JP2007024188A - Balancer device for engine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the operating efficiency of an oil pump and to reduce thrust working on a balancer shaft in utilizing the rotation of the balancer shaft of an engine as the driving force of the oil pump. <P>SOLUTION: The oil pump is driven at a reduced speed by one of a pair of balancer shaft 41, 42 through gear transmission means 53, 54. Gear transmission means 48, 49 for synchronously rotating both balancer shafts 41, 42, and the gear transmission means 53, 54 for driving the oil pump, are respectively composed of helical gears. The synchronizing helical gear 49 connected to the one balancer shaft 42, and the helical gear 53 for driving the oil pump, are provided to generate thrust in reverse directions to each other. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

    The present invention relates to an engine balancer device, and more particularly to a balancer device with an oil pump.

In an engine balancer device, a pair of balancer shafts rotating in opposite directions are supported by a balancer housing so as to rotate in a parallel relationship with a crankshaft. With regard to this type of balancer device, Patent Document 1 discloses that a balancer unit is fastened to the lower part of an engine body and arranged in an oil pan, and the first balancer shaft of both balancer shafts is rotationally driven by a crankshaft. It is described that the second balancer shaft is driven by the first balancer shaft through the gear transmission means for synchronization and the oil pump is driven by the second balancer shaft. This oil pump is directly connected to the second balancer shaft, and rotates at the same rotational speed as the balancer shaft.
US Pat. No. 5,535,643

    By the way, for example, in an in-line four-cylinder engine, the balancer shaft is rotated at a speed twice as high as the engine speed. However, it is not always preferable in terms of pump efficiency to connect the oil pump directly to the balancer shaft and perform such high-speed rotation. is not. In other words, the oil pump is set so that the required oil flow rate and oil pressure can be secured in the low / medium speed rotation range of the engine, and the relief mechanism is operated to keep the oil pressure constant in the high rotation range. . Therefore, when the oil pump is operated at the same rotational speed as that of the balancer shaft, the relief mechanism works in most engine rotation ranges, and the work efficiency is deteriorated.

    On the other hand, as a gear for synchronously rotating a pair of balancer shafts, a helical gear is employed instead of a spur gear from the viewpoint of suppressing meshing noise or increasing meshing transmission efficiency. However, in the case of a helical gear, since the thrust force in the opposite direction acts on both balancer shafts due to the engagement between the drive side and the driven side, the thrust force becomes the rotational resistance of the balancer shaft, and reduction thereof is desired.

    Therefore, the present invention has an object to efficiently drive the oil pump and reduce the rotational resistance of the balancer shaft when the rotational force of the balancer shaft is used for driving the oil pump.

    In order to solve such problems, the present invention employs a helical gear as a synchronizing gear and a pump driving gear provided on the oil pump driving balancer shaft while the oil pump is decelerated and rotated by the balancer shaft. Thrust forces are now countered to each other.

The invention according to claim 1 is a pair of balancer shafts provided in parallel with the crankshaft and each having a mass portion for allowing the center of gravity to deviate from the axis, and gear transmission means for synchronously rotating the balancer shafts. A balancer unit for an engine, wherein the balancer unit is provided in an engine body, and the pair of balancer shafts are rotationally driven by a crankshaft,
An oil pump that is decelerated and driven by gear transmission means by one of the pair of balancer shafts;
The synchronizing gear transmission means is constituted by helical gears coupled to and meshing with each of the balancer shafts,
The gear transmission means for driving the oil pump is composed of helical gears that are coupled to the one balancer shaft and the oil pump drive shaft and mesh with each other,
The synchronizing helical gear coupled to the one balancer shaft and the oil pump driving helical gear coupled to the balancer shaft are provided so as to generate thrust forces in opposite directions to each other. .

    Therefore, since the oil pump is driven at a reduced speed by the balancer shaft, it is possible to avoid an excessive increase in the number of revolutions of the oil pump, thereby suppressing relief of the discharged oil, and operating efficiency of the oil pump. Increases, which in turn increases engine efficiency.

    Further, the synchronous helical gear coupled to one of the balancer shafts and the oil pump driving helical gear coupled to the balancer shaft are provided so as to generate thrust forces in opposite directions. Thus, the thrust force acting on the balancer shaft is reduced, and the rotational resistance of the balancer shaft is reduced. Therefore, it becomes advantageous for the stabilization of the rotation of the balancer shaft, lubrication, and consequently the efficiency of the engine.

The invention according to claim 2 is the invention according to claim 1,
Chain transmission means is provided on one end side of the other of the balancer shafts to transmit the rotational driving force of the crankshaft,
The oil pump is disposed on the other end side of the balancer shafts,
The helical gear for driving the oil pump is provided on the other end of the one of the balancer shafts.

    Accordingly, the oil pump can be arranged without causing interference with the chain transmission means, which is advantageous in laying out the balancer shaft, the oil pump, the gear transmission means, and the chain transmission means so as to be compact as a whole.

    Also, one balancer shaft provided with the chain transmission means of the two balancer shafts does not provide a thrust force canceling effect, but the balancer shaft receives a part of the thrust force by the transmission chain. Even when a thrust receiving portion is provided, there is no great rotational resistance.

    That is, according to the present invention, of the balancer shafts, the other balancer shaft that cannot receive the thrust force by the chain transmission means is configured to cancel the thrust force described above. Therefore, the rotational resistance due to the thrust force is reduced on both balancer shafts.

The invention according to claim 3 is the invention according to claim 1 or claim 2,
Each of the balancer shafts is supported by bearings on both sides in the axial direction across the mass portion,
The synchronizing gear transmission means is disposed on the opposite side of the mass portion across one of the bearings on both sides,
The gear transmission means for driving the oil pump is disposed on the opposite side of the mass portion with the other bearing among the bearings on both sides.

    Accordingly, the bearings on both sides of the mass part support the mass part and the gear transmission means in a balanced manner, and the mass part and the two gear transmission means are stably supported.

According to a fourth aspect of the present invention, in any one of the first to third aspects,
The balancer housing that accommodates both the balancer shafts and the housing of the oil pump are separately formed, and the both housings are fastened to each other by bolts.

    Therefore, after the balancer shaft is assembled into the balancer housing to form the balancer unit side, the oil pump can be assembled to the balancer unit side, which facilitates production.

The invention according to claim 5 is the invention according to claim 4,
An oil suction port for attaching an oil strainer is provided at the lower part of the balancer housing, and an oil suction path from the oil suction port to the oil pump is formed so as to extend across the balancer housing and the pump housing. It is characterized by.

    In other words, when the structure in which the pump housing is fastened to the balancer housing as described above is employed, it may be difficult to dispose the oil strainer substantially at the center in the engine longitudinal direction. Therefore, an oil suction port is provided in the balancer housing, and a suction system of the oil pump is configured by effectively using the balancer housing. Therefore, it becomes easy to arrange the oil strainer at the approximate center in the engine longitudinal direction.

    As described above, according to the present invention, one of a pair of balancer shafts drives the oil pump at a reduced speed via the gear transmission means, and the gear transmission means and the oil pump rotate both balancer shafts synchronously. Since the driving gear transmission means are each constituted by a helical gear, the synchronous helical gear coupled to the one balancer shaft and the helical gear for driving the oil pump are provided so as to generate thrust forces in opposite directions. The operating efficiency of the oil pump, and hence the efficiency of the engine is increased, and the thrust force acting on the one balancer shaft is reduced, which is advantageous for stabilizing the rotation of the balancer shaft, lubrication, and consequently the efficiency of the engine.

    Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<Schematic configuration of the entire engine>
In the engine balancer apparatus shown in FIG. 1, reference numeral 1 denotes an in-line four-cylinder direct-injection diesel engine body, and 2 denotes a balancer unit. In the engine body 1, 3 is a cylinder block, 4 is a cylinder head coupled to the upper surface of the cylinder block 3, 5 is a lower block coupled to the lower surface of the cylinder block 3, 6 is a cylinder head cover, and 7 is a lower surface of the lower block 5. Is an oil pan combined with An oil pump 8 is coupled to the rear part of the balancer unit 2. The balancer unit 2 and the oil pump 8 are coupled to the lower surface of the lower block 5 and accommodated in the oil pan 7.

    A timing case 11 is coupled to the cylinder block 3 on the front side of the engine body 1 (the side where the timing chains are arranged), and a timing case cover 12 is provided so as to cover the timing case 11. The cylinder block 3 is provided with a water pump 13, a thermostat valve 14, and the like, and a high-pressure fuel pump 15 for fuel injection supported by the timing case 11. An intake manifold 16, a fuel injection common rail 17, a vacuum pump 18, and the like are disposed on the cylinder head 4. A water-cooled oil cooler 19 and an oil filter 20 are disposed on the side surface of the lower block 5. The fuel pump 15 and the common rail 17 are connected by a fuel supply pipe 21 and a return pipe 22, and the water pump 13 and the oil cooler 19 are connected by a cooling water supply pipe 23 and a return pipe 24.

    As shown in FIG. 2, the timing case cover 12 is coupled to a flange provided on the front surface of each of the cylinder head 4, the timing case 11, the lower block 5, and the oil pan 7. Between them, a timing chain and other chain transmission means are provided.

    2, 26 and 27 are large and small crank pulleys coupled to the crankshaft 25, 28 is a cam pulley coupled to each camshaft for driving the intake and exhaust valves, 29 is a pump pulley for the fuel pump 15, and 30 is The balancer pulleys 31 and 32 for the balancer unit 2 are large and small idle pulleys provided coaxially. These pulleys 26 to 32 are all sprockets.

    Then, the transmission chain 33 for driving the fuel pump is wound around the small-diameter crank pulley 27, the pump pulley 29, and the large-diameter idle pulley 31, and the timing chain 34 is wound around the cam pulleys 28, 28 and the small-diameter idle pulley 32. A transmission chain 35 for driving the balancer unit is wound around the large-diameter crank pulley 26 and the balancer pulley 30.

<Balancer unit, oil pump>
As shown in FIGS. 3 and 4, the balancer unit 2 is configured by housing a pair of balancer shafts 41, 42 extending in the longitudinal direction of the engine (parallel to the axis of the crankshaft 25) in a balancer housing. The balancer housing is formed by vertically aligning the upper housing 43 and the lower housing 44, and the pump housing 45 of the oil pump 8 is coupled to the rear surfaces of the balancer housings 43, 44 by bolts 40.

    As shown also in FIG. 5, the balancer shafts 41 and 42 have mass portions 41a and 42a that make their respective centers of gravity deviate from the axial center, and the front end side and the rear end side sandwiching the mass portions 41a and 42a. Are rotatably supported by front and rear bearings 46, 47 formed in the balancer housings 43, 44. The axial centers of the balancer shafts 41 and 42 are arranged in parallel so as to be symmetrical in the same horizontal plane with respect to a vertical plane passing through the axial center of the crankshaft 25. In addition, a half-shaped shaft metal is fitted to the portions of the balancer shafts 41 and 42 that are supported by the bearings 46 and 47.

    Gears 48 and 49 having the same diameter and meshing with each other are coupled to the front end portions of the balancer shafts 41 and 42 as gear transmission means for synchronization. Due to this meshing, both balancer shafts 41 and 42 are rotated in the opposite direction synchronously so that the mass portions 41a and 42a are always located at the same height. Helical gears are used as the gears 48 and 49. Each of the balancer shafts 41 and 42 rotates so that the upper half circumference side is directed from the inside to the outside.

    The balancer housings 43 and 44 are formed with a mass portion accommodating chamber 51 for accommodating the mass portions 41 a and 42 a of the balancer shafts 41 and 42 between the front and rear bearings 46 and 47, and further, in front of the front bearing 46. A gear housing chamber 52 for housing the gears 48 and 49 is formed. That is, the bearing portion 50 in which the front bearing 46 is formed is located between the mass portion accommodating chamber 51 and the gear accommodating chamber 52, and partitions both the accommodating chambers 51, 52. Gears 48 and 49 are arranged on the opposite side of the portions 41a and 42a.

    The balancer pulley 30 is coupled to a shaft end of the balancer shaft 41 (hereinafter referred to as the first balancer shaft 41) that protrudes further forward from the helical gear 48 housed in the gear housing chamber 52. The gear ratio between the large-diameter crank pulley 26 coupled to the crankshaft 25 and the balancer pulley 30 is 2.

    Accordingly, the balancer shafts 41 and 42 receive the rotational driving force of the crankshaft 25 by the balancer pulley 30 at the front end of the first balancer shaft 41, and are synchronized with each other by the meshing of the helical gears 48 and 49, so that the engine speed is twice. It will rotate at the number of rotations.

    Further, a gear transmission means for driving the pump is arranged on the opposite side of the mass portions 41a and 42a with the rear bearing 47 interposed therebetween. As shown in FIG. 4, the gear transmission means includes a transmission gear 53 coupled to the shaft end of the balancer shaft 42 (hereinafter referred to as the second balancer shaft 42), and a transmission gear 54 coupled to the drive shaft of the oil pump 8. Are intertwined with each other. Helical gears are employed as the pump drive transmission gears 53 and 54. The transmission gear 54 on the oil pump 8 side is a large-diameter gear having more teeth than the transmission gear 53 on the second balancer shaft 42 side.

    Accordingly, the oil pump 8 is driven at a reduced speed by receiving the rotational driving force of the crankshaft 25 from the first balancer shaft 41 via the second balancer shaft 42 and the transmission gears 53 and 54.

    As shown in FIGS. 5 and 6, the first balancer shaft 41 has a mass portion accommodating chamber 51 side surface and a gear accommodating chamber 52 side surface of a bearing portion 50 in which a front bearing (radial bearing) 46 is formed. The opposing thrust thrust receiving surfaces 41b and 41c are formed with the above-mentioned surfaces as thrust movement restricting surfaces (thrust bearings). Although not shown in the drawing, the second balancer shaft 42 is also formed with opposed annular thrust receiving surfaces 42b and 42c having opposite end surfaces of the bearing portion 50 as thrust movement restricting surfaces as shown in FIG. Yes. Accordingly, the balancer shafts 41 and 42 are restricted by the thrust receiving surfaces 41b, 41c, 42b and 42c whose axial movements are opposed to each other.

    Thus, the synchronous helical gear 49 of the second balancer shaft 42 and the helical gear 53 for driving the pump have their tooth lines twisted in the same direction so that thrust forces in opposite directions are generated.

    That is, as shown in FIG. 3 by the arrow indicating the direction in which the thrust force acts, in the synchronous gear transmission means, the drive-side helical gear 48 coupled to the first balancer shaft 41 and the driven coupled to the second balancer shaft 42. Due to the meshing with the side helical gear 49, thrust forces in opposite directions are generated. The second balancer shaft 42 has a thrust force toward the rear.

    On the other hand, in the pump drive gear transmission means, thrust forces in opposite directions are generated by the meshing of the helical gear 53 of the second balancer shaft 42 and the helical gear 54 of the oil pump 8. However, since the helical gear 53 of the second balancer shaft 42 is now a driving side gear, the tooth streaks are twisted in the same direction as that of the driven helical gear 49 for synchronization as described above, so that the second balancer shaft 42 On the other hand, the thrust force toward the front works.

    Therefore, in the second balancer shaft 42, the thrust force in the reverse direction is given by the meshing of the synchronizing helical gears 48 and 49 and the meshing of the pump driving helical gears 53 and 54. Will be reduced. Therefore, the friction between the thrust receiving surfaces 42b, 42c of the second balancer shaft 42 and the bearing portion 50 is reduced, that is, the rotational resistance is reduced, which is advantageous for lubrication of the shaft and stabilization of the rotation.

    On the other hand, since the first balancer shaft 41 has one helical gear coupled thereto, the effect of reducing the thrust force due to the canceling as described above cannot be obtained. However, the thrust force acting on the first balancer shaft 41 is less than the axial force. It is also received by the transmission chain 35 via a balancer pulley 30 connected to the end. Therefore, the friction between the thrust receiving surfaces 41b and 41c of the first balancer shaft 41 and the bearing portion 50 is reduced, that is, the rotational resistance is reduced, which is advantageous for lubrication of the shaft and stabilization of the rotation.

    In the case where the oil pump 8 is driven by the first balancer shaft 41 via the helical gear transmission means, the first balancer shaft 41 is provided with two helical gears for synchronization and for driving the oil pump. In this case, it is possible to make the first balancer shaft 41 have a thrust force acting in opposite directions by configuring the helical gears so that the tooth lines are twisted in the opposite directions.

    A total of 6 parts between the front bearings 46, 46 of the balancer housings 43, 44 and one outside each of the bearings 46, 46, and one through each of the rear bearings 47, 47 and both outsides of the bearings 47, 47. Bolt holes 56 are provided at the locations. The balancer housings 43 and 44 are coupled to each other by applying a fastening bolt 55 to the bolt hole 56. In order to position the balancer housings 43 and 44 at the time of this coupling, cylindrical positioning pins 57 are fitted into the bolt holes 56 at the two right and left sides of the six bolt holes 56 of the lower housing 44. Yes. Each positioning pin 57 is fitted into the two bolt holes 56 at the front right and left sides on the upper housing 43 side as positioning holes.

    As shown in FIGS. 3 and 5, oil discharge ports 58 and 59 for discharging oil from the storage chambers 51 and 52 are provided at the upper portions of the mass storage chamber 51 and the gear storage chamber 52 of the upper housing 43. Is formed. Two oil discharge ports 58 of the mass portion storage chamber 51 are provided corresponding to the mass portions 41a and 42a of the balancer shafts 41 and 42, and the oil discharge port 59 of the gear storage chamber 52 is also connected to the synchronization gears 48 and 49. Correspondingly, two places are provided. On the periphery of these oil discharge ports 58 and 59, flanges 58a and 59a rising from the housing body are formed over the entire periphery. The flanges 58a and 59a serve to increase the rigidity of the upper housing 43, and hence the balancer housings 43 and 44 as a whole, which is advantageous in achieving stable rotation of the balancer shafts 41 and 42. The oil discharge will be described later.

<Lower block>
As shown in FIG. 7, the lower block 5 is connected to a frame 60 having a plurality of bolt holes extending in the left-right front-rear direction and fastened to the cylinder block 3, and spaced from each other in the front-rear direction. A plurality of (five) cross beams 61 extending in the left-right direction (the horizontal direction perpendicular to the crankshaft 25), and a connecting wall 62 that connects the adjacent cross beams 61 to each other on the lower surface side as shown in FIG. It has. The remaining four cross beams 61 other than the central cross beam 61 are provided with journal bearing mounting portions 63 that support the journal of the crankshaft 25. As shown in FIG. 7, oil recovery ports 64 for recovering oil dropped from above (on the cylinder block 3 side) to the oil pan 7 are formed on the left and right sides of each connecting wall 62. Further, on the left part of the lower block 5, a connecting frame 66 is provided that divides the left oil recovery port 64 in the left and right directions and connects adjacent cross beams 61 extending in the front-rear direction.

    The lower block 5 is formed with bolt holes 67 for fastening the balancer unit 2 and the oil pump 8 at the cross beam 61 or a total of six locations in the vicinity of the cross beam 61, and an oil passage is formed. Has been. This point will be described later.

<Conclusion of balancer unit to lower block>
As shown in FIG. 3, bolt boss portions 68 having bolt holes extending in the vertical direction are formed at a total of four locations on both front and rear sides of the balancer housings 43 and 44 of the balancer unit 2. On the other hand, on the lower surface of the lower block 5, as shown in FIG. 9 (a perspective view showing the engine body 1 and the balancer unit 2 upside down), a bolt hole 67 corresponding to the bolt hole of the bolt boss portion 68 is opened. ing. The balancer unit 2 is fastened to the lower surface of the lower block 5 by applying a bolt 70 passed through the bolt hole of the bolt boss portion 68 to the bolt hole 67 of the lower block 5.

    In this example, the balancer unit 2 is fastened to the lower block 5 together with the oil pump 8 with the oil pump 8 coupled to the rear surface thereof. Therefore, a bolt boss portion 72 to which the two fastening bolts 70 are applied is also provided in the pump housing 45 of the oil pump 8.

    Thus, with respect to the fastening of the balancer unit 2 to the lower block 5, the balancer unit 2 is provided with first and second positioning pins 73 and 74 for positioning the balancer unit 2 on the lower block 5. . As shown in FIG. 3, the first positioning pin 73 is disposed in the vicinity of the bolt boss portion 68 on the left side of the front portion of the balancer housing 43, 44. On the other hand, the second positioning pin 74 has a bolt boss portion on the right side of the rear portion that is diagonally positioned in a quadrilateral connecting the four bolt boss portions 68 of the balancer housings 43 and 44 with respect to the bolt boss portion 68 on the left side of the front portion. It is arranged in 68 bolt holes.

    As shown in FIG. 10, the first positioning pin 73 has an orifice 75 through which oil is formed so as to penetrate the axial center portion in the axial direction, and is fitted into the oil introduction port 77 of the balancer housing 43. Yes. The oil introduction port 77 is open at a position close to the front left bolt boss 68 on the side of the first balancer shaft 41 (on the opposite side of the second balancer shaft 42 across the first balancer shaft 41). Then, the first positioning pin 73 fitted in the oil introduction port 77 is fitted into the oil supply port 76 of the lower block 5 as a positioning hole, thereby positioning the balancer unit 2 on the lower block 5 at the same time. The oil supply port 76 of the lower block 5 and the oil introduction port 77 of the balancer housing 43 are connected.

    That is, the first positioning pin 73 has not only the positioning function but also an orifice function for narrowing the oil passage diameter from the lower block 5 to the balancer unit 2 to distribute and supply an appropriate amount of lubricating oil. An O-ring 99 that prevents oil leakage from between the first positioning pin 73 and the oil supply port 76 of the lower block 5 is fitted to a portion of the first positioning pin 73 that protrudes from the oil introduction port 77.

    The oil supply system of the engine including the oil supply port 76 and the oil introduction port 77 will be described later.

    On the other hand, as shown in FIG. 11, the second positioning pin 74 has a cylindrical shape having a hole through which the fastening bolt 70 is passed, and is fitted into the bolt boss portion 68 on the right side of the rear portion. A positioning hole 69a having a diameter larger than that of the threaded portion is formed at the inlet portion of the bolt hole 69 of the lower block 5, and the second positioning pin 74 is fitted into the positioning hole 69a. Thus, the balancer unit 2 is positioned on the lower block 5.

    As described above, since both the first positioning pin 73 and the second positioning pin 74 are provided in the upper housing 43 of the balancer unit 2, the positioning accuracy of the balancer unit 2 is increased when the balancer unit 2 is attached to the lower block 5. In addition to facilitating the fastening operation with the bolt 70, the balancer unit 2 is advantageous in reducing engine secondary vibration.

    That is, when the balancer housings 43 and 44 and the pump housing 45 are coupled and fastened to the lower block 5 as in this example, positioning means may be provided on each of the balancer housing side and the pump housing side. However, in this case, positioning pins may interfere with each other due to manufacturing errors between the balancer housings 43 and 44 and the pump housing 45, and positioning may be difficult. Therefore, in the present invention, the positioning pins are collected on the balancer housing side without providing the positioning means on the pump housing 45 side so that the balancer unit 2 can be fastened to the lower block 5 of the engine body 1 with high positioning accuracy. It is a thing.

    In addition, the first positioning pin 73 and the second positioning pin 74 are arranged so as to have a substantially diagonal positional relationship in the quadrilateral connecting the four bolt boss portions 68 of the balancer unit 2. This is further advantageous for improving the positioning accuracy.

    Then, with the balancer unit 2 positioned on the lower block 5 by the positioning pins 73 and 74 as described above, the bolts 70 are applied to the balancer unit 2 and the oil pump 8 so that they are fastened to the lower block 5. ing. In this case, since the position where the balancer unit 2 and the oil pump 8 are fastened is the cross beam 61 where the rigidity of the lower block 5 is high or in the vicinity thereof, the support thereof is stable.

<About oil supply system>
Next, the oil supply system that supplies oil from the oil pan 7 to the parts that require lubrication or cooling of the engine body 1 and the balancer unit 2 will be described.

-Oil supply to the engine body-
First, on the lower surface of the lower housing 44 of the balancer unit 2 (a position corresponding to the approximate center in the engine longitudinal direction), an oil suction port 78 for sucking oil from the oil pan 7 into the oil pump 8 as shown in FIG. Is open. As shown in FIGS. 5 and 9, a strainer 79 is fitted into the oil suction port 78 and is held by a strainer presser 80. An outlet of an oil suction path 81 extending rearward from the oil suction port 78 is opened on the rear surface of the lower housing 44.

    As shown in FIG. 13, an inlet of a pump housing side oil suction path 82 connected to the oil suction path 81 of the lower housing 44 is opened on the front surface of the pump housing 45 of the oil pump 8. The oil pump 8 of this example is a trochoid type, and an outlet of the oil discharge passage 83 is opened on the upper surface of the pump housing 45.

    As shown in FIGS. 7 and 14, a first oil passage 84 is formed in the second cross beam 61 from the rear of the lower block 5. The first oil passage 84 is for supplying the oil discharged from the oil pump 8 to the oil cooler 19 shown in FIG. 1, and an inlet is opened on the lower surface of the lower block 5. The inlet is disposed so as to correspond to the outlet of the oil discharge passage 83 of the pump housing 45, and the oil pump 8 is fastened to the lower block 5, whereby the oil discharge passage 83 and the first oil passage 84 of the pump housing 45 are connected. And will be connected.

    Further, the first oil passage 84 extends upward from the inlet of the lower surface of the lower block and then changes the direction to the left, and the outlet is opened on the left side surface of the lower block 5 as shown in FIG. The outlet of the first oil passage 84 is connected to the oil inlet of the oil cooler 19 when the oil cooler 19 is fastened to the lower block 5.

    The oil cooled by the oil cooler 19 is supplied to the oil filter 20 shown in FIG. 1, and the oil that has passed through the oil filter 20 is supplied again to the second oil passage 85 of the lower block 5. As shown in FIG. 15, the second oil passage 85 has an inlet opening on the left side surface of the lower block 5, and is connected to the outlet of the oil filter 20 by fastening the oil filter 20 to the lower block 5. The

    The second oil passage 85 extends rightward from the side surface of the lower block 5 to the position of the connecting frame 66 and then passes through the position of the connecting frame 66 to the front end of the lower block 5 as shown in FIG. It extends. A balancer oil passage 86 for distributing and supplying a part of the oil to the balancer unit 2 branches from the middle of the portion extending in the front-rear direction of the second oil passage 85 and extends downwardly. The oil supply port 76 is open to the bottom (see FIG. 10). Then, the balancer oil passage 86, that is, the oil supply port 76 into which the first positioning pin 73 is fitted is disposed close to the front left bolt boss portion 68 of the balancer unit 2, as is apparent from FIG. ing.

    The second oil passage 85 is bent to the right at the cross beam 61 at the front end of the lower block 5 to supply oil to each part of the engine body 1, and extends to the right side of the lower block 5 through the cross beam 61. Next, it is folded on the right side and extends forward, and further extends upward at the front end portion of the lower block 5, and an outlet 87 is opened on the upper surface of the lower block 5.

    A timing case 11 having an oil ascending path 88 is placed on the upper surface of the front end portion of the lower block 5 as shown in FIG. By this placement, the outlet 87 of the second oil passage 85 is connected to the oil rising path 88 of the timing case 11. The oil ascending path 88 communicates with a main oil gallery 89 extending in the front-rear direction through the cylinder block 3 at its ascending end.

−Oil supply to balancer unit−
As shown in FIG. 17, in the upper housing 43 of the balancer unit 2, an oil introduction path 91 extends downward from an oil introduction port 77 into which the first positioning pin 73 with an orifice is fitted. An opening is formed in the lower surface of the upper housing 43. On the mating surface of the upper housing 43 and the lower housing 44, as shown in FIG. 18 (bottom view of the upper housing 43), a front oil supply path 92 extending from the oil introduction path 91 to the front bearings 46, 46, A rear oil supply passage 93 extending from the oil introduction passage 91 to the rear bearings 47 and 47 is formed.

    The oil introduction path 91 is located on the side of the front bearing 46 on the first balancer shaft 41 side, and the front oil supply path 92 extends laterally from the oil introduction path 91 so that the first balancer shaft 41 and Each front bearing 46 of the second balancer shaft 42 is reached. On the other hand, the rear oil supply passage 93 extends rearward from the oil introduction passage 91 in the side of the mass portion accommodating chamber 51 and then bends to the side to receive the rear bearings of the first balancer shaft 41 and the second balancer shaft 42. 47 has been reached. Therefore, the front oil supply path 92 from the oil introduction path 91 to the front bearing 46 is shorter than the rear oil supply path 93 from the oil introduction path 91 to the rear bearing 47.

    The front and rear oil supply passages 92 and 93 are basically constituted by grooves 92 a and 93 a, grooves 92 b and 93 b and grooves 92 c and 93 c formed in the upper housing 43.

    That is, the grooves 92 a and 93 a are formed on the mating surface of the upper housing 43 and extend from the oil introduction path 91 to the bearings 46 and 47 of the first balancer shaft 41 via the bolt holes 56. The grooves 92b and 93b are formed on the surface of the first balancer shaft side bearings 46 and 47 on the upper housing 43 side, and extend across the bearings 46 and 47 following the grooves 92a and 93a. The grooves 92c and 93c are formed in the mating surfaces between the adjacent bearings 46 and 46 and the bearings 47 and 47 of the upper housing 43, and follow the grooves 92b and 93b through the position of the bolt hole 56. It extends so as to cross between the bearings, and reaches the second balancer shaft side bearings 46 and 47.

    The oil supply paths 92 and 93 are configured such that the oil reaches the bearings 46 and 47 around the bolt 55 by making the hole diameter slightly larger than that of the bolt 55 at the position of the bolt hole 56.

    As shown in FIG. 17, an oil reservoir groove 94 that communicates with the front oil supply passage 92 and extends in the circumferential direction is formed on the surface of the lower housing 44 of the first balancer shaft 41 side front bearing 46. On the surface of the lower housing 44 of the rear bearing 47 of the first balancer shaft 41, an oil reservoir groove (not shown) that communicates with the rear oil supply passage 93 is formed in the same manner as the front bearing 46.

    In addition, oil reservoir grooves 95, 95 communicating with the front oil supply passage 92 and extending in the circumferential direction are formed on each surface of the upper housing 43 side of the second balancer shaft 42 side front bearing 46 and the lower housing 44. ing. On the surface of the housings 43 and 44 of the rear bearing 47 of the second balancer shaft 42, an oil reservoir groove (not shown) that communicates with the rear oil supply path 93 is formed as well as the front bearing 46.

    Accordingly, the oil discharged from the oil pump 8 is supplied from the second oil passage 85 of the lower block 5 through the orifice 75 of the first positioning pin 73 to the balancer unit 2. By restricting the oil supply amount to the balancer unit 2 by the orifice 75, oil supply from the second oil passage 85 to each part of the engine body 1 is ensured.

    Thus, the portion of the oil supply port 76 on the lower block 5 side and the portion of the oil introduction port 77 on the balancer unit 2 side connected by the first positioning pin 73 are bolt boss portions that fasten the balancer unit 2 to the lower block 5. 68 are close to each other, and the fastening force by the bolt 70 is strong. That is, a high surface pressure that presses the portion of the oil supply port 76 and the portion of the oil introduction port 77 works. Accordingly, the connection between the oil supply port 76 and the oil introduction port 77 by the first positioning pin 73 is ensured, and oil leakage when oil is supplied from the lower block 5 to the balancer unit 2 is prevented.

    Further, since the front oil supply path 92 extending from the oil introduction path 91 to the front bearing 46 is shorter than the rear oil supply path 93 extending from the oil introduction path 91 to the rear bearing 47, the oil is supplied to the rear bearing. A larger amount of the passage resistance is supplied to the front bearing 46 having a smaller passage resistance than 47, which is advantageous for balanced lubrication. That is, since the first balancer shaft 41 is driven to rotate by the crankshaft 25 while being pulled upward by the transmission chain 35, a large force is applied to the front bearing 46. However, with the configuration of the oil supply passage as described above, the oil can be positively supplied to the front bearing 46 without increasing the amount of oil distributed from the engine body 1 side to the balancer unit 2 side. Therefore, insufficient lubrication of the balancer shafts 41 and 42 at the front bearing 46 can be avoided, and the rotation of the balancer shafts 41 and 42 can be stabilized.

    The oil supplied to the bearings 46 and 47 flows down from both the front and rear sides to the mass portion storage chamber 51, the gear storage chamber 52, and the like. As described above, oil is more actively supplied to the front bearing 46 than to the rear bearing 47. On both sides of the front bearing 46, thrust receiving surfaces 41b, 41c, 42b, 42c of the balancer shafts 41, 42 are provided. Has been placed. Accordingly, the oil supplied to the front bearing 46 is restricted by the thrust receiving surfaces 41b, 41c, 42b, and 42c from flowing into the mass portion accommodating chamber 51 and the gear accommodating chamber 52 without moderation. That is, an appropriate amount of oil necessary for the lubrication of the gears 48 and 49 can be supplied from the front bearing 46 to the gear housing chamber 52, and the gears 48 and 49 can be supplied without increasing the amount of oil supplied to the front bearing 46. This is advantageous for proper lubrication.

    Then, as described above, since a large amount of oil does not flow into the mass portion accommodating chamber 51 and the gear accommodating chamber 52, the rotational resistance of the mass portions 41a, 42a and the gears 48, 49 is not greatly increased. Further, the oil flowing into the storage chambers 51 and 52 is scraped by rotation of the mass portions 41a and 42a and the gears 48 and 49, as will be described later, but the fact that the amount of inflow of oil is small is necessary for the scraping. This means that the amount of work is reduced, and combined with the reduction of the rotational resistance, is advantageous in reducing energy loss.

<Oil discharge of balancer unit>
As described above, the oil discharge ports 58 and 59 formed in the upper portion of the mass storage chamber 51 and the gear storage chamber 52 of the balancer unit 2 are for discharging oil from the storage chambers 51 and 52. It is. As shown in FIG. 7, the connecting wall 62 that connects the adjacent horizontal beams 61 of the lower block 5 on the lower surface side is provided so as to cover the oil discharge ports 58 and 59 of the balancer unit 2 from above. . However, as shown in FIG. 19, oil is placed between the upper edge (the edges of the oil discharge ports 58 and 59) and the connecting wall 62 of the mass portion storage chamber 51 and the gear storage chamber 52. An oil discharge gap 98 that allows the oil to be discharged from 59 to the oil pan 7 is formed.

    Therefore, the connecting wall 62 prevents the oil dripping from the cylinder block 3 from entering the mass storage chamber 51 and the gear storage chamber 52 from the oil discharge ports 58 and 59 of the balancer unit 2. Then, the dropped oil is recovered by dropping into the oil pan 7 from the oil recovery ports 64 on both sides of the connecting wall 62.

    On the other hand, the oil in the mass storage chamber 51 and the gear storage chamber 52 is discharged from the oil discharge ports 58 and 59 by the rotation of the balancer shafts 41 and 42 and collected in the oil pan 7. That is, as each of the balancer shafts 41 and 42 rotates in the direction from the inner side to the outer side on the upper half circumference side, the oil in the mass portion accommodating chamber 51 is rotated by the rotation of the mass portions 41a and 42a in the direction. The oil in the gear housing chamber 52 is scraped out from the oil outlet 59 by the rotation of the gears 48 and 49 in this direction.

    As described above, since the oil discharge gap 98 is formed between the edge of the oil discharge ports 58 and 59 and the connection wall 62, the connection wall 62 is connected to the oil from the oil discharge ports 58 and 59. It does not hinder the discharge, and the scraped oil falls to the oil pan 7 through the gap 98.

    Further, since the flanges 58a and 59a rise from the main body of the upper housing 3 at the edges of the oil discharge ports 58 and 59, the oil flows along the upper surface of the upper housing 43 by the flanges 58a and 59a. 59 is prevented from entering.

<Others>
In the above embodiment, the bolt 70 is applied to the balancer unit 2 and the oil pump 8 in a state where the balancer unit 2 is positioned on the lower block 5 by the positioning pins 73 and 74, but these are fastened to the lower block 5. 2 and the oil pump 8 have a dimensional error, the fastening between the oil pump 8 and the lower block 2 becomes insufficient, and the oil discharge path 83 of the oil pump 8 and the first oil path 84 of the lower block 5 are connected. There is also a concern that a defect may occur.

    Accordingly, when the balancer unit 2 is fastened to the lower block 5 with the oil pump 8 coupled to the balancer unit 2, the oil pump 8 is set so that a minute gap is formed between the fastening surfaces of the oil pump 8 and the lower block 5. As shown in FIG. 9, a cylindrical collar 96 serving as a spacer is interposed between the fastening surfaces, and the oil pump 8 is fastened to the lower block 5 through bolts 70 in the collar 96. Good. That is, the dimensional error is absorbed by the collar 96. In that case, as shown in FIG. 9, the seal of the connecting portion between the oil discharge passage 83 of the oil pump 8 and the first oil passage 84 of the lower block 5 is secured by interposing an O-ring 97 at the connecting portion. be able to.

1 is a side view showing a schematic configuration of a diesel engine according to the present invention. It is a front view which shows the timing chain etc. of the same engine. It is a perspective view which shows the balancer unit and oil pump of the same engine. It is a perspective view which shows the balancer unit and oil pump which removed the upper housing. It is a disassembled perspective view of the balancer unit. It is sectional drawing of the front part bearing part of the same balancer unit. It is a top view which shows the relationship between the lower block of an engine main body, and a balancer unit. It is a side view which shows the relationship. It is the perspective view which looked at the attachment aspect of the balancer unit to an engine main body from the engine lower surface side. It is sectional drawing which shows the positioning part of an engine main body and a balancer unit by the 1st positioning pin with an orifice. It is sectional drawing which shows the positioning part of the engine main body and balancer unit by a 2nd positioning pin. It is sectional drawing which shows the oil strainer part of a balancer unit. It is a perspective view of an oil pump. It is sectional drawing of the lower block in the AA of FIG. It is a side view of a lower block. It is sectional drawing of the lower block in the BB line of FIG. It is a cross-sectional view of the balancer unit (a cross-sectional view taken along the line CC in FIG. 18). It is a bottom view of the upper housing of a lower block. FIG. 10 is a sectional view taken along line D-D in FIG. 9.

Explanation of symbols

1 Engine body
2 Balancer unit
3 Cylinder block
5 Lower block
7 Oil pan
8 Oil pump
20 Oil filter
40 Pump fastening bolt 41, 42 Balancer shaft 41a, 42a Mass portion 41b, 41c Thrust receiving surface 42b, 42c Thrust receiving surface 43, 44 Balancer housing
45 Pump housing
46 Front bearing
47 Rear bearing 48, 49 Synchronous helical gear
51 Mass storage room
52 Gear storage chamber 53, 54 Transmission gear for pump drive 58, 59 Oil discharge port 58a, 59a 鍔
61 horizontal girder
62 Connecting wall
64 Oil recovery port
68 Bolt boss
70 Fastening bolt
73 First positioning pin
74 Second positioning pin
75 Orifice
76 Oil supply port
77 Oil inlet
78 Oil inlet
79 Oil strainer 81, 82 Oil suction passage
84 1st oil passage
85 Second oil passage
86 Oil passage for balancer
92 Front oil supply path
93 Rear oil supply path
98 Oil drain gap

Claims (5)

A balancer unit having a pair of balancer shafts provided in parallel to the crankshaft and having mass portions that allow the center of gravity to deviate from the axial center and gear transmission means for synchronously rotating the balancer shafts is an engine body. An engine balancer device in which the pair of balancer shafts are rotationally driven by a crankshaft,
An oil pump that is decelerated and driven by gear transmission means by one of the pair of balancer shafts;
The synchronizing gear transmission means is constituted by helical gears coupled to and meshing with each of the balancer shafts,
The gear transmission means for driving the oil pump is composed of helical gears that are coupled to the one balancer shaft and the oil pump drive shaft and mesh with each other,
The synchronizing helical gear coupled to the one balancer shaft and the oil pump driving helical gear coupled to the balancer shaft are provided so as to generate thrust forces in opposite directions to each other. Engine balancer device. In claim 1,
Chain transmission means is provided on one end side of the other of the balancer shafts to transmit the rotational driving force of the crankshaft,
The oil pump is disposed on the other end side of the balancer shafts,
A balancer device for an engine, characterized in that a helical gear for driving the oil pump is provided on the other end of the balancer shaft. In claim 1 or claim 2,
Each of the balancer shafts is supported by bearings on both sides in the axial direction across the mass portion,
The synchronizing gear transmission means is disposed on the opposite side of the mass portion across one of the bearings on both sides,
A balancer device for an engine, characterized in that gear transmission means for driving the oil pump is arranged on the opposite side of the mass portion with the other bearing among the bearings on both sides. In any one of Claim 1 thru | or 3,
A balancer device for an engine, wherein the balancer housing for housing both balancer shafts and the housing for the oil pump are formed separately, and the two housings are fastened to each other by bolts. In claim 4,
An oil suction port for attaching an oil strainer is provided at a lower portion of the balancer housing, and an oil suction path from the oil suction port to the oil pump is formed so as to extend across the balancer housing and the pump housing. An engine balancer device.

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