JPH0828700A - Operating device of transmission for automobile - Google Patents

Abstract

PURPOSE:To effectively convert the longitudinal motion of two rods which are close to each other into the sliding or rotational motion of an operating shaft, realize the miniaturization, and eliminate the sense of incompatibility in the operating feeling. CONSTITUTION:A fork operating shaft 12 is slidably and turnably mounted on a case 11b of a transmission 11 in the axial direction. An operating rod 13 to operate the operating shaft is mounted on a driver's seat. A first lever 12a to turn this operating shaft around the axis is fixed to the operating shaft, and a second lever 14 to slide the operating shaft in the axial direction is pivotably supported on the case. The tip of the first lever is connected to the operating rod by a first rod 16, and one end of the second lever is connected to the operating rod by a second rod 17. An annular body 18 is fitted to the operating shaft non-slidably in the axial direction and turnably around the axis. A ball part is insertable, and a socket 14a to rotatably store the ball part is provided on the other end of the second lever.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle transmission operating device for remotely operating a vehicle transmission with an operating rod provided in a driver's seat.

[0002]

2. Description of the Related Art Conventionally, in an operating device for a transmission such as a truck, an operating rod provided in a driver's seat and a fork operating shaft provided in the transmission are connected by a rod. This connection system includes a one-line system using one rod and a two-line system using two rods or wire cables. On the other hand, the fork operation shaft of the transmission slides in the operation axis direction and rotates around the axis to select the transmission gear inside the transmission. For this reason, if the connection method is one,
It is said that the operation feeling is generally dull because the operation of the sliding direction and the rotating direction is transmitted to the rod of the book, and the operation sensitivity is inferior to that of the two-rod type. In the case of the two-wire type, the longitudinal movement of the rod or wire cable due to the operation of the operating rod is converted into sliding or rotary movement of the operating shaft near the transmission. If the wire cable is used, this conversion is performed by laying the wire cable.When using the rod, the forward / backward movement of the rod is converted into a rotational movement by using a crank mechanism, and the rotational movement is changed in angle. It is converted into linear motion by the link mechanism.

[0003]

However, there is a limit to the wiring of the wire cable in the vicinity of the transmission because of restrictions on the bending radius of the cable and restrictions on the total bending angle.
When a rod is used, the crank mechanism and the link mechanism use a link mechanism that absorbs an error that occurs when the rotary motion is converted into a linear motion, so that the operating device becomes larger and the operation feeling is increased. Also, the use of the link mechanism gave a feeling of strangeness. An object of the present invention is to effectively convert the back-and-forth movement of two adjacent rods or wire cables into sliding or rotating movement of the operating shaft,
Another object of the present invention is to provide an operating device for a transmission for an automobile, which is compact and does not give an uncomfortable feeling to the operation.

[0004]

The structure of the present invention for achieving the above object will be described with reference to FIGS. 1 to 3 corresponding to the embodiments. According to the present invention, the fork operation shaft 12 is attached to the case 11b of the transmission 11 so as to be slidable in the axial direction and rotatable about the axis, and the operation shaft 12 is attached to the driver's seat in the axial select direction and the axial center. An operating rod 13 for operating in the shift direction around is provided, a first lever 12a for rotating the operating shaft 12 around the axis is fixed to the operating shaft 12, and the operating shaft 12 is attached to the case 11b. The second lever 14 for sliding in the direction is pivotally supported, and the tip of the first lever 12a and the operating rod 13 are the first wire cable or the first rod 1.
6, the one end of the second lever 14 and the operating rod 13
And are improvements in the operating device of the transmission for a vehicle connected by the second wire cable or the second rod 17. The characteristic configuration is that an annular body 18 is fitted onto the operating shaft 12 so as not to be slidable in the axial direction and rotatable about its axis, and a stud 18b having a ball portion 18d at its tip is provided upright on the annular body 18. Thus, the upright ball portion 18d can be inserted, and the socket 14a that rotatably accommodates the ball portion 18d in the inserted state is provided at the other end of the second lever 14. In addition, the ball portion 18d is attached to the resin bearing 22.
The ball portion 18d can be inserted into the socket 14a together with the resin bearing 22.

[0005]

When the operating rod 13 is operated, the first wire cable or the first rod 16 and the second wire cable or the second rod 17 are operated. The first wire cable or first rod 16 rotates the operating shaft 12 via the first lever 12a, and the second wire cable or second rod 17 rotates the second lever 14. The socket 14a provided at the other end of the second lever 14 rotates while accommodating the ball portion 18d. The annular body 18 slides the operation shaft 12 with the movement of the ball portion 18d. The rotation of the second lever 14 causes the operation shaft 1
The error in converting into the linear motion of 2 is absorbed by the rotation of the annular body 18 and the ball portion 18d slightly coming out of the socket 14a.

[0006]

An embodiment of the present invention will be described in detail with reference to the drawings. As shown in FIGS. 1 to 4, the vehicle includes a transmission 11 for effectively producing the output of the engine according to the running state. Although not shown, a plurality of transmission gears are arranged on the main shaft inside the transmission 11, and the shifter lever 1
A desired transmission gear can be selected by 1a. The shifter lever 11a is the fork operating shaft 1
The fork operating shaft 12 is slidably moved in the axial direction and is attached to the transmission 11 so as to be rotatable about its axis, and is slid or rotated to move the fork operating shaft 12 via the shifter lever 11a. Making a choice.

At the driver's seat, an operating rod 13 is provided for operating the operating shaft 12 in the select direction in which it slides in the axial direction and in the shift direction in which it rotates about the axis. In this example, the operating rod 13 is provided so as to project upward from the inside of the box body 13a, and has a slot 13b for moving the operating rod 13 in the vehicle width direction.
And lateral grooves 13c corresponding to the number of transmission gears are provided in the direction orthogonal to the groove 13b, that is, in the front-back direction with respect to the vehicle traveling direction. The operating rod 13 has a slot 13 as shown by the solid arrow in FIG.
The operation shaft 12 is slid when moved in the vehicle width direction F along b, and is rotated when moved in the front-rear direction G along the lateral groove hole 13c.

A first lever 12a for rotating the operation shaft 12 about its axis is fixed to the operation shaft 12 via a fixing portion 12d, and the first lever 12a is operated by moving the tip end of the first lever 12a back and forth. The shaft 12 is adapted to rotate. An auxiliary lever 12e is provided upright on the opposite side of the fixed portion 12d coaxially with the first lever 12a, and a rod of the power cylinder 12f is connected to the tip of the auxiliary lever 12e. When attempting to rotate the operation shaft 12 via the first lever 12a, the power cylinder 12f ensures the operation by extending or contracting the rod of the cylinder 12f in the direction in which the operation shaft 12 is to be rotated. It is designed to reduce the burden.

The case 11b of the transmission 11 includes an operating shaft 12
A second lever 14 is provided for sliding the shaft in the axial direction. The second lever 14 is processed into an L-shape, and its substantially center is pivotally supported by a pivotal support member 11c provided on the case 11b, and the operation shaft 12 can be slid by rotating the second lever 14. You can do it. The tip of the first lever 12a and the operating rod 13 are connected by a first rod 16, and the operation rod 13 in the shift direction G moves to move the first lever.
The operation shaft 12 is rotated via the lever 12a, and
One end of the lever 14 and the operating rod 13 are connected by a second rod 17, and the movement of the operating rod 13 in the select direction F rotates the second lever 14.

As shown in FIGS. 1 and 2, an annular body 18 is fitted to the end of the operating shaft 12. The ring-shaped body 18 is composed of a base portion 18a having an inverted horseshoe shape and a stud 18b having a ball portion 18d at its tip, and is integrally formed. A circular hole 18c is provided in the center of the base portion 18a, and the operation shaft 1
It is fitted in 2 through a pair of bushes 19, 19. After being fitted, the female screw portion 1 provided at the end of the operation shaft 12
It is fixed to 2b by a double nut 21 to prevent the annular body 18 from sliding in the axial direction. The bushes 19 and 19 are made of a resin having a small friction coefficient, so that the annular body 18 can smoothly rotate with respect to the operation shaft 12. Stud 18b having ball portion 18d at the tip
Is erected substantially in the center of the plane portion of the side surface of the annular body 18.

A socket 14a is provided at the other end of the second lever 14.
And the socket 14a is provided with a recess 14b into which the ball portion 18d of the stud 18b is inserted. The ball portion 18d receives the ball portion 18d and is inserted into the recess 14b through a resin bearing 22 having a cylindrical outer shape. The recess 14b is a circular hole having a diameter slightly larger than the outer diameter of the resin bearing 22, and the resin bearing 22 is rotatable and detachable while the resin bearing 22 is inserted.
To house. The accommodating portion for accommodating the ball portion 18d of the resin bearing 22 includes a dome portion 22a having a diameter slightly larger than the diameter of the ball portion 18d and a tubular portion 22b continuous with the dome portion 22a and slightly shorter than the radius of the ball portion 18d. Have.
As a result, the socket 14a is rotatable and detachably attached with the ball portion 18d inserted therein.
Will be accommodated. A dust cover 18e is provided around the lower portion of the socket 14a and the lower portion of the stud 18b to prevent dust.

The operation of the thus-configured operating device for the automobile transmission will be described. When the driver changes the transmission gear according to the vehicle speed, the driver can operate the operating rod 1 provided in the driver's seat.
3 is moved to a desired position with a clutch (not shown) stepped on. The movement of the operating rod 13 is transmitted to the transmission 11 via the first rod 16 and the second rod 17. Here, when the operating rod 13 is moved in the front-back direction, the first rod 1
6 moves back and forth, the first lever 12 provided on the operation shaft 12
The operation shaft 12 is rotated via a. When the operating rod 13 is moved in the vehicle width direction, the second lever 14 is rotated via the second rod 17. Since the socket 14a provided at the other end of the second lever 14 rotates while accommodating the ball portion 18d, the annular body 18 slides the operation shaft 12 along with the movement of the ball portion 18d. The error in converting the rotation of the second lever 14 into the linear motion of the operation shaft 12, that is, the dimension D with respect to the shaft center when rotating from the solid line position to the broken line position in FIG. 4, is circular as shown in FIG. It is absorbed by the rotation of the body 18 and the ball portion 18d slightly coming out of the socket 14a. As a result, the forward and backward movements of the first rod 16 and the second rod 17 due to the movement of the operating rod 13 are effectively converted into the movement of the operating shaft 12, and as a result, the shift gear desired by the driver can be changed.

In the above embodiment, the first rod 16 and the second rod 17 are used to control the movement of the operating rod 13 by the transmission 1.
However, it may be transmitted using a wire cable. In the above embodiment, the ball portion 18d is inserted into the recess 14b of the socket 14a via the resin bearing 22. It need not be provided in particular. Further, in the above embodiment, the annular body is prevented from sliding in the axial direction by the double nut, but the single nut may prevent the sliding at the step of the operating shaft. Further, in the above embodiment, the resin bearing 22 for accommodating the ball portion 18d is constructed by combining the dome portion 22a and the tubular portion 22b, but as shown in FIG.
The ball portion 18 is provided in a spherical shape so as to surround the vicinity of the base portion of
d may be accommodated. In this case, the resin bearing 22 is fitted into the ball portion 18d due to its elasticity, and the socket 14a
When the ball portion 18d slightly comes out of the socket, the resin bearing 22 follows the ball portion 18d and comes out of the socket 14a as shown in detail in FIG.

[0014]

As described above, according to the present invention, the second lever slides the operating shaft through the annular body 18 by rotating the socket while the ball portion is accommodated therein. The back-and-forth movement of two adjacent rods or wire cables can be effectively converted into sliding or rotating movement of the operating shaft. Further, the error in converting the rotation of the second lever into the linear motion of the operation shaft is absorbed by the rotation of the annular body and the ball partly coming out of the socket, so that the operating device of the present invention has a link mechanism. It can be downsized without the need and does not give an uncomfortable feeling to the operation.

[Brief description of drawings]

FIG. 1 is a sectional view taken along line AA of FIG. 3 showing an embodiment of the present invention.

FIG. 2 is a sectional view taken along line BB of FIG.

FIG. 3 is a configuration diagram of an operating device showing an embodiment of the present invention.

FIG. 4 is a view on arrow C of FIG.

5 is a view showing a state in which the second lever is rotated, EE of FIG.
FIG.

FIG. 6 is a view corresponding to FIG. 2 showing another embodiment of the present invention.

FIG. 7 is a view corresponding to FIG. 5 showing another embodiment of the present invention.

[Explanation of symbols]

 11 gearbox 11b case 12 operation shaft 12a first lever 13 operation rod 14 second lever 14a socket 16 first rod 17 second rod 18 annular body 18b stud 18d ball portion 22 resin bearing

Claims (2)

[Claims] 1. A fork operating shaft (12) is attached to a case (11b) of a transmission (11) so as to be slidable in an axial direction and rotatable about an axis, and the operating shaft (12) is installed in a driver's seat. ) Is provided with an operating rod (13) for operating the select direction in the axial direction and the shift direction around the axis, and the operating axis (12) is for rotating the operating axis (12) around the axis. The first lever (12a) is fixed, and the case (11b) is pivotally supported by the second lever (14) for sliding the operation shaft (12) in the axial direction.
The tip of (12a) and the operating rod (13) are connected by a first wire cable or a first rod (16), and the second lever (1)
In an operating device of a transmission for an automobile, wherein one end of 4) and the operating rod (13) are connected by a second wire cable or a second rod (17), the operating shaft (12) cannot slide in the axial direction. The stud (18b) having a ball portion (18d) at its tip is erected on the annular body (18), and A socket (14a) for accommodating the ball portion (18d) is provided at the other end of the second lever (14) so that the ball portion (18d) can be inserted and can rotate in the inserted state. An operating device for an automobile transmission. 2. The ball portion (18d) is rotatably housed in a resin bearing (22), and the ball portion (18d) is configured to be insertable into a socket (14a) together with the resin bearing (22). 1. The operating device for a vehicle transmission according to 1.