JPH0234513Y2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a transmission operating device.

BACKGROUND OF THE INVENTION A floor-type transmission operating device located away from a transmission is disclosed, for example, in Japanese Patent Application Laid-open No. 161621/1983. This is illustrated and explained in Figures 3 to 5.1
indicates a lever bracket, which is composed of a base plate 2 fixed to the floor and a mounting plate 3 constructed in a gate shape on the base plate 2. An upper bearing 5 and a lower bearing 6 are mounted on the upper wall 4 of the mounting plate 3. A spherical bearing 7 is fixed with screws 8. 9 indicates a change lever, and a spherical part 10 is attached near the middle lower end thereof,
This spherical part 10 is rotatably supported by a spherical bearing 7, and the X direction (select operation) and Y direction (shift operation) are orthogonal to each other with this spherical part 10 as the center.
It has become possible to operate it with ease. Reference numeral 11 denotes a bell crank constituting a select plate that is linked to the select operation of the change lever 9, and is mounted on one side wall 12 of the mounting plate 3 via a support shaft 13 so as to be freely rotatable in the vertical direction. Reference numerals 14 and 15 indicate two remote control cables connected to the control rods of the transmission (not shown), respectively.
The tip of one of the cables 14 is connected to the lower end of the change lever 9, and the other cable 14 is connected to the lower end of the change lever 9.
5 is connected to one end of the lever bracket 1 of the bell crank 11 located on the lower side. 16
indicates an arm constituting a select lever that transmits the tilting operation force when selecting the change lever 9 to the bell crank 11, and the center point O of the spherical part 10
The base 17 is perpendicular to the axis of the change lever 9 and is oriented in the direction of the tilting operation of the select operation of the change lever 9.
The spherical bearing 7 and the spherical portion 10 are coupled to each other by passing through the spherical bearing 7 and the spherical portion 10. A spherical portion 18 is formed at the tip of this arm 16, and this tip spherical portion 18 is connected to the other end of the bell crank 11 by a guide rail 19 and a slider 21 that is in sliding contact with and engaged with a guide groove 20 of this guide rail 19. They are connected via a guide mechanism 22. Specifically, the guide rail 19 is fixed to the bell crank 11, and the slider 21 is rotatably held by the tip ball portion 18.

Problems to be Solved by the Invention However, in the above-described structure, the arm 16 is fixedly connected to the change lever 9, and its distal end bulb 18 is connected to the bell crank 11 via the guide mechanism 22. When the tip bulb 18 is tilted in the X direction and selected from the state shown by the solid line in FIGS. 4 and 5 to the state shown by the imaginary line,
As shown in FIG. 5, the bell crank 1 moves upward in a straight line parallel to the axis of the change lever 9.
The distance _l 1 from the support shaft 13 of the bell crank 11 to the tip ball portion 18 becomes longer by the dimension δ, and the support shaft 13 of the bell crank 11 becomes longer by the dimension δ.
The distance l ₁ from to the tip bulb 18 and the distance from the support shaft 13 to the pin 23 that connects the cable 15
_l2 , that is, the lever ratio, changes depending on the magnitude of the select angle θ (see FIG. 4) of the change lever 9, and there is a possibility that the select operability of the change lever 9 may be impaired.

Therefore, the present invention provides a transmission operating device that can set the lever ratio of the bell crank to a constant value and improve the select operation of the change lever.

Means for Solving the Problems In the present invention, the spherical part constituting the center of tilting operation of the change lever is rotatably supported on a spherical bearing disposed on the upper wall of the lever bracket. A bell crank that interlocks the control rod of the transmission is attached to one side wall via a spindle so as to be rotatable in the circumferential direction of the spindle and movable in the axial direction of the spindle. A ball portion is provided at the tip of an arm that biases one side wall of the lever bracket in at least one of the axial directions of the support shaft by an elastic member, and transmits the tilting operation force of the change lever to the bell crank. The tip ball part is connected to the bell crank by forming a ball joint in cooperation with the tip ball part, and further, the ball part is formed of a hemisphere fixed to the change lever, and the top of the hemisphere is connected to the bell crank. A shaft body surrounding the change lever above the center of the tilting operation of the change lever is protruded from the center of the end face, and the base of the arm is fitted into the shaft body so as to be rotatable in the circumferential direction.

Function When the change lever is tilted in a direction that transmits the tilting force of the change lever to the bell crank, the arm rotates in the circumferential direction of the change lever and the bell crank follows the tilting operation of the change lever. By moving in the axial direction of the support shaft, the lever ratio of the bell crank is always kept constant regardless of the tilting operation angle of the change lever.

Embodiments Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings, in which the same parts as the conventional structure are denoted by the same reference numerals.

As shown in Figures 1 and 2, lever bracket 1
A hat-shaped socket 24 is fixed to the upper wall 4, and a spherical bearing 26 consisting of an upper bearing 25a and a lower bearing 25b is built into the socket 24, and a spherical part 27 forming the center of tilting operation of the change lever 9 is installed. is rotatably supported by a spherical bearing 26. The upper bearing 25 is placed between the ceiling of the socket 24 and the upper bearing 25a.
A spring 28 is interposed to slidably press a to the spherical portion 27. An annular elastic body 29 made of rubber is interposed between the inner part of the socket 24 of the lever bracket 1 and the lower bearing 25b and urges the lower bearing 25b upward.
A lever bracket 1 is attached to the inner peripheral edge of this elastic body 29.
A dust boot 31 is integrally formed to seal the gap between the through hole 30 and the change lever 9. Also, a support shaft 13 is attached to one side wall 12 of the lever bracket 1.
At one end of the bell crank 32, which is rotatably mounted in the circumferential direction of the vertical support shaft 13 through the bell crank 32 and forming a separate plate, there are two remote control rods connected to a transmission control rod (not shown). The other cable 15 ends of the cables 14 and 15 are connected. Further, the bell crank 32 is attached to one side wall 12 of the lever bracket 1 so as to be movable in the axial direction of the support shaft 13.
a biases the support shaft 13 in at least one of the axial directions. Specifically, a support shaft 13 is fixed to one side wall 12 of the lever bracket 1, and an intermediate portion of the bell crank 32 of this support shaft 13 is fixed to the support shaft 13.
A coil spring as an elastic member 13a is externally fitted to a portion between one side wall 12 of the support shaft 13 and the bell crank 32. , both ends of this coil spring 13a are brought into contact with one side wall 12 and the bell crank 32, and this coil spring 13a is
The bell crank 32 is urged away from the one side wall 12 by the elastic force of the bell crank 32 and comes into contact with the head of the support shaft 13. Reference numeral 33 indicates an arm that transmits the tilting force of the change lever 9 in the X direction to the bell crank 32, and a ball portion 18 is provided protruding from the tip of this arm 33.
This tip ball portion 18 is connected to the other end of the bell crank 32 by forming a ball joint 34 in cooperation with the tip ball portion 18. This ball joint 3
Reference numeral 4 includes a ball end portion 18 and a bearing 36 which is equipped with a ball seat 35 that rotatably supports the ball end portion 18 and is mounted on the bell crank 32. Further, the base portion 37 of the arm 33 is connected to the change lever 9 by the spherical portion 27 so as to be rotatable only in the horizontal direction. Specifically, the spherical part 2
7 is fixed to the change lever 9.
The outer periphery is rotatably fitted into a shaft 39 that projects from the center of the flat upper end surface of this hemisphere 38 and surrounds the change lever 9 on the tilting operation center O of the change lever 9 through a bearing hole 40. The outer circumferential surface 43 is fitted into the base 37 of the arm 33, in which the surface 41 is formed into a convex spherical surface that is smoothly continuous with the convex spherical surface 42 of the hemisphere 38, and the protruding portion above the base 37 of the shaft body 39.
and a spacer 44 formed into a convex spherical surface that smoothly continues to the convex spherical surface 41 of the base 37. The spacer 44 and the arm 33 are prevented from coming off by a retaining ring 45 fitted to a protruding portion of the shaft body 39 above the spacer 44. In addition,
Reference numeral 46 designates an escape hole for the arm 33 formed in the socket 24 and the spherical bearing 26.

According to the above embodiment structure, the change lever 9
When the change lever 9 is tilted in the direction of transmitting the tilting force to the bell crank 32, that is, when the select operation is performed as shown by the imaginary line in FIG.
Following the tilting operation, the arm 33 moves upward, but at this time, since the distal end ball portion 18 of the arm 33 is connected to the other end of the bell crank 32 by a ball joint 34, the arm 33 moves upward. The tip receives a restricting force from the bell crank 32 in the circumferential direction of the change lever 1, and this restricting force causes the arm 33 to
The base 37 rotates in the circumferential direction of the shaft body 39, and the arm 33 rotates in the circumferential direction of the change lever 1. In parallel with this, the other end of the bell crank 32 receives a moving force from the arm 33 in the axial direction of the support shaft 13 as a reaction force of the above-mentioned regulating force, and this moving force causes the bell crank 32 to move due to the elastic force of the elastic member 13a. It moves in the axial direction of the support shaft 13 against the pressure and approaches one side wall 12 of the lever bracket 1. Such rotation of the arm 33 in the circumferential direction of the change lever 9 and the bell crank 3
2, the tip ball portion 18 of the arm 33 moves upward in an arcuate trajectory around the support shaft 13 as shown by the imaginary line in FIG. The lever ratio is always kept constant.

In the above embodiment, the tilting operation force transmitted from the change lever 9 to the bell crank 32 is used as the selection operation force, but the same applies even when the tilting operation force is configured as the shift operation force. effective.

Effects of the invention As described above, according to the invention, when the change lever is selected, the rotation direction of the arm is changed by rotating the change lever in the circumferential direction of the arm and moving the support shaft of the bell crank in the axial direction. It absorbs the displacement caused by the difference in the rotation direction of the bell crank,
The lever ratio of the bell crank can always be kept constant without being affected by the tilting operation angle of the change lever. Moreover, since the bell crank is biased against one side wall of the lever bracket in the axial direction of the support shaft by an elastic member, the movement of the arm and bell crank is reduced by reducing rattling in this support shaft portion. It can also be made smoother. In addition, since the base of the arm is located above the center of tilting operation of the change lever, when shifting the change lever,
The arm rotates but does not move the bell crank. For this reason, there is a practical effect of improving the tilting operability of the change lever.

[Brief explanation of the drawing]

Fig. 1 is a partially cutaway front view of an embodiment of the present invention, Fig. 2 is a side view of the same embodiment, Fig. 3 is a perspective view of a conventional transmission operating device, and Fig. 4. 5 is a partially cutaway front view of the main part of the conventional device, and FIG. 5 is an explanatory diagram of the operation of the conventional device. 1...Lever bracket, 4...Top wall, 9...
Change lever, 12... One side wall, 13... Support shaft, 13a... Elastic member, 18... Tip bulb, 2
6... Spherical bearing, 27... Spherical part, 32... Bell crank, 33... Arm, 34... Ball joint, 37... Base, 38... Hemisphere, 39...
...Axis body, O...Tilting operation center.

Claims (1)

[Scope of utility model registration request] A bell crank which rotatably supports a spherical part constituting the center of tilting operation of the change lever on a spherical bearing disposed on the upper wall of the lever bracket, and interlocks the control rod of the transmission with one side wall of the lever bracket. is attached via a support shaft so as to be rotatable in the circumferential direction of the support shaft and movable in the axial direction of the support shaft, and the bell crank is attached to one side wall of the lever bracket by means of an elastic member to at least support the support shaft. A ball is protruded from the tip of an arm that biases in one of the axial directions and transmits the tilting force of the change lever to the bell crank, and the ball is connected to the bell crank. Together, they form a ball joint and connect.
Further, the spherical part is formed of a hemisphere fixed to the change lever, and a shaft body that surrounds the change lever on the tilting operation center of the change lever is protruded from the center of the upper end surface of the hemisphere, and the shaft body is provided with a shaft body that surrounds the change lever on the center of the tilting operation of the change lever. A transmission operating device characterized in that a base portion is fitted so as to be rotatable in a circumferential direction.