JP2018084310A - Shift damper structure for transmission - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a shift damper structure for a transmission including a first transmission member, a second transmission member rotated when power of the first transmission member is transmitted thereto, and an elastic member accommodated in an accommodation chamber formed between both members, and transmitting the power of the first transmission member to the second transmission member, and efficiently preventing vibration of the elastic member.SOLUTION: A first transmission member 19 is rotated when operating force of a shift operation or a select operation is transmitted thereto manually or by actuators 2, 3. A second transmission member 21 is disposed on a position different from the first transmission member 19, and relatively rotatable to the first transmission member 19. An elastic member 23 is accommodated in an accommodation chamber 23 formed between the first transmission member 19 and the second transmission member 21. The accommodation chamber 23 is filled with a fluid restricting operation of the elastic member 23. A selecting mechanism 100 is disposed to selectively permit inflow of a fluid to the accommodation chamber 23 and outflow of the fluid from the accommodation chamber 23.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a shift damper structure for a transmission.

  For example, Patent Document 1 discloses that a first transmission member that is rotated by transmission of an operation force of manual or actuator shift operation or selection operation is disposed at a position different from that of the first transmission member and is relative to the first transmission member. A second transmission member that rotates, and a storage chamber formed between the first transmission member and the second transmission member, and the power of the first transmission member is transmitted to the second transmission member, and the first transmission member 2 discloses an operation device for a transmission including an elastic member that allows rotation of a transmission member and an operation unit that performs a shift operation or a selection operation by the rotation of the second transmission member.

Special table 2003-529024 gazette

  In the transmission operating device of the above-mentioned document, the elastic member that absorbs the impact from the operating portion and is suppressed from being transmitted from the second transmission member to the first transmission member is used. The vibration may cause manual shift operation or feeling during a shift operation, power control of the actuator, controllability, and the like.

  It is an object of the present invention to provide a transmission shift damper structure that efficiently prevents vibration of an elastic member.

  In order to solve the above-mentioned problem, a first transmission member that is rotated by transmission of an operation force of manual or actuator shift operation or selection operation is disposed at a position different from that of the first transmission member and relative to the first transmission member. A second transmission member provided rotatably and a storage chamber formed between the first transmission member and the second transmission member and transmitting the power of the first transmission member to the second transmission member. An elastic member that allows rotation of the second transmission member, and an operation unit that performs a shift operation or a selection operation by the rotation of the second transmission member, and fluid that regulates the operation of the elastic member is contained in the storage chamber. A selection mechanism that is filled and allows the fluid to flow into and out of the storage chamber is provided.

  The storage chamber may be formed by the first transmission member and the second transmission member.

  The selection mechanism regulates the outflow of fluid from the storage chamber and the inflow of fluid into the storage chamber when a rotational difference is generated between the first transmission member and the second transmission member, When there is no rotational difference between the first transmission member and the second transmission member, the restriction may be released.

  A fluid reservoir for storing the fluid may be formed, and the fluid stored in the fluid reservoir may be supplied to the storage chamber.

  Since the operation of the elastic member can be regulated by the fluid filled in the storage chamber, it is possible to efficiently suppress the vibration of the elastic member even when the impact from the operating portion is absorbed by the elastic member. It is. As a result, it is possible to efficiently prevent manual shift operation or feeling deterioration during shift operation, actuator power control deterioration, controllability deterioration, and the like.

It is explanatory drawing which shows notionally the structure of the operating device of a transmission. It is a top view which shows the structure of a damper apparatus. It is AA sectional drawing of FIG. It is BB sectional drawing of FIG.

  FIG. 1 is an explanatory diagram conceptually showing the structure of the transmission operating device. The operating device shown in FIG. 1 includes a shift and select shaft 1, a selection actuator 2 that performs a selection operation by sliding the shift and select shaft 1 in the axial direction, and the shift and select shaft 1 about its axis. And a shift actuator 3 that performs a shift operation by rotating the lens to the right.

  As a result of the select operation, the inner lever (operating portion) 4 mounted on the shift and select shaft 1 is integrally slid in the axial direction together with the shift and select shaft 1, and a shift fork (not shown) to be shifted in the transmission 6 is moved. select.

  As a result of the shift operation, the inner lever 4 is pivoted together with the shift and select shaft 1, and the shift fork selected as the shift target is slid to shift the transmission 6.

  The selection actuator 2 is constituted by a motor. The gear 7 provided on the output shaft 2 a of the motor 2, the gear 8 that always meshes with the gear 7, the pinion 11 provided on the transmission shaft 9 that rotates integrally with the gear 8, and the pinion 11 mesh Thus, the rotational power of the motor 2 is converted into the select operation force by the rack 1a formed on the shift and select shaft 1 as described above.

  The shift actuator 3 is also constituted by a motor. The gear 12 provided on the output shaft 3 a of the motor 3, the gear 13 that is always meshed with the gear 12, the gear 16 that is provided on the transmission shaft 14 that rotates integrally with the gear 13, The rotational power of the motor 3 is converted into a shift operation force by the gear 17 that is engaged with and supported by the spline coupling so as to be able to rotate integrally with the shift and select shaft 1 and slide in the axial direction. When the shift and select shaft 1 slides in the axial direction with respect to the gear 17, the select operation is allowed.

  A damper device 18 is provided between the shift actuator 3 and the shift and select shaft 1. By this damper device 18, the impact from the transmission 6 is absorbed and the impact force is prevented from being transmitted to the motor 3.

  Next, the configuration of the damper device 18 will be described in detail with reference to FIGS.

  2 is a plan view showing the configuration of the damper device, FIG. 3 is a cross-sectional view taken along the line AA in FIG. 2, and FIG. 4 is a cross-sectional view taken along the line BB in FIG. The damper device 18 is provided on the transmission shaft 14 in the illustrated example. The transmission shaft 14 is composed of a first rotating shaft 14a and a second rotating shaft 14b that have the same axis and are formed separately.

  A damper device 18 as a shift damper structure for a transmission is formed in a disk shape and is supported in a state where the thickness direction is directed in the vertical direction. The damper device 18 includes a first transmission member 19 that rotates integrally with the first rotation shaft 14a, and a first transmission member 19 that rotates integrally with the second rotation shaft 14b and can rotate relative to the first transmission member 19. The first transmission member 19 is accommodated in each of a plurality of accommodation chambers 22 formed between the second transmission member 21 stacked from above and the first transmission member 19 and the second transmission member 21 arranged at different positions. And a compression spring 23.

  Each storage chamber 22 is formed entirely by a concave portion 24 formed on the lower surface of the first transmission member 19 and recessed upward, and a second transmission member 21 that closes a portion opened to the lower side of the concave portion 24. . The storage chamber 22 is formed in an arc shape along the rotation direction of the first transmission member 19 and the second transmission member 21 in plan view. By injecting oil (fluid) into the storage chamber 22, the expansion / contraction operation of the compression spring 23 can be restricted.

  The plurality of storage chambers 22 are arranged at predetermined intervals in the rotation direction of the first transmission member 19 and the second transmission member 21. The second transmission member 21 has an operation portion 26 that is formed radially from the rotation center side of the second transmission member 21 and partitions the storage chamber 22 in the rotation direction.

  The compression spring 23 is accommodated in a compressed state between the inner wall surface of the accommodation chamber 22 and the operating portion 26 in a posture oriented in a tangential direction with respect to the arc shape of the accommodation chamber 22. The compression springs 23, 23 are arranged on both sides in the rotational direction of the operating portion 26, and elastically bias the operating portion 26 from both directions, so that the operating portion 26 is elastic at a neutral position in the storage chamber 22. Retained. According to this structure, the first transmission member 19 and the second transmission member 21 are elastically connected by the compression spring 23 and can transmit power from one to the other.

  Incidentally, when a large impact force acts on the second transmission member 21, the second transmission member 21 rotates relative to the first transmission member 19 against the elastic force of the compression spring 23 (the first transmission member). 19 and the second transmission member 21 cause a rotation difference), and the operating portion 26 is displaced toward one side in the rotation direction of the storage chamber 22.

  An oil reservoir (fluid reservoir) 27 that is recessed downward is provided at a position overlapping the storage chamber 22 in plan view on the upper surface of the first transmission member 19. In other words, an oil reservoir 27 is provided for each storage chamber 22. The oil reservoir 27 and the storage chamber 22 communicate with each other through a flow hole 28 extending in the vertical direction.

  Oil in the transmission case housing the transmission is supplied to the oil reservoir 27. The supply means may be a gear or the like that directly receives the oil scattered from the liquid surface, or the oil may be forcibly supplied to the oil reservoir 27 by a pump or the like.

  The oil accumulated in the oil reservoir 27 in this way flows into the accommodation chamber 22 through the flow hole 28, while the oil is injected into the accommodation chamber 22 due to the expansion and contraction operation of the compression spring 23. When the pressure increases, the oil flows out from the flow hole 28.

  Two flow holes 28 are provided for each oil reservoir 27. The operation part 26 in a neutral state in the storage chamber 22 is located between the two flow holes 28 in a plan view. When a rotation difference is generated between the first transmission member 19 and the second transmission member 21, the operating portion 26 rotates relatively from the neutral position of the storage chamber 22, and one of the two flow holes 28, 28 is It is closed by the operating part 26, and the inflow of oil from the oil reservoir part 27 into the storage chamber 22 is restricted. On the other hand, when there is no rotational difference between the first transmission member 19 and the second transmission member 21, the operating portion 26 is held in the neutral position of the storage chamber 22, and the two flow holes 28, 28 are both opened. It will be in the state.

  As shown in FIGS. 2 and 4, a selection mechanism 100 that selectively opens and closes the flow hole 28 is provided by the two flow holes 28, 28 and an operation unit 26 that opens and closes the flow hole 28. While the flow hole 28 is closed, the inflow / outflow of the oil in the storage chamber 22 is restricted, while such restriction is released by the opening operation.

  Since the selection mechanism 100 is closed when the impact force is absorbed by the damper device 18, the pressure of the oil filled in the storage chamber 22 increases. As the pressure rises, the expansion / contraction operation of the compression spring 23 is restricted, and the vibration caused thereby is suppressed. Incidentally, in order to prevent the pressure in the storage chamber 22 from becoming higher than necessary, the oil in the storage chamber 22 is discharged from the discharge oil passage 29 to the transmission case when the pressure exceeds a predetermined level.

  According to the shift damper structure for a transmission configured as described above, the impact force is efficiently absorbed by the elastic force of the damper device 18, and the vibration caused by the elastic absorption of the impact force. Can be suppressed by the oil in the storage chamber 22.

  Note that the present invention can also be applied to those in which the shift and select shaft 1 is manually selected and shifted. In this case, the two actuators 2 and 3 are omitted, and the shift and select shaft 1 is mechanically connected to a shift lever (not shown) for manual operation.

  Further, the fluid is not limited to oil, and any fluid may be used as long as it has a viscosity capable of regulating the vibration of the compression spring 23.

  In addition, a damper device 18 may be provided on the transmission shaft 9 or the like disposed between the select actuator 2 and the shift and select shaft 1. Alternatively, the damper device 18 may be provided on the shift and select shaft 1 itself.

2 Motor (actuator)
3 Motor (actuator)
4 Inner lever (acting part)
19 First transmission member 21 Second transmission member 22 Storage chamber 23 Compression spring (elastic member)
27 Oil reservoir (fluid reservoir)

Claims (4)

A first transmission member that is rotated by an operation force of manual or actuator shift operation or selection operation;
A second transmission member disposed at a position different from the first transmission member and provided to be rotatable relative to the first transmission member;
The second transmission member is accommodated in a storage chamber formed between the first transmission member and the second transmission member, and the power of the first transmission member is transmitted to the second transmission member to allow rotation of the second transmission member. An elastic member;
An operation part that performs a shift operation or a select operation by rotation of the second transmission member,
The storage chamber is filled with a fluid that regulates the operation of the elastic member, and includes a selection mechanism that allows the fluid to flow into and out of the storage chamber. Shift damper structure. The transmission shift damper structure according to claim 1, wherein the housing chamber is formed by the first transmission member and the second transmission member. The selection mechanism regulates the outflow of fluid from the storage chamber and the inflow of fluid into the storage chamber when a rotational difference is generated between the first transmission member and the second transmission member, The shift damper structure for a transmission according to claim 1, wherein the restriction is released when there is no rotational difference between the first transmission member and the second transmission member. A fluid reservoir for storing the fluid is formed;
The shift damper structure for a transmission according to any one of claims 1 to 3, wherein fluid accumulated in the fluid reservoir is supplied to the storage chamber.

Images