JP2019210847A - Engine with supercharger - Google Patents

Abstract

To provide an engine with supercharger for improving the lubricity and sealability of a bearing part of a supercharger utilizing blow-by gas.SOLUTION: The engine with supercharger includes a blow-by gas passage 71 for introducing blow-by gas including oil mist into an intake passage 30 at its site on the upstream side further than a supercharger 34, the supercharger 34 having a space part 34f consisting of a clearance in the vicinity of a bearing part 83, the blow-by gas passage 71 being provided with an oil separation supply part OP for separating oil from the blow-by gas and supplying the oil into the space part 34f.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a supercharged engine, and more particularly to an engine that recirculates blow-by gas in an intake passage. Note that blow-by gas generally means gas that leaks from the combustion chamber of the engine, and the blow-by gas contains oil mist.

  Patent Document 1 discloses a supercharged engine that recirculates blow-by gas in an intake passage. In this engine, oil mist contained in blow-by gas is used to improve the airtightness of the supercharger (supercharger).

  Specifically, a small amount of blow-by gas is introduced into the supercharger. When the blow-by gas passes through the rotor chamber of the supercharger, the oil contained in the blow-by gas enters and adheres to the gap between the rotor shaft and the rotor body. Thereby, the oil of blow-by gas is made to function as a sealing agent, and the airtightness in a rotor chamber is improved.

Japanese Patent Laid-Open No. 04-203213

  In Patent Document 1, a small amount of blow-by gas is introduced into the rotor chamber, and oil that adheres to the rotor shaft or the like when passing through the rotor chamber is used. The amount of blow-by gas introduced into the rotor chamber is small, and the oil spreads throughout the rotor chamber. Therefore, the amount of oil adhering to the drive site such as the bearing portion is very small. Therefore, it cannot be said to be sufficient as a sealant or a lubricating oil, and there is room for improvement.

  In addition, since oil adheres to the entire rotor chamber, the rotor chamber becomes dirty with oil.

  An object of the disclosed technology is to efficiently improve the lubricity and sealing performance of a bearing portion of a supercharger using oil mist contained in blow-by gas.

  The disclosed technology relates to an engine provided with a supercharger in the middle of an intake passage for introducing intake air into a combustion chamber.

  The engine includes a blow-by gas passage that introduces blow-by gas that is generated in the engine and includes oil mist to a portion upstream of the supercharger in the intake passage, and the supercharger sends out intake air An oil separation supply unit is provided in the vicinity of the bearing portion of the rotor. The oil separation supply unit separates oil from the blowby gas and supplies the oil to the space by the blowby gas passage.

  Specifically, the engine is also disposed in a portion upstream of the supercharger in the intake passage, and is controlled by a throttle valve that is controlled according to the operating state of the engine, and is generated in the engine. A blowby gas passage for introducing blowby gas containing oil mist into a portion of the intake passage between the throttle valve and the supercharger, and an upstream side of the blowby gas passage, A variable PCV valve.

  The supercharger is rotatably supported by a supercharger main body in which an intake port for sucking in intake air and a discharge port for discharging the intake air are formed, and a bearing portion in the supercharger main body. Accordingly, a rotor for sending intake air from the suction port to the discharge port, and a space portion formed by a gap formed in the vicinity of the bearing portion are provided.

  A communication passage is provided that branches from the downstream portion of the PCV valve in the blow-by gas passage and communicates with the space portion. Oil is separated from the blow-by gas upstream of the communication passage. An oil separation supply unit that supplies the oil to the communication path may be provided.

  That is, according to such a supercharged engine, the supercharger has a space portion formed by a gap in the vicinity of the bearing portion, and in the blowby gas passage, oil is separated from the blowby gas, An oil separation supply unit that supplies the oil to the space is provided. Therefore, the oil contained in the blow-by gas can be supplied to the bearing portion of the supercharger through the space portion, and the lubricity of the bearing portion of the supercharger can be efficiently improved with the oil contained in the blow-by gas. Can do.

  As a result, the oil is separated in the oil separation supply unit, and blow-by gas having a reduced oil content is introduced into the intake passage. Accordingly, oil contamination in the intake passage and the rotor chamber of the supercharger can be suppressed.

  In the engine, the oil separation supply unit is constituted by the blow-by gas passage, and a straight portion that separates oil from the blow-by gas by inertia and introduces oil into the communication passage; and a downstream side of the straight portion It is good also as having the cross part which branches so that it may bend from and goes to the said intake passage.

  In this case, the oil separation supply unit can be realized with a simple and compact structure without providing a separate device. Therefore, the member cost can be reduced, and since it can be arranged in a small space, it is excellent in assembling property and can be lightened.

  In the engine, the supercharger may further include a sealing material that seals the bearing portion in the vicinity of the bearing portion, and the space portion is adjacent to the sealing material.

  In this case, since the sealing property can be improved by the introduced oil, the performance of the supercharger can be stably maintained over a long period of time.

  According to the disclosed technology, it is possible to efficiently improve the lubricity and sealing performance of the bearing portion of the supercharger using oil mist contained in blow-by gas.

It is a figure which shows the main structures of a supercharged engine. It is a schematic top view which shows the specific structure of an intake unit. FIG. 3 is a schematic front view of the intake unit viewed from the direction of arrow A shown in FIG. 2. FIG. 3 is a schematic rear view of the intake unit viewed from the direction of arrow B shown in FIG. 2. (B) is a longitudinal cross-sectional view of a supercharger. (A) is sectional drawing in the Va-Va line | wire of (b), (c) is sectional drawing in the Vc-Vc line | wire of (b). It is a schematic diagram which shows the connection of a supercharger and a blow-by gas reduction system. (A) is a schematic top view which shows concretely the structure of the principal part of a blow-by gas passage. (B) is a schematic rear view corresponding to (a). It is the schematic which shows the flow of the intake air at the time of supercharging. It is the schematic which shows the flow of the intake at the time of non-supercharging. It is the schematic which shows the flow of the intake in the principal part at the time of supercharging. It is the schematic which shows the flow of the intake in the principal part at the time of non-supercharging.

  Hereinafter, embodiments of the disclosed technology will be described in detail based on the drawings. However, the following description is merely illustrative in nature and does not limit the present invention, its application, or its use.

  FIG. 1 shows a main configuration of an engine 1 (also simply referred to as engine 1) provided with a supercharger 34 to which the disclosed technology is applied. 2 to 4 show a specific structure of the intake unit 3 provided in the engine 1. FIG. 2 is a view of the intake unit 3 as viewed from above. FIG. 3 is a view of the intake unit 3 as viewed from the direction of arrow A (front) shown in FIG. FIG. 4 is a view of the intake unit 3 as seen from the direction (rear) of the arrow B shown in FIG.

  The engine 1 is, for example, a 4-stroke internal combustion engine mounted on an automobile (vehicle) and includes a mechanical or drive supercharger 34. The fuel of the engine 1 is not particularly limited, but is gasoline in the present embodiment.

  The engine 1 includes four cylinders 11 arranged in a row, although detailed illustration is omitted. The engine 1 is a so-called in-line four-cylinder horizontal engine 1 in which four cylinders 11 are mounted so as to be aligned in the vehicle width direction.

  Thereby, the left-right direction of the engine 1 which is the direction (cylinder row direction) in which the four cylinders 11 are arranged substantially coincides with the vehicle width direction. In the in-line multi-cylinder engine 1, the cylinder row direction matches the direction in which the crankshaft 15 extends.

  Each figure shows directions such as up, down, left and right. Unless otherwise specified, “front” refers to the front side of the vehicle, “rear” refers to the rear side of the vehicle, “left” refers to one side in the vehicle width direction, and “right” refers to , Refers to the other side in the vehicle width direction. Further, “upper” refers to the upper side of the state where the engine 1 is mounted on the automobile, and “lower” refers to the lower side thereof.

(Schematic configuration of engine 1)
The engine 1 is disposed on the engine main body 10 having four cylinders 11, the front side of the engine main body 10, the intake passage 30 communicating with each cylinder 11 via the intake port 18, and the rear side of the engine main body 10. The exhaust passage 50 communicates with each cylinder 11 through the exhaust port 19.

  The intake passage 30 is a combination of a plurality of passages through which intake air (gas such as air) flows and devices such as an air cleaner 31, a supercharger 34, an intercooler 36, and a surge tank 38 disposed in the middle of these passages. The intake unit 3 is configured. The engine body 10 combusts an air-fuel mixture composed of intake air supplied through the intake unit 3 and fuel in the combustion chamber 16 formed in each cylinder 11, and exhaust gas generated by the combustion is exhausted through the exhaust passage 50. Is configured to do.

  Specifically, the engine body 10 includes a cylinder block 12 and a cylinder head 13 placed on the cylinder block 12. Four cylinders 11 are formed inside the cylinder block 12. These cylinders 11 are arranged along the direction in which the crankshaft 15 extends (only one cylinder is shown in FIG. 1).

  A piston 14 is slidably inserted in each cylinder 11. Each piston 14 is connected to a crankshaft 15 via a connecting rod 141. A combustion chamber 16 is defined by the piston 14, the cylinder 11, and the cylinder head 13. The “combustion chamber” here is not limited to the meaning of only the space formed when the piston 14 reaches compression top dead center. The term “combustion chamber” is used in a broad sense.

  For example, two intake ports 18 are formed in each cylinder 11 in the cylinder head 13 (only one intake port 18 is shown in FIG. 1). The two intake ports 18 are adjacent to each other in the cylinder row direction and communicate with the corresponding cylinders 11 respectively.

  An intake valve 21 is disposed in each of the two intake ports 18. The intake valve 21 opens and closes between the combustion chamber 16 and each intake port 18. The intake valve 21 is opened and closed at a predetermined timing by an intake valve mechanism.

  As shown in FIG. 1, the intake valve mechanism has a variable valve mechanism 23. The variable valve mechanism 23 is configured to continuously change the rotation phase of the intake camshaft within a predetermined angle range. Thereby, the valve opening timing and the valve closing timing of each intake valve 21 change continuously.

  Further, for example, two exhaust ports 19 are formed for each cylinder 11 in the cylinder head 13 (FIG. 1 shows only one exhaust port 19). The two exhaust ports 19 are adjacent to each other in the cylinder row direction and communicate with the corresponding cylinders 11.

  Exhaust valves 22 are respectively disposed in the two exhaust ports 19. The exhaust valve 22 opens and closes between the combustion chamber 16 and each exhaust port 19. The exhaust valve 22 is opened and closed at a predetermined timing by an exhaust valve mechanism.

  As shown in FIG. 1, the exhaust valve mechanism has a variable valve mechanism 24. The variable valve mechanism 24 is configured to continuously change the rotational phase of the exhaust camshaft within a predetermined angular range. Thereby, the valve opening timing and valve closing timing of each exhaust valve 22 change continuously.

  An injector 6 is attached to the cylinder head 13 for each cylinder 11. Each injector 6 is, for example, a multi-injection type fuel injection valve, and is configured to inject fuel directly into each combustion chamber 16.

  A fuel supply system 61 is connected to each injector 6. The fuel supply system 61 includes a fuel tank 63 that stores fuel, and a fuel supply path 62 that connects the fuel tank 63 and the injector 6 to each other. A fuel pump 65 and a common rail 64 are interposed in the fuel supply path 62.

  A spark plug 25 is attached to the cylinder head 13 for each cylinder 11. The tip of the spark plug 25 faces the inside of the combustion chamber 16. By the operation of the spark plug 25, the air-fuel mixture in the combustion chamber 16 is forcibly ignited.

(Intake unit 3)
An air cleaner 31 that filters fresh air is disposed at the upstream end of the intake passage 30. The surge tank 38 is a container-like device that temporarily stores intake air, and is disposed at the downstream end of the intake passage 30, that is, at the upstream portion of the intake port 18 in the intake passage 30. A throttle valve 32 is disposed in a portion of the intake passage 30 downstream of the air cleaner 31. The opening degree of the throttle valve 32 is controlled according to the operating state of the engine 1. Thereby, the amount of fresh air introduced into the combustion chamber 16 is adjusted.

  A supercharger 34 is disposed in a portion of the intake passage 30 downstream of the throttle valve 32. The supercharger 34 supercharges the intake air introduced into each combustion chamber 16. The supercharger 34 is driven (mechanical) by the engine 1 (specifically, power transmitted from the crankshaft 15). The supercharger 34 is configured as, for example, a two-shaft rotor type roots blower.

  An electromagnetic clutch 34 a and a drive pulley 34 d are interposed between the supercharger 34 and the crankshaft 15. An annular timing belt is wound around the drive pulley 34d and the crankshaft 15, and these are configured to rotate in conjunction with each other. The supercharger 34 may be an electric type driven by electricity.

  The electromagnetic clutch 34a connects between the supercharger 34 and the crankshaft 15 to transmit driving force, or interrupts driving force transmission. When the ECU 7 (control device) switches between the disconnection and connection of the electromagnetic clutch 34a, the on-state and the off-state of the supercharger 34 are switched.

  That is, the engine 1 switches between the ON state and the OFF state of the supercharger 34, thereby supercharging the intake air introduced into the combustion chamber 16 (supercharging operation) and overcharging the intake air introduced into the combustion chamber 16. It is possible to switch between non-supply operation (natural intake operation). Details of the supercharger 34 will be described later.

  The intercooler 36 is disposed at a downstream portion of the supercharger 34 in the intake passage 30. The intercooler 36 exchanges heat with the intake air that has passed through the supercharger 34, and cools the intake air compressed by the supercharger 34. The intercooler 36 is, for example, a water cooling type.

  The intake passage 30 is a first passage 33 that constitutes a portion downstream of the throttle valve 32 and upstream of the supercharger 34, and a portion downstream of the supercharger 34 and upstream of the intercooler 36. , A second passage 35 that is downstream of the intercooler 36 and upstream of the surge tank 38, and a downstream side of the surge tank 38, And an independent passage 39 constituting the upstream portion.

  The independent passage 39 is formed to branch into a plurality from the surge tank 38 for each intake port 18. The first passage 33, the second passage 35, the third passage 37, and the independent passage 39 constitute a main intake passage 30 </ b> A that is the main body of the intake passage 30.

  In addition to the main intake passage 30 </ b> A, the intake passage 30 is provided with a bypass passage 40 that bypasses the supercharger 34 and the intercooler 36. Specifically, the bypass passage 40 is branched from a portion in the middle of the first passage 33 (upstream branching portion 33a) and connected to the surge tank 38 (downstream branching portion).

  A bypass valve 41 that changes the cross-sectional area of the bypass passage 40 is disposed in the bypass passage 40. The bypass valve 41 changes the flow path cross-sectional area of the bypass passage 40 according to the operating state of the engine 1. Thereby, the bypass valve 41 adjusts the flow rate of the intake air flowing through the bypass passage 40.

  The intake passage 30 is provided with an evaporated fuel passage 66 for introducing the evaporated fuel generated in the fuel tank 63 into the intake passage 30. The evaporated fuel passage 66 is connected to a purge valve 68 disposed in the first passage 33 from above the fuel tank 63 via a canister 67. The canister 67 is a container that temporarily stores evaporated fuel.

(Exhaust passage 50)
The exhaust passage 50 is connected to the rear side of the engine body 10 opposite to the intake passage 30. Although illustration is omitted, the upstream end portion of the exhaust passage 50 constitutes an independent passage branched for each cylinder 11. These independent passages are connected to the exhaust port 19 of each cylinder 11.

  In the exhaust passage 50, an exhaust purification system having one or more catalytic converters 51 is disposed. The catalytic converter 51 includes a three-way catalyst, and is disposed adjacent to the downstream side of the exhaust port 19 in the exhaust passage 50 (so-called direct catalyst). The exhaust purification system is not limited to the configuration including only the three-way catalyst.

  An EGR passage 52 constituting an external EGR system is connected between the intake passage 30 and the exhaust passage 50. The EGR passage 52 introduces part of the exhaust gas into the intake passage 30. Specifically, the upstream end of the EGR passage 52 is connected to a portion of the exhaust passage 50 downstream of the catalytic converter 51 and communicates with the exhaust passage 50.

  On the other hand, the downstream end of the EGR passage 52 is configured to communicate with a portion upstream of the supercharger 34 in the intake passage 30 and downstream of the throttle valve 32 (details will be described later).

  A water-cooled EGR cooler 53 is disposed in the EGR passage 52. The EGR cooler 53 cools the exhaust gas flowing through the EGR passage 52. The flow rate of the exhaust gas flowing through the EGR passage 52 is adjusted by the EGR valve 54. The amount of cooled exhaust gas (external EGR gas) introduced into the intake passage 30 is adjusted by adjusting the opening of the EGR valve 54.

(Blow-by gas reduction system 70)
Further, the engine 1 is provided with a blow-by gas reduction system 70 that introduces a gas (blow-by gas) leaking from the combustion chamber 16 into the intake passage 30 and returns it to the combustion chamber 16. Blow-by gas contains oil mist.

  Specifically, as shown in FIG. 1, a PCV valve 72 is provided on the upper portion of the cylinder head cover 26 of the engine body 10. The blow-by gas passage 71 constituting the blow-by gas reduction system 70 has an upstream end connected to the PCV valve 72. The PCV valve 72 varies the flow rate of blow-by gas flowing into the blow-by gas passage 71.

  The downstream end of the blow-by gas passage 71 is connected to the upstream portion of the bypass passage 40. The blow-by gas passage 71 has a first communication passage 73 connected to the suction side of the supercharger 34 and a second communication passage 74 connected to the discharge side of the supercharger 34. Details of the blow-by gas passage 71 will be described later.

(Supercharger 34)
As shown in FIG. 5, the supercharger 34 has a casing 34b (supercharger main body) in which a rotor chamber 343 and a gear chamber 344 are formed. Inside the rotor chamber 343 and the gear chamber 344, a pair of rotating shafts 81 and 82 composed of a driving side and a driven side are arranged so as to extend in parallel to the cylinder row direction. Each of the rotary shafts 81 and 82 is rotatably supported by a pair of bearing portions 83 and 84 each including a suction side and a discharge side.

  As shown in FIG. 6, on the left side of the rotor chamber 343, a small-capacity bearing chamber 345 that houses the ends of the rotary shafts 81 and 82 is provided so as to protrude from the casing 34b. The bearing chamber 345 accommodates a ball bearing that constitutes the suction side bearing portion 83. End portions of the rotary shafts 81 and 82 protruding into the bearing chamber 345 through the shaft hole 345a are pivotally supported via the ball bearings. The bearing chamber 345 is provided with a seal material (suction side seal material 91), and the suction side seal material 91 closes the gap between the shaft hole 345a and the rotary shafts 81 and 82.

  The gear chamber 344 is disposed adjacent to the right side of the rotor chamber 343. The rotary shafts 81 and 82 protrude into the gear chamber 344 through the shaft hole 344a. The gear chamber 344 is also provided with a sealing material that closes the gap between the shaft hole 344a and the rotary shafts 81 and 82. Unlike the bearing chamber 345, the gear chamber 344 is provided with two sealing materials 92 and 93, which will be described later.

  The gear chamber 344 houses a gear 346 that rotates the drive-side rotation shaft 81 and the driven-side rotation shaft 82 in conjunction with each other. The discharge-side bearing portion 84 is housed in the gear chamber 344 together with the gear 346. The gear chamber 344 is filled with an appropriate amount of lubricating oil.

  In the rotor chamber 343, the first rotor 341 and the second rotor 342 are accommodated so as to partially mesh with each other. The first rotor 341 is integrally fixed to the driven-side rotating shaft 82, and the second rotor 342 is integrally fixed to the driving-side rotating shaft 81. The drive-side rotary shaft 81 extends longer than the driven-side rotary shaft 82, protrudes from the gear chamber 344, and is connected to the electromagnetic clutch 34a.

  A suction port 34c communicating with the rotor chamber 343 is opened at the left end of the casing 34b, as shown in the cross-sectional view (c) indicated by the line Vc-Vc on the right side of FIG. On the other hand, a discharge port 34e that opens in a V shape or a triangle shape that exposes the rotor chamber 343 is opened on the front side surface of the casing 34b.

  The suction port 34 c communicates with the first passage 33. The discharge port 34e communicates with the second passage 35. As the first rotor 341 and the second rotor 342 rotate, the intake air flowing through the first passage 33 is sucked into the rotor chamber 343 through the suction port 34c. The intake air drawn into the rotor chamber 343 is sent out toward the right side and compressed. The compressed intake air is discharged from the discharge port 34e.

(Layout of intake unit 3)
As shown in FIG. 2, the intake unit 3 is disposed along the front side of the engine body 10, specifically, along the front surfaces of the cylinder head 13 and the cylinder block 12. In particular, the supercharger 34 and the intercooler 36 are arranged in the vicinity of the upstream end of the intake port 18 so as to increase the supercharging response.

  The supercharger 34 is disposed on the front side of the engine main body 10 so as to sandwich a horizontally long surge tank 38 extending in the left-right direction. Between the rear part of the supercharger 34 and the front part of the engine body 10, there is a gap corresponding to the dimension of the surge tank 38. The first passage 33 extends in the cylinder row direction on the left side of the supercharger 34, and is connected to the left end portion of the supercharger 34 where the suction port 34c is open.

  Moreover, as shown in FIG. 3, the supercharger 34 and the intercooler 36 are arranged in the up-down direction in this order, and are adjacent up and down. The second passage 35 extends substantially in the vertical direction so as to connect the front part of the supercharger 34 having the discharge port 34e and the front part of the intercooler 36.

  As shown in FIGS. 2 and 4, the surge tank 38 is disposed in a gap between the rear portion of the supercharger 34 and the plurality of independent passages 39. The third passage 37 extends so as to pass below the supercharger 34. The intercooler 36 is located below the surge tank 38, and the rear portion of the intercooler 36 and the bottom of the surge tank 38 are connected by a third passage 37.

  The bypass passage 40 branches from the upstream branch portion 33a of the first passage 33 and extends upward, and then extends to the right. The downstream end of the bypass passage 40 is bifurcated and connected to the upper portion of the surge tank 38 (see FIGS. 2, 4, and 9A).

(Use of blow-by gas to the turbocharger 34)
The external EGR gas includes dust such as soot and oxides, water vapor, and the like. The water vapor and the like flow into the rotor chamber 343 of the supercharger 34 as the external EGR gas is introduced into the intake air. When the EGR cooler 53 cools the water vapor, it becomes condensed water in the EGR passage 52 and the bypass passage 40, and flows into the first passage 33 from the bypass passage 40 and may flow into the rotor chamber 343 of the supercharger 34. is there.

  When these dust and condensed water flow into the rotor chamber 343 of the supercharger 34, the dust and condensed water may act on the bearing portion and the sealing material and may be deteriorated. Therefore, in this engine 1, by using the blow-by gas reduction system 70, the intake air around the bearing portion and the seal material is sucked in accordance with the operating state of the engine 1, and the oil is supplied to the periphery of the bearing portion and the seal material. It has been devised to supply.

  Specifically, as shown in FIG. 1, a first communication path 73 and a second communication path 74 that branch from a portion of the blow-by gas path 71 on the downstream side of the PCV valve 72 are provided. Then, as shown in FIG. 6, these are spaces formed by gaps communicating with the respective bearing portions 83, 84 provided in the vicinity of the respective bearing portions 83, 84 on the suction side and the discharge side through the casing 34 b of the supercharger 34. It communicates with the parts (suction side annular space part 34f, discharge side annular space part 34h).

  FIG. 6 schematically shows a main part of the blow-by gas passage 71. FIG. 7 specifically shows the main part of the blow-by gas passage 71. As shown in these drawings, the downstream end of the blow-by gas passage 71 is composed of a downstream introduction passage 71a, an upstream introduction passage 71b, a first branch passage 73a, a second branch passage 74a, and the like.

  The downstream introduction path 71a is connected to a portion (a branch base 42 described later) of the bypass passage 40 in the vicinity of the upstream branch portion 33a, and from an introduction port (blow-by gas introduction port 75) that opens to the connection site, Blow-by gas is introduced into the intake passage 30.

  And the 1st branch path 73a and the 2nd branch path 74a have branched from the site | part upstream of the blow-by gas introduction port 75 in the downstream introduction path 71a. The first branch path 73a is located upstream of the second branch path 74a. The first branch path 73 a communicates with the first communication path 73, and the second branch path 74 a communicates with the second communication path 74.

  The upstream introduction path 71b continues in a state intersecting with the upstream side of the downstream introduction path 71a. Specifically, the upstream side introduction path 71b extends in the cylinder row direction, and the downstream side introduction path 71a branches so as to bend from the downstream side of the upstream side introduction path 71b, and is laterally substantially perpendicular to the cylinder row direction. Extending in the direction. The first branch path 73a extends in the cylinder row direction from the bent portion of the upstream side introduction path 71b and the downstream side introduction path 71a so as to be connected straight to the upstream side introduction path 71b.

  On the other hand, the second branch path 74a extends in the cylinder row direction in parallel with the first branch path 73a from the middle of the downstream side introduction path 71a. The upstream introduction path 71b is configured by a pipe having a larger diameter than the first branch path 73a and the second branch path 74a (the flow path area is large).

  Although details will be described later, the upstream introduction path 71 b, the downstream introduction path 71 a, and the first branch path 73 a are oils that separate oil from blow-by gas and supply the oil to the first communication path 73. A separation supply unit OP is configured. The upstream introduction path 71b constitutes a straight portion, and the downstream introduction path 71a constitutes a cross portion.

  As shown in FIGS. 2 and 4, the first communication passage 73 and the second communication passage 74 are disposed between the supercharger 34 and the bypass passage 40 disposed above the supercharger 34. The oil separation supply unit OP is disposed in a slight gap between the first passage 33 and the bypass passage 40 and is compactly configured by the blow-by gas passage 71. Thereby, the layout of the blow-by gas passage 71 and the communication passages 73 and 74 is configured to be organic and compact. Further, since the communication passages 73 and 74 are arranged in the cylinder row direction, the intake air flows smoothly and the layout can be made compact.

  As shown in FIGS. 5 and 6, suction-side annular spaces 34f each having an annular gap are provided around shaft holes 345a facing the respective bearing chambers 345 of the casing 34b. As shown in an enlarged view in FIG. 6, the suction side annular space 34f is provided with an annular step 34f1 having a diameter larger than that of the shaft hole 34a. The suction side sealing material 91 is adjacent to and faces the suction side annular space portion 34f through the annular step portion 34f1. The annular step portion 34f1 increases the volume of the suction side annular space portion 34f. The annular step portion 34f1 can be formed by cutting an inner portion of each sealing material 91 in the casing 34b using an end mill or the like.

  As shown in the sectional view (c) of FIG. 5, the two suction-side annular spaces 34f, 34f are connected to each other by a single first connection path 34g formed of a vertical hole. Accordingly, the two suction-side annular spaces 34f and 34f can be easily communicated by drilling.

  On the other hand, a discharge-side annular space 34h made of an annular gap is also provided around each shaft hole 344a facing the gear chamber 344 of the casing 34b. Two seal materials (an outer seal material 92 and an inner seal material 93) are arranged around each shaft hole 344a facing the gear chamber 344 with a gap therebetween. The outer seal material 92 is located on the gear chamber 344 side, and the inner seal material 93 is located on the rotor chamber 343 side.

  A discharge-side annular space 34 h is provided between the outer sealing material 92 and the inner sealing material 93. Each of the outer sealing material 92 and the inner sealing material 93 is adjacent to and faces the discharge-side annular space 34h. As in the cross-sectional view (a) shown on the left side in FIG. 5, the two discharge-side annular spaces 34h and 34h are also connected to each other by a second connection path 34i formed of a vertical hole, like the suction-side annular space 34f. Has been.

  The first communication path 73 is connected to each suction-side annular space 34f through the first connection path 34g. The second communication path 74 is connected to each discharge-side annular space 34h via the second connection path 34i.

  As described above, the first communication passage 73 and the second communication passage 74 that branch from the blow-by gas passage 71 through the oil separation supply section OP are respectively connected to the suction-side bearing portion 83 and the discharge-side bearing portion in the supercharger 34. The suction side annular space portion 34f and the discharge side annular space portion 34h provided in the vicinity of each of the 84 communicate with each other. Therefore, depending on the operating state of the engine 1, the intake air around the bearing portions 83, 84 and the seal materials 91, 92, 93 is sucked or the oil around the bearing portions 83, 84 and the seal materials 91, 92, 93 is oiled. Can be supplied. An example of this will be described in the case of supercharging and non-supercharging (natural intake).

(When supercharging)
8A and 9A show the flow of intake air during supercharging in the intake passage 30. FIG. For example, when acceleration is requested because the accelerator is stepped on, the ECU 7 operates the supercharger 34 (that is, the electromagnetic clutch 34a is connected) while the automobile is running, and the opening degree of the bypass valve 41 is appropriately set. adjust.

  At this time, the throttle valve 32 is normally adjusted to be fully open, and fresh air is introduced into the intake passage 30 without load. Further, the external EGR gas is introduced into the intake passage 30 by appropriately adjusting the opening degree of the EGR valve 54 according to the operating state of the engine 1. Further, blow-by gas is also introduced into the intake passage 30 by appropriately adjusting the opening degree of the PCV valve 72.

  Thus, fresh air, external EGR gas, and blow-by gas (also simply referred to as intake air) are introduced into the combustion chamber 16 in a supercharged state through the main intake passage 30A. At this time, a part of the intake air that has passed through the supercharger 34 flows back upstream of the supercharger 34 through the bypass passage 40 by adjusting the opening degree of the bypass valve 41. The boost pressure of the intake air introduced into the combustion chamber 16 is adjusted by the reverse flow rate of the intake air.

  Thus, when the supercharger 34 is operating, the inside of the rotor chamber 343 becomes a high pressure. Therefore, the internal pressures of the suction-side annular space portion 34f and the discharge-side annular space portion 34h that are located in the vicinity of the rotor chamber 343 and communicate with the rotor chamber 343 through the shaft holes 344a and 345a also increase in accordance with the supercharging pressure. . Usually, the internal pressure of each of the suction-side annular space portion 34f and the discharge-side annular space portion 34h is higher than the internal pressure of the blow-by gas passage 71.

  Accordingly, dust and condensed water adhering to the periphery of the bearing portions 83 and 84 and the sealing materials 91, 92, and 93 together with the intake air, the suction-side annular space portion 34f and the first communication passage 73, the discharge-side annular space portion 34h, The blow-by gas passage 71 can be sucked out through the second communication passage 74. As a result, deterioration of the bearing portions 83 and 84 and the sealing materials 91, 92, and 93 can be suppressed.

(Non-supercharging)
FIG. 8B and FIG. 9B show the flow of intake air during non-supercharging (natural intake) in the intake passage 30. For example, in the case of idling or coasting, the ECU 7 stops the operation of the supercharger 34 (that is, disconnects the electromagnetic clutch 34a), and fully opens the bypass valve 41.

  At this time, the opening degree of the throttle valve 32 is appropriately adjusted according to the operating state of the engine 1, and an appropriate amount of fresh air is introduced into the intake passage 30. Further, the external EGR gas is introduced into the intake passage 30 by appropriately adjusting the opening degree of the EGR valve 54 according to the operating state of the engine 1. Further, blow-by gas is also introduced into the intake passage 30 by appropriately adjusting the opening degree of the PCV valve 72.

  As a result, the intake air flowing through the intake passage 30 bypasses the supercharger 34 and is introduced into the combustion chamber 16 in a state of natural intake. In this way, when the supercharger 34 is not operating, the interior of the rotor chamber 343 is in a non-pressurized state. For this reason, the internal pressures of the suction-side annular space portion 34f and the discharge-side annular space portion 34h do not increase.

  Therefore, the difference between the internal pressure of the blow-by gas passage 71 and the internal pressure of each of the suction-side annular space portion 34f and the discharge-side annular space portion 34h is relatively small, and depends on the operating state of the engine 1 than the internal pressure of the blow-by gas passage 71. Also, the internal pressure of each of the suction side annular space portion 34f and the discharge side annular space portion 34h is higher, or the internal pressure of each of the suction side annular space portion 34f and the discharge side annular space portion 34h is higher in the blow-by gas passage 71. It becomes higher than the internal pressure.

  For example, according to various studies by the inventors of the present application, during low load operation or medium load operation, the internal pressure (negative pressure) of the discharge-side annular space 34h is equal to the pressure (negative pressure) of the blow-by gas passage 71. There is almost no difference. On the other hand, the internal pressure of the suction side annular space 34 f is lower than that of the blow-by gas passage 71.

  Thus, depending on the operating state of the engine 1, blow-by gas may be introduced into the suction-side annular space 34f and the discharge-side annular space 34h. In this case, as schematically shown in FIG. 6, the blow-by gas is introduced into the suction-side annular space portion 34f and the discharge-side annular space portion 34h via the first branch passage 73a and the second branch passage 74a. .

  At this time, the first branch path 73a is linearly connected to the upstream side introduction path 71b (straight portion) extending linearly. Therefore, the oil mist contained in the blow-by gas easily flows into the first communication path 73 due to inertia. Blow-by gas that is lighter than oil mist tends to flow into the downstream introduction path 71a (cross section). As a result, the blow-by gas containing a relatively large amount of oil is distributed to the first communication path 73 and flows into the suction-side annular space 34f.

  Unlike the gear chamber 344, the suction-side annular space 34f is located in the vicinity of the bearing chamber 345 where oil is insufficient and lubrication is likely to occur. Therefore, by supplying blow-by gas containing a large amount of oil to these, the sealing performance of the suction-side sealing material 91 and the lubricity of the suction-side bearing portion 83 can be improved.

(Convention of blow-by gas passage 71 with respect to intake passage 30)
Blow-by gas contains oil mist. For this reason, when blow-by gas is introduced into the intake passage 30, the oil mist adheres to the inside of the intake passage 30, and oil contamination occurs. In particular, in a portion where a valve or the like is disposed, the flow of intake air is disturbed, so that oil tends to concentrate and adhere. In such a part, oil accumulates and changes in quality over time. As a result, if the oil becomes highly viscous, the operation of the valve may be hindered.

  Therefore, in this engine 1, the structure and arrangement of the intake passage 30 and the blow-by gas passage 71 are devised so that such troubles due to oil contamination can be suppressed.

  As shown in FIGS. 9A and 9B, the upstream side portion of the bypass passage 40 is connected to the branch base portion 42 that branches from the upstream branch portion 33 a in the direction intersecting the intake passage 30, and to the downstream side of the branch base portion 42. A bent portion 43 that is bent in this manner and an extending portion 44 that extends along the supercharger 34 are provided on the downstream side of the bent portion 43.

  Specifically, the branch base 42 branches slightly upward from the upper portion of the intake passage 30 (first passage 33) extending in the left and right cylinder row direction. A portion where the branch base portion 42 in the intake passage 30 branches is an upstream branch portion 33a. The bent portion 43 extends obliquely upward from the branch base portion 42 toward the left side away from the surge tank 38, then bends in a U or V shape, and faces obliquely upward to the right.

  The extending portion 44 is connected to the downstream side of the bent portion 43 and extends rightward so as to avoid the supercharger 34. The downstream side of the extending portion 44 is bifurcated and connected to the upper portion of the surge tank 38 (see FIGS. 2 and 4).

  A bypass valve 41 is disposed in the upstream portion of the extending portion 44. Further, an EGR passage 52 is connected from the side (rear side) to a portion between the bent portion 43 and the bypass valve 41 in the bypass passage 40 on the upstream side. In FIG. 9A and FIG. 9B, the EGR passage 52 is connected to the bypass passage 40 from the front side of the paper (in order to show the EGR passage 52, the connection direction of the EGR passage 52 is changed for convenience).

  An EGR valve 54 is installed at a connection portion between the bypass passage 40 and the EGR passage 52. The EGR valve 54 is a diaphragm valve, and the valve is controlled in a direction substantially orthogonal to the flow of intake air flowing through the bypass passage 40. The EGR valve 54 is adjacent to the bypass valve 41.

  A concave portion 42a (blow-by gas introducing portion) that protrudes upward is provided on the upper portion of the branch base portion 42. The blow-by gas inlet 75 is opened in the recess 42a, and the branch base 42 communicates with the blow-by gas passage 71 through the recess 42a.

  A purge valve 68 is disposed at a portion downstream of the branch base 42 (portion upstream of the supercharger 34) in the upstream branch portion 33a of the intake passage 30 and above the branch base 42. Has been. An evaporative fuel passage introduction port (evaporated fuel introduction port 68a) is opened at the site, and evaporative fuel is introduced into the intake passage 30 from the evaporative fuel introduction port 68a.

  At the time of supercharging, for example, as shown in FIG. 9A, intake air made up of fresh air, external EGR gas, recirculation gas (gas returned through the bypass passage 40), blow-by gas, etc., enters the combustion chamber 16 through the main intake passage 30. It is introduced in a mixed state. At this time, since the blow-by gas is introduced from the branch base 42, the blow-by gas can be smoothly introduced into the main intake passage 30A and dispersed along the flow of the external EGR gas and the reflux gas.

  Since the flow of the external EGR gas and the reflux gas is hindered, the oil contained in the blow-by gas does not affect the EGR valve 54 and the bypass valve 41.

  Since the evaporated fuel introduction port 68a is a relatively small hole, if the oil adheres and accumulates, the evaporated fuel may not be appropriately introduced into the intake passage 30. On the other hand, in the engine 1, the evaporated fuel introduction port 68 a is arranged on the downstream side of the branch base portion 42 and on the branch side thereof. Accordingly, the oil contained in the blow-by gas is prevented from traveling toward the evaporated fuel introduction port 68a by the wall surface (first oil regulating unit 45) of the branch base portion 42, so that oil contamination of the evaporated fuel introduction port 68a can be suppressed.

  At the time of non-supercharging, for example, as shown in FIG. 9B, intake air such as fresh air, external EGR gas, blow-by gas, etc. is introduced into the combustion chamber 16 through the bypass passage 40 in a mixed state. At this time, since the blow-by gas is introduced from the branch base portion 42, the blow-by gas can be smoothly introduced into the bypass passage 40 on the flow of fresh air and can be dispersed.

  Further, since the flow of fresh air is hindered, the oil contained in the blow-by gas does not affect the evaporated fuel introduction port 68a.

  On the other hand, since the blow-by gas passes through the EGR valve 54 and the bypass valve 41, the oil contained in the blow-by gas may adhere to the EGR valve 54 and the bypass valve 41 and accumulate.

  However, in this engine 1, the blow-by gas is introduced from the branch base portion 42, and therefore passes through the bent portion 43 before reaching the EGR valve 54. Since the flow of the blow-by gas is deflected by the bent portion 43, the oil contained in the blow-by gas easily adheres to the wall surface (second oil regulating portion 46) of the bent portion 43 due to inertia. Therefore, oil contamination of the EGR valve 54 and the bypass valve 41 can be suppressed.

  Further, the external EGR gas introduced from the EGR passage 40 into the bypass passage 40 joins from a direction substantially orthogonal to the flow of intake air flowing through the bypass passage 40. As a result, the flow of intake air is disturbed, so that the oil is more likely to adhere to the second oil restricting portion 46. Therefore, oil contamination of the EGR valve 54 and the bypass valve 41 can be further suppressed.

  Oil adhering to the wall surface of the bent portion 43 may drop on the intake passage 30 along the wall surface and may adversely affect the throttle valve 32. However, since the throttle valve 32 is disposed upstream of the upstream branching portion 33a, there is no possibility that the throttle valve 32 is contaminated with oil.

  The supercharged engine according to the disclosed technology is not limited to the above-described embodiment, and includes various other configurations. For example, in the embodiment, the oil separation supply unit OP configured by the blow-by gas passage 71 is shown, but the oil separation supply unit OP is not limited thereto. For example, a centrifuge may be installed in the middle of the blow-by gas passage 71 to actively separate oil and intake air.

DESCRIPTION OF SYMBOLS 1 Engine 3 Intake unit 10 Engine main body 30 Intake passage 30A Main intake passage 31 Air cleaner 32 Throttle valve 33 1st passage 33a Upstream branch part 34 Supercharger 34f Inlet side annular space part 34h Discharge side annular space part 343 Rotor room 344 Gear Chamber 35 Second passage 36 Intercooler 37 Third passage 38 Surge tank 39 Independent passage 40 Bypass passage 41 Bypass valve 42 Branch base 43 Bending portion 44 Extension portion 50 Exhaust passage 51 Catalytic converter 52 EGR passage 53 EGR cooler 54 EGR valve 61 Fuel supply system 70 Blow-by gas reduction system 71 Blow-by gas passage 71a Downstream introduction passage (cross section)
71b Upstream introduction path (straight part)
72 PCV valve 73 1st communication path (communication path)
73a First branch path 74 Second communication path 74a Second branch path 75 Blow-by gas introduction port 81 Rotating shaft (drive side)
82 Rotating shaft (driven side)
83 Bearing (suction side)
84 Bearing (discharge side)
91 Suction side sealing material 92 Outer sealing material 93 Inner sealing material

Claims (4)

An engine having a supercharger in the middle of an intake passage for introducing intake air into a combustion chamber,
A blow-by gas passage that introduces blow-by gas that is generated in the engine and contains oil mist to a portion upstream of the supercharger in the intake passage,
The supercharger has a space portion formed by a gap in the vicinity of a bearing portion of a rotor that sends out intake air,
An engine with a supercharger, wherein an oil separation supply unit that separates oil from blowby gas and supplies the oil to the space is provided in the blowby gas passage. An engine having a supercharger in the middle of an intake passage for introducing intake air into a combustion chamber,
A throttle valve that is disposed at a position upstream of the supercharger in the intake passage, and is controlled according to the operating state of the engine;
A blow-by gas passage that introduces blow-by gas generated in the engine and containing oil mist into a portion of the intake passage between the throttle valve and the supercharger;
A PCV valve disposed upstream of the blow-by gas passage and capable of varying the flow rate of the blow-by gas;
With
The supercharger is
A supercharger main body formed with an intake port for inhaling intake air and an exhaust port for discharging intake air;
A rotor that is pivotally supported via a bearing portion inside the supercharger main body and rotates to feed intake air from the suction port to the discharge port.
A space formed by a gap formed in the vicinity of the bearing portion;
Have
A branch passage that branches from the downstream side of the PCV valve in the blow-by gas passage and communicates with the space is provided;
An engine with a supercharger, provided with an oil separation supply unit that separates oil from blow-by gas and supplies the oil to the communication path upstream of the communication path. The supercharged engine according to claim 2,
The oil separation supply unit
It is constituted by the blowby gas passage,
A straight part that separates oil from blow-by gas by inertia and introduces oil into the communication path;
A cross part that branches from the downstream side of the straight part and bends toward the intake passage;
An engine with a supercharger. The engine with a supercharger according to any one of claims 1 to 3,
The supercharger further includes a sealing material that seals the bearing portion in the vicinity of the bearing portion,
An engine with a supercharger, wherein the space is adjacent to the sealing material.

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