betreibbare Brennkraftmaschine
DE102016014142A1 (de) 2016-11-25 2018-05-30 Daimler Ag Verbrennungskraftmaschine für ein Kraftfahrzeug, insbesondere für einen Kraftwagen
DE102017205589B4 (de) 2017-04-03 2019-03-14 Audi Ag Saugstrahlpumpe

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WO2018073194A1 (fr) * 2016-10-21 2018-04-26 Elringklinger Ag Dispositif de séparation, dispositif moteur et procédé de séparation
CN109844270A (zh) * 2016-10-21 2019-06-04 爱尔铃克铃尔股份公司 分离装置、发动机装置和分离方法
CN109844270B (zh) * 2016-10-21 2020-06-02 爱尔铃克铃尔股份公司 分离装置、发动机装置和分离方法
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FR3063304A1 (fr) * 2017-02-28 2018-08-31 Mgi Coutier Dispositif d’aspiration et de decantation d’un gaz de carter et installation associee
DE102017203877A1 (de) 2017-03-09 2018-09-13 Polytec Plastics Germany Gmbh & Co. Kg Geschaltete Saugstrahlpumpe
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DE102014223288A1 (de) 2016-05-19
EP3020935B1 (fr) 2019-01-09

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