JP2021107725A - Detent mechanism, manual transmission, and vehicle - Google Patents

Abstract

To provide a detent mechanism which optimizes operability of a control lever, and to provide a manual transmission and a vehicle.SOLUTION: A detent mechanism positions a rod or a shift arm which moves in a first direction in conjunction with a control lever movable to multiple shift positions. The detent mechanism includes: an irregularity part; a fixing part which is provided at the rod or the shift arm and to which the irregularity part is fixed; and a detent part which contacts with the irregularity part and moves forward or rearward in a moving direction in response to movement of the irregularity part. The irregularity part is configured so that a load applied to the detent part when the irregularity part moves with the rod or the shift arm changes in a second direction orthogonal to the first direction and the moving direction. The fixing part is configured to be rotatable relative to the rod or the shift arm so that the detent part passes the side, at which a load is small, of the irregularity part when the rod or the shift arm moves.SELECTED DRAWING: Figure 2

Description

The present disclosure relates to detent mechanisms, manual transmissions and vehicles.

Conventionally, in a vehicle equipped with a transmission such as a manual transmission, a detent mechanism for positioning a rod or a shift arm that moves in conjunction with an operation lever of the transmission is provided. The detent mechanism has an uneven portion and a detent portion. The uneven portion is provided on the rod or the shift arm and has a plurality of concave portions. The detent portion is configured to fit into any of a plurality of recesses in the concave-convex portion that moves with the rod or shift arm.

When the operating lever moves to any of the plurality of shift positions, the rod or shift arm moves in a predetermined direction in conjunction with the movement, and the detent portion is fitted into any of the plurality of concave portions of the concave-convex portion, so that the rod or the shift arm is fitted. The shift arm is positioned.

For example, Patent Document 1 discloses a configuration in which a plurality of detent portions are provided. In this configuration, the operating force of the rod is made different by making the detent portion fitted in any of the plurality of recesses different between the neutral position and the shifting position.

Japanese Unexamined Patent Publication No. 2003-269609

However, since the shape of the wall constituting the recess is the same in the moving direction of the rod or the shift arm, the operability of the operating lever changes depending on whether the detent portion comes out of the recess or enters the recess. Therefore, there is a possibility that the operability may not be optimum when the detent portion exits the recess and when the detent portion enters the recess.

An object of the present disclosure is to provide a detent mechanism, a manual transmission and a vehicle capable of optimizing the operability of an operating lever.

The detent mechanism for this disclosure is
A detent mechanism that positions a rod or shift arm that moves in the first direction in conjunction with an operating lever that can move to multiple shift positions.
Uneven part and
A fixed portion provided on the rod or shift arm and to which the uneven portion is fixed, and a fixed portion.
A detent portion that comes into contact with the uneven portion and advances and retreats in the advancing / retreating direction according to the movement of the uneven portion.
With
The uneven portion is configured so that the load applied to the detent portion when moving together with the rod or the shift arm changes in the first direction and the second direction orthogonal to the advancing / retreating direction.
The fixed portion is configured to be rotatable with respect to the rod or shift arm so that when the rod or shift arm moves, the detent portion passes through the side of the uneven portion where the load is small.

The manual transmission related to this disclosure is
It is equipped with the above-mentioned detent mechanism.

The vehicle pertaining to this disclosure
Equipped with the above manual transmission.

According to the present disclosure, the operability of the operation lever can be optimized.

It is a figure which shows the structure of the vehicle which provided the detent mechanism which concerns on embodiment of this disclosure. It is a figure which shows the detent mechanism which concerns on this embodiment. It is a figure which shows the structure of the detent part. It is a figure for demonstrating the relationship between the detent part and the uneven part when a rod moves. It is a figure for demonstrating the relationship between the detent part and the uneven part when a rod moves. It is a perspective view of the concavo-convex portion. It is a figure which shows the outer shape of the left side part of a concavo-convex part. It is a figure which shows the outer shape of the right-hand side part of the concavo-convex part. It is a figure for demonstrating how the detent part comes out from a recess. It is a figure for demonstrating how the detent part enters a recess. It is a figure for demonstrating the state of rotation of a fixed part. It is a figure for demonstrating the state of rotation of a fixed part. It is a figure which shows an example of the movement locus of a detent part in a concavo-convex part. It is a figure which shows the outer shape of the left side part of the concavo-convex part which concerns on the modification. It is a figure which shows the outer shape of the right side part of the concavo-convex part which concerns on the modification. It is a figure which shows the deformation example of the concavo-convex portion formed in an annular shape. It is a figure which shows the detent mechanism which has a pair of annular members.

Hereinafter, embodiments of the present disclosure will be described in detail with reference to the drawings. FIG. 1 is a diagram showing a configuration of a vehicle 1 provided with a detent mechanism 100 according to an embodiment of the present disclosure.

As shown in FIG. 1, the vehicle 1 has a propeller shaft 2, a differential gear 3, a drive wheel 4, an engine 5, a transmission 6, and an operating lever 7.

The engine 5 is an internal combustion engine such as a diesel engine. The power of the engine 5 is transmitted to the transmission 6 via a clutch (not shown), and the power transmitted to the transmission 6 is transmitted to the drive wheels 4 via the propeller shaft 2 and the differential gear 3.

The transmission 6 is a transmission such as a manual transmission, and constitutes a plurality of transmission stages. In other words, the transmission 6 has a transmission mechanism or the like that connects or disconnects the output shaft of the engine 5 and the propeller shaft 2 and changes the gear ratio.

The operation lever 7 is a lever for switching the shift stage of the transmission 6 by the operation of the driver, and is configured to be movable to a plurality of shift positions. The plurality of shift positions are, for example, a predetermined first traveling stage position, a neutral position, a predetermined second traveling stage position, and the like. The operating lever 7 is connected to the rod 110 of the detent mechanism 100 provided in the transmission 6. The predetermined first running stage position and second running stage position are shift positions such as, for example, a third speed position and a fourth speed position.

As shown in FIG. 2, the detent mechanism 100 is a mechanism for positioning the rod 110, and has a detent portion 120, an uneven portion 130, and a fixing portion 140 in addition to the rod 110.

The rod 110 moves in the first direction in conjunction with the operating lever 7. The first direction is, for example, the front-back direction in FIG.

For example, when the operating lever 7 moves from the second traveling stage position to the first traveling stage position via the neutral position, the rod 110 moves in the rear direction and moves from the first traveling stage position to the second traveling stage position via the neutral position. When moving to the traveling stage position, it moves forward.

The uneven portion 130 is fixed to the fixing portion 140 provided on the rod 110, and has recesses 131, 132, and 133 arranged in the first direction. The recess 131 is arranged in the middle of the three recesses 131, 132, 133. The recess 132 is arranged next to the recess 131. The recess 133 is arranged next to the front of the recess 131.

The fixing portion 140 is formed in a tubular shape, and is provided on the rod 110 by being passed through the rod 110.

The detent portion 120 is for positioning the rod 110 in the first direction, and has a ball 122 and an urging member 123 as shown in FIG.

The ball 122 is provided at the tip end portion of the detent portion 120, and is urged toward the uneven portion 130 side by the urging member 123. As a result, the ball 122 is configured to be in contact with the uneven portion 130 and to be able to advance and retreat in the vertical direction (advance / retreat direction) with respect to the uneven portion 130.

Further, the ball 122 is configured to fit into any of the three recesses 131, 132, 133 according to the position of the operating lever 7. Specifically, the ball 122 moves relatively between adjacent recesses while advancing and retreating with respect to the concave-convex portion 130 against the urging force of the urging member 123 in response to the movement of the concave-convex portion 130.

Note that FIG. 2 shows an example in which the detent portion 120 is located in the central recess 131. Further, when the detent portion 120 is located in the central recess 131, it is assumed that the operating lever 7 is located in the neutral position. When the detent portion 120 is located in the recess 132 at the rear end, it is assumed that the operating lever 7 is located at the second traveling stage position. When the detent portion 120 is located in the recess 133 at the front end, it is assumed that the operating lever 7 is located at the first traveling stage position.

For example, in the detent portion 120 located in the recess 131 in the middle, as shown in FIG. 4A, when the operating lever 7 moves from the neutral position to the second traveling stage position, the rod 110 moves to the front side. In this case, the detent portion 120 escapes from the recess 131 and enters the recess 132 adjacent to the rear.

Further, as shown in FIG. 4B, when the operating lever 7 moves from the neutral position to the first traveling stage position, the rod 110 moves to the rear side. In this case, the detent portion 120 escapes from the recess 131 and enters the recess 133 adjacent to the front.

By doing so, the rod 110 that moves in conjunction with the movement of the operating lever 7 is positioned.

Further, as shown in FIGS. 5, 6A and 6B, the recesses 131, 132, and 133 are configured so that the inclination angles of the wall portions forming the respective spaces are different in the second direction. FIG. 5 is a perspective view of the uneven portion 130. FIG. 6A is a diagram showing the outer shape of the left side portion of the uneven portion 130, and FIG. 6B is a diagram showing the outer shape of the right side portion of the uneven portion 130. The uneven portion 130 has a shape that follows the shape of the rod 110, but is shown in FIG. 5 and the like as a planar shape in consideration of the legibility of the drawing and the like.

The second direction is, for example, a front-rear direction (first direction) and a left-right direction orthogonal to the up-down direction. The second direction also includes a direction in which the angle formed by the first direction is slightly deviated from 90 °.

For example, the recess 131 is composed of a rear wall 131B and a front wall 131C located on both sides of the bottom 131A in the front-rear direction. The rear wall 131B and the front wall 131C are configured so that the inclination angle changes in the left-right direction.

The rear wall 131B is inclined so as to be located upward as it goes backward, and the inclination angle becomes smaller as it goes from left to right. Therefore, the rear wall 131B is longer on the right side B2 than on the left side B1. Further, the upper end T1 of the rear wall 131B is located rearward toward the right side.

The front wall 131C is inclined so as to be located upward as it goes forward, and the inclination angle increases as it goes from left to right. Therefore, the front wall 131C is shorter on the right side C2 than on the left side C1. Further, the upper end T2 of the front wall 131C is located rearward toward the right side.

Further, the recess 132 is composed of a rear wall 132B and a front wall 132C located on both sides of the bottom 132A in the front-rear direction. The front wall 132C is configured so that the inclination angle changes in the left-right direction.

The front wall 132C is inclined so as to be located upward as it goes forward, and the inclination angle increases as it goes from left to right. Therefore, the front wall 132C is shorter on the right side C4 than on the left side C3. Further, the front wall 132C is connected to the upper end T1 of the rear wall 131B of the recess 131.

The rear wall 132B is inclined so as to be positioned upward toward the rear, and is configured to have the same inclination angle in the left-right direction, but is configured so that the inclination angle changes in the left-right direction. You may.

Further, the recess 133 is composed of a rear wall 133B and a front wall 133C located on both sides of the bottom 133A in the front-rear direction. The rear wall 133B is configured so that the inclination angle changes in the left-right direction.

The rear wall 133B is inclined so as to be located upward as it goes backward, and the inclination angle becomes smaller as it goes from left to right. Therefore, the rear wall 133B is longer on the right side B4 than on the left side B3. Further, the rear wall 133B is connected to the upper end T2 of the front wall 131C of the recess 131.

The front wall 133C is inclined so as to be positioned upward as it goes forward, and is configured so that the inclination angle is the same in the left-right direction, but the inclination angle is changed in the left-right direction. You may be.

With this configuration, the uneven portion 130 is configured so that the load applied to the detent portion 120 when moving together with the rod 110 changes in the left-right direction.

When the detent portion 120 comes out of the recess, the smaller the inclination angle of the wall portion, the smaller the load when the ball 122 of the detent portion 120 goes up the wall portion. That is, the smaller the inclination angle of the wall portion, the smaller the load applied to the detent portion 120.

For example, as shown in FIG. 7A, since the inclination angle of the left side C1 is smaller than that of the right side C2, the load applied to the detent portion 120 on the left side C1 side (arrow X1) is applied to the detent portion 120 on the right side C2 side. It is smaller than (arrow X2). Therefore, when the detent portion 120 moves from the bottom portion 131A to the front side in the recess 131, it is easier for the detent portion 120 to climb the wall portion when it rises from the left side C1 side.

Further, the uneven portion 130 is configured so that the suction force to the detent portion 120 when moving together with the rod 110 changes in the left-right direction.

When the detent portion 120 enters the recess, the larger the inclination angle of the wall portion, the easier it is for the ball 122 of the detent portion 120 to enter the recess. That is, the larger the inclination angle of the wall portion, the greater the suction force to the detent portion 120.

For example, as shown in FIG. 7B, since the left side B3 has a larger inclination angle than the right side B4, the suction force (arrow X3) to the detent portion 120 on the left side B3 side is the detent portion 120 on the right side B4 side. It is larger than the suction force to (arrow X4). Therefore, when the detent portion 120 enters the recess 133 from the upper end T2 on the front side of the recess 131, the left side B3 of the detent portion 120 is more likely to enter the recess 133.

As described above, the concave portion of the concave-convex portion 130 in the present embodiment is composed of two walls including a first portion having a different shape from each other and a wall portion in which the second portion is arranged in the left-right direction.

The first portion is a portion where the suction force to the detent portion 120 when the detent portion 120 enters the recess is larger than that of the second portion on the same wall. In other words, the tilt angle of the first portion is larger than the tilt angle of the second portion on the same wall.

The second portion is a portion where the load applied to the detent portion 120 when the detent portion 120 comes out of the recess is smaller than that of the first portion on the same wall. In other words, the tilt angle of the second portion is smaller than the tilt angle of the first portion on the same wall.

The first portion according to the present embodiment is a portion of the recess 131 including the left side B1 side of the rear wall 131B and a portion including the right side C2 side of the front wall 131C. The first portion is a portion of the recess 132 that includes the right side C4 of the front wall 132C and a portion of the recess 133 that includes the left side B3 of the rear wall 133B.

The second portion according to the present embodiment is a portion of the recess 131 including the right side B2 side of the rear wall 131B and a portion including the left side C1 side of the front wall 131C. The second portion is a portion of the recess 132 that includes the left side C3 of the front wall 132C and a portion of the recess 133 that includes the right side B4 of the rear wall 133B.

Further, as shown in FIG. 8A, the uneven portion 130 is configured to have a width sufficient to accommodate two detent portions 120 in the left-right direction. The fixing portion 140 is configured to be rotatable with respect to the rod 110 (not shown).

The rotatable range of the fixed portion 140 is not particularly limited, but it is preferable that the detent portion 120 is restricted to a range that does not protrude from the uneven portion 130.

Since the fixing portion 140 is freely rotatable with respect to the rod 110, when the uneven portion 130 moves, the fixing portion 140 is attached to the rod 110 so that the detent portion 120 passes through the side where the load on the uneven portion 130 is small. Rotate against.

For example, suppose that the driver moves the operating lever 7 from the neutral position to the first traveling stage position. In this case, since the uneven portion 130 moves in the rear direction together with the rod 110, the detent portion 120 moves in the direction from the rear to the front with respect to the uneven portion 130.

The detent portion 120 located at the bottom 131A of the recess 131 moves to the left side C1 side on which the load of the front wall 131C is small when exiting from the recess 131, and climbs the front wall 131C (see FIGS. 6A and 7A). ..

In this case, the fixed portion 140 rotates to the right side, and the detent portion 120 faces the region on the left side C1 side and climbs the front wall 131C.

Then, after reaching the upper end T2, the detent portion 120 passes through the side where the load on the rear wall 133B is small when entering the recess 133, that is, the left side B3 side where the suction force to the detent portion 120 is large. It enters the bottom 133A (see FIGS. 6A and 7B).

Further, it is assumed that the driver moves the operation lever 7 from the first traveling stage position to the neutral position. In this case, since the uneven portion 130 moves in the forward direction together with the rod 110, the detent portion 120 moves in the direction from the front to the rear with respect to the uneven portion 130.

The detent portion 120 located at the bottom portion 133A of the recess 133 moves to the right side B4 side, which is the side where the load of the rear wall 133B is small when exiting the recess 133, and climbs the rear wall 133B (see FIG. 6B).

In this case, as shown in FIG. 8B, the fixing portion 140 rotates to the left side, and the detent portion 120 faces the region on the right side B4 side and climbs the rear wall 133B.

Then, after reaching the upper end T2, the detent portion 120 passes through the side where the load on the front wall 131C is small when entering the recess 131, that is, the side on the right side C2 which is the side where the suction force to the detent portion 120 is large. It enters the bottom 131A (see FIG. 6B).

That is, the fixing portion 140 can be rotated so that the detent portion 120 passes through the side where the load when exiting the recess is small and passes through the side where the suction force when entering the recess is large. As a result, optimum operability can be obtained when the detent portion 120 comes out of the recess and when it enters the recess.

Further, in the present embodiment, of the two adjacent recesses in the front-rear direction (first direction), the first portion in the recess where the detent portion 120 comes out and the second portion in the recess where the detent portion 120 enters are in the left-right direction. They are arranged in the same area in (second direction).

Specifically, in the direction from the rear to the front, in the left side region, the left side C3 of the front wall 132C in the recess 132, the left side B1 of the rear wall 131B in the recess 131, the left side C1 and the recess of the front wall 131C in the recess 131. The left side B3 of the rear wall 133B in 133 is arranged.

Further, in the direction from front to rear, in the right side region, the right side B4 of the rear wall 133B in the recess 133, the right side C2 of the front wall 131C in the recess 131, the right side B2 of the rear wall 131B in the recess 131, and the front wall in the recess 132. The right side C4 of 132C is arranged.

Therefore, when the driver operates the operation lever 7, the fixed portion 140 does not rotate at T1 and T2 of the upper end portion where the ascending movement and the descending movement of the detent portion 120 are switched between the adjacent recesses, and the detent portion 120 does not rotate. Can be moved linearly. As a result, the operability of the operation lever 7 can be further improved.

Further, even when the driver moves the operation lever 7 at once from the first running stage position to the second running stage position or moves the operating lever 7 at once from the second running stage position to the first running stage position, the operating lever 7 may be moved at once. The detent portion 120 can be moved linearly. Specifically, as shown in FIG. 9, when the driver reciprocates the operation lever 7 between the first traveling stage position and the second traveling stage position, the movement locus R of the detent portion 120 is an uneven portion. The trajectory is like drawing a loop over the entire 130.

As a result, even when the operating lever 7 is moved in a plurality of stages, the detent portion 120 moves linearly without rotating the fixed portion 140, so that the operability of the operating lever 7 can be further improved.

Further, in the present embodiment, the uneven portion 130 is configured so that the inclination angle of the concave portion wall gradually changes in the left-right direction. That is, the uneven portion 130 is configured so that the load gradually changes in the second direction.

As a result, the fixed portion 140 can be smoothly rotated, so that the operability of the operating lever 7 can be further improved.

Further, since the fixed portion 140 rotates freely, the fixed portion 140 can be spontaneously rotated so that the detent portion 120 faces the side where the load on the uneven portion 130 is small. As a result, the operability of the operation lever 7 can be improved.

In the above embodiment, the inclination angle of the wall portion constituting the recess is different in the left-right direction, but the present disclosure is not limited to this, and for example, the depth of the recess may be different in the left-right direction. good. FIG. 10A is a diagram showing the outer shape of the left side portion of the uneven portion according to the modified example. FIG. 10B is a diagram showing the outer shape of the right-hand side portion of the uneven portion according to the modified example.

As shown in FIGS. 10A and 10B, each recess of the concave-convex portion 130 according to this embodiment also has a wall portion in which the first portion and the second portion having different shapes are arranged in the left-right direction, as in the above embodiment. It is configured to include. The first portion is a portion in which the suction force to the detent portion 120 is larger than that of the second portion when the detent portion 120 enters the recess, as in the above embodiment.

The second portion is a portion in which the load applied to the detent portion 120 when the detent portion 120 comes out of the recess is smaller than that of the first portion, as in the above embodiment. The depth of the second portion according to this form is smaller than the depth of the first portion.

Specifically, the depth of the central recess 131 in the uneven portion 130 is smaller on the left side than on the right side. Further, the depths of the recesses 132 and 133 at both front and rear ends of the uneven portion 130 are smaller on the right side than on the left side.

When the depth of the recess is small, when the detent portion 120 comes out of the recess, the load when the ball 122 of the detent portion 120 goes up the wall portion becomes smaller than when the depth of the recess is large. That is, the smaller the depth of the recess, the smaller the load applied to the detent portion 120.

On the other hand, when the depth of the recess is large, when the detent portion 120 enters the recess, the ball 122 of the detent portion 120 is more likely to enter the recess than when the depth of the recess is small. That is, as the depth of the recess increases, the suction force into the detent portion 120 increases.

The first portion according to this form is a portion of the recess 131 including the left side B1 side of the rear wall 131B and a portion including the left side C1 side of the front wall 131C. The first portion is a portion of the recess 132 that includes the right side C4 of the front wall 132C and a portion of the recess 133 that includes the right side B4 of the rear wall 133B.

The second portion according to this embodiment is a portion of the recess 131 including the right side B2 side of the rear wall 131B and a portion including the right side C2 side of the front wall 131C. The second portion is a portion of the recess 132 that includes the left side C3 of the front wall 132C and a portion of the recess 133 that includes the left side B3 of the rear wall 133B.

For example, assume that the detent portion 120 moves from the recess 131 to the recess 133. In this case, when the detent portion 120 is removed from the recess 131, the fixed portion 140 is rotated so that the detent portion 120 is located on the region side including the left side C1 of the front wall 131C on which the load is small, and the detent portion 120 is rotated. It passes through the region (see FIG. 10A).

Then, when the detent portion 120 enters the recess 133 at the upper end T2, the detent portion 120 passes through the region including the left side B3 of the rear wall 133B on the side where the suction force is large and enters the recess 133.

Further, it is assumed that the detent portion 120 moves from the recess 133 to the recess 131. In this case, when the detent portion 120 is removed from the recess 133, the fixed portion 140 is rotated so that the detent portion 120 is located on the region side including the right side B4 of the rear wall 133B on the side where the load is small, and the detent portion 120 is rotated. It passes through the region (see FIG. 10B).

Then, when the detent portion 120 enters the recess 131 at the upper end T2, the detent portion 120 passes through the region including the right side C2 of the front wall 131C on the side where the suction force is large and enters the recess 131.

Further, the upper ends T1 and T2, which are the connecting portions of the adjacent recesses, may have a curved shape. As a result, the detent portion 120 can be smoothly moved between the adjacent recesses, and the operability of the operation lever 7 can be improved.

Further, as the radius of curvature of the connecting portion becomes larger, the connecting portion becomes smoother, so that the load applied to the detent portion 120 becomes smaller. Therefore, it is preferable to determine the optimum radius of curvature of the connecting portion in consideration of the load applied to the detent portion 120, the ease of manufacturing the uneven portion 130, and the like.

Further, the connecting portions of the adjacent recesses may have a flat surface.

Further, in the above embodiment, the uneven portion 130 is formed in a rectangular shape, but the present disclosure is not limited to this, and as shown in FIG. 11, the uneven portion 150 may be formed in an annular shape.

The concavo-convex portion 150 in this form is a connecting portion 150C, 150D that connects the first portion 150A constituting the left side region, the second portion 150B forming the right side region, and the first portion 150A and the second portion 150B. And have.

The first portion 150A has, for example, the same configuration as the left side shape of the concave-convex portion 130 shown in FIG. 6A, and has a uniform inclination angle and depth of the concave portion of the wall portion forming the concave portion in the left-right direction. ..

The first portion 150A is, for example, a portion corresponding to a region (see FIG. 9) for the detent portion 120 to move in the direction from the rear to the front, and has recesses 151, 152, and 153. The recess 151 corresponds to the recess 131 shown in FIG. 6A, the recess 152 corresponds to the recess 132, and the recess 153 corresponds to the recess 133.

The second part 150B has a configuration in which the first part 150A is arranged upside down, and is, for example, a part corresponding to a region (see FIG. 9) for the detent part 120 to move in the direction from the front to the back.

The connecting portion 150C connects the recess 153 of the first portion 150A and the recess 152 of the second portion 150B. In the connecting portion 150C, the fixing portion 140 rotates so that the position of the detent portion 120 is changed from the position of the recess 153 of the first portion 150A to the position of the recess 152 of the second portion 150B, so that, for example, the recess 153 and the recess It has a structure that makes a difference in height from 152.

The connecting portion 150D connects the recess 152 of the first portion 150A and the recess 153 of the second portion 150B. The connecting portion 150D has, for example, the recess 153 and the recess because the fixing portion 140 rotates so that the position of the detent portion 120 is from the position of the recess 153 of the second portion 150B to the position of the recess 152 of the first portion 150A. It has a structure that makes a difference in height from 152.

In this configuration, for example, when the detent portion 120 is located in the recess 153 of the first portion 150A, the fixing portion 140 rotates to the left, and the position of the detent portion 120 is from the recess 153 of the first portion 150A to the second portion 150B. Move to the recess 152.

By doing so, the driver can operate the operation lever 7 to position the detent portion 120 from the recess 152 of the second portion 150B to the recess 151 of the second portion 150B.

Further, when the detent portion 120 is located in the recess 153 of the second portion 150B, the fixing portion 140 rotates to the right, and the position of the detent portion 120 moves from the recess 153 of the second portion 150B to the recess 152 of the first portion 150A. do.

By doing so, the driver can operate the operating lever 7 to position the detent portion 120 from the recess 152 of the first portion 150A to the recess 151 of the first portion 150A.

Even with such a configuration, the operability of the detent unit 120 can be improved. Further, the recess 151 of the first part 150A and the recess 151 of the second part 150B may be connected by a connecting portion.

Further, in the above-described embodiment, the uneven portion 130 is composed of one member, but the present disclosure is not limited to this, and the concave-convex portion 130 may be composed of a plurality of members.

Further, in the above embodiment, the fixing portion 140 is provided directly on the rod 110, but the present disclosure is not limited to this, and the fixing portion 140 may be provided on another member provided on the rod 110.

For example, the detent mechanism 100 shown in FIG. 12 has a pair of annular members 160 provided on the rod 110. The pair of annular members 160 have a large diameter portion 161 and a small diameter portion 162. The large diameter portion 161 has a diameter equal to or larger than the outer diameter of the fixed portion 140. The pair of annular members 160 correspond to the "supports" of the present disclosure.

The small diameter portion 162 has a smaller diameter than the large diameter portion 161 and is provided on the side where the pair of annular members 160 face each other. The diameter of the small diameter portion 162 is smaller than the inner diameter of the fixed portion 140 so that the fixed portion 140 can rotate.

A fixing portion 140 is provided at a portion of each small diameter portion 162. As a result, the fixed portion 140 is rotatably arranged.

Further, since the diameter of the large diameter portion 161 is equal to or larger than the outer diameter of the fixed portion 140, it is possible to regulate the movement of the fixed portion 140 with respect to the rod 110. That is, the annular member 160 rotatably supports the fixing portion 140 and restricts the movement of the fixing portion 140 with respect to the rod 110. The large diameter portion 161 corresponds to the “regulatory portion” of the present disclosure.

As a result, the fixing portion 140 is positioned with respect to the rod 110, and the rotation of the fixing portion 140 can be stabilized.

The annular member 160 may be provided only for the purpose of providing the fixing portion 140, or for example, a bush or the like connecting the two members may be the annular member 160. Further, a member that is not formed in an annular shape may be provided as a support portion instead of the annular member.

Further, in the above embodiment, of the two recesses adjacent to each other in the first direction, the first portion and the second portion are arranged in the same region in the second direction, but the present disclosure is not limited to this. , It does not have to be arranged in the same area.

Further, in the above embodiment, the uneven portion has three concave portions, but the present disclosure is not limited to this, and a configuration having two concave portions may be used, or a configuration having four or more concave portions is used. You may.

Further, in the above embodiment, the rod is provided with the uneven portion, but the present disclosure is not limited to this, and the shift arm connected to the rod may be provided with the uneven portion.

In addition, the above embodiments are merely examples of embodiment of the present disclosure, and the technical scope of the present disclosure should not be construed in a limited manner by these. That is, the present disclosure can be implemented in various forms without departing from its gist or its main features.

The detent mechanism of the present disclosure is useful as a detent mechanism, a manual transmission and a vehicle capable of optimizing the operability of the operating lever.

1 Vehicle 2 Propeller shaft 3 Differential gear 4 Drive wheel 5 Engine 6 Transmission 7 Operating lever 100 Detent mechanism 110 Rod 120 Detent part 122 Ball 123 Bias member 130 Concavo-convex part 131 Recessed 131A Bottom 131B Rear wall 131C Front wall 132 Recessed 132A Bottom 132B Rear wall 132C Front wall 133 Recessed 133A Bottom 133B Rear wall 133C Front wall 140 Fixed part

Claims (12)

A detent mechanism that positions a rod or shift arm that moves in the first direction in conjunction with an operating lever that can move to multiple shift positions.
Uneven part and
A fixed portion provided on the rod or shift arm and to which the uneven portion is fixed, and a fixed portion.
A detent portion that comes into contact with the uneven portion and advances and retreats in the advancing / retreating direction according to the movement of the uneven portion.
With
The uneven portion is configured so that the load applied to the detent portion when moving together with the rod or the shift arm changes in the first direction and the second direction orthogonal to the advancing / retreating direction.
The fixing portion is configured to be rotatable with respect to the rod or shift arm so that the detent portion passes through the side of the uneven portion where the load is small when the rod or shift arm moves.
Detent mechanism. The uneven portion has a plurality of concave portions arranged in the first direction.
The detent portion is arranged so as to fit into any of the plurality of recesses according to the position of the operating lever.
The recess is configured to change the suction force into the detent portion when moving with the rod or shift arm in the second direction.
The fixing portion is configured to be rotatable with respect to the rod or shift arm so that the detent portion passes through the side having a large suction force when entering the recess.
The detent mechanism according to claim 1. The recess is composed of a plurality of walls including a wall portion in which a first portion and a second portion are arranged in the second direction.
In the first portion, when the detent portion enters the recess, the suction force into the detent portion is larger than that in the second portion.
In the second portion, the load applied to the detent portion when the detent portion comes out of the recess is smaller than that of the first portion.
The detent mechanism according to claim 2. The tilt angle of the second portion is smaller than the tilt angle of the first portion.
The detent mechanism according to claim 3. The depth of the second part is smaller than the depth of the first part.
The detent mechanism according to claim 3 or 4. Of the plurality of recesses, the connecting portion of the two adjacent recesses has a curved shape.
The detent mechanism according to any one of claims 3 to 5. Of the two recesses adjacent to each other in the first direction, the first portion of the recess in which the detent portion exits and the second portion of the recess in which the detent portion enters are in the same region in the second direction. Being placed,
The detent mechanism according to any one of claims 3 to 6. A support provided on the rod or shift arm to rotatably support the fixed portion.
The detent mechanism according to any one of claims 1 to 7. The support has a regulating that regulates the movement of the fixing to the rod or shift arm.
The detent mechanism according to claim 8. The uneven portion is configured so that the load gradually changes in the second direction.
The detent mechanism according to any one of claims 1 to 9. A manual transmission comprising the detent mechanism according to any one of claims 1 to 10. The manual transmission according to claim 11 is provided.
vehicle.

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