KR20200013526A - Shift lever apparatus for vehicle - Google Patents

Abstract

The present invention relates to a shift lever of a manual transmission vehicle having an electronic clutch, wherein the shift lever and a sensor are configured to avoid contact, so that occurrence of a hitting sound due to the contact between the shift lever and the sensor is prevented, and a sensing value is clearly derived as the shift lever is operated using the maximum rotation radius of the shift lever, thereby improving reliability. In addition, disclosed is a shift lever device for a vehicle, which reduces overall layouts, reduces manufacturing costs, and improves productivity in accordance with structural simplification.

Description

Vehicle shift lever device {SHIFT LEVER APPARATUS FOR VEHICLE}

The present invention relates to a shift lever device of a manual shift vehicle equipped with an electronic clutch, in which a recognition speed according to an operation of a manual shift lever is improved, and precise sensing is performed to improve reliability.

In general, a transmission mounted on a vehicle performs a function of transferring a driving force generated from an engine while driving to a driving wheel according to a driving state of a vehicle, and is classified into manual, automatic, and continuously variable transmission according to an operation method.

The manual transmission operates the select lever and the shift lever independently of the plurality of gear trains provided in the transmission by receiving the tension of the select cable and the shift cable according to the operation of the shift lever installed in the cabin. It is a way to transmit power according to shifting through gear train.

Recently, a method for electronically controlling a clutch pedal for controlling a clutch essential to a manual transmission has been proposed. That is, when shifting the manual transmission, the clutch pedal should be pressed in to control the operation of the clutch. When driving a frequent shifting section, there is a problem in that the driver feels fatigue as the depression of the clutch pedal increases. In order to solve this problem, an automatic transmission vehicle has been applied, but there is a problem in that the characteristics and effects of the manual transmission should be excluded.

To this end, a structure for controlling the clutch is applied to a shift lever having a pattern of a manual transmission.

However, in order to control the clutch of the manual transmission with the shift lever, a sensor must be installed on the shift lever. Since the shift lever and the sensor are configured to rotate together, a problem occurs when the shift lever is operated due to the impact between the shift lever and the sensor. have. In addition, the shift lever of the manual transmission is shifted quickly. If the sensor does not detect the shift lever accurately and quickly, the shift operation is not performed at an appropriate timing. In addition, as additional components for connecting the shift lever and the sensor must be complicated, a console layout for providing the disadvantage is disadvantageous.

The matters described as the background art are only for the purpose of improving the understanding of the background of the present invention, and should not be taken as acknowledging that they correspond to the related art already known to those skilled in the art.

KR 10-2015-0026445 (2015.02.25)

The present invention has been proposed to solve such a problem, in the shift lever of a manual shift vehicle equipped with an electronic clutch, the shift lever and the sensor is configured to be in non-contact to eliminate the impact sound caused by the contact between the shift lever and the sensor, It is an object of the present invention to provide a shift lever device for a vehicle that simplifies the structure and improves manufacturing cost and productivity.

A shift lever device for a vehicle according to the present invention for achieving the above object is rotatably installed on the lever body, the shift lever is connected to the shift cable; A guide socket mounted to a lower portion of the shift lever and formed to surround the shift cable together with the lower portion of the shift lever to fix the shift cable to the shift lever, and to transmit a rotation position of the shift lever; And a sensor module installed at a lower side of the shift lever in the lever body and detecting a position of the guide socket to determine a shift will according to a rotation position of the shift lever.

The upper part of the shift lever is provided with a handle part, the lower part of the shift cable and the guide socket are connected, and the center part is formed with a spherical body connection part. It is characterized by.

The lower end of the shift lever has a spherical cable connection portion is formed, the end of the shift cable is formed to surround the cable connection portion, characterized in that provided with a clip portion having a slit in some section.

The guide socket is formed so that the upper portion is recessed downward so that the lower portion of the shift lever is inserted, and the lower portion of the socket body having a position transmitting portion; And a fixed guide disposed to be spaced apart at predetermined intervals along the circumference of the socket body and extending upward from the socket body to surround the lower portion of the shift lever inserted into the socket body.

The circumferential surface of the socket body is spaced apart from the fixing guide, characterized in that a plurality of recessed grooves are formed recessed from the upper side to the lower side of the circumferential surface.

One of the plurality of recessed grooves is characterized in that the deeper and larger than the other recessed grooves or the same formed so that the shifting cable is inserted.

The plurality of recessed grooves are respectively provided between the plurality of fixed guides, characterized in that spaced at regular intervals.

A locking flange protruding in a radial direction is formed at a lower portion of the shift lever, and a locking groove in which the locking flange is inserted along the circumference is formed inside the circumferential surface of the socket body.

The lower portion of the socket body is extended downwards and is provided with an extension portion provided with a position transmitting portion at the extended end, characterized in that the position transmitting portion is positioned on the sensor module side in the state where the guide socket is installed on the shift lever.

The fixing guide extends upward from the upper circumferential surface of the socket body, but is formed to be collected toward the center of the socket body.

The position transmitting part of the socket body is configured to generate a magnetic field, and the sensor module is formed to be wider than the rotation radius of the shift lever, and is configured to detect the magnetic field of the position transmitting part to detect the position of the position transmitting part as the shift lever is rotated. It is done.

The sensor module has a detection area for detecting the shift will in the direction in which the shift lever is shifted, and when the shift lever is rotated and the position sending part is located in the detection area, the shift will is reflected, and the clutch release signal is transmitted. Vehicle shift lever device.

The sensor module has a guide region for partitioning a shift region according to a plurality of shift stages, and the guide region has the same polarity as the magnetic field polarity of the position transmitting unit.

The shift lever device for a vehicle having the structure as described above is configured in the shift lever of a manual shift vehicle equipped with an electronic clutch and is configured such that the shift lever and the sensor are not in contact with each other, thereby eliminating the impact sound generated when the shift lever and the sensor are in contact with each other. By using the maximum rotation radius of the lever, the sensing value is clearly derived as the shift lever is operated, thereby improving reliability. In addition, the overall layout is reduced due to structural simplification, manufacturing cost is reduced, and productivity is improved.

1 to 2 are views showing a shift lever device for a vehicle according to an embodiment of the present invention.
3 is an assembly view of the shift lever device for a vehicle shown in FIG.
4 to 8 are views for explaining the shift lever device for a vehicle shown in FIG.

Hereinafter, a shift lever device for a vehicle according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

1 to 2 are views showing a shift lever device for a vehicle according to an embodiment of the present invention, Figure 3 is an assembly view of the shift lever device for a vehicle shown in Figure 1, Figures 4 to 8 for the vehicle shown in Figure 1 It is a figure for demonstrating a shift lever apparatus.

1 to 2, the shift lever device for a vehicle according to the present invention includes a shift lever 20 rotatably installed on the lever body 10 and having a shift cable 50 connected thereto; It is mounted to the lower portion of the shift lever 20, and formed to surround the shift cable 50 together with the lower portion of the shift lever 20 so that the shift cable 50 is fixed to the shift lever 20, the shift lever 20 A guide socket 30 configured to send out a rotation position of the; And a sensor module 40 installed at the lower side of the shift lever 20 in the lever body 10 to detect the position of the guide socket 30 to determine the shift intention according to the rotational position of the shift lever 20. Include.

The present invention relates to a shift lever (20) of a manual shift vehicle equipped with an electronic clutch, wherein the shift lever (20) is linked with an e-clutch that engages and disengages the clutch only by operating the shift lever 20. It is about.

Here, the shift lever 20 is connected to the shift cable 50, which is a select cable, and the shift cable 2 is connected through the engaging lever 1 to perform shifting according to the rotational direction of the shift lever 20. Can be. That is, in the present invention, when the shift lever 20 is operated, the shift determination of the driver is determined to determine the engagement release operation of the clutch, and the select cable is interlocked with the operation of the shift lever 20 while the clutch is released. The shift stage is changed by a shift cable. In addition, the select cable and the sheet cable are not configured, and the shift lever 20 is transmitted as an electronic signal so that the shift stage is changed as the actuator operates the select lever and the shift lever of the transmission according to the electronic signal. Can be.

As such, since the select lever and the shift lever of the transmission are operated as the shift lever 20 is operated, shifting is performed, a detailed description thereof has been omitted, and a detailed description thereof has been omitted, and a clutch operation according to the shift lever 20 is operated. Will now be described.

2 to 3, the shift lever device of the present invention comprises a lever body 10, a shift lever 20, a guide socket 30, and a sensor module 40. That is, in a state in which the shift lever 20 is rotatably installed on the lever body 10, the shift cable 50 is fixed to the shift lever 20 through the guide socket 30 and together with the shift lever 20. The sensor module 40 grasps that the guide socket 30 is moved so as to grasp the shift will according to the position of the shift lever 20. Here, the sensor module 40 may be made to be simply fastened to the lower portion of the lever body 10 in a snap fit structure.

In particular, the shift lever 20 is located on the upper side in the lever body 10, the sensor module 40 is located below the shift lever 20 in the lever body 10, the lower portion of the shift lever 20 As the guide socket 30 is installed, as the shift lever 20 is rotated to select the shift stage, the maximum radius of the movement of the guide socket 30 is secured, so that the sensor module 40 is guide socket 30. By clearly identifying the movement of the), you can accurately determine the willingness to shift. That is, the guide socket 30 is provided at the lower part farthest from the rotation center point of the shift lever 20, so that the maximum amount of movement of the guide socket 30 is ensured when the shift lever 20 rotates. Accordingly, the sensor module 40 can clearly grasp the position of the shift lever 20.

In addition, the guide socket 30 is fixed to the shift lever 20, the shift cable 50 connected to the shift lever 20, so that the shift cable 50 is not separated from the shift lever 20.

Thus, according to the shift lever 20 of the present invention, as the guide socket 30 is mounted at the bottom, it can be moved to the maximum moving radius of the guide socket 30 when the shift lever 20 is operated, and the shift lever ( 20 is spaced apart from the guide socket 30 to the lower side of the sensor module 40 is installed, the sensor module 40 can clearly determine the position of the guide socket 30 so that the operation timing of the clutch can be accurately controlled. .

Referring to the present invention described above in detail, as shown in Figure 3, the upper portion of the shift lever 20 is provided with a handle portion 22, the lower portion of the shifting cable 50 and the guide socket 30 Is connected, and the central body portion 24 is formed in the central portion, the shift lever 20 can be rotated in front, rear, left and right as seated on the lever body 10 through the body connecting portion (24).

That is, the upper portion of the shift lever 20 is provided with a handle portion 22 for the driver to grip, the lower portion of the shift cable 50 is fixed by the guide socket 30. In particular, the shift lever 20 of the manual transmission should be operated in the left and right directions as well as the front and rear directions, and a spherical body connecting portion 24 is formed in the middle of the shift lever 20, and the body connecting portion 24 is formed. As seated on the lever body 10, the shift lever 20 can be freely rotated to be operated in the front, rear, left and right directions. To this end, the lever body 10 may be formed with a groove in which the body connecting portion 24 of the shift lever 20 is seated, and the shift lever 20 has a body connecting portion 24 in a state seated on the lever body 10. ) Is rotated to the rotation center.

On the other hand, as shown in Figure 4, the lower end of the shift lever 20 is formed of a spherical cable connecting portion 26, the end of the shifting cable 50 is formed to surround the cable connecting portion 26, but part Clip portion 52 having a slit 54 in the section may be provided.

In this way, the clip portion 52 of the shifting cable 50 is connected to surround the cable connecting portion 26 of the shifting lever 20 formed in a spherical shape, so that the shifting cable 50 moves forward, backward, left, and right. The clip portion 52 and the cable connection portion 26 of the shift lever 20 are relatively rotatable, so that the shift lever 20 can be smoothly rotated. In addition, since the clip portion 52 of the shifting cable 50 has a slit 54 and is formed in a C shape, the clip portion 52 can be easily assembled to the cable connection portion 26.

On the other hand, as shown in Figures 5 to 7, the guide socket 30 is formed so that the upper portion is recessed downward so that the lower portion of the shift lever 20 is inserted, the socket having a position sending portion (32a) in the lower portion Body 32; And a plurality of fixed guides spaced apart from each other at predetermined intervals along the circumference of the socket body 32 and extending upward from the socket body 32 to surround the lower portion of the shift lever 20 inserted into the socket body 32 ( 34);

As can be seen in Figure 5, the socket body 32 of the guide socket 30 is formed so that the upper portion is opened as the upper portion is recessed downward, the lower portion of the shift lever 20 is inserted into the recessed portion of the upper portion. The socket body 32 is formed so that the plurality of fixing guides 34 extend upward along the circumference, and the fixing guide 34 wraps the lower portion of the shift lever 20 inserted into the socket body 32, The play between the guide socket 30 and the shift lever 20 is removed. Here, the width between the plurality of fixing guides 34 is preferably formed smaller than the lower width of the shift lever 20.

In addition, the fixing guide 34 extends upward from the upper circumference of the socket body 32 and is formed to be collected toward the center of the socket body 32, so that the plurality of fixing guides 34 are inserted into the socket body 32. The contact force is secured by being in contact with the shift lever 20. That is, when the lower portion of the shift lever 20 is inserted into the upper portion of the socket body 32, the plurality of fixed guides 34 are formed while being unfolded, and the restoring force of the fixed guide 34 is inserted into the shift lever 20. The play between the fixed guide 34 and the shift lever 20 is removed by acting as a contact force to the bottom of the.

As described above, as the plurality of fixing guides 34 wrap the shift lever 20, the shaking is minimized in the state where the socket body 32 is mounted on the shift lever 20, and thus the position transmission is mounted on the socket body 32. The position of the shift lever 20 through the unit 32a may be transmitted with accurate information.

In more detail, a plurality of recessed grooves 32b may be formed on the circumferential surface of the socket body 32 so as to be spaced apart from the fixing guide 34 and recessed downward from the upper side of the circumferential surface.

Thus, a plurality of recessed grooves 32b are formed on the circumferential surface of the socket body 32 from the upper side to the lower side, such that the lower portion of the shift lever 20 is inserted into the upper portion of the socket body 32 and fixed to the fixed guide 34. In contact, the fixing guide 34 may be led to spread outward.

To this end, the number of the fixing guide 34 and the recessed grooves 32b may be the same, and the plurality of recessed grooves 32b are provided between the plurality of fixing guides 34 and spaced apart at regular intervals. When the lower portion of the shift lever 20 is inserted between the plurality of fixing guides 34, the fixing guide 34 may be smoothly opened to the outside by being guided by the recessed groove 32b.

On the other hand, one of the recessed grooves 32b-1 of the plurality of recessed grooves 32b may be formed deeper and larger than the other recessed grooves 32b so as to insert the shifting cable 50, or may be formed in the same manner.

Guide socket 30 in the present invention is configured to wrap around the transmission cable (50). To this end, any one of the recessed grooves 32b-1 of the recessed grooves 32b of the socket body 32 constituting the guide socket 30 is sized to allow the shifting cable 50 to be inserted therein, and the shifting cable It is to be formed deeper than the other recessed groove (32b) so that 50 can be seated on the bottom of the recessed portion of the socket body (32).

As such, through the plurality of recessed grooves 32b, the fixing guide 34 may guide the operation of elastically opening by the shift lever 20, and the shifting cable 50 to a specific recessed groove 32b-1. By being inserted and seated, the connection state of the transmission cable 50 may be fixed to the lower portion of the shift lever 20 inserted into the socket body 32.

Meanwhile, as illustrated in FIGS. 6 and 7, a locking flange 28 protruding in a radial direction is formed at a lower portion of the shift lever 20, and a locking flange is formed along the circumference of the inner side of the socket body 32. As the locking groove 32c into which the 28 is inserted is formed, when the socket body 32 is mounted to the lower portion of the shift lever 20, the shift lever 20 is caught in the locking groove 32c of the socket body 32. As the flange 28 is fastened, the shift lever 20 and the guide socket 30 may be fixed to each other. In particular, as a one-touch fastening that the locking flange 28 is inserted into the locking groove 32c by a simple operation of pushing the socket body 32 of the guide socket 30 to the lower portion of the shift lever 20, workability is achieved. This is improved.

On the other hand, the lower portion of the socket body 32 is extended downward and the extension portion 32d provided with the position sending portion 32a is formed at the extended end, so that the guide socket 30 is installed in the shift lever 20. The position sending unit 32a may be located at the sensor module 40 side.

Thus, the lower portion of the socket body 32 is formed so that the extension portion 32d extends downward, and the position sending portion 32a is installed at the end of the extension portion 32d, whereby the position sending portion 32a and the sensor module are provided. As the distance of 40 approaches, the sensor module 40 can more accurately grasp the position of the position transmitter 32a. That is, as the distance between the position sending part 32a and the sensor module 40 gets closer, the accuracy is improved, and the extension part 32d is formed to extend downward in the lower part of the socket body 32, thereby providing the position sending part 32a. And the distance between the sensor module 40 is closer.

On the other hand, the position sending portion 32a of the socket body 32 is configured to generate a magnetic field, the sensor module 40 is formed wider than the rotation radius of the shift lever 20, and the magnetic field of the position sending portion 32a It is configured to detect the position of the position transmission unit 32a as the shift lever 20 is rotated.

In this way, the position transmitting unit 32a may be made of a magnet, the sensor module 40 may be made of a PCB sensor. Here, the sensor module 40 is formed wider than the rotation radius of the shift lever 20 to accommodate all the movement radius of the guide socket 30 as the shift lever 20 rotates.

Specifically, as illustrated in FIG. 8, the shift lever 20 is rotated by the sensor module 40 having the detection area 40a for detecting the shift intention in the shifting direction of the shift lever 20. When the position sending part 32a is located in the detection area 40a, the shift will is reflected and the clutch release signal can be sent.

As can be seen in Figure 8, the sensor module 40 is provided with a detection area 40a, the detection area 40a is located in the shift operation direction of the shift lever 20, the shift lever 20 is shifted operation The driver's willingness to shift. That is, when the shift lever 20 is operated so that the position transmitter 32a reaches the detection area 40a, the driver shifts to another shift stage, thereby releasing the engagement of the clutch through communication with the ECU. . In this way, when the engagement of the clutch is released, the shift to the specific shift stage can be completed by the above-described shift cable 50.

In addition, the sensor module 40 has a guide area 40c for partitioning the shift area 40b according to the plurality of shift stages, and the guide area 40c has the same polarity as the magnetic field polarity of the position sending part 32a. By being configured, the shift lever 20 is operated to prevent misoperation when shifting to another shift stage.

That is, the position sending part 32a is provided in the guide socket 30 mounted below the shift lever 20, and the position sending part 32a is made of a magnet. Here, the guide area 40c of the position sending part 32a and the sensor module 40 has a repulsive force generated by the same polarity, so that the shift lever 20 is operated to partition the shift area 40b. The operation of the shift lever 20 is restricted to 40c). Thus, the shift lever 20 is limited to the rotational operation to the guide region 40c, and only the shift region 40b is allowed to move, thereby preventing misoperation of the shift lever 20.

The shift lever device for a vehicle having the structure as described above is configured such that the shift lever 20 and the sensor are non-contacted in the shift lever 20 of the manual shift vehicle provided with the electronic clutch, so that the shift lever 20 is in contact with the sensor. As a result of the impact sound is eliminated, and the sensing value is clearly derived as the shift lever 20 is operated using the maximum rotation radius of the shift lever 20, thereby improving reliability. In addition, the overall layout is reduced due to structural simplification, manufacturing cost is reduced, and productivity is improved.

While the invention has been shown and described with respect to particular embodiments, it is within the skill of the art that various changes and modifications can be made therein without departing from the spirit of the invention provided by the following claims. It will be self-evident for those of ordinary knowledge.

10: lever body 20: shift lever
22: handle part 24: body connection
26: cable connection 28: jamming flange
30: guide socket 32: socket body
32a: Position sending part 32b: Recessed groove
32c: Jamming groove 32d: Extension part
34: fixed guide 40: sensor module
50: shifting cable 52: clip portion
54: Slit

Claims (13)

A shift lever rotatably installed on the lever body and connected to a shift cable;
A guide socket mounted on a lower portion of the shift lever and configured to surround the shift cable together with the lower portion of the shift lever to fix the shift cable to the shift lever, and to transmit a rotation position of the shift lever; And
And a sensor module installed on the lever body and sensing a position of the guide socket to determine a shift will according to the rotational position of the shift lever. The method according to claim 1,
The upper part of the shift lever is provided with a handle part, the lower part of the shift cable and the guide socket are connected, and the center part has a spherical body connection part, and the shift lever is rotatable back, front, left and right as it is seated on the lever body through the body connection part. Vehicle shift lever device, characterized in that. The method according to claim 1,
At the lower end of the shift lever, a spherical cable connection part is formed.
The shift lever device for a vehicle, characterized in that the end of the shift cable is formed to surround the cable connection portion, the clip portion having a slit in some section. The method according to claim 1,
The guide socket is formed so that the upper portion is recessed downward so that the lower portion of the shift lever is inserted, and the lower portion of the socket body having a position transmitting portion; And
A plurality of shifting spaced apart at a predetermined interval along the circumference of the socket body, the fixing guide to cover the lower portion of the shift lever inserted upwardly extending from the socket body inserted into the socket body; vehicle shift lever device comprising a. The method according to claim 4,
The circumferential surface of the socket body is spaced apart from the fixing guide, a shift lever device for a vehicle, characterized in that a plurality of recessed grooves formed from the upper side to the lower side of the circumferential surface formed. The method according to claim 5,
One recessed groove of the plurality of recessed grooves is a vehicle shift lever device, characterized in that formed deeper and larger than the other recessed grooves so that the shifting cable is inserted. The method according to claim 5,
A plurality of recessed grooves are respectively provided between the plurality of fixed guides, the shift lever device for a vehicle, characterized in that spaced at regular intervals. The method according to claim 4,
At the bottom of the shift lever, a locking flange protruding in the radial direction is formed,
Vehicle shift lever device, characterized in that the engaging groove is formed in the inner peripheral surface of the socket body is inserted into the locking flange along the circumference. The method according to claim 4,
The lower portion of the socket body extends downward and is provided with an extension portion provided with a position transmitting portion at the extended end, the vehicle speed lever device for the position transmitting portion is positioned on the sensor module side while the guide socket is installed on the shift lever. The method according to claim 4,
The fixed guide extends upward from the upper circumferential surface of the socket body, the shift lever device for a vehicle, characterized in that formed to be collected toward the center of the socket body. The method according to claim 4,
The position transmitting part of the socket body is configured to generate a magnetic field,
The sensor module is wider than the rotation radius of the shift lever, and is configured to detect a magnetic field of the position transmission unit, the shift lever device for a vehicle, characterized in that for detecting the position of the position transmission unit as the shift lever is rotated. The method according to claim 11,
The sensor module has a detection area for detecting the shift will in the direction in which the shift lever is shifted, so that when the shift lever is rotated and the position sending part is located in the detection area, the shift will is reflected, and the clutch release signal is transmitted. Vehicle shift lever device. The method according to claim 12,
The sensor module has a guide region for partitioning a shift region according to a plurality of shift stages, wherein the guide region is configured with the same polarity as the magnetic field polarity of the position transmitting unit.

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