KR20210156820A - Lever type vehicular remote shifting switching unit - Google Patents

Abstract

The present invention relates to a remote shift lever unit (10) placed on a steering wheel side unit connected to a steering shaft of a vehicle, and comprising: a lever housing (100) which is placed on the steering shaft side; a rotary unit (300) in which at least a part is placed on one end of the lever housing (100) and in which at least a part is rotatable toward the length of the lever housing (100); a lever button unit (400) in which at least a part is placed on one end of the lever housing (100) and which is operable along the length of the lever housing (100); a common moving unit (500) which is connected to the rotary unit (300) and the lever button unit (400) and is operable by being linked to an operation of one or more of the rotary unit (300) and the lever button unit (400); and a motion switching unit (600) which detects the operation of the common moving unit (500) when the common moving unit (500) operates. The present invention aims to provide a remote shift lever unit which is capable of improving operation reliability.

Description

Remote shift lever switching unit {LEVER TYPE VEHICULAR REMOTE SHIFTING SWITCHING UNIT}

The present invention is a switch mounted on a vehicle, and relates to a switch for a vehicle that implements a complex operation but has a simple and compact structure.

Typically, a steering wheel assembly for a vehicle includes a steering wheel, a steering column, a steering roll connector assembly, and a multi-function switch assembly. The steering wheel is for the driver to set the steering direction, and the rotation of the steering wheel by the driver is transmitted to the wheels through the steering column to set the steering angle of the vehicle. In addition, vehicles such as automobiles are required to function as various convenient means to provide users with a more stable and comfortable driving state beyond the function as a moving means.

For example, a window switch for opening and closing a window, a steering light switch for turning on/off the steering light, an audio switch for driving audio, a wiper switch for driving a wiper, etc. are disposed on the steering wheel of a vehicle produced recently, and a multi-function switch The assembly includes a light and fog lamp, a wiper, various audio devices, and a vehicle window switch, so that the driver does not lose attention to the front even while operating the various devices by increasing the operability of the various devices, which is the upper part of the steering wheel. Whether implemented as a button switch on the steering wheel or as a vehicle lever switch on the side of the steering wheel, various functions are concentrated on the console switch.

In recent automobile switches, switches of various functions tend to be complexly aggregated. As the function increases, the structure becomes more complex and the possibility of malfunction due to the complex structure increases.

In particular, not only a simple convenience function of the vehicle, but also an essential function of the vehicle, such as a shift lever for changing the shift range, is converted to a mechanical or electronic switch. It has advantages and disadvantages such as cognition for manipulation.

However, since it is a vehicle device, the importance of durability and operation state recognition through user manipulation is emphasized. In the case of the switch structure according to the prior art, the space occupied by the components is excessive or inconvenient in operation due to structural restrictions. It was accompanied by induced problems such as. In particular, there is a considerable difficulty in implementing a compact switch device due to the individual arrangement of each component for individual operation of the configuration of the switch.

The present invention was invented to solve the problems of the prior art, and an object of the present invention is to improve durability by enabling complex operation implementation through a compact and simple structure, and to minimize operation space by enabling more accurate operation implementation It is to provide a remote shift lever switching unit having a structure that achieves an improvement in operation reliability.

The present invention provides a remote shift lever unit disposed on a side of a steering wheel connected to a steering shaft of a vehicle, a lever housing 100 disposed on the steering shaft side, and at least a portion of which is disposed at one end of the lever housing 100 At least a part of the rotary part 300 is rotatable with respect to the length of the lever housing 100 , and at least a part of the lever is disposed at one end of the lever housing 100 and is movable along the length of the lever housing 100 . A common moving that is connected to the button unit 400, the rotary unit 300, and the lever button unit 400 and is movable in conjunction with at least one operation of the rotary unit 300 and the lever button unit 400 It provides a remote shift lever unit (10) including a unit (500) and a motion switching unit (600) for sensing the operation of the common moving unit (500) when the common moving unit (500) is in operation.

In the remote shift lever switching unit, the motion switching unit 600 includes: a motion switching sensor unit 620 , that is, more specifically, a motion switching sensor unit 620 disposed inside the lever housing 100 , and , a corresponding position of the motion switching sensor unit 620 may include a motion switching sensor corresponding unit 610 disposed at an end of the common moving unit 500 .

In the remote shift lever switching unit, the common moving part 500 is movable in a straight line along the longitudinal direction of the lever housing 100 and is rotatable about the longitudinal direction of the lever housing 100, , The common moving part 500 is: connected to the rotary part 300 and the lever button part 400, and in some cases, in contact with the rotary part 300, and the lever button part 400 and A common moving block 510 that is directly connected and receives an operating force from at least one of the rotary unit 300 and the lever button unit 400, and is disposed at an end of the common moving block 510 and the common It may include a common moving holder 520 that operates together with the moving block 510 and in which the motion switching sensor counterpart 610 is disposed.

In the remote shift lever switching unit, the common moving block 510 includes: a common moving block body 511 in which the common moving holder 520 is disposed at one end, and the other end of the common moving block body 511 A common moving block button body 513 arranged and connected to the lever button unit 400, more specifically directly connected, and at least the common moving block body 511 and the common moving block button body 513. In one, more specifically, it may include a common moving block locker 515 disposed on the outer periphery of any one and engaged with the rotary unit 300 to limit relative rotation.

In the remote shift lever switching unit, one end of the common moving block body 511 may include a common moving block holder accommodating part 517 accommodating a part of the common moving holder 520 .

In the remote shift lever switching unit, on the outer periphery of the common moving block button body 513, at least a part of the lever button part 400 (lever button block) disposed through at least a part of the rotary part 300 Extension locking part 424 ) and a common moving block button body coupling part 514 directly connected may be provided.

In the remote shift lever switching unit, one end of the common moving block button body 513 may include a rotary block body accommodating part 3231 disposed inside the rotary part 300 to be linearly movably received. .

In the remote shift lever switching unit, a cross section of the common moving block button body 513 on a plane perpendicular to the longitudinal direction of the lever housing 100 may be a polygonal cross section.

In the remote shift lever switching unit, on the outer periphery of the common moving block button body 513, a common moving block button body guide 516 for guiding linear relative movement inside the rotary part 300 may be provided. .

In the remote shift lever switching unit, the common moving holder 520 includes: a common moving holder body 521 in which a motion switching sensor corresponding unit 610 spaced apart from the motion switching sensor unit 620 is disposed. and a common moving holder connecting part 523 connected to the common moving holder body 521 and having an end disposed at an end of the common moving block 510 .

In the remote shift lever switching unit, the rotary part 300 includes: a rotary knob 310, at least a part of which is disposed on the end side of the lever housing 100, and relative rotation with the rotary knob 310 at one end It may include a rotary block 320 connected so as not to do so.

* In the remote shift lever switching unit, the rotary knob 310 includes: a rotary outer knob 310a disposed on an end side of the lever housing 100 and an inner side of the rotary outer knob 310, A rotary inner knob 310b that can be rotated relative to the inside of the lever housing 100 may be included.

In the remote shift lever switching unit, the rotary block 320 includes: a rotary block body 321 disposed inside the rotary inner knob 310b to limit relative rotation with the rotary inner knob 310b; It may include a rotary block body linear guide 323 which is disposed extending from the end of the rotary block body 321 and disposed through at least a portion of the lever button part.

In the remote shift lever switching unit, a rotary block body guide 322 is disposed on the outer periphery of the rotary block body 321, and the rotary inner nub 310b is positioned at a position corresponding to the rotary block body guide 322. An inner knob guide 319b capable of mating relative motion with the rotary block body guide 322 may be provided on the inside of the .

In the remote shift lever switching unit, a rotary block body linear guide through hole 324 that is formed through the rotary block body 321 may be provided.

In the remote shift lever switching unit, the rotary part 300 may include a rotary detent part 330 formed at one end of the lever housing 100 and the rotary block body 321 .

In the remote shift lever switching unit, the rotary detent unit 330 includes: a rotary detent groove 331 formed inside the lever housing 10 and a receiving arrangement in the rotary detent groove 331 . A rotary detent elastic part 333 that is, and the rotary detent elastic part 333 elastically supported by the rotary detent ball 335 and the rotary block body 321 are formed in the rotary detent ball It may also include a rotary detent 337 in contact with 335 .

In the remote shift lever switching unit, the lever button part 400 may be disposed through at least a part of the rotary part 300 .

In the remote shift lever switching unit, the lever button part 400 includes: a lever button knob 410 exposed to the outside as an end of the rotary part 300 and disposed through at least a part of the rotary part 300 . And, together with the lever button knob 410 , more specifically, it may include a lever button block 420 connected to the lever button knob 410 and linearly operated together with the lever button knob 410 .

In the remote shift lever switching unit, the lever button knob 410 includes: a lever button knob body 411 that can be pressed in the longitudinal direction of the lever housing 100 by a user, and the lever button knob body 411 It may include a lever button knob extension portion 413 that is formed extending from the rotary portion 300 and is disposed penetrating at least a portion of the rotary portion 300 .

In the remote shift lever switching unit, the lever button block 420 includes: a lever button block body 421 connectable to the lever button knob body 411; It may include a lever button block extension portion 423 connected to the common moving portion 500 through the rotary portion 300 .

* In the remote shift lever switching unit, the lever button knob 410 may include a lever button knob guide 415 that can be inserted and disposed relative to at least a portion of the rotary unit 300 to be movable in a straight line.

In the remote shift lever switching unit, the lever button unit 400 may include a lever button return unit 430 for returning to the original position when the pressing force applied to the lever button knob 410 is removed.

In the remote shift lever switching unit, the lever button return part 430 includes: a lever button return base 435 positioned so that the lever button block body 421 is disposed between the lever button knob 410 and , a lever button return support part 433 that is connected to the lever button return base 435 to variably protrude, and the other end of the lever button return support part 433 and directly with the lever button block body 421 It includes a lever button return body 431 in contact, and the lever button return body 431 may be provided with a lever button return body through-hole 432 allowing at least a portion of the rotary part 300 to pass therethrough.

In the remote shift lever switching unit, the lever button unit 400 includes a lever button stopper unit 440 that allows operation within a preset range of the lever button knob 410 of the lever button block 420 . may include

In the remote shift lever switching unit, the lever button stopper unit 440 includes: a lever button stopper 441 disposed inside the rotary unit 300 and a corresponding position of the lever button stopper 441 . It may include a lever button stopper corresponding portion 443 formed on the lever button knob 410 .

In the remote shift lever switching unit, the lever button stopper counterpart 443 may be formed of a material different from that of the lever button block 420 .

In the remote shift lever switching unit, a unit light source 710 disposed inside the lever housing 100 and a space inside the lever housing 100 are divided and output from the unit light source 710 A unit light source unit 700 including a unit light source light blocking rib 720 for spatially blocking light from being emitted may be further provided.

In the remote shift lever switching unit, the lever housing 100 includes a housing base 110 and a housing cover 120 that are engaged with each other, and is positioned inside the housing base 110 and the housing cover 120 . It is fixedly mounted and may further include a housing base holder 130 for fixing the position of the motion switching sensor unit 620 .

In the remote shift lever switching unit, the housing base holder 130 includes: a sensor holder body 131 disposed perpendicular to the lever substrate 200 disposed inside the lever housing 100; It may include a sensor holder fastening part 133 connected to the end of the sensor holder body 131 to be fixedly mounted on the lever substrate 200 .

In the remote shift lever switching unit, one surface of the sensor holder body 131 is formed through the sensor holder body 131 , and the motion switching sensor unit 620 is spaced apart through the sensor holder mounting unit 132 . It may directly face the correspondingly disposed motion switching sensor counterpart 610 .

In the remote shift lever switching unit, the motion switching sensor unit 620 is disposed on one surface of the lever sub board 210 of the lever board 200 and disposed on the other surface of the sensor holder body, and the lever board A sensor holder substrate caulking 135 connected to the lever sub substrate 210 of 200 and fixing the position of the lever sub substrate 210 may be further provided.

In the remote shift lever switching unit, the lever housing 100 includes a housing base 110 and a housing cover 120 that are engaged with each other, and the motion switching sensor unit 620 includes the motion switching sensor corresponding unit ( 610) and may be disposed directly on the lever substrate 200 side.

In the remote shift lever switching unit, the motion switching sensor unit 620 may be disposed directly on the lever substrate 200 , and the motion switching sensor counterpart 610 and the mounting surface may be disposed orthogonal to each other.

According to the present invention, it is possible to provide a remote shift lever switching unit that implements a shift-by-wire function of a shift lever device of a vehicle and improves operation reliability and durability.

In addition, the remote shift lever switching unit of the present invention may enable a compact configuration by integrating the rotary operation and the lever button operation through the common moving unit, but changing the position or direction of the operation flow.

In addition, the remote shift lever switching unit of the present invention can achieve cost reduction due to productivity enhancement by minimizing components and increasing design freedom due to this, as well as improving assembly properties.

In addition, the remote shift lever switching unit of the present invention can minimize the mounting space through the interference prevention structure of the arrangement area of the rotary/lever button operation, and can prevent or minimize the possibility of malfunction due to interference between components.

Although the remote shift lever switching unit of the present invention has been mainly described with a shift lever switch structure for realizing shift-by-wire, it is clear that the operation structure of the rotary and lever button switches of the present invention can be applied to various switching functions of a vehicle. do.

1 is a schematic perspective view of a remote shift lever switching unit according to an embodiment of the present invention.
2 is a partial perspective view of a rotary operation and a lever button operation portion of the remote shift lever switching unit according to an embodiment of the present invention.
3 is a schematic exploded perspective view of a remote shift lever switching unit according to an embodiment of the present invention.
4 is a partially enlarged perspective view of FIG. 3 ;
5 is a schematic plan view of a remote shift lever switching unit according to an embodiment of the present invention.
Fig. 6 is a partial cross-sectional view taken along line AA of Fig. 5;
FIG. 7 is a partially enlarged view of reference numeral B of FIG. 6 .
8 is a schematic plan view from another viewpoint of the remote shift lever switching unit according to an embodiment of the present invention.
Fig. 9 is a schematic partial cross-sectional view taken along line DD in Fig. 8 ;
FIG. 10 is a partially enlarged view of reference numeral E of FIG. 9 .
11 is a partially enlarged view of reference numeral F of FIG. 10 .
12 is a schematic partial enlarged perspective view of a housing sensor holder and a lever substrate of a remote shift lever switching unit according to an embodiment of the present invention.
13 is a schematic partial enlarged perspective view of a housing sensor holder and a lever substrate disposed in a lever housing of a remote shift lever switching unit according to an embodiment of the present invention.
14 is a schematic partial enlarged perspective view of a lever sub substrate of a lever substrate attached to a housing sensor holder of a remote shift lever switching unit according to an embodiment of the present invention.
15 and 16 are partial cross-sectional views of a lever button unit, a common moving unit, and a motion switching unit before and after operation of the remote shift lever switching unit according to an embodiment of the present invention.
17 is an exploded perspective view of a remote shift lever switching unit according to an embodiment of the present invention.
18 is a partial cross-sectional view of an end of a remote shift lever switching unit according to an embodiment of the present invention.
19 is a partial front cross-sectional view of a remote shift lever switching unit according to an embodiment of the present invention.
20 is a partial enlarged view of reference numeral H of FIG. 19 of a remote shift lever switching unit according to an embodiment of the present invention.
21 and 22 are enlarged partial cross-sectional views of the portion indicated by the reference numeral G of FIG. 18 of the remote shift lever switching unit according to an embodiment of the present invention, the position change according to the pressing operation of the lever button knob 410 It is a diagram illustrating a change in the relative distance between the motion switching sensor corresponding unit 610 and the motion switching sensor unit 620 .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

The remote shift lever switching unit 10 of the present invention is a switch device, and in particular, as a specific embodiment of the present invention, a vehicle that converts the shift state of the vehicle into an electrical signal away from a direct physical operation method through a physical connection of the vehicle's shifting device Although it is mainly described when it is implemented as a switching unit for implementing the shift-by-wire of , the present invention is not limited thereto, and various applications are possible as a component for implementing various switching operations of a device, particularly a vehicle.

The remote shift lever switching unit 10 of the present invention is a remote shift lever unit disposed on a side of a steering wheel connected to a steering shaft of a vehicle. The remote shift lever switching unit 10 of the present invention includes a lever housing 100 and; It includes a rotary unit 300, a lever button unit 400, a common moving unit 500, and a motion switching unit 600, and may be formed in an integrated base substrate structure in some cases, but in this embodiment In the description, a case in which the lever substrate 200 is provided is mainly described.

The lever housing 100 is disposed on the steering shaft side, and more specifically, the radial direction of the steering shaft (not shown) is formed in the longitudinal direction.

The lever housing 100 includes a housing base 110 and a housing cover 120 , and in some cases, a housing base holder 130 and a housing cover display 140 , wherein the housing base holder 130 has an internal space. In addition, the housing cover display 140 may be disposed outside the housing cover 120 .

The housing base 110 includes a base shaft body 111 and a base knob body 113 , and the base shaft body 111 includes a shaft body mounting part 115 mounted on the steering wheel side of the vehicle. The base knob body 113 is connected to the end side of the base shaft body 111 to enable a shift selection operation of a user, that is, a driver. An end of the base shaft body 111 is provided with a shaft body coupling part 112 , which is engaged with the cover body coupling part 122 on the side of the housing cover 120 to be described below to form a coupling structure.

1 and 3, the housing cover 120 is a component implemented as a lever-type housing having a rectangular length, and is formed in a configuration having a shorter length than the housing base 110. Various selections are possible according to design specifications. do. The cover body 121 of the housing cover 120 is engaged with the base shaft body 111 of the housing base 110 to form an internal space. The end of the cover body 121 is provided with a shaft body coupling part 112, which is engaged with the cover body coupling part 122 on the side of the housing cover 120 to form a coupling structure as described above. do.

In addition, a cover body connector through-hole 123 is formed at a lower side of the cover body 121 to serve as a mounting hole for connection with an external electric device.

Other components such as the lever substrate 200 are disposed in the inner space formed by the housing cover 120 and the housing body 110 . It may be configured to be inserted into the lever housing, but the wiring line in this embodiment is implemented with the lever substrate 200 .

The lever substrate 200 is fixedly positioned in the inner space formed by the housing cover 120 and the housing body 110 , and a separate substrate fastening part 202 for fixing and mounting the lever substrate 200 is further provided. it might be A lever board connector 201 is disposed on one surface of the lever board 200 , and the lever board connector 201 is connected to an external electrical device through the cover body connector through hole 123 to achieve electronic signal transmission. have. That is, the lever substrate 200 is connected to an external electric device, for example, a control unit (not shown) side of the vehicle to facilitate transmission of signal changes manipulated by the user, and a power supply function through connection with an external power device. can also be performed. At least a portion of the motion switching unit 600 to be described below is disposed on the lever substrate 200 to achieve electrical communication.

The lever board 200 of the present invention is provided with a lever board sub connector 203 , and includes at least a part of the lever board 210 , that is, the lever sub board 210 as a separate sub board, the lever sub board 210 . ) acts as a component connected through the lever board sub-connector 203 . The lever sub-board 210 is implemented in the form of an FPCB in this embodiment so that a predetermined position change is possible. It detects the operation of the rotary unit 300 and/or the lever button unit 400 disposed on the and the common moving unit 500 operated thereby.

At least a portion of the rotary unit 300 is disposed at one end of the lever housing 100 to form a structure in which at least a portion is rotatably movable with respect to the length of the lever housing 100 . That is, the rotary unit 300 may detect and execute a switching operation according to a predetermined rotary operation of the motion switching unit 600 through a rotation operation with the longitudinal direction of the lever housing 100 as the central axis of rotation. ) includes a rotary knob 310 and a rotary block 320 . At least a portion of the rotary knob 310 is disposed on the end side of the lever housing 100 . More specifically, the rotary knob 310 includes a rotary outer knob 310a and a rotary inner knob 310b. The rotary outer knob 310a is disposed on the end side of the lever housing 100, and the rotary outer knob 310a is configured to have a flat portion with an outer peripheral surface cut out by a predetermined cutout so that a driver may grip or pinch to achieve operation convenience.

The rotary outer knob 310a forms a through structure, and an outer knob through hole 311a is formed at the outer end of the rotary outer knob 310a to form another component, that is, the lever button knob 410 of the lever button unit 400. ) to be exposed to the outside.

An outer knob fastening part 317a is provided inside the opposite side of the end where the outer knob through hole 311a of the rotary outer knob 310a is formed, and the outer knob fastening part 317a is an inner provided in the rotary inner knob 310b. It is engaged with the knob fastening part 317b to prevent relative rotation of the rotary outer knob 310a and the rotary inner knob 310b, and the rotational force provided by the user is transferred to the rotary inner knob 310b as it is.

The rotary inner knob 310b is disposed on the inside of the rotary outer knob 310 and has a structure that can be rotated relative to the inside of the lever housing 100, and the rotary inner knob 310b is, as described above, the rotary outer knob ( 310a) and opponents are restricted. The rotary inner knob 310b has an inner knob through hole 311b formed at one end thereof, and one end of the lever button knob 410 can be disposed therethrough, and the inner knob through hole 311b is the rotary inner knob 310b. A through structure may be formed, and the lever button knob guide 415 of the lever button knob 410 of the lever button part 400 to be described below is relatively movably accommodated in the inner knob through hole 311b.

In addition, an inner knob extension through-hole 312b of the rotary inner knob 310b is provided, and the lever button knob extension 413 is movable through the inner knob extension through-hole 312b to form an inner Allows relative movement of the knob extension through-hole 312b and the lever button knob extension 413 .

An inner knob rib 313b is disposed at an end opposite to the rotary inner knob 310b, and the inner knob rib 313b forms a plurality of separate rib piece structures to be accommodated inside the base knob body 113 . An inner knob rib guide protrusion 315b is formed on the outer circumferential surface of the inner knob rib 313b to protrude in the outer circumferential direction, and engages with the inner portion of the base knob body 113 of the housing base 120 to prevent separation and separation, A structure in which the rotary inner knob 310b is relatively rotatably mounted to the housing base 120 of the lever housing 100 may be formed.

An inner knob block accommodating part 318b is provided inside the rotary inner knob 310b, and at least a portion of the rotary block 320 is accommodated in the inner knob block accommodating part 318b.

The rotary block 320 is connected so as not to rotate relative to the rotary knob 310 at one end, and the rotary block 320 includes a rotary block body 321 and a rotary block body linear guide 323 .

The rotary block body 321 is disposed inside the rotary inner knob 310b to limit relative rotation with the rotary inner knob 310b. As described above, the rotary block body 321 has an inner knob block receiving portion 318b. is accepted in

In this case, the rotary block body 321 may further include a guide element for guiding the engagement state to prevent relative motion with the rotary knob 310 and to prevent unnecessary ratchet noise. That is, the rotary block body guide 322 is disposed on the outer periphery of the rotary block body 321 , and the rotary block body guide 322 is located inside the rotary inner nub 310b to a position corresponding to the rotary block body guide 322 . ) and an inner knob guide 319b capable of engaging relative movement, the rotary block body guide 322 and the inner knob guide 319b form an engaging configuration with each other to prevent relative rotation between components and assemble in-place can be further strengthened.

In addition, the rotary block body linear guide 323 is disposed on the outside of the rotary block body 321, the rotary block body linear guide 323 is a linear relative movement with the lever button block 420 of the lever button part 400 can guide you. That is, the rotary block body linear guide 323 penetrates through the lever button block body through-hole 422 formed in the lever button block body 421 formed in the lever button block 420 of the lever button unit 400 to penetrate the lever. It is possible to enable a stable linear motion by the pressing force input through the button knob 410 .

A space for accommodating at least a portion of the common moving block 510 of the common moving unit 500 to be described later is formed at the other end of the rotary block body 321 . That is, the rotary block body common accommodating part 3231 is formed at the other end of the rotary block body 321, and the rotary block body common accommodating part 3231 forms a prismatic structure to form a rotary block body 321 and common moving. It is also possible to prevent relative rotation between the units 500 .

In addition, a predetermined rotary block body common stopper 3211 is formed in the rotary block body common accommodating part 3231, and the rotary block body common stopper 3211 is a common moving block 510 of the common moving part 500 to be described later. In engagement with the common moving block locker 515 of the, relative rotation is limited with respect to the axial rotation operation about the longitudinal direction of the lever housing 100 as an axis.

On the other hand, the rotary unit 300 according to an embodiment of the present invention provides a sense of operation to the user by detenting the rotation of the rotary knob 310) and the rotary detent unit 330 for stealing a predetermined operating position. includes The rotary detent portion 330 is formed at one end of the lever housing 100 and the rotary block body 321 , the rotary detent portion 330 includes a rotary detent groove 331 and a rotary detent elastic portion 333 . ), and a rotary detent ball 335 and a rotary detent 337 .

The rotary detent groove 331 is formed inside the lever housing 100 , and the rotary detent groove 331 is formed in the base knob body 113 of the housing base 110 of the lever housing 100 . A rotary detent elastic part 333 is accommodated in the rotary detent groove 331 , and one end of the rotary detent elastic part 333 is elastically supported by the inside of the rotary detent groove 331 , and the rotary detent groove 331 . The other end of the elastic part 333 elastically supports the rotary detent ball 335 . The rotary detent elastic part 333 is implemented as a coil type in this embodiment, but is not limited thereto. The rotary detent ball 335 is elastically supported by the rotary detent elastic part 333 , and the rotary detent ball 335 is in contact with the rotary detent 337 . That is, the rotary detent 337 is formed in the rotary block body 321 and is in contact with the rotary detent ball 335 , the rotary detent 337 according to an embodiment of the present invention is a predetermined preset detent. have a profile.

On the other hand, the remote shift lever unit 10 of the present invention includes a lever button unit 400, the lever button unit 400 is disposed through at least a portion of the rotary unit 300 to enable a more compact configuration. . More specifically, the lever button unit 400 includes a lever button knob 410 and a lever button block 420 .

The lever button knob 410 is exposed to the outside as an end of the rotary part 300 and is disposed through at least a portion of the rotary part 300 , and the lever button block 420 is connected to the lever button knob 410 and the lever button It is linearly operated together with the knob 410 . That is, one end of the lever button knob 410 is exposed to the outside to enable a user's pressing operation, and the lever button knob 410 penetrates the rotary unit 300 to form the rotary unit 300 and the lever housing 100 . posted on the side

More specifically, the lever button knob 410 includes a lever button knob body 411 and a lever button knob extension portion 413 , the lever button knob body 411 is the length of the lever housing 100 by the user. direction, the lever button knob extension portion 413 is formed to extend from the lever button knob body 411 , and is disposed through at least a portion of the rotary portion 300 . That is, a curved surface is formed on the outer surface of the lever button knob body 411 to facilitate the user's pressing operation, and the lever button knob extension part 413 on the inner surface of the lever button knob body 411 is The lever button knob extension portion 413 is formed to extend apart from two in this embodiment, and the number is not limited thereto as an example, but in this embodiment two are spaced apart to ensure stable operation. take

The lever button knob extension portion 413 is provided with a lever button knob extension engaging portion 414, and the lever button knob extension engaging portion 414 closes the inner knob extension portion through-hole 312b formed in the rotary inner knob 310b. By forming a physical connection structure through engagement with the lever button block body knob extension engaging portion 425 disposed on the lever button block body 421 of the lever button block 420 through, the pressing force is applied to the lever button knob 410 If present, the pressing force is transmitted to the lever button block 420 through the lever button knob 410 so that it can be operated in a straight line.

Meanwhile, the lever button knob 410 may include a lever button knob guide 415 . That is, the lever button knob 410 includes a lever button knob guide 415 , and the lever button knob guide 415 is formed in at least a portion of the rotary part 300 , more specifically, in the center of the rotary inner knob 310b. As described above, it is possible to take a relatively movable structure through the inner knob through hole 311b, achieve stable operation of the lever button knob 410, and prevent rattle noise caused by micro vibration.

The lever button block 420 includes a lever button block body 421 and a lever button block extension 423 . The lever button block body 421 is connectable to the lever button knob body 411 , and the lever button block extension part 423 is connected to the lever button block body 421 and penetrates the rotary part 300 to form a common moving part. (500) is connected. The lever button block body knob extension engaging portion 425 disposed on the lever button block body 421 of the lever button block 420 is engaged with the lever button knob extension engaging portion 414, and the lever button block extension portion 423 ) is disposed through the rotary block body through-hole 324 formed in the rotary block body 321 of the rotary block 320 to be relatively movable.

The lever button unit 400 may include a lever button return unit 430 , wherein the lever button return unit 430 returns the lever button knob 410 to its original position when the pressing force applied to the lever button knob 410 is removed. bring it back More specifically, the lever button return unit 430 includes a lever button return base 435 , a lever button return support 433 , and a lever button return body 431 .

The lever button return base 435 is positioned such that the lever button block body 421 is disposed between the lever button knob 410, and the lever button return support 433 is connected to the lever button return base 435 so as to be variably variable. It is formed to protrude, and the lever button return body 431 is connected to the other end of the lever button return support 433 and is in direct contact with the lever button block body 421 . In this embodiment, the lever button return unit 430 has been described as having a rubber pad structure, but various modifications are possible within a range that provides an elastic support force.

On the other hand, when providing a return force through the lever button return portion 430 of the lever button portion 400 of the present invention, malfunction due to excessive operation or to prevent or minimize rattling noise due to contact between components generated during the return operation It may further include a component that That is, the lever button unit 400 may include a lever button stopper unit 440 , the lever button stopper unit 440 operates within a preset range of the lever button knob 410 of the lever button block 420 . allow

More specifically, the lever button stopper portion 440 includes a lever button stopper 441 and a lever button stopper corresponding portion 443 . The lever button stopper 441 is disposed inside the rotary part 300 , and the lever button stopper corresponding part 443 is formed in the lever button knob 410 at a position corresponding to the lever button stopper 441 . In this embodiment, the lever button stopper counterpart 443 is formed of a material different from that of the lever button block 420 .

That is, in this embodiment, a lever button stopper 441 protruding toward the lever button block body 421 of the lever button block 420 is disposed inside the rotary inner knob 310b of the rotary part 300, A lever button stopper corresponding portion 443 is disposed on one surface of the lever button block body 421 as a corresponding position of the lever button stopper 441, and in this embodiment, the lever button stopper corresponding portion 443 is made of a predetermined soft material in advance. It is selected as a material having elasticity within a set range.

The lever button block body damper arrangement part 426 is formed in the lever button block body 421 , and the lever button block body damper arrangement part 426 is a body damper stopper arrangement part formed on one surface of the lever button block body 421 . 4261 , a body damper engaging arrangement portion 4263 , and a body damper return arrangement unit 4265 .

The body damper stopper arrangement 4261 is formed on one surface facing the lever button stopper 441 , and the body damper stopper arrangement 4263 is connected to the body damper stopper arrangement 4261 , the body damper stopper arrangement 4263 ) extends to the inside of the lever button block body 421, and the body damper stopper return arrangement 4265 is formed on the opposite side of the side where the body damper stopper arrangement part 4261 is disposed. The lever button stopper corresponding part 443 is formed of an elastic soft material of a different material through the double injection structure, and the lever button stopper corresponding part 443 includes the lever button block damper body part 4431 and the lever button block damper knob part. 4433 , and a lever button block damper return portion 4435 .

The lever button block damper knob part 4433 is exposed to the body damper stopper arranging part 4261 , and the lever button block damper return part 4435 faces the lever button return part 430 and the body damper return part 4265 is disposed. ), and the lever button block damper body portion 4431 connects the lever button block damper knob portion 4433 and the lever button block damper return portion 4435 to the inner space of the lever button block body 421 . do.

Through such a configuration, it is possible to prevent the occurrence of rattling noise or the like generated during the operation of the lever button block body or due to minute vibration, and it is also possible to limit excessive operation.

On the other hand, in the remote shift lever unit in an embodiment of the present invention, the common moving part 500 is connected to the rotary part 300 and the lever button part 400 to at least one of the rotary part 300 and the lever button part 400 . It is movable in conjunction with any one operation, and the common moving unit 500 is movable in a straight line along the longitudinal direction of the lever housing 100 and is rotatable around the longitudinal direction of the lever housing 100 .

More specifically, the common moving unit 500 includes a common moving block 510 and a common moving holder 520, wherein the common moving block 510 is contacted with the rotary unit 300 and connected to the lever button unit ( 400) to receive an operating force from at least one of the rotary unit 300 and the lever button unit 400, and the common moving holder 520 is disposed at the end of the common moving block 510 to provide a common moving block ( It operates together with 510 and a motion switching sensor counterpart 610 is disposed.

The common moving block 510 includes a common moving block body 511 , a common moving block button body 513 , and a common moving block locker 515 .

The common moving block body 511 has a common moving holder 520 disposed at one end, the common moving block body 511 is formed in a predetermined rod shape, and the end of the common moving block body 511, that is, the lever button knob A common moving block button body 513 is disposed on the end side facing the 410 . In the present embodiment, the common moving block body 511 and the common moving block button body 513 are integrally formed, but various modifications are possible, such as being formed separately from each other and having a connected structure.

A common moving holder 520 is disposed at the other end of the common moving block body 511 , and the common moving holder 520 includes a common moving holder body 521 and a common moving holder connecting portion 523 . The common moving holder body 521 has a motion switching sensor counterpart 610 disposed on one surface facing the motion switching sensor 620 of the busbar switching unit 600 to be described below, and the other of the common moving holder body 521 . A common moving holder connection part 523 is disposed on one surface

The common moving block button body 513 is disposed at the other end of the common moving block body 511 and is directly connected to the lever button unit 400. On the outer periphery of the common moving block button body 513, the rotary unit 300 At least a part of the lever button part 400 disposed through at least a part thereof, and a common moving block button body coupling part 514 directly connected thereto are provided.

That is, the common moving block button body coupling part 514 formed on the outer periphery of the common moving block button body 513 is the lever button block of the lever button part 400 disposed through at least a part of the rotary part 300 ( It is directly connected to the lever button block extension locking portion 424 formed on the lever button block extension portion 423 of the 420 , and can receive the pressing force input through the lever button portion 400 intact.

On the other hand, the common moving block button body 513 is accommodated in the rotary block 320 of the rotary unit 300, the rotary block 320 of the rotary unit 300 includes a rotary block body receiving portion 3231, One end of the common moving block button body 513 may be linearly movably received and disposed inside the rotary block body receiving portion 3231 of the rotary block 320 .

At this time, perpendicular to the longitudinal direction of the lever housing 100 of the common moving block button body 513 to prevent relative rotation between the common moving block 510 and the rotary block 320 having the common moving block button body 513. The cross-section on the plane may be a polygonal cross-section, in particular a rectangular cross-sectional structure. Through this configuration, the common moving block button body 513 has the rotary block body receiving part 3231 inserted, and the relative rotation between the rotary block 320 and the common moving block 510 is limited through the angular engagement structure, so that the user When the rotary knob 310 is rotated, the rotating operation is accurately transmitted to the common moving block 510 and the common moving holder 520 .

In this embodiment, the rotary block body receiving portion 3231 is formed in the rotary block body 321 and is connected to the rotary block body through hole 324 allowing the lever button block extension portion 423 to move through it.

In addition, when the common moving block button body 513 is accommodated in the rotary block body accommodating part 3231, it may further include a component for guiding stable accommodation and stable linear operation of the common moving block 520 . That is, a common moving block button body guide 516 is provided on the outer periphery of the common moving block button body 513 , and in a position corresponding to the common movie block button body guide 516 , the rotary block body accommodating part 3231 is inside. A common moving block button body guide corresponding portion corresponding to the common moving block button body guide 516 is disposed. In FIG. 10, due to the characteristics of the cross-sectional view, the rotary block body receiving part 3231 has a common moving block button body guide corresponding part included on the inside, but the common moving block button body guide corresponding part is in the direction perpendicular to the paper of FIG. It is clear from the present invention that the configuration is formed as a groove as much as the thickness of the common moving block button body guide 516 .

On the other hand, a component for limiting the relative rotation between the common moving block 520 and the lever button block 420 may be further provided. That is, the common moving block locker 515 is formed on the outer peripheral surface of the common moving block button body 513, and the common moving block locker 515 is at least one of the common moving block body 511 and the common moving block button body 513. It is disposed on the outer periphery of any one engages with the rotary unit 300 to limit the relative rotation. In this embodiment, the common moving block locker 515 has a configuration disposed on the outer periphery of the common moving block button body 513, and the rotary block 320 has a rotary block body to the corresponding position of the common moving block locker 515. A common stopper 3211 is formed so that the relative rotation is limited through engagement of both. That is, a predetermined rotary block body common stopper 3211 is formed in the rotary block body common receiving part 3231 toward the end of the common moving holder 520 side of the rotary block 320, the rotary block body common stopper ( 3211 is engaged with the common moving block locker 515 of the common moving block 510 of the common moving unit 500 . That is, when the user provides a rotational force to the rotary knob 310 because the relative rotation is limited with respect to the shaft rotational operation with the longitudinal direction of the lever housing 100 as the axis, the lever housing 100 smoothly rotates without a play in the circumferential direction and rotates accurately. You can also implement actions.

On the other hand, as described above, the common moving holder 520 is disposed on the other end side of the common moving block body 511, and the common moving holder 520 includes the common moving holder body 521 and the common moving holder connecting part 523. ), and the common moving holder body 521 has a motion switching sensor counterpart 610 disposed on one surface facing the motion switching sensor unit 620 of the busbar switching unit 600 to be described below, and the common moving holder body A common moving holder connecting portion 523 is disposed on the other side of the 521, and in this embodiment, a common moving block holder receiving portion 517 is included at one end of the common moving block body 511, the common moving block holder receiving A portion of the common moving holder 520 is accommodated in the unit 517 .

The common moving holder connection part 523 is integrally formed with the common moving holder body 521 in this embodiment, and the common moving holder connection part 523 is provided at the end of the common moving holder connection part 523, and the common moving block body is provided. The end of the common moving holder connecting portion 523 is disposed in the common moving block holder receiving portion 517 of 511 . At this time, the common moving block holder fastening part 525 is provided on the outer periphery of the common moving holder connecting part 523, and the common moving block holder fastening part 518 is provided at an equal position on the common moving block body 511. When the common moving holder connection part 523 is inserted into the common moving block holder receiving part 517 of the moving block body 511, the common moving block holder coupling part 525 is engaged with the common moving block holder coupling part 518. to form a fastening structure.

In addition, a guide element for stable mounting when the common moving holder connecting portion 523 and the common moving holder body 521 of the present embodiment are coupled may be further provided. That is, on the outer periphery of the common moving block holder connecting portion 523, a common moving holder connecting portion guide 527 that forms an insertion and mounting direction in the longitudinal direction is further provided, and the common moving block holder receiving portion of the corresponding common moving block body 5110 ( When a guide groove (not shown) corresponding to the inner surface of the 517 is provided, or the common moving holder connection part 523 is inserted into the common moving block holder receiving part 517 of the common moving block body 511, stable insertion It can also be made to form a structure.

The motion switching unit 600 detects the operation of the common moving unit 500 when the common moving unit 500 is in operation. As described above, the motion switching unit 600 includes the motion switching sensor unit 620 and and a motion switching sensor counterpart 610 .

The motion switching unit 600 includes a motion switching sensor unit 620 and a motion switching sensor correspondence unit 610 . The motion switching sensor unit 620 is disposed inside the lever housing 100 , and the motion switching sensor corresponding unit 610 is disposed at the end of the common moving unit 500 as a corresponding position of the motion switching sensor unit 620 . . The motion switching sensor unit 620 is disposed on the lever sub substrate 201 of the lever substrate 200, the motion switching sensor unit 620 is implemented as a magnetic sensor, and the motion switching sensor counterpart 610 is implemented as a magnet. , motion switching sensor unit 620 with the proximity of the motion switching sensor corresponding unit 610, the motion switching sensor unit 620 detects the change state of the room according to the rotation of the motion switching sensor corresponding unit 610, the change angle Sensing is achieved, which is transmitted to a control unit (not shown) to determine a shift operation selected by the driver through a predetermined control process, and transmits a predetermined shift range signal to the main control unit (ECU) of the vehicle.

In this embodiment, in which the motion switching sensor unit 620 detects according to the rotation of the motion switching sensor corresponding unit 610, it is possible to select a shift range of D, ND, N, NR, R according to each shift range, P In the selection of the parking shift range operation, the motion switching sensor unit 620 detects proximity according to the linear operation of the motion switching sensor response unit 610 through the operation operation of the lever button unit 400 to select a predetermined parking shift range. can also be run.

On the other hand, compared to the motion switching sensor counterpart 610 of the motion switching sensor unit 620 of the present invention, a component for occupying a more accurate position may be further provided. That is, the lever housing 100 may further include a housing base holder 130 in addition to the housing base 110 and the housing cover 120 . The housing base holder 130 is coupled to the sensor holder body 131 and the sensor holder. part 133 .

The sensor holder body 131 is disposed in a form perpendicular to the lever substrate 200 , and one surface of the sensor holder body 131 is disposed to have a surface perpendicular to the corresponding motion switching sensor counterpart 610 . have a configuration

A sensor holder substrate caulking 135 is disposed on the other surface of the sensor holder body. The sensor holder substrate caulking 135 is disposed on the other surface of the sensor holder body, and the sensor holder substrate caulking 135 is connected to the lever sub substrate 210 . That is, the sensor holder substrate caulking 135 forms a protruding structure in this embodiment, and a lever sub substrate caulking counterpart 211 engaged with the sensor holder substrate coding 135 is formed on one surface of the lever sub substrate 210 . to form an interlocking structure.

In some cases, the lever sub-board caulking counterpart 211 engaged with the sensor holder substrate coding 135 may form a cogging coupling structure with each other through a caulking process. That is, through the caulking process of hot caulking to form a caulking bond by applying heat or cold caulking to form a caulking bond by cold work, the sensor holder substrate coding 135 and the lever sub-board caulking counterpart 211 are coupled to each other, It is also possible to prevent the risk of unnecessary rattling noise or errors due to positional fluctuations by solidifying the bonding state of the two without being separated even by minute vibrations.

The sensor holder fastening part 133 is connected to the end of the sensor holder body 131 and disposed vertically, more specifically, the sensor holder fastening part 133 has a fastening through hole formed therein, and the substrate fastening part 202 ) is fixed to the lever board 200 through a fastening through-hole formed in the sensor holder fastening part 133 so that the sensor holder fastening part 133 is positioned and fixed to the lever board 200 . The position is fixed to the lever substrate 200 .

The sensor holder mounting part 132 is formed through the sensor holder body 131, and on one surface of the lever sub-board 210 disposed on the other surface of the sensor holder body 131, the motion switching sensor part ( 620 is disposed, and the motion switching sensor unit 620 directly faces the motion switching sensor corresponding unit 610 disposed at a distance through the sensor holder mounting unit 132 to minimize interference, and the motion switching sensor corresponding unit 610 ) of the rotation or movement state can be detected.

In addition, the remote shift lever unit 10 of the present invention may further include an optical output device for facilitating confirmation of the selected shift range. That is, the remote shift lever unit 10 includes a unit light source unit 700, and the unit light source unit 700 includes a unit light source 710, and in some cases, a separate unit light transmission unit (not shown). Alternatively, the lever housing 100 includes a housing cover display 140 as described above, wherein the housing cover display 140 is disposed outside the housing cover 120 . Each shift range icon 141 is displayed on the housing cover display 140 through a method such as laser etching, and the light emitted from the unit light source 710 is transmitted to the housing cover display 140, which is each shift range. It may be output to the outside through the icon 141 to enhance the driver's visibility. In this case, in order to prevent the light emitted from the unit light source unit 710 from being transmitted to the shift range icon 141 on the other side in some cases, the unit light source unit 700 may further include a unit light source light blocking rib 720, The unit light source blocking rib 710 may be disposed on the housing base 110 and/or housing cover 120 side of the lever housing 100 .

The above embodiments are examples for explaining the present invention, and the present invention provides at least a part of the lever button part 400 that is movable along the length of the lever housing 100 by being disposed at one end of the lever housing 100, and the A common moving part 500 connected to the rotary part 300 and the lever button part 400 and capable of interlocking with at least one operation of the rotary part 300 and the lever button part 400, and the common Various modifications are possible within the scope of providing the remote shift lever unit 10 including a motion switching unit 600 that detects the operation of the common moving unit 500 when the moving unit 500 is operated.

That is, in the above embodiments, in comparison with the motion switching sensor counterpart 610 of the motion switching sensor unit 620 of the present invention, a case has been described in which a component for occupying a more accurate position has been described, but the provided motion According to the configuration of the switching sensor unit 620 and/or the motion switching sensor corresponding unit 610 , the motion switching sensor unit 620 is disposed directly on the lever board 200 side without a separate housing base holder 130 . It is also possible to take a configuration that is

That is, the lever housing 100 includes a housing base 110 and a housing cover 120 that are engaged with each other, and the motion switching sensor unit 620 is spaced apart from the motion switching sensor counterpart 610 to the lever substrate 200 . It can take a structure disposed directly on the side, more specifically, the motion switching sensor unit 620 of the present invention is disposed directly on the lever substrate 200, the motion switching sensor unit 620 and the motion switching sensor corresponding unit ( The arrangement surface of 610 may take a structure in which it is orthogonally arranged. 17 is an exploded perspective view of the remote shift lever unit 10, FIG. 18 is a partial cross-sectional view of the end of the remote shift lever unit 10, FIG. 19 is a partial front sectional view of the remote shift lever unit 10 is shown, in FIG. 20 is a partial enlarged view of the reference numeral H in FIG. 19, and in FIGS. 21 and 22 are enlarged partial cross-sectional views of the portion indicated by the reference symbol G in FIG. 18, the lever button knob 410 ), a relative distance change between the motion switching sensor corresponding unit 610 and the motion switching sensor unit 620, the position of which varies according to the pressing operation, is shown.

Unlike the previous embodiment, the lever housing 100 includes a housing base 110 and a housing cover 120 , and the motion switching sensor unit 620 is disposed in a space between the housing base 110 and the housing cover 120 . The lever substrate 200 side, that is, the plane where the motion switching sensor unit 620 is disposed and the plane formed by the motion switching sensor corresponding unit 610 are fixed and disposed directly on the bottom/rear side of the lever substrate 200 They may be formed in relative positions to take a structure that is orthogonal to each other. In this case, unlike in the previous embodiment, by taking a configuration excluding the housing base holder 130, it is possible to improve the assembling property.

As shown in FIGS. 21 and 22 , when the pressing operation of the lever button knob 410 is performed, the position of the motion switching sensor corresponding unit 610 is changed by the interaction between the above-described components, and the motion switching sensor unit The distance between the 620 and the motion switching sensor counterpart 610 is changed from the relative distance of reference numeral d1 to the relative distance of reference numeral d2. The switching sensor unit 620 and the motion switching sensor corresponding unit 610 may detect or perform a push operation due to a signal change caused by a change in magnetic flux according to a mutual position change. However, in some cases, when such a direct arrangement structure is adopted, a software or sensitivity performance improvement structure may be adopted to correct inaccuracies due to operation or mounting position errors. The magnet arrangement structure of the motion switching sensor counterpart 610 may take an NS pole arrangement in which the interface between the N pole and the S pole is orthogonal to the plane formed by the motion switching sensor counterpart 610, and in some cases, the motion switching sensor Various configurations are possible according to design specifications, such as the N pole arrangement structure in which the interface between the N pole and the S pole of the corresponding unit 610 is parallel to the plane formed by the motion switching sensor corresponding unit 610 .

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

10...Remote shift lever switching unit
100...Lever housing 200...Lever board
300...Rotary part 400...Lever button part
500...Common moving part 600...Motion switching part

Claims (5)

A remote shift lever unit disposed on a side of a steering wheel connected to a steering shaft of a vehicle, the remote shift lever unit comprising:
A lever housing 100 disposed on the steering shaft side, and
At least a part of the rotary part 300 is disposed at one end of the lever housing 100, and at least a part of the rotary part 300 is rotatable with respect to the length of the lever housing 100;
At least a part of the lever button part 400 is disposed at one end of the lever housing 100 and is movable along the length of the lever housing 100;
A common moving unit 500 connected to the rotary unit 300 and the lever button unit 400 and capable of interlocking with at least one operation of the rotary unit 300 and the lever button unit 400;
and a motion switching unit 600 for detecting the operation of the common moving unit 500 when the common moving unit 500 is operated,
The motion switching unit 600 includes: a motion switching sensor unit 620 and a motion switching sensor corresponding unit 610 disposed at an end of the common moving unit 500 to a corresponding position of the motion switching sensor unit 620 . including,
The lever housing 100 includes a housing base 110 and a housing cover 120 that are engaged with each other, and is fixedly mounted inside the housing base 110 and the housing cover 120 so that the motion switching sensor unit ( The remote shift lever unit (10), characterized in that it further comprises a housing base holder (130) for fixing the position (620).
The method of claim 1,
The housing base holder 130 includes:
a sensor holder body 131 disposed in a form perpendicular to the lever substrate 200 disposed inside the lever housing 100;
The remote shift lever unit (10) comprising a sensor holder fastening part (133) connected to an end of the sensor holder body (131) and fixedly mounted on the lever substrate (200).
3. The method of claim 2,
One surface of the sensor holder body 131 is formed through the sensor holder body 131,
The remote shift lever unit (10), characterized in that the motion switching sensor unit (620) directly faces the motion switching sensor corresponding unit (610) disposed to correspond to a spaced apart through the sensor holder mounting unit (132).
4. The method of claim 3,
The motion switching sensor unit 620 is disposed on one surface of the lever sub substrate 210 of the lever substrate 200,
and a sensor holder substrate caulking 135 disposed on the other surface of the sensor holder body, connected to the lever sub substrate 210 of the lever substrate 200, and fixing the position of the lever sub substrate 210. A remote shift lever unit (10) with
A remote shift lever unit disposed on a side of a steering wheel connected to a steering shaft of a vehicle, the remote shift lever unit comprising:
A lever housing 100 disposed on the steering shaft side, and
At least a part of the rotary part 300 is disposed at one end of the lever housing 100, and at least a part of the rotary part 300 is rotatable with respect to the length of the lever housing 100;
At least a part of the lever button part 400 is disposed at one end of the lever housing 100 and is movable along the length of the lever housing 100;
A common moving unit 500 connected to the rotary unit 300 and the lever button unit 400 and capable of interlocking with at least one operation of the rotary unit 300 and the lever button unit 400;
and a motion switching unit 600 for detecting the operation of the common moving unit 500 when the common moving unit 500 is operated,
The motion switching unit 600 includes: a motion switching sensor unit 620 and a motion switching sensor corresponding unit 610 disposed at an end of the common moving unit 500 to a corresponding position of the motion switching sensor unit 620 . including,
The lever housing 100 includes a housing base 110 and a housing cover 120 that are engaged with each other, and the motion switching sensor unit 620 is spaced apart from the motion switching sensor counterpart 610 to the lever substrate ( 200) placed directly on the side,
The remote shift lever unit (10), characterized in that the plane on which the motion switching sensor unit (620) is arranged and the plane on which the motion switching sensor corresponding unit (610) is arranged are orthogonal to each other.

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