JP4218667B2 - Internal combustion engine starting torque transmission mechanism - Google Patents

Description

  The present invention relates to an internal combustion engine starting rotational force transmission mechanism that transmits a rotational force in one direction by a starting motor to a crankshaft side and prevents reverse rotational force transmission through a one-way clutch.

In the internal combustion engine starter, an internal combustion engine start torque transmission mechanism in which the starter motor side and the ring gear are always kept in mesh by providing a one-way clutch (reverse input cutoff clutch) between the starter motor and the crankshaft. (See, for example, Patent Document 1).
Japanese Patent Laying-Open No. 2003-83216 (page 2-3, FIGS. 4 and 7)

  Among the techniques disclosed in Patent Document 1, particularly in the prior art, the ring gear (second reduction gear) is provided to the crankshaft via a bearing. Further, the ring gear is connected to a drive gear interlocking with the crankshaft through the one-way clutch by disposing a one-way clutch on the side opposite to the bearing contact surface. Therefore, when the starter motor is driven, the one-way clutch is engaged to transmit the rotational force from the ring gear to the drive gear, and the crankshaft can be rotated by the starter motor.

  However, since the ring gear is attached to the crankshaft with a bearing, even if the ring gear stops rotating after starting the internal combustion engine, the bearing must always function during operation of the internal combustion engine. The inside requires a lot of lubricating oil.

Furthermore, it is impossible to separate the ring gear from the crankshaft, and vibration from the crankshaft must be received through the bearing.
An object of the present invention is to provide an internal combustion engine starting rotational force transmission mechanism that can prevent a bearing from functioning during operation of the internal combustion engine and that can separate a ring gear from a crankshaft.

In the following, means for achieving the above object and its effects are described.
The internal combustion engine starting rotational force transmission mechanism according to claim 1 transmits the rotational force in one direction by the starting motor to the crankshaft side through a one-way clutch, and prevents reverse rotational force transmission. A starting rotational force transmission mechanism, which is attached to the internal combustion engine main body through a bearing in a freely rotating state, rotates by receiving the rotational force of the starting motor, and is connected to an inner race of the one-way clutch; a ring gear in a non-contact state with respect to the crankshaft side, the internal combustion engine body mounted on the crankshaft side on the opposite side as to rotate in conjunction with the crankshaft relative to said ring gear, said one-way clutch a race connecting member which is connected to the outer race, a portion of the ring gear, and a cylindrical shape around the crankshaft That the cylindrical portion is formed, characterized in that the bearing on the outer peripheral side of the cylindrical portion is disposed.

  The ring gear is attached not by the crankshaft side but by the bearing to the internal combustion engine main body side. For this reason, the bearing functions during a period in which the ring gear is rotated by the starting motor at the time of starting. If the starting motor stops after the internal combustion engine is started, the rotation of the bearing also stops. Therefore, the bearing does not rotate during operation of the internal combustion engine. As described above, since the bearing only needs to function for a short period at the time of starting, it is not necessary to supply a large amount of lubricating oil to the bearing.

Further, since the ring gear does not need to be supported by the crankshaft, it can be designed to be separated from the crankshaft .

That is , the ring gear can be brought into a non-contact state with respect to the crankshaft side as in the above configuration, and can be completely separated from the crankshaft, so that it is not subjected to vibration from the crankshaft during operation of the internal combustion engine. Can be.

Also, the race connecting member is connected to the outer race of the one-way clutch, and the ring gear is connected to the inner race, and in particular, the one-way clutch is covered with the connecting body of the race connecting member and the outer race as viewed from one side. Is possible. In this way, during operation of the internal combustion engine, it is possible to cover a one-way clutch that particularly requires an oil seal, so that a design that can easily realize a high degree of sealing performance even when a large amount of lubricating oil is supplied to the one-way clutch can be achieved. It becomes like this.

In particular, in the above arrangement, the ring gear is an internal combustion engine main body side, because the race connecting member is as the internal combustion engine body with respect to the ring gear are on opposite sides, an internal combustion engine outside, particularly for the transmission side The one-way clutch can be covered with the race connecting member and the outer race. As a result, it becomes easy to realize the high sealing performance of the one-way clutch with respect to the outside of the internal combustion engine, and the oil seal can be performed with the one-way clutch completely isolated from the transmission side. Therefore, the oil used for lubricating the internal combustion engine can be used for lubricating the one-way clutch.
Further, according to the above configuration, the inner race of the one-way clutch is formed on the inner peripheral side of the ring gear, and the bearing is disposed on the outer peripheral side of the cylindrical portion formed in a part of the ring gear. The impact force when the one-way clutch is engaged with the inner race acts in a direction to reduce the clamping force with respect to the bearing by the cylindrical portion and the internal combustion engine main body side.
Therefore, by disposing the bearing as described above, the impact force on the bearing at the time of engagement of the one-way clutch is reduced rather than providing the bearing between the inner race and the crankshaft. Therefore, an excessive load is not generated on the bearing even when the one-way clutch is engaged. This can prevent the bearing from being damaged.
According to a second aspect of the present invention, in the internal combustion engine starting rotational force transmission mechanism according to the first aspect, a first oil seal member is disposed in a gap between the outer race and the ring gear, and a first oil seal member is disposed in the gap between the ring gear and the internal combustion engine body. Two oil seal members are arranged.
By disposing the first oil seal member and the second oil seal member in this manner, the inside of the internal combustion engine starting rotational force transmission mechanism can be oil-sealed easily and with high sealing performance. As a result, the internal combustion engine starting rotational force transmission mechanism can be lubricated with the oil used for lubricating the internal combustion engine.
According to a third aspect of the present invention, in the internal combustion engine starting rotational force transmission mechanism according to the second aspect, the first oil seal member is disposed on the inner peripheral side of the cylindrical portion, and the second oil seal member is disposed on the outer peripheral side. It is characterized by.
Accordingly, each oil seal can be easily arranged by fitting, and the oil seal can be surely performed.
The internal combustion engine starting rotational force transmission mechanism according to claim 4, wherein in the second or third aspect, the second oil seal member and the bearing are located inside the bearing at a gap between the ring gear and the internal combustion engine body. And are arranged in parallel.
By arranging the second oil seal member and the bearing in this arrangement relationship, the lubricating oil supplied to the bearing can be reliably sealed.

6. The internal combustion engine starting rotational force transmission mechanism according to claim 5, wherein the rotational force in one direction by the starting motor is transmitted to the crankshaft side through a one-way clutch, and transmission of rotational force in the reverse direction is prevented. A starting rotational force transmission mechanism, which is attached to the internal combustion engine main body through a bearing in a freely rotating state, rotates by receiving the rotational force of the starting motor, and is connected to an inner race of the one-way clutch; A ring gear in a non-contact state with respect to the crankshaft side, and attached to the crankshaft side on the opposite side of the internal combustion engine body with respect to the ring gear and rotating in conjunction with the crankshaft; a race connecting member which is connected to the outer race, first o in the gap before Kia Utaresu and said ring gear Lucille member is arranged, wherein the second oil seal member in a gap between the ring gear and the internal combustion engine body is disposed.

The ring gear is attached not by the crankshaft side but by the bearing to the internal combustion engine main body side. For this reason, the bearing functions during a period in which the ring gear is rotated by the starting motor at the time of starting. If the starting motor stops after the internal combustion engine is started, the rotation of the bearing also stops. Therefore, the bearing does not rotate during operation of the internal combustion engine. As described above, since the bearing only needs to function for a short period at the time of starting, it is not necessary to supply a large amount of lubricating oil to the bearing.
Further, since the ring gear does not need to be supported by the crankshaft, it can be designed to be separated from the crankshaft.
That is, the ring gear can be brought into a non-contact state with respect to the crankshaft side as in the above configuration, and can be completely separated from the crankshaft, so that it is not subjected to vibration from the crankshaft during operation of the internal combustion engine. Can be.
Also, the race connecting member is connected to the outer race of the one-way clutch, and the ring gear is connected to the inner race, and in particular, the one-way clutch is covered with the connecting body of the race connecting member and the outer race as viewed from one side. Is possible. In this way, during operation of the internal combustion engine, it is possible to cover a one-way clutch that particularly requires an oil seal, so that a design that can easily realize a high degree of sealing performance even when a large amount of lubricating oil is supplied to the one-way clutch can be achieved. It becomes like this.
In particular, in the above configuration, the ring gear is on the internal combustion engine body side, and the race connecting member is on the opposite side of the ring gear from the internal combustion engine body. The one-way clutch can be covered with the race connecting member and the outer race. As a result, it becomes easy to realize the high sealing performance of the one-way clutch with respect to the outside of the internal combustion engine, and the oil seal can be performed with the one-way clutch completely isolated from the transmission side. Therefore, the oil used for lubricating the internal combustion engine can be used for lubricating the one-way clutch.
Furthermore, according to the above configuration, the first oil seal member is disposed in the gap between the outer race and the ring gear, and the second oil seal member is disposed in the gap between the ring gear and the internal combustion engine body. In addition, the inside of the internal combustion engine starting rotational force transmission mechanism can be oil-sealed with high sealing performance. As a result, the internal combustion engine starting rotational force transmission mechanism can be lubricated with the oil used for lubricating the internal combustion engine.

  According to a sixth aspect of the present invention, in the internal combustion engine starting rotational force transmission mechanism according to the fifth aspect, a cylindrical portion that is cylindrical around the crankshaft is formed in a part of the ring gear, and the cylindrical portion is formed on the inner peripheral side of the cylindrical portion. The first oil seal member is disposed, and the second oil seal member is disposed on the outer peripheral side.

Accordingly, each oil seal can be easily arranged by fitting, and the oil seal can be surely performed.
The internal combustion engine starting rotational force transmission mechanism according to claim 7, wherein the second oil seal member and the bearing are located inside the bearing at a gap between the ring gear and the internal combustion engine body. And are arranged in parallel.

  By arranging the second oil seal member and the bearing in this arrangement relationship, the lubricating oil supplied to the bearing can be reliably sealed.

[Embodiment 1]
FIG. 1 shows an internal combustion engine starting rotational force transmission mechanism of an internal combustion engine for a vehicle, and shows a cross-sectional view around the rear side of the internal combustion engine that outputs to the transmission side.

  Below the cylinder block 2 of the internal combustion engine is disposed a rear end of a crankshaft 4 rotatably supported by a ladder beam. A flywheel 6 and an outer race support plate 8 (corresponding to a race connecting member) are attached to the rear end of the crankshaft 4, and a ring gear 10 is attached to the cylinder block 2.

  The flywheel 6 showing the upper half in FIG. 1 has a substantially disc shape with a circular opening at the center, and the side opposite to the side in contact with the outer race support plate 8 is connected to the transmission. As a part of the clutch mechanism for transmitting the rotational force between them, a clutch disk 6a is attached in a ring shape. The clutch mechanism may be formed separately from the flywheel 6.

  The outer race support plate 8 shown in the upper half in FIG. 1 is formed in a circular flat plate shape having an opening at the center, and the flywheel 6 and the rear end surface 4a of the crankshaft 4 at the periphery of the center opening. It is fixed by bolt fastening. Accordingly, the flywheel 6 is configured to rotate in conjunction with the crankshaft 4.

  The ring gear 10 shown in the upper half in FIG. 1 is a disk having a large opening at the center and a bent portion (cylindrical portion 10c and bent portion 10f) in the radial direction. An inner race 10a of the clutch 12 is provided, and a gear portion 10b is provided in a ring shape on the outer peripheral portion. In the ring gear 10, the inner race 10 a is the most central, but is not supported by the inner race 10 a and is lifted from the peripheral surface 4 b of the crankshaft 4.

  On the rear side of the cylinder block 2, a semicircular surface portion 2a is formed so as to protrude. Similarly, a semicircular surface portion continuous with the semicircular surface portion 2a on the cylinder block 2 side also exists on the rear side of the oil pan disposed below the cylinder block 2. As a whole, a short circumferential surface portion 14 is formed over the entire circumference of the crankshaft 4. A bearing (here, a rolling bearing is used) 16 is fitted to the inner circumferential surface 14a of the short circumferential surface portion 14, and the ring gear 10 is located inside the bearing 16 at the position of the cylindrical portion 10c. By being fitted, the ring gear 10 is supported on the internal combustion engine main body side via the bearing 16. Therefore, when the one-way clutch 12 is in the released state, the ring gear 10 can freely rotate independently of the rotation of the crankshaft 4.

  The gear portion 10b of the ring gear 10 is always meshed with the pinion gear of the starting motor at a phase position below the crankshaft 4, and the entire ring gear 10 rotates by receiving a rotational force from the starting motor via the pinion gear. .

  An outer race 18 is attached to the outer peripheral portion of the outer race support plate 8 so as to face the inner race 10 a formed at the center opening of the ring gear 10. Thus, a one-way clutch 12 is configured between the ring gear 10 and the outer race support plate 8.

  The one-way clutch 12 is used when the starting motor rotates the ring gear 10 via the pinion gear at the time of starting the internal combustion engine, that is, in the case of rotation in one direction for transmitting torque from the ring gear 10 side to the outer race support plate 8. The outer race support plate 8 and the ring gear 10 are engaged. As a result, the starting motor can rotate the crankshaft 4.

  When the internal combustion engine starts operation, the crankshaft 4 is rotated by the output of the internal combustion engine, and when the rotation of the outer race support plate 8 interlocked with the crankshaft 4 becomes faster than the rotation of the ring gear 10 by the starting motor, the ring gear The rotation 10 is a rotation in the opposite direction relative to the outer race support plate 8. For this reason, the one-way clutch 12 is in a disengaged state, and even if the pinion gear and the ring gear 10 are always meshed, it is possible to prevent over-rotation of the starting motor after the internal combustion engine is started.

  Here, as the lubricating oil for the bearing 16 and the one-way clutch 12, engine oil is supplied as indicated by an arrow A through the oil passage in the cylinder block 2 or the crankshaft 4. However, since the outer race support plate 8 and the ring gear 10 are disposed with the one-way clutch 12 in between, it is necessary to prevent oil leakage during this period. For this purpose, the ring-shaped first oil seal member 20 is disposed between the outer race 18 integrally attached to the outer race support plate 8 and the cylindrical portion 10 c of the ring gear 10. The first oil seal member 20 is fixed to the ring gear 10 side by being fitted to the inner peripheral surface 10d of the cylindrical portion 10c. Thus, the seal lip 20a formed on the inner peripheral side of the first oil seal member 20 is slidably in contact with the outer peripheral surface of the outer race 18 and performs an oil seal.

  On the opposite side (outer peripheral side) to the inner peripheral side where the first oil seal member 20 is disposed across the cylindrical portion 10c, the second oil seal member 22 having a diameter larger than that of the first oil seal member 20 is described above. The bearing 16 is arranged in parallel. The bearing 16 is disposed on the inner side and the second oil seal member 22 is disposed on the outer side. Similar to the bearing 16, the second oil seal member 22 is fixed at a position shown in the drawing by being fitted to the inner peripheral surface 14 a of the short circumferential surface portion 14. As a result, the seal lip 22a formed on the inner peripheral side of the second oil seal member 22 is slidably in contact with the outer peripheral surface 10e of the cylindrical portion 10c to perform oil sealing.

According to the first embodiment described above, the following effects can be obtained.
(I). The ring gear 10 is attached to the internal combustion engine main body side (here, the cylinder block 2 and the oil pan) by a bearing 16 rather than the crankshaft 4 side. For this reason, the bearing 16 actually rotates and functions during the period when the ring gear 10 is rotated by the starting motor at the time of starting. Therefore, if the starting motor stops after the internal combustion engine is started, the rotation of the bearing 16 is also stopped, so that the bearing 16 can be prevented from functioning during the operation of the internal combustion engine.

  Thus, since the bearing 16 rotates only for a short period of time at the time of starting, it is not necessary to supply a large amount of lubricating oil to the bearing 16. Further, the bearing 16 itself does not need to be enlarged due to double rows of balls, and it is not necessary to supply a large amount of lubricating oil. Therefore, as shown in FIG. 1, the bearing 16 can be sufficiently lubricated even with the amount of lubricating oil supplied only by the gap 24 between the cylinder block 2 and the ring gear 10. From this, the lubricating oil path need not be specially considered for the bearing 16, the lubricating oil path can be simplified, and the internal combustion engine can be reduced in size.

  (B). Since the ring gear 10 is not supported by the crankshaft 4, it can be separated from the crankshaft 4 and brought into a non-contact state. That is, as shown in FIG. 1, the gap 26 can be provided with respect to the peripheral surface 4 b of the crankshaft 4. For this reason, vibration from the crankshaft 4 during operation of the internal combustion engine is not transmitted to the ring gear 10, and wear due to vibration at the contact point between the gear portion 10b and the pinion gear and noise due to radiated sound from the ring gear 10 are prevented. can do. Further, the gap 26 facilitates the supply of the lubricating oil to the one-way clutch 12, and in particular, the lubricating oil can be sufficiently supplied to the one-way clutch 12 that is in a sliding state during operation of the internal combustion engine. Can be enhanced.

  (C). The outer race support plate 8, which is a race connecting member, is connected to an outer race 18 that forms part of the one-way clutch 12, and the ring gear 10 is connected to an inner race 10 a that forms part of the one-way clutch 12. Yes. As a result, the one-way clutch 12 can be completely covered by the connection body of the outer race support plate 8 and the outer race 18 as viewed from one side, and here viewed from the transmission side. . Thus, during operation of the internal combustion engine, it becomes possible to completely cover the one-way clutch 12 that is particularly required to be oil-sealed. Therefore, even if a large amount of lubricating oil is supplied to the one-way clutch 12, high sealing performance is achieved. It can be easily realized.

  In this manner, the first oil seal member 20 can perform oil sealing in a state where the one-way clutch 12 is completely isolated from the transmission side. Therefore, by introducing the oil used for lubricating the internal combustion engine through the gap 26, the oil can be used for lubricating the one-way clutch 12.

  Further, as described above, the first oil seal member 20 is disposed, and the second oil seal member 22 is disposed in the gap between the ring gear 10 and the internal combustion engine main body, and the bearing is located inward of the second oil seal member 22 in the same gap. 16 are arranged in parallel. For this reason, the inside of the internal combustion engine starting rotational force transmission mechanism can be oil-sealed easily and with high sealing performance.

In this way, the internal combustion engine starting rotational force transmission mechanism can be lubricated with the oil used for lubricating the internal combustion engine.
(D). The first oil seal member 20 is disposed on the inner peripheral surface 10d side of the cylindrical portion 10c formed in the ring gear 10, and the second oil seal member 22 and the bearing 16 are disposed on the outer peripheral surface 10e side. For this reason, each oil seal member 20 and 22 and the bearing 16 can be easily arrange | positioned by fitting, and a bearing and an oil seal can be performed reliably.

  (E). The outer race 18 of the one-way clutch 12 is disposed on the inner peripheral surface 10d opposite to the outer peripheral surface 10e where the bearing 16 is disposed in the cylindrical portion 10c of the ring gear 10 via the first oil seal member 20. The cylindrical portion 10c is not in direct contact with the one-way clutch 12. Further, the inner race 10a of the one-way clutch 12 is formed on the inner peripheral side of the ring gear 10, but the impact force when the one-way clutch 12 is engaged with the inner race 10a is less than the cylindrical portion 10c with respect to the bearing 16 and the short circumference. It becomes the direction which reduces the clamping force by the surface part 14. FIG.

  For this reason, rather than providing a bearing between the inner race 10a and the crankshaft 4, in the case of the arrangement as shown in FIG. Therefore, an excessive load is not generated on the bearing 16 even when the one-way clutch 12 is engaged. This can prevent the bearing 16 from being damaged.

[Embodiment 2]
In the present embodiment, as shown in FIG. 2, the bearing 52 and the second oil seal member 54 are unitized as the assembly 50. In addition, the same code | symbol is attached | subjected about the structure same as FIG.

  The outer race 52a of the bearing 52 is formed wider than the inner race 52b, and the second oil seal member 54 is fitted in advance on the inner peripheral side of the outer race 52a to form the assembly 50. Therefore, when the internal combustion engine is assembled, the bearing 52 and the second oil seal member 54 can be assembled by fitting the assembly 50 to the inner circumferential surface 14a of the short circumferential surface portion 14. Incidentally, an O-ring 56 may be disposed between the outer race 52a and the inner circumferential surface 14a of the short circumferential surface portion 14 as shown in FIG. 2 in order to make the seal more complete.

According to the second embodiment described above, the following effects can be obtained.
(I). The effect of the first embodiment is produced.
(B). Since the bearing 52 and the second oil seal member 54 can be assembled to the internal combustion engine simultaneously by fitting the assembly 50, the internal combustion engine can be assembled efficiently.

[Other embodiments]
(A). In the above embodiment, the flywheel 6 is bolted together with the outer race support plate 8 as shown in FIG. 1, but is connected to the cover of the torque converter instead of the flywheel 6. It may be a drive plate.

1 is a longitudinal sectional view of an internal combustion engine starting rotational force transmission mechanism according to Embodiment 1. FIG. The longitudinal cross-sectional view of the assembly periphery of Embodiment 2. FIG.

Explanation of symbols

  2 ... Cylinder block, 2a ... Semi-circumferential surface portion, 4 ... Crankshaft, 4a ... Rear end surface, 4b ... Circumferential surface, 6 ... Flywheel, 6a ... Clutch disc, 8 ... Outer race support plate, 10 ... Ring gear, 10a ... Inner race, 10b ... gear portion, 10c ... cylindrical portion, 10d ... inner peripheral surface, 10e ... outer peripheral surface, 12 ... one-way clutch, 14 ... short circumferential surface portion, 16 ... bearing, 18 ... outer race, 20 ... first oil Seal member, 20a ... seal lip, 22 ... second oil seal member, 22a ... seal lip, 24, 26 ... gap, 50 ... assembly, 52 ... bearing, 52a ... outer race, 52b ... inner race, 54 ... second oil Seal member 56 ... O-ring.

Claims (7)

An internal combustion engine starting rotational force transmission mechanism that transmits a rotational force in one direction by the starting motor to the crankshaft side through a one-way clutch and prevents reverse rotational force transmission,
It is attached to the internal combustion engine body side through a bearing in a freely rotating state, receives the rotational force of the starting motor and rotates, and is connected to the inner race of the one-way clutch and is not in contact with the crankshaft side With the ring gear in
The internal combustion engine body mounted on the crankshaft side on the opposite side as to rotate in conjunction with the crankshaft relative to said ring gear, and a race connecting member which connects the outer race of the one-way clutch,
A cylindrical portion that is cylindrical around the crankshaft is formed in a part of the ring gear, and the bearing is disposed on the outer peripheral side of the cylindrical portion.
An internal combustion engine starting rotational force transmission mechanism. The internal combustion engine according to claim 1, wherein a first oil seal member is disposed in a gap between the outer race and the ring gear, and a second oil seal member is disposed in a gap between the ring gear and the internal combustion engine body. Engine starting torque transmission mechanism. 3. The internal combustion engine starting rotational force transmission mechanism according to claim 2 , wherein the first oil seal member is disposed on the inner peripheral side of the cylindrical portion , and the second oil seal member is disposed on the outer peripheral side . 4. The internal combustion engine according to claim 2 , wherein the second oil seal member and the bearing are arranged in parallel with the bearing inside in a gap between the ring gear and the internal combustion engine main body. Starting torque transmission mechanism. An internal combustion engine starting rotational force transmission mechanism that transmits a rotational force in one direction by the starting motor to the crankshaft side through a one-way clutch and prevents reverse rotational force transmission,
It is attached to the internal combustion engine body side through a bearing in a freely rotating state, receives the rotational force of the starting motor and rotates, and is connected to the inner race of the one-way clutch and is not in contact with the crankshaft side With the ring gear in
A race connecting member that is attached to the crankshaft side on the opposite side of the ring gear from the internal combustion engine body and rotates in conjunction with the crankshaft, and is connected to the outer race of the one-way clutch;
Before the first oil seal member is arranged in a gap between the ring gear and Kia Utaresu, engine startup torque, wherein a second oil seal member is arranged in a gap between the ring gear and the internal combustion engine body Transmission mechanism. 6. The cylindrical portion according to claim 5, wherein a cylindrical portion having a cylindrical shape around a crankshaft is formed in a part of the ring gear, the first oil seal member is disposed on the inner peripheral side of the cylindrical portion, and the second oil seal member is disposed on the outer peripheral side. An internal combustion engine starting rotational force transmission mechanism, wherein an oil seal member is disposed. 7. The internal combustion engine according to claim 5, wherein the second oil seal member and the bearing are arranged in parallel with a gap between the ring gear and the internal combustion engine main body with the bearing inside. Starting torque transmission mechanism.

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