JP6502596B2 - Internal combustion engine - Google Patents

Description

  The present invention relates to a dry sump type internal combustion engine, and more particularly to a lubrication system and blow-by gas recirculation system for an internal combustion engine.

  As a dry sump type internal combustion engine, an oil tank separated from the crank chamber, a scavenge pump for pumping the lubricating oil accumulated at the bottom of the crank chamber to the oil tank, lubricating oil stored in the oil tank for each internal combustion engine It is known to have a feed pump that pumps to the sliding part. Such an internal combustion engine does not need to provide an oil pan at the lower part of the crank chamber, so the vertical height of the internal combustion engine can be reduced. In addition, since the amount of lubricating oil retained in the crank chamber is small, the inclination angle of the internal combustion engine (the angle between the cylinder axis and the vertical line) can be increased while avoiding oil immersion of the crankshaft. The vertical height can be further reduced.

  In a dry sump type internal combustion engine, in order to omit the scavenge pump, a passage connecting the crank chamber and the oil tank is allowed to flow from the crank chamber side to the oil tank side, while a one-way valve to prevent reverse flow is provided. There is one that is provided to transport lubricating oil from the crank chamber to the oil tank using pressure pulsations of the crank chamber accompanying reciprocating motion of the piston (e.g., Patent Document 1).

JP 2007-187133 A

  The fluid transported from the crank chamber to the oil tank includes a liquid containing a lubricating oil and a gas containing a blowby gas. Therefore, in order to transport the lubricating oil to the oil tank smoothly, it is necessary to discharge the gas component from the oil tank to the outside to suppress the increase in internal pressure of the oil tank. In Patent Document 1, a crank chamber and an oil tank are connected by two passages, a fluid containing lubricating oil is transported from the crank chamber to the oil tank through one passage, and a crank from the oil tank is passed through the other passage. The gas component is returned to the chamber. Further, a blowby gas passage connecting the crank chamber and the intake passage of the engine is separately provided, and the blowby gas is transported to the intake passage via the blowby gas passage. Thus, in Patent Document 1, many passages are required to transport the lubricating oil and the blowby gas, and the configuration is complicated. In addition, each passage must be provided with a one-way valve to regulate the flow direction, and if a gas-liquid separation passage is provided in the blowby gas passage, a passage must be provided to return the separated lubricating oil to the oil tank. Become.

  An object of the present invention is, in view of the above background, to enable circulation of lubricating oil and reflux of blowby gas with a simple configuration in a dry sump type internal combustion engine.

  In order to solve the above-mentioned subject, the present invention is an internal combustion engine (E), and a crank chamber (2) whose internal pressure is pulsated by a piston (11) which reciprocates in a cylinder (3), lubricating oil is stored. First return passage (45) connecting the oil tank (47), the intake passage (29) for supplying combustion air to the cylinder, the lower portion (2A) in the vertical direction of the crank chamber, and the oil tank ), A blowby gas passage (51, 52) connecting the gas phase portion of the oil tank and the intake passage, and an oil supply passage connecting the liquid phase portion of the oil tank and the sliding portion of the internal combustion engine (65), a feed pump (66) provided in the oil supply passage for pumping lubricating oil from the oil tank toward the sliding portion, and provided in the first return passage, the crank chamber While allowing flow to the oil tank side from and having first one-way valve that prevents reverse flow and (48).

  According to this configuration, when the piston descends and the pressure in the crank chamber becomes high, the first one-way valve is opened, and the lubricating oil accumulated in the lower portion of the crank chamber is recovered to the oil tank and Gas is returned to the intake passage through the first return passage and the blowby gas passage. Therefore, it is not necessary to provide a passage for returning the blowby gas from the oil tank to the crank chamber or a passage for flowing the blowby gas from the crank chamber to the intake passage, and the configuration of the passage of the internal combustion engine is simplified. Further, since the oil tank is provided between the first return passage and the blowby gas passage, the lubricating oil contained in the blowby gas is separated from the blowby gas and collected in the oil tank.

  In the above invention, the first reflux passage and the blowby gas passage may be connected to the oil tank via a gas-liquid separation device (46).

  According to this configuration, the gas-liquid mixed fluid containing the blow-by gas and the lubricating oil is more reliably separated into the gas containing the blow-by gas and the liquid containing the lubricating oil by passing through the gas-liquid separation device.

  In the above invention, a supercharger (24) is provided in the intake passage, and the blow-by gas passage connects the gas-liquid separation device and a portion of the intake passage upstream of the supercharger. First blow-by gas passage (51), and a second blow-by gas passage (52) connecting the gas-liquid separation device and a portion of the intake passage downstream of the supercharger, The blow-by gas passage may be provided with a second one-way valve (53) that allows the flow from the oil tank side to the intake passage side while blocking the reverse flow.

  According to this configuration, when the supercharger is not operating, blow-by gas is supplied to the intake passage via the second blow-by gas passage by the intake negative pressure generated in the downstream portion of the intake passage. On the other hand, when the supercharger is operating, the pressure in the downstream portion of the intake passage becomes high, so the second one-way valve is closed. Then, the blow-by gas is supplied to the intake passage via the first blow-by gas passage, using the differential pressure between the oil tank and the upstream side portion of the intake passage as a driving force. As described above, even when a supercharger is provided in the intake passage, blowby gas can be efficiently supplied to the intake passage.

  In the above invention, the valve operating chamber (6) in which the valve operating mechanism (35) for driving the intake and exhaust valves (33, 34) is disposed, and the second connecting the crank chamber and the valve operating chamber. The fuel cell system may further include a return passage (56) and a fresh air passage (61) connecting the intake passage and the valve operating chamber.

  According to this configuration, the lubricating oil accumulated in the valve operating chamber is transported to the crank chamber via the second reflux passage. Also, when the piston moves up and the crank chamber becomes negative pressure, fresh air is introduced from the intake passage to the valve operating chamber and the crank chamber through the new air passage, the valve operating chamber and the second return passage, Ventilation is performed.

  Further, in the above invention, the second return flow passage is provided with a third one-way valve (57) which allows flow from the valve operating chamber side to the crank chamber side while blocking reverse flow. Good to have. Further, the fresh air passage may be provided with a fourth one-way valve (62) which allows the flow from the intake passage to the valve-operating chamber side while blocking the reverse flow.

  According to this configuration, even when the pressure in the crank chamber increases due to the lowering of the piston, the backflow of the lubricating oil and the blowby gas from the crank chamber to the valve operating chamber is suppressed.

  Further, in the above invention, the wall portions (6B, 6C) which define the lower portion in the vertical direction of the valve operating chamber are formed in a shape continuously falling toward the lowermost portion (6D) in the vertical direction, The open end of the return passage on the valve operating chamber side may be open at the lowermost portion of the wall of the valve operating chamber.

  According to this configuration, the lubricating oil, which is used to lubricate the valve operating mechanism, flows to the opening end on the valve operating chamber side of the second return passage by gravity.

  Further, in the above invention, the second reflux passage may extend continuously downward from the open end on the valve operating chamber side to the open end on the crank chamber side.

  According to this configuration, the lubricating oil flows from the valve operating chamber side to the crank chamber side by gravity from the valve operating chamber side.

  Further, in the above invention, the wall portion which defines the valve operating chamber may have an annular barrier (6E) surrounding an open end on the valve operating chamber side of the fresh air passage.

  According to this configuration, the barrier inhibits movement of the lubricating oil adhering to the wall of the valve chamber to the fresh air passage, so that the lubricating oil is prevented from entering the fresh air passage and the intake passage.

  Further, in the above invention, an oil filter (68) is provided at a portion closer to the sliding portion than the feed pump of the oil supply passage, and the oil filter is mounted on the oil tank when the internal combustion engine is stopped. It may be disposed at a position higher than the oil level of the stored lubricating oil.

  According to this configuration, the lubricating oil is prevented from flowing out from the oil tank to the sliding portions of the internal combustion engine when the internal combustion engine is stopped.

  According to the above configuration, in the dry sump type internal combustion engine, circulation of the lubricating oil and reflux of the blowby gas can be enabled with a simple configuration.

Configuration diagram of an internal combustion engine according to an embodiment Cross section of internal combustion engine

  Hereinafter, an embodiment in which the present invention is applied to an internal combustion engine for a vehicle will be described with reference to the drawings.

  As shown in FIGS. 1 and 2, the engine body 1 of the internal combustion engine E has a cylinder block 4 having a crank chamber 2 at the rear and a cylinder 3 at the front, and a front of the cylinder block 4 And a head cover 7 connected to the front of the cylinder head 5 to form a valve operating chamber 6 between the cylinder head 5 and the cylinder head 5. The axis A of the cylinder 3 has an angle with respect to the horizontal plane, and the engine body 1 is inclined so that the crank chamber 2 side is lower than the valve operating chamber 6 side.

  A piston 11 is accommodated in the cylinder 3 so as to be capable of reciprocating along the axis A. The piston 11 is connected to a crankshaft 12 rotatably disposed in the crank chamber 2 via a connecting rod 13. The axis B of the crankshaft 12 extends in a direction perpendicular to the axis A of the cylinder 3 and is disposed parallel to the horizontal plane. In a portion of the cylinder head 5 facing the cylinder 3, a hemispherically formed combustion chamber recess 14 is formed. The combustion chamber recess 14 cooperates with the top of the cylinder 3 and the piston 11 to form a combustion chamber 15.

  Although the number of cylinders 3 in the engine body 1 and the phase difference between the pistons 11 are arbitrary, the internal pressure of the crank chamber 2 periodically pulsates between positive pressure and negative pressure according to the reciprocation of each piston 11 Is set as. For example, the engine body 1 may be a single cylinder, two cylinders, or three cylinders. In the case of two cylinders, the phase difference between the two pistons 11 may be the same phase or 90 °. In the case of three cylinders, the phase of each piston 11 may be 0 ° -180 ° -0 ° or 0 ° -180 ° -90 °.

  The cylinder head 5 is formed with two intake ports 16 extending from the combustion chamber 15 to one side surface of the cylinder head 5 and two exhaust ports 17 extending from the combustion chamber 15 to the other side surface of the cylinder head 5 ing. The side perpendicular to the axis A of the cylinder 3 and the axis B of the crankshaft 12 and on which the intake port 16 of the cylinder head 5 is provided is the intake side, and the side on which the exhaust port 17 is provided is the exhaust side. In FIG. 1, the intake side is above the exhaust side.

  An intake device 21 for supplying combustion air to the combustion chamber 15 is connected to each intake port 16. The intake system 21 includes, from the upstream side, an air inlet 23, an air cleaner 23 having a filter element 23 A, a compressor 24 A of the turbocharger 24, an intercooler 25, a throttle valve 26, and an intake manifold 27. It is connected to the intake port 16. The intake system 21 forms a series of intake passages 29 together with the intake port 16. The supercharger 24 is an exhaust gas turbocharger in the present embodiment. In other embodiments, the supercharger 24 may be replaced by a known supercharger such as a supercharger.

  Each exhaust port 17 is connected to an exhaust device (not shown) for discharging the burned gas (exhaust gas) generated in the combustion chamber 15 to the outside. The exhaust system includes, in order from the upstream side, an exhaust manifold, a turbine 24B of the turbocharger 24, a catalytic converter, a silencer, and an exhaust outlet, and is connected to the exhaust port 17 in the exhaust manifold. The exhaust system forms a series of exhaust passages together with the exhaust port 17.

  The cylinder head 5 is provided with a poppet-type intake valve 33 and an exhaust valve 34 (collectively referred to as intake and exhaust valves 33 and 34) for opening and closing the intake port 16 and the exhaust port 17. The stem ends 33A, 34A of the intake and exhaust valves 33, 34 are disposed in the valve operating chamber 6, and are biased in the closing direction by a valve spring (not shown). The intake and exhaust valves 33 and 34 are driven to open and close by the valve operating mechanism 35 in synchronization with the rotation of the crankshaft 12.

  The valve mechanism 35 presses the intake camshaft 36 and the exhaust camshaft 37 disposed in the valve chamber 6, and the base end 39A rotatably supported by the intake rocker shaft 38 and the stem end 33A of the intake valve 33. An intake rocker arm 39 having a distal end 39B, and an exhaust rocker arm 42 having a proximal end 42A rotatably supported by the exhaust rocker shaft 41 and a distal end 42B pressing the stem end 34A of the exhaust valve 34. The intake camshaft 36, the exhaust camshaft 37, the intake rocker shaft 38, and the exhaust rocker shaft 41 are disposed in parallel with the crankshaft 12. The intake camshaft 36 and the exhaust camshaft 37 are connected to the crankshaft 12 via a power transmission mechanism (not shown), and rotate at a half rotation speed of the crankshaft 12 in synchronization with the crankshaft 12. The power transfer mechanism may be, for example, a known chain transfer mechanism including sprockets coupled to the respective shafts 12, 36, 37, and a chain extending across the respective sprockets.

  As shown in FIG. 2, when viewed from the direction along the axis B of the crankshaft 12, the valve mechanism 35 is disposed offset to the intake side (upward) with respect to the axis A of the cylinder 3. Specifically, the exhaust camshaft 37 is disposed closer to the axis A than the intake camshaft 36 when viewed in the direction along the axis B of the crankshaft 12. Further, the exhaust rocker shaft 41 is disposed closer to the axis A than the intake rocker shaft 38. Further, the intake rocker arm 39 is disposed such that the proximal end 39A is closer to the intake side than the distal end 39B, and the exhaust rocker arm 42 is disposed closer to the intake side than the distal end 42B. By arranging the valve operating mechanism 35 offset to the intake side (upper side), the valve operating chamber 6 can reduce the space on the exhaust side (lower side) with respect to the intake side. As a result, the valve operating chamber 6 and the cylinder head 5 are prevented from projecting to the exhaust side (downward) with respect to the cylinder block 4.

  By suppressing the protrusion of the valve operating chamber 6 to the exhaust side, the wall portion 6B forming the exhaust side portion in the wall portion 6A of the valve operating chamber 6 is formed so as to continuously go down to the cylinder block 4 side. be able to. The lower portion of the valve operating chamber 6 is mainly formed by the exhaust side wall 6B and the combustion chamber 15 side (the cylinder block 4 side) wall 6C, and the exhaust side wall 6B and the combustion chamber 15 side The boundary with the wall 6C is the lowermost portion 6D of the valve operating chamber 6. The lubricating oil adhering to the wall portions 6B and 6C of the valve operating chamber 6 flows to the lowermost portion 6D along the wall portions 6B and 6C.

  The lowermost portion 2 </ b> A in the vertical direction of the crank chamber 2 is connected to an oil tank 47 via a first reflux passage 45 and a first gas-liquid separator 46. The first return passage 45 is provided with a first one-way valve 48 that allows the flow of fluid from the crank chamber 2 side to the oil tank 47 side and blocks the reverse flow. The first one-way valve 48 is closed in the initial state, and opens when the pressure on the crank chamber 2 side is higher than the pressure on the oil tank 47 side by a predetermined value or more. In the present embodiment, the first one-way valve 48 is a reed valve, and is provided at an end of the first return passage 45 on the crank chamber 2 side.

  The oil tank 47 may be integrally formed with the engine body 1 or may be a tank separated from the engine body 1. A predetermined amount of lubricating oil is stored inside the oil tank 47, and has a liquid phase portion by the liquid lubricating oil and a gas phase portion by a gas (air) present above the liquid phase portion. The gas in the gas phase portion includes an oil mist or the like in which a blowby gas or a lubricating oil is misted (atomized).

  The first gas-liquid separation device 46 is a device for separating a gas-liquid mixed fluid containing lubricating oil and blowby gas supplied from the first reflux passage 45 into a liquid component containing lubricating oil and a gas component containing blowby gas. is there. The first gas-liquid separation device 46 may be a cyclone-type separation device that performs gas-liquid separation using centrifugal force, or a labyrinth-type separation device in which the flow path is meandered by a baffle plate. In the present embodiment, the first gas-liquid separator 46 is provided at the upper part of the oil tank 47, and the liquid discharge port is connected to the inside of the oil tank 47. Further, the gas discharge port of the first gas-liquid separation device 46 is connected by the first blow-by gas passage 51 to a portion between the air cleaner 23 and the compressor 24A which is an upstream portion of the intake passage 29 than the compressor 24A. . Further, the gas discharge port of the first gas-liquid separation device 46 is connected by the second blow-by gas passage 52 to an intake manifold 27 which is a downstream side portion of the intake passage 29 with respect to the compressor 24A.

  The second blow-by gas passage 52 is provided with a PCV valve 53 (second one-way valve) that allows the flow of fluid from the side of the first gas-liquid separator 46 to the side of the intake passage 29 and blocks the reverse flow. ing. The PCV valve 53 is closed in the initial state, and opens when the pressure on the intake passage 29 side is lower than the pressure in the first gas-liquid separator 46 (oil tank 47) by a predetermined value or more.

  The cylinder block 4 and the cylinder head 5 are formed with a second return passage 56 connecting the lowermost portion 6D of the valve operating chamber 6 and the crank chamber 2. The second return passage 56 extends continuously downward from the end on the valve operating chamber 6 side to the end on the crank chamber 2 side. That is, the liquid is caused to flow in the second reflux passage 56 from the valve operating chamber 6 side to the crank chamber 2 side by gravity.

  The second return passage 56 is provided with a third one-way valve 57 that allows the flow of fluid from the valve operating chamber 6 side to the crank chamber 2 side and blocks the reverse flow. The third one-way valve 57 is closed in the initial state, and opens when the pressure on the crank chamber 2 side is lower than the pressure on the valve operating chamber 6 by a predetermined value or more. In the present embodiment, the third one-way valve 57 is a reed valve, and is provided at the end of the second return passage 56 on the crank chamber 2 side.

  The valve operating chamber 6 and a portion of the air cleaner 23 of the intake passage 29 between the filter element 23A and the compressor 24A are connected by a fresh air passage 61. In the fresh air passage 61, a fourth one-way valve 62 and a second gas-liquid separation device 63 are provided in series in the order described from the intake passage side. The fourth one-way valve 62 allows the flow of fluid from the side of the intake passage 29 to the side of the valve operating chamber 6 and blocks the reverse flow. The fourth one-way valve 62 is closed in the initial state, and opens when the pressure on the valve operating chamber 6 side is lower than the pressure on the intake passage 29 by a predetermined value or more.

  The second gas-liquid separation device 63 is a device for separating a liquid such as oil contained in the passing gas. Similar to the first gas-liquid separation device 46, the second gas-liquid separation device 63 may be a known separation device such as a cyclone-type separation device or a labyrinth-type separation device. In the present embodiment, the second gas-liquid separator 63 is a labyrinth-type separator, and is formed on the head cover 7. If the internal combustion engine E has a plurality of cylinders 3 in series, the second gas-liquid separator 63 may extend in the direction in which the cylinders 3 are arranged.

  The passage in the second gas-liquid separation device 63 is connected to the fourth one-way valve 62 at one end, and is connected to the upper portion of the valve operating chamber 6 at the other end. As shown in FIG. 2, a passage hole 64 connecting one end of the passage in the second gas-liquid separation device 63 and the valve operating chamber 6 is formed in the wall portion 6A of the valve operating chamber 6. Around the passage hole 64, there is formed a barrier 6E annularly protruding from the wall 6A forming the valve operating chamber 6 so as to surround the passage hole 64. The barrier 6E adheres to the wall 6A of the valve operating chamber 6, and prevents the lubricating oil flowing along the wall 6A from reaching the passage hole 64. In this way, the entry of the lubricating oil into the second gas-liquid separator 63 is suppressed. In another embodiment, the passage hole 64 may be cylindrical and protrude from the wall 6A.

  The liquid phase portion of the oil tank 47 is connected to the main gallery 69 of the internal combustion engine E via an oil supply passage 65. The main gallery 69 has a plurality of branch pipes extending to each sliding portion of the internal combustion engine E. The sliding parts of the internal combustion engine E include sliding parts of the crankshaft 12 and its bearings, sliding parts of the respective camshafts 36 and 37 and their bearings, and respective camshafts 36 and 37 and rocker arms 39 and 42 , The sliding portions between the rocker arms 39 and 42 and the rocker shafts 38 and 41, the sliding portions between the inner wall of the cylinder 3 and the piston 11, the sliding portions of the turbocharger 24, and the like. The oil supply passage 65 is provided with a feed pump 66 for pressure-feeding lubricating oil from the oil tank 47 side to the sliding portion. The feed pump 66 is a known trochoid pump, and is connected to the crankshaft 12 by a power transmission device 67 including a sprocket and a chain, and rotates under the driving force of the crankshaft 12.

  The main gallery 69 is connected to the upstream end of the supercharger oil passage 71 connected to the oil tank 47 at the downstream end via the bearing (sliding portion) of the turbocharger 24. In another embodiment, the downstream end of the supercharger oil passage 71 may be connected to the crank chamber 2 or the second return passage 56.

  Further, an oil filter 68 is provided on the downstream side of the feed pump 66 of the oil supply passage 65. The oil filter 68 has a casing forming a passage, and a filter element disposed in the casing, and removes foreign matter from the passing lubricating oil. The oil filter 68 is disposed at a position higher than the oil level of the lubricating oil in the oil tank 47 when the internal combustion engine E is stopped.

  Next, the operation of the internal combustion engine E will be described with reference to FIG. When the internal combustion engine E is stopped, the lubricating oil is stored in the oil tank 47, and a part of the lubricating oil is present in the oil supply passage 65 and the first return passage 45. Since the oil filter 68 is disposed above the oil surface of the lubricating oil in the oil tank 47, the lubricating oil naturally flows out from the oil tank 47 to each sliding portion of the internal combustion engine E when the internal combustion engine E is stopped. There is no.

  When the internal combustion engine E is driven, the crankshaft 12 is rotated and the feed pump 66 is driven. Thus, the lubricating oil of the oil tank 47 is pressure-fed to the sliding parts of the internal combustion engine E via the oil supply passage 65. The lubricating oil supplied to the sliding portion in the crank chamber 2 such as the crankshaft 12 drops by gravity and collects in the lowermost portion 2 A of the crank chamber 2. Further, the lubricating oil supplied to the sliding portion in the valve operating chamber 6 such as the camshafts 36 and 37 drops by gravity and gathers in the lowermost portion 6 D of the valve operating chamber 6.

  When the piston 11 reciprocates, pressure pulsations occur in the crank chamber 2, and the pressure pulsations are used as a driving force to transport the lubricating oil in the valve chamber 6 to the crank chamber 2 and transport the lubricating oil in the crank chamber 2 to the oil tank 47 Be done. Further, blowby gas of the crank chamber 2 is supplied to the intake passage 29, and fresh air of the intake passage 29 is supplied to the valve operating chamber 6 and the crank chamber 2.

  When the piston 11 descends, the volume of the crank chamber 2 contracts and the pressure in the crank chamber 2 rises, and the pressure in the crank chamber 2 becomes higher than that of the oil tank 47 and the valve operating chamber 6. Therefore, the first one-way valve 48 is opened and the third one-way valve 57 is closed. Thereby, the lubricating oil and the blowby gas flow through the first reflux passage 45 to the first gas-liquid separator 46. In the first gas-liquid separator 46, the lubricating oil which is a liquid and the blowby gas which is a gas are separated, and the lubricating oil is supplied to the oil tank 47.

  When the supercharger 24 is not driven during low load operation of the internal combustion engine E, the downstream portion (intake manifold 27) of the intake passage 29 has a pressure lower than that of the first gas-liquid separation device 46 due to intake negative pressure. Thus, the PCV valve 53 is opened, and the blowby gas separated by the first gas-liquid separation device 46 flows through the second blowby gas passage 52 to the intake passage 29. At this time, according to the pressure difference between the first gas-liquid separator 46 and the upstream portion (air cleaner 23) of the intake passage 29 which is the atmospheric pressure, it passes through the first blowby gas passage 51 and Fresh air flows into the liquid separation device 46.

  In a state where the supercharger 24 is driven during the internal combustion engine E and during high load operation etc., the downstream side portion (intake manifold 27) of the intake passage 29 has a pressure higher than that of the first gas-liquid separation device 46, and PCV The valve 53 is closed. Therefore, the blow-by gas separated by the first gas-liquid separation device 46 is the first blow-by gas passage by the pressure difference between the first gas-liquid separation device 46 and the upstream portion (air cleaner 23) of the intake passage 29 which is atmospheric pressure. The gas flows from the first gas-liquid separator 46 into the intake passage 29 after passing through 51.

  When the piston 11 moves up, the volume of the crank chamber 2 expands and the pressure in the crank chamber 2 decreases, and the pressure in the crank chamber 2 becomes lower than that of the oil tank 47 and the valve operating chamber 6. Therefore, the first one-way valve 48 is closed and the third one-way valve 57 is opened. Thus, the lubricating oil in the valve operating chamber 6 flows into the crank chamber 2 through the second return passage 56. In addition, the fourth one-way valve 62 is opened by the pressure of the valve operating chamber 6 being lower than the pressure of the upstream side portion (air cleaner 23) of the intake passage 29 which is the atmospheric pressure. The fresh air is supplied to the valve operating chamber 6 through the fresh air passage 61 including the gas-liquid separation device 63, and the fresh air supplied to the valve operating chamber 6 passes through the second return passage 56 together with the lubricating oil to the crank chamber It flows to 2.

  Hereinafter, the effects of the internal combustion engine E according to the present embodiment will be described. In the internal combustion engine E, since both the lubricating oil and the blow gas are discharged from the crank chamber 2 by the first return passage 45, the passage for discharging the lubricating oil and the blowby gas can be simplified. In addition, the gas-liquid mixed fluid flowing through the first reflux passage 45 is separated into a gas containing blow-by gas and a liquid containing lubricating oil, the liquid is collected in the oil tank 47, and the blow-by gas is used as the first or second blow-by. The gas passes through the gas passages 51 and 52 and is supplied to the intake passage 29. Further, since the first gas-liquid separation device 46 is provided between the first reflux passage 45, the first and second blow-by gas passages 51, 52, and the oil tank 47, the gas-liquid separation can be performed more reliably. .

  Further, since the crank chamber 2 and the valve operating chamber 6 are connected by the second return passage 56 and the valve operating chamber 6 and the intake passage 29 are connected by the fresh air passage 61, the lubricant accumulated in the valve operating chamber 6 The oil is discharged to the crank chamber 2, and fresh air is introduced from the intake passage 29, and the valve operating chamber 6 and the crank chamber 2 are ventilated.

  Since the third return passage 56 is provided with the third one-way valve 57, when the vehicle equipped with the internal combustion engine E travels on a slope, the crank chamber 2 side of the second return passage 56 is the valve valve chamber 6 side. Even if it becomes higher, backflow of oil from the crank chamber 2 to the valve operating chamber 6 is prevented.

  Although the description of the specific embodiment is finished above, the present invention can be widely modified and implemented without being limited to the above embodiment. Although the example which provided the supercharger 24 was described in said embodiment, the supercharger 24 may be abbreviate | omitted. In this case, the first blowby gas passage 51 may also be omitted. Moreover, although the example which provided both the 3rd one-way valve 57 and the 4th one-way valve 62 was described in said embodiment, in the other embodiment, the 3rd one-way valve 57 and the 4th one-way valve 62 are mentioned. At least one of them may be provided in the internal combustion engine E.

  In other embodiments, the first gas-liquid separator 46 may be omitted. When the first gas-liquid separation device 46 is omitted, the first reflux passage 45 and the first and second blowby gas passages 51 and 52 are directly connected to the oil tank 47, and the blowby gas is oiled from the first reflux passage 45. It is preferable to flow to the first and second blowby gas passages 51, 52 through the gas phase portion in the tank 47.

DESCRIPTION OF SYMBOLS 1: Engine main body 2: Crank chamber 2A: Lowermost part 3: Cylinder 6: Valve chamber 6A: Wall 6B: Wall 6C: Wall 6D: Bottom 6E: Barrier 11: Piston 15: Combustion chamber 24: Supercharging Machine 27: Intake manifold 29: Intake passage 33: Intake valve 34: Exhaust valve 35: Valve mechanism 45: First return passage 46: First gas-liquid separation device 47: Oil tank 48: First one-way valve 51: First 1 blow-by gas passage 52: second blow-by gas passage 53: PCV valve (second one-way valve)
56: second return passage 57: third one-way valve 61: fresh air passage 62: fourth one-way valve 63: second gas-liquid separator 65: oil supply passage 66: feed pump 67: power transmission 68: oil Filter E: Internal combustion engine

Claims (9)

An internal combustion engine,
A crank chamber in which the internal pressure pulsates by a piston reciprocating in the cylinder;
An oil tank containing lubricating oil,
An intake passage for supplying combustion air to the cylinder;
A first return passage connecting a lower portion of the crank chamber in the vertical direction and the oil tank ;
And an oil supply passage that connects the sliding portion of the liquid-phase portion and the internal combustion engine before Symbol oil tank,
A feed pump provided in the oil supply passage for pumping lubricating oil from the oil tank toward the sliding portion;
A first one-way valve provided in the first return passage to allow flow from the crank chamber side to the oil tank side while blocking reverse flow;
The first reflux passage is connected to the oil tank via a gas-liquid separator .
An internal combustion engine , wherein a gas outlet of the gas-liquid separation device is directly connected to the intake passage by a blow-by gas passage . A supercharger is provided in the intake passage,
The blow-by gas passage is a first blow-by gas passage connecting the gas-liquid separation device and a portion of the intake passage upstream of the turbocharger, the gas-liquid separation device, and the turbocharger of the intake passage. And a second blow-by gas passage connecting the downstream portion with
Wherein the second blow-by gas passage, the one that allows the flow to the intake passage side from the oil tank, according to claim 1, characterized in that the second one-way valve that prevents reverse flow is provided Internal combustion engine according to claim 1. A valve operating chamber in which a valve operating mechanism for driving intake and exhaust valves is disposed;
A second return passage connecting the crank chamber and the valve operating chamber;
The internal combustion engine according to claim 1 or 2 , further comprising a fresh air passage connecting the intake passage and the valve operating chamber. Wherein the second return passage, while allowing the flow to the crank chamber side from the valve chamber side, claim 3, characterized in that the third one-way valve that prevents reverse flow is provided Internal combustion engine according to claim 1. Wherein the fresh air passage, the one that allows the flow to the valve chamber side from the intake passage, according to claim 3 or claim, wherein a fourth one-way valve that prevents reverse flow is provided An internal combustion engine according to item 4 . The wall portion which defines the lower portion in the vertical direction of the valve operating chamber is formed in a shape which is continuously lowered toward the lowermost portion in the vertical direction,
The open end on the valve operating chamber side of the second return passage is open at the lowermost portion of the wall portion of the valve operating chamber, The valve according to any one of claims 3 to 5 , Internal combustion engine according to claim 1. The internal combustion engine according to claim 6 , wherein the second return passage extends continuously downward from the open end on the valve operating chamber side to the open end on the crank chamber side. The wall portion which defines the valve operating chamber has an annular barrier which surrounds an open end of the fresh air passage on the valve operating chamber side, according to any one of claims 3 to 7 , Internal combustion engine as described. An oil filter is provided at a portion closer to the sliding portion than the feed pump of the oil supply passage.
The oil filter, any one of claims 1 to claim 8, characterized in that it is arranged at a position higher than the oil level of the lubricating oil stored in the oil tank when said suspension of the internal combustion engine Internal combustion engine according to claim 1.

Images