KR20210125343A - Vehicular rotary type switching unit - Google Patents

Abstract

Provided, in the present invention, is a rotary switch unit (10) comprising: a rotary switch module (100) mounted on a vehicle to execute a rotary switching operation; and a rotary return module (200) that executes a return to the original position and a detent operation of the rotary switch module (100), wherein the rotary return module (200) performs a self-alignment with a magnetic force. Therefore, the present invention is capable of preventing unnecessary noises caused by repetitive operation.

Description

Rotary switch unit {VEHICULAR ROTARY TYPE SWITCHING UNIT}

The present invention relates to a switch device for a vehicle. More particularly, it relates to a rotary switch unit in which the overall size of the rotary operation implementation is miniaturized, the operation feeling is improved, the internal structure is simple, and the rotary switch unit can operate more stably to implement an interface function for adjusting various output devices of the vehicle.

BACKGROUND ART In vehicles such as automobiles, functions are required as various convenient means to provide users with a more stable and comfortable driving state beyond a function as a moving means. Accordingly, the vehicle is provided with various convenience facilities and various switches for operating and controlling them.

The demand for these switch devices used in vehicles is increasing according to the recent trend of luxury vehicles. In particular, since various switch devices and convenience facilities are installed around the driver's seat, these switch devices are required to be compact. Prevention of interference between devices is required as an essential part of design.

As a switch device according to the prior art, an adjustment interface device for selecting an operation through a dial-type rotation operation is widely used.

However, in the case of the conventional rotary operation switch, theft operation component that achieves vibration transmission through contact for providing an operation position to the user has been widely used. In the case of a theft operation component making physical contact in this way, there is a risk of wear, and when a large amount of rotation is required, there is a problem of providing a user's discomfort when implementing a quick and smooth operation due to noise generation and continuous vibration.

In addition, due to such direct physical contact, a predetermined sense of detent is changed over time according to wear, so that it is difficult to maintain the initial setting state.

The present invention was invented to solve the problems of the prior art, and at the same time achieves cost reduction and at the same time prevents abrasion when realizing a theft operation through a compact configuration, reduces return noise, and realizes self-alignment operation to a preset position An object of the present invention is to provide a rotary switch unit having a structure that enhances a user's sense of operation by enabling smooth rotary operation.

The present invention includes a rotary switch module 100 that is mounted on a vehicle and executes a rotary switching operation, and a rotary return module 200 that performs an original position return and detent operation of the rotary switch module 100, the The rotary return module 200 provides a rotary switch unit 10 characterized in that it performs self-alignment with magnetic force.

In the rotary switch unit, the rotary switch module 100 includes: a rotary switch module knob 110 gripped by a user, is connected to the rotary switch module knob 110 and receives a user's rotational force to rotate It may include a rotary switch module body 120 that executes.

In the rotary switch unit, the rotary return module 200 includes: a rotary self detent 300 that provides a sense of detent while the rotary switch module 100 rotates, and the rotary switch module 100 rotates It may include a rotary self-return unit 400 that performs positional self-alignment by using magnetic force to a preset position during the operation. That is, the rotary return module 200 is: a part of the rotary switch module 100 and another part of the rotary switch module 100 are fixed in relative positions with respect to the vehicle side, providing a sense of detent while the rotary switch module 100 is rotated and a rotary self-detent 300, some of which are fixedly mounted on the rotary switch module 100 side, and other portions are fixedly arranged relative to the vehicle side, while the rotary switch module 100 is rotated in advance It may include a rotary self-return unit 400 that performs positional self-alignment with magnetic force at a set position.

In the rotary switch unit, the rotary self-return unit 400 includes: the rotary self-return movable housings 420 and 420a, and the rotary self-return movable housing 420 and the rotary self-return movable housing 420 are fixedly arranged relative to their corresponding positions. It may include housings 410 and 410a, the rotary self-return movable housing 420 and the rotary self-return magnet 430 disposed in the rotary self-return fixed housing 410 . That is, the rotary self-return unit 400 includes: the rotary self-return movable housings 420 and 420a that are fixedly positioned on the rotary switch module 100 and the rotary self-return movable housing 420 to a corresponding position. Rotary self-return fixed housings 410 and 410a fixed in a relative position with respect to the switch module 100, the rotary self-return movable housing 420 and the rotary self-return fixed housing 410, the rotary switch module ( 100) may include a rotary self-return magnet 430 that generates a magnetic force to perform positional self-alignment at a preset position during rotation.

In the rotary switch unit, the rotary self-return magnet 430 includes: a return movable magnet 433 that is fixedly positioned on the rotary self-return movable housings 420 and 420a and is movable together with the rotary switch module 100; , The rotary self-return fixed housings 410 and 410a may include a fixed return magnet 431 disposed in a fixed position and forming a preset position.

That is, the rotary self-return magnet 430 includes: a return movable magnet 433 that is fixedly positioned on the rotary self-return movable housings 420 and 420a and is movable together with the rotary switch module 100, and the rotary self-return The fixed housings 410 and 410a may include a return fixing magnet 431 that is fixedly disposed and forms a preset position.

In the rotary switch unit, the longitudinal axis segments of the return movable magnet 433 and the return fixed magnet 431 facing each other may be substantially perpendicular to the rotation axis of the rotary switch module 100 .

In the rotary switch unit, the longitudinal axis segments of the return movable magnet 433 and the return fixed magnet 431 facing each other may be substantially horizontal to the rotation axis of the rotary switch module 100 .

In the rotary switch unit, the rotary self-return fixed housing 410 includes: a return fixed housing base 411 fixed and disposed on the vehicle; It may include a return fixed housing detent receiving portion 413 for accommodating at least a portion of the tent 300 .

In the rotary switch unit, a return fixed housing detent fixing portion 419 engaged with at least a portion of the rotary self detent 300 may be provided inside the return fixed housing detent receiving portion 413 . .

In the rotary switch unit, the rotary self-detent 300 includes: a rotary self-detent elastic part 310 having an end fixed to the rotary switch module 100 side and allowing preset elastic deformation; A rotary self-detent holder 320 that is fixedly positioned on the rotary self-detent elastic part 310) side, and a rotary self-detent roller 330 that is rotatably mounted to the rotary self-detent holder 320 and a rotary self-detenting body 340 for guiding a position of the rotary self-detenting roller 330 in contact with the rotary self-detenting roller 330 .

In the rotary switch unit, both ends of the rotary self-detent elastic part 310 are fixedly connected to the outside of the rotary switch module 100, and the rotary self-detent holder 320 is fixedly positioned on the outer periphery could be

In the rotary switch unit, the rotary self-detent elastic part 310 may have an arc-shaped structure.

In the rotary switch unit, the rotary self-detent elastic part 310 includes: a rotary self-detent elastic module mounting part 311 formed at both ends and fixedly connected to the outside of the rotary switch module 100; It may include a rotary self-detent elastic holder mounting part 313 disposed with the rotary self-detent elastic module mounting part 311 interposed therebetween to connect the rotary self-detent holder 320 .

In the rotary switch unit, the rotary self-detent holder 320 includes: a detent holder cover 323 located in the rotary self-detent elastic holder mounting part 313, and the rotary self-detent elastic part 310 ) may include a detent holder body 321 engaged with the detent holder cover 323 and coupled to the detent holder cover 323 and connected to the rotary self detent roller 330 to be rotatably relative.

In the rotary switch unit, the detent holder body 321 includes: a detent holder body main part 3211 that is seated in engagement with the rotary self-detent elastic part 310, and one side is the main detent holder body It may include a detent holder side 3215 connected to the part 3211 and mounted on the other side to be rotatably rotated relative to the rotary self-detent roller 330 .

In the rotary switch unit, the detent holder side roller gripper 32151 is provided on the detent holder side 3215, and the rotary self detent roller 330 includes: the rotary self detent body 340 and A detent roller body 331 capable of contacting relative rotation, and a detent roller shaft extending at an end of the detent roller body 311 and rotatably engaged and mounted to the detent holder side roller gripper 32151 ( 333) may be included.

In the rotary switch unit, the rotary self-detent body 340 includes: a rotary detent body that allows the rotary switch module 100 to reach a preset position on one surface of the rotary self-detent body 340 . The neutral portion 341 and the rotary detent body neutral portion 341 form a significant step in the contact surface to the outside, thereby limiting the rotation of the rotary self-detent roller 330. Rotary detent body restriction portion (343).

First, the rotary switch unit according to an embodiment of the present invention can provide a rotary switch unit that prevents unnecessary noise generation due to repetitive operation and achieves self-alignment to a preset position.

Second, the rotary switch unit according to an embodiment of the present invention is a rotary switch of a structure that prevents a change in position alignment due to wear and maintains a position alignment state through magnetic force to improve operation durability, and provides a user with an improved feeling of operation Units can also be provided.

1 is a schematic perspective view of a rotary switch unit according to an embodiment of the present invention.
2 is a schematic exploded perspective view of a rotary switch unit according to an embodiment of the present invention.
3 is a schematic partial cross-sectional perspective view of a rotary switch unit according to an embodiment of the present invention.
4 is a schematic partial cross-sectional perspective view of a rotary self-return fixed housing of a rotary switch unit according to an embodiment of the present invention.
5 is a schematic partial projection perspective view for explaining the operation implementation of the rotary self-detent of the rotary switch unit according to an embodiment of the present invention.
6 is a partially enlarged projected perspective view for explaining a detailed configuration of a rotary self-detent of a rotary switch unit according to an embodiment of the present invention.
7 is a schematic perspective view of a rotary self-return unit of a rotary switch unit according to an embodiment of the present invention.
8 is a schematic exploded perspective view of a rotary self-return unit of a rotary switch unit according to an embodiment of the present invention.
9 is a schematic partial cross-sectional view of a rotary self-return portion of a rotary switch unit according to an embodiment of the present invention.
10 is a schematic partial front view of a rotary self-return unit of a rotary switch unit according to an embodiment of the present invention.
11 is a schematic partial plan view of a rotary self-return portion of a rotary switch unit according to an embodiment of the present invention.
12 is a partial front view of the rotary self-detent of the rotary self-detent of the rotary switch unit according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, 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 rotary switch unit 10 according to an embodiment of the present invention includes a rotary switch module 100 and a rotary return module 200 .

The rotary switch module 100 may be rotatably disposed in a vehicle interior space, such as a center console box or a center fascia of the vehicle's interior, in particular, a driver's seat of the vehicle. A rotary switch structure is disposed, a detailed description thereof will be omitted, and the rotary switch module 100 in this embodiment will be described with reference to an upper end that can be rotated relative to the vehicle.

More specifically, the rotary switch module 100 includes a rotary switch module knob 110 and a rotary switch module body 120 . The rotary switch module knob 110 is gripped by the user, and the rotary switch module body 120 is connected to the rotary switch module knob 110 and receives the user's rotational force to perform a rotational operation.

That is, in this embodiment, the rotary switch module 100 includes a rotary switch module knob 110 and a rotary switch module body 120, and the rotary switch module knob 110 is mounted on a vehicle to execute a rotary switching operation. However, the rotary switch module knob 110 may take a structure in which a predetermined groove is formed on the outer periphery to prevent sliding during rotation operation through the user's grip, and the rotary switch module body 120 is the rotary switch module knob 110 . It is connected to the lower end of the rotary switch module body 120 connected to the rotary switch module knob 110 when the user grips and rotates the rotary switch module knob 110 also performs a rotation operation.

The rotary switch module knob 110 in this embodiment forms a structure with an open top, and has an internal space, so that other button-type or touch-type switches may be disposed, and electrical connection wiring of these button-type or touch-type switches A through hole is provided in the center for the penetration of the rotary switch module body 120, and an electrical connection structure with the lower substrate (not shown) may be formed through the through hole on the side of the rotary switch module body 120 .

A module knob mounting part 111 is formed on the bottom of the rotary switch module knob 110 , and a module body mounting part 121 is formed on the rotary switch module body 120 side, and the module knob mounting part 111 and the module body mounting part 121 are formed. ) may be engaged with each other to prevent relative rotation between the rotary switch module knob 110 and the rotary switch module body 120 .

In this embodiment, a rotary switch (not shown) for performing a rotary switching function by a rotating operation of the rotary switch module 100 is provided on the bottom side of the rotary switch module knob 110 , and a rotary switching signal according to this rotary operation is transmitted to an external device through a substrate (not shown), and a switching operation corresponding to a predetermined preset rotary switching operation may be performed.

The rotary switch unit 10 according to an embodiment of the present invention may further include a component for returning and guiding the rotational operation of the rotary switch module 100 to its original position. That is, the rotary switch unit 10 according to an embodiment of the present invention includes a rotary return module 200 , wherein the rotary return module 200 performs an original position return and detent operation of the rotary switch module 100 . make it

On the other hand, the rotary return module 200 in the present embodiment performs self-alignment by magnetic force. In more detail, the rotary return module 200 includes a rotary self detent 300 and a rotary self return unit 400 .

The rotary self-detent 300 is partly disposed on the rotary switch module 100 and the other part is disposed on the vehicle side. to provide.

In this embodiment, the other part of the rotary self-detent 300 takes a structure in which a relative position is fixed with respect to the vehicle side, but the other part of the rotary self-detent 300 may be directly fixed to the vehicle and disposed. , a structure in which another part of the rotary self-detent 300 is directly or indirectly connected to the vehicle structure or other connection structure directly to the vehicle and fixed in a relative position relative to the vehicle side, such as may be connected through a separate fixed connection member It is clear from the present invention that various arrangement structures can be formed within the range of taking .

A part of the rotary self-return unit 400 is fixedly mounted on the rotary switch module 100 side, and the other part is fixed in a relative position on the vehicle side, and the magnetic force at a preset position while the rotary switch module 100 rotates. to perform positional self-alignment. That is, when the external force is removed, the position self-alignment is performed by the magnetic force.

In this embodiment, the other part of the rotary self-return part 400 also takes a structure in which a relative position is fixed with respect to the vehicle side, but the other part of the rotary self-return part 400 may also be directly fixed to the vehicle and disposed. , which may be connected through a separate fixed connection member, etc., another part of the rotary self-return unit 400 is directly or indirectly connected to the vehicle structure or other connection structure directly to the vehicle, and is fixedly mounted and rotated relative to the vehicle side It is clear from the present invention that various designs are possible within the range of taking a structure to achieve self-alignment when a rotational state with a part disposed on the side of the rotary switch module is possible.

More specifically, the rotary self-return unit 400 includes rotary self-return movable housings 420 and 420a, rotary self-return fixed housings 410 and 410a, and a rotary self-return magnet 430 .

First, the rotary self-return movable housings 420 and 420a are fixedly positioned on the rotary switch module 100 . More specifically, the rotary self-return movable housings 420 and 420a are one side of the rotary switch module 100 forming the rotational operation, that is, directly on the outer periphery of the rotary switch module 100 or rotate together with the rotary switch module 100. form a structure

As shown in Figure 1, the rotary self-return movable housing 420 is implemented as an accommodation space formed directly on the outer periphery of the rotary switch module body 120 of the rotary switch module 100 forming a rotation operation, this embodiment A portion of the rotary self-return magnet 430, that is, a return movable magnet to be formed in the rotary self-return movable housing 420 as the formed accommodation space, is formed in the outer periphery of the rotary switch module. 433 is fixedly arranged, and when the rotary switch module body 120 rotates, a circumferential rotation operation is performed together.

The rotary self-return fixed housing 410 is fixedly disposed relative to the rotary switch module 100 at a corresponding position of the rotary self-return movable housing 420 . More specifically, the rotary self-return fixed housing 410 is the rotary switch module 100, that is, the rotary switch module body 120 of the rotary switch module 100 to the corresponding position of the rotary self-return movable housing 420. The inner circumference of the rotary switch module body 120 The relative position is fixed with respect to the rotary self-return movable housing 420 formed in the .

In this embodiment, the rotary self-return fixed housing 410 includes a return fixed housing base 411 and a return fixed housing detent receiving portion 413 . The return fixed housing base 411 is fixedly positioned on the vehicle. A return fixed housing mounting unit 416 is disposed at a lower end of the return fixed housing base 411 , and the return fixed housing mounting unit 416 is fixedly positioned inside the vehicle to a corresponding position and inserted and mounted.

A return fixed housing detent receiving portion 413 is disposed at an end of the return fixed housing base 411 . The return fixed housing detent receiving portion 413 is positioned on the return fixed housing base 411 to accommodate at least a portion of the rotary self detent 300, in this embodiment the return fixed housing detent receiving portion 413 is disposed on the side end of the return fixed housing base 411 , the upper end is open and at least a portion of the rotary self detent 300 , that is, the return fixed housing detent receiving space for accommodating the rotary self detent body 340 . (415). In the present embodiment, the return fixed housing detent accommodating space 415 forms an arc-shaped structure and takes a structure formed and disposed along the outer periphery of the rotary switch module body 120 disposed nearby.

The return fixed housing detent accommodating space 415 is formed as an accommodating space having an open top structure, and the rotary self detent body 340 corresponding to the shape of the return fixed housing detent accommodating space 415 is is mounted to accommodate. At this time, the rotary self-detent body 340 also forms an arc-shaped structure to be engaged with the return fixed housing detent accommodating space 415 , and in some cases, an interference fit structure may be formed.

On the other hand, when the rotary self-detent body 340 is accommodated and mounted in the return fixed housing detent accommodating space 415, a component for preventing the positional movement of the rotary self-detent body 340 may be further provided. have. That is, the return fixed housing detent fixing unit 419 disposed toward the end of the rotary self detent body 340 is provided on the inner surface of the return fixed housing detent receiving space 415, the return fixed housing detent high The government 419 takes a protruding structure and is engaged with the return fixed housing detent fixing unit 419 on the bottom surface of the rotary self detent body 340 to the corresponding position of the return fixed housing detent fixing unit 419. A corresponding part (not shown) is provided so that the rotary self-detent body 340 is provided with a return fixed housing detent receiving space through the engagement of the detent fixed counterpart (not shown) and the return fixed housing detent fixing part 419 . It is possible to implement the preset in-position operation of the rotary switch module knob 110 and the rotary switch module body 120 more accurately by preventing the position change of the ultimate detent operation by unnecessarily moving the position inside the 415 . .

The rotary self-return magnet 430 is disposed in the rotary self-return movable housing 420 and the rotary self-return fixed housing 410 and applies magnetic force to perform positional self-alignment at a preset position while the rotary switch module 100 is rotated. create More specifically, the rotary self-return magnet 430 includes a return fixed magnet 431 and a return movable magnet 433 . The return fixed magnet 431 and the return movable magnet 433 are configured in a disk type in this embodiment and are spaced apart from each other. Various arrangement structures can be taken within the range of taking a structure that forms an attractive force. That is, in the present embodiment, the return fixed magnet 431 and the return movable magnet 433 are implemented as a disk type, but are not limited thereto and are bar type in the range of performing a position alignment operation through a predetermined magnetic force at a preset position. There are a number of options available, such as However, in the present embodiment, the return fixed magnet 431 and the return movable magnet 433 of the disk type are disposed to face each other.

The return movable magnet 433 is fixedly positioned in the rotary self-return movable housing 420 to be movable together with the rotary switch module 100, and the return fixing magnet 431 is located in the rotary self-return movable housing 410 and 410a. Positioned fixedly arranged to form a preset position.

As shown in FIG. 1 and the like, in this embodiment, the longitudinal axis segments opposite to each other of the return movable magnet 433 and the return fixed magnet 431 are arranged substantially perpendicular to the rotation axis of the rotary switch module 100 . take That is, the rotary switch module knob 110 and the rotary switch module body 120 of the rotary switch module 100 rotate the vertical axis as the longitudinal axis in the drawing, and the return movable magnets are spaced apart from each other to face each other. The line segment in the longitudinal direction of the line segment connecting the 433 and the return fixing magnet 431 is perpendicular to the rotation axis on which the rotary switch module 100 described above rotates.

Through such a vertical arrangement, the face-to-face arrangement area of the return movable magnet 433 and the return fixed magnet 431 may be increased to further strengthen the implementation of the self-aligning operation to a preset position.

Meanwhile, the rotary self-detent 300 in this embodiment includes a rotary self-detent elastic part 310 and a rotary self-detent holder 320 .

The rotary self-detent elastic part 310 has an end fixed to the rotary switch module 100 side and allows preset elastic deformation. That is, at least a part of the rotary self-detent elastic part 310 is connected to the rotary switch module 100 side, and at least another part includes the rotary self-detent holder 320 . The rotary self-detent elastic part 310 has an end fixed to the rotary switch module 100 side, and various configurations are possible in a range that allows a preset elastic deformation, but the rotary self-detent elastic part ( 310 is a relatively elastic plate having a predetermined thickness, and is implemented as an arc-shaped flexible piece.

That is, as shown in FIG. 3 , the rotary self-detent elastic unit 310 according to an embodiment of the present invention is accommodated in the return fixed housing detent receiving unit 413 of the rotary self-return fixed housing 410 . Like the shape of the rotary self-detent 330 , it is arranged on the outer periphery of the rotary switch module body 120 in a structure having a predetermined rigidity in an arc-shaped structure, or in other words, a predetermined elasticity in other words.

In this embodiment, the rotary self-detent elastic part 310 has a structure in which both ends are connected to the outer periphery of the rotary self-detent module body 120, and the rotary self-detent elastic part 310 has both ends. It is fixedly connected to the outside of the rotary switch module 100, and the rotary self-detent holder 320 is fixedly positioned on the outer periphery.

The rotary self-detent elastic part 310 includes a rotary self-detent elastic module mounting part 311 and a rotary self-detent elastic holder mounting part 313 . The rotary self-detent elastic module mounting part 311 is formed at both ends and is fixedly connected to the outside of the rotary switch module 100, and the rotary self-detent elastic holder mounting part 313 is a rotary self-detent elastic module mounting part 311. It is disposed between and connects the rotary self-detent holder 320 .

That is, rotary self-detent elastic module mounting parts 311 are formed on both ends of the rotary self-detent elastic part 310, and the rotary self-detent elastic module mounting part 311 is connected to the outer periphery of the rotary switch module body 120. do. At this time, the module body detent mounting part 123 is disposed on the outer periphery of the rotary switch module body 120 in this embodiment, and the rotary self-detent elastic module mounting part 311 of the rotary self-detent elastic part 310 is a module It is connected to the body detent mounting portion 123 side to take a structure in which predetermined both ends are fixed in position and the front end is elastically deformed. It is connected to the module body detent mounting part 123 side, and both ends are fixed in position and the front end has a predetermined rigidity, but can take a structure in which a predetermined elastic deformation is possible.

The rotary self-detent elastic part 310 has an arc-shaped structure. Through such a configuration, it is possible to more smoothly implement a preset elastic deformation operation at a preset point while having a predetermined rigidity.

On the other hand, the rotary self-detent holder 320 is fixedly disposed on the rotary self-detent elastic part 310 side. The rotary self-detent holder 320 includes a detent holder body 321 and a detent holder cover 323 . The detent holder cover 323 is located in the rotary self-detent elastic holder mounting part 313, and the detent holder body 321 has the detent holder cover 323 with the rotary self-detent elastic part 310 interposed therebetween. interlocked and joined

At this time, in the rotary self-detent holder 320 , more specifically, the lower end of the detent holder body 321 is connected with a rotary self-detent roller 330 , and the rotary self-detent roller 330 has a rotary self-detent The holder 320 is rotatably connected to the detent holder body 321 of the holder 320 .

That is, the detent holder body 321 includes a detent holder body main part 3211 and a detent holder side 3215 . The detent holder body main part 3211 is seated in engagement with the rotary self-detent elastic part 310, and one surface of the detent holder body main part 3211 is opposite to the detent holder cover 323 side. A smooth seating structure may be formed by disposing the rotary self-detent elastic part 310 between them. In some cases, a detent holder through hole 3213 is formed in the detent holder body main part 3211 , and the detent holder cover 323 has a detent cover through hole at a corresponding position of the detent holder through hole 3213 . 3231 is formed, and a rotary self-detent elastic holder mounting portion 313 is formed in the rotary self-detent elastic portion 310 as a corresponding position thereof, in some cases the detent holder through hole 3213 and the detent cover The through-hole 3231 and the rotary self-detent elastic holder mounting part 313 are arranged in a line with each other and fixed in position through a separate fastening means to be engaged, and in some cases, the detent holder through-hole 3213 and the detent The cover through hole 3231 has a protrusion structure and a concave structure that can be engaged with each other, so that any one of the detent holder through hole 3213 and the detent cover through hole 3231 is formed in a protruding structure, so that the rotary self detent elasticity A stable position maintaining structure may be formed through a structure disposed through the holder mounting part 313 .

The detent holder side 3215 has one side connected to the detent holder body main part 3211, and in this embodiment, the detent holder side 3215 is a rotary switch module to both ends of the detent holder body main part 3211. The detent holder is spaced apart from the center of rotation of the body 120 in the radial direction, and the upper end of the detent holder side 3215 has a height higher than the upper surface of the detent holder body main part 3211 and is spaced apart from each other. A structure in which a part of the rotary self-detent elastic part 310 is seated in the space between the sides 3215 may be configured.

On the other side of the detent holder side 3215 , a rotary self-detent roller 330 is mounted to be rotatably relative. That is, in the present embodiment, the detent holder side roller gripper 32151 is provided on the detent holder side 3215 , and the rotary self detent roller 330 is rotatably mounted on the detent holder side roller gripper 32151 . do.

The rotary self-detent roller 330 includes a detent roller body 331 and a detent roller shaft 333 . The detent roller body 331 is arranged in a structure that can be rotated relative to the rotary self detent body 340, and the detent roller body 331 has a larger radius than the detent roller shaft 333 and has a concentric arrangement structure. to form

The detent roller shaft 333 is formed to extend to the end of the detent roller body 311 and is rotatably engaged and mounted to the detent holder side roller gripper 32151 . A pair of detent holder side roller grippers 32151 are disposed to be spaced apart from each other, and the width between each part of the detent holder side roller grippers 32151 is the length of the detent roller body 331 and the detent formed extending therefrom. It corresponds to the sum of the lengths considering the mounting position with the roller shaft 333 . The detent holder side roller gripper 32151 has a predetermined clip holding shape to prevent unwanted separation and separation after the detent roller shaft 333 is mounted, but has a clearance structure that allows smooth relative rotation.

In this embodiment, the rotary self-detent roller forms a uniaxial grip structure on the detent holder side roller gripper 32151 to pivotally rotate, but the rotary detent roller in the present invention is limited to the shaft-rotating structure. no. That is, within the range where the rotary self-detent roller takes a structure that forms a state of constant contact with the rotary self-detent body 340 as described below, a ball-type three-dimensional rotational contact structure supported by an elastic body such as a spring may be adopted. In addition, various modifications are possible according to design specifications, such as a bullet-type uniaxial movable contact structure.

A rotary self-detent body 340 is disposed at a corresponding position of the rotary self-detent roller 330, and the rotary self-detent roller 330 and the rotary self-detent body 340 are in constant contact in this embodiment. to form

That is, the rotary self-detent body 340 is in contact with the rotary self-detent roller 330 to guide the position of the rotary self-detent roller 330 .

As described above, the rotary self-detent body 340 is arranged to be accommodated in the return fixed housing detent accommodating space 415 , and the rotary self-detent body 340 also forms an arc-shaped structure to detent the return fixed housing. It is disposed to be engaged with the accommodation space 415 , and in some cases, an interference fit structure may be formed. The rotary self-detent body 340 includes a rotary detent body neutral portion 341 and a rotary detent body restriction portion 343 .

The rotary detent body neutral portion 341 is a point at which the rotary switch module 100 reaches a preset position, and in the rotary detent body neutral portion 341 , the rotary self-detent roller 330 and the rotary self-detent The contact force between one surface of the body 340 forms the lowest state than the contact force between one surface of the rotary self-detent roller 330 and the rotary self-detent body 340 near the rotary detent body neutral portion 341 . That is, the point where the elastic restoring force according to the positional deformation of the rotary self-detent elastic part 310 connected to the rotary switch module 100 is the lowest is the rotary detent body neutral portion 341, and the rotary detent body neutral portion ( 341), the elastic restoring force according to the positional deformation of the rotary self-detent elastic part 310 gradually increases toward the outside.

In addition, the rotary detent body restriction portion 343 forms a significant step in the contact surface to the outside of the rotary detent body neutral portion 341 to limit the rotation of the rotary self detent roller 330 and ultimately to the rotary It is possible to prevent excessive rotation of the switch module 100 .

On the other hand, although this vertical arrangement structure was taken in the previous embodiment, the rotary switch unit 10 of the present invention is not limited thereto, and various configurations are possible. That is, as shown in FIGS. 7 to 11 , the longitudinal axis segments opposite to each other of the return movable magnet 433 and the return fixed magnet 431 of the rotary switch unit 10 of the present invention are the rotary switch module 100 ) may have a structure substantially horizontal to the axis of rotation. In this case, the rotary self-return movable housing 420a has a structure for accommodating at least a part of the rotary self-return magnet 430 described below, and the rotary self-return movable housing 420a is the rotary switch module body 120 . It may take a configuration that is connected to the outer periphery of the rotary self-detent holder (320a) to the outside of the rotation radius. That is, the rotary self-return fixed housing 410a is spaced apart from the outer periphery of the rotary switch module body 120, and the return for accommodating the rotary self-detent body 340 inside the rotary self-return fixed housing 410a The return fixed housing detent accommodating space 417 of the fixed housing detent receiving portion 413 is disposed, and the rotary self detent body 340 is rotatably disposed in the rotary self detent holder 320a. Forms a state of constant contact with the detail roller 330 .

Inside the return fixed housing detent receiving space 417 of the return fixed housing detent receiving portion 413, that is, toward the bottom of the return fixed housing base 411a, the rotary switch module body 120 in the longitudinal direction of the rotary shelf It takes a configuration in which the rotary self-return movable housing 420a is spaced apart from the corresponding position of the return fixed housing 410a. A return fixed housing fixed magnet receiving portion 415a is disposed on the bottom of the return fixed housing base 411a of the rotary self return fixed housing 410a, and a rotary self return magnet 420 is disposed in the return fixed housing fixed magnet receiving portion 415a. ) of the return fixing magnet 433 is disposed. A return movable magnet 433 is disposed in the rotary self-return movable housing movable magnet receiving portion 421a of the rotary self-return movable housing 420a in its corresponding position.

That is, the rotary self-detent holder 320a is fixedly positioned on the rotary self-detent elastic part 310 side, and the alternative configuration of the rotary self-detent holder 320a is the rotary self-detent holder in the previous embodiment and It is substantially the same and has a through hole in the side so that the rotary self-detent elastic part 310 can be withdrawn through it. A rotary self-return movable housing 420a is disposed on the outer circumferential side in the rotational radial direction of the rotary self-detent holder 320a, and the rotary self-return fixed housing 410 to its corresponding position as a preset position forming a neutral state. A magnet mounting position is formed on the outer periphery side.

By making such a facing arrangement, the outermost position rotary self-return magnet 430 of the rotary switch module body 120 is arranged, the amount of torque provided to facilitate self-alignment in the preset position and to escape it By requesting a larger value compared to the case where the radius is arranged at a point with a small radius, a structure that is smoother but prevents unnecessary and unwanted operation execution may be adopted.

In this embodiment, the rotary self-detent holder 320a and the rotary self-return movable housing 420a form an integral structure, and may take a configuration that is separable from each other, and the rotary self-detent holder 320a and the rotary self-return movable housing 420a By forming a radial arrangement structure of the load through the connection structure of the housing 420a, a selection structure in which the rigidity in the rotary self-detent elastic part 310 connected thereto is stronger than in the case of the previous embodiment is formed Various selections and modifications are possible according to design specifications.

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. Therefore, 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 equivalent range should be construed as being included in the scope of the present invention.

10...Rotary switch unit
100...Rotary switch module 200...Rotary return unit
300...Rotary Self Detent 400...Rotary Self Return

Claims (17)

A rotary switch module 100 mounted on a vehicle to execute a rotary switching operation;
and a rotary return module 200 that executes an original position return and detent operation of the rotary switch module 100,
The rotary switch unit (10), characterized in that the rotary return module (200) performs self-alignment with magnetic force.
The method of claim 1,
The rotary switch module 100 includes:
A rotary switch module knob 110 gripped by a user;
A rotary switch unit (10) connected to the rotary switch module knob (110) and comprising a rotary switch module body (120) for receiving a user's rotational force to perform a rotational operation.
The method of claim 1,
The rotary return module 200 includes:
A rotary self-detent 300 that provides a sense of detent while the rotary switch module 100 rotates;
Rotary switch unit (10), characterized in that it includes a rotary self-return unit (400) for performing positional self-alignment using magnetic force to a preset position while the rotary switch module (100) is rotated.
4. The method of claim 3,
The rotary self-return unit 400 includes:
Rotary self-return movable housings 420 and 420a, and
Rotary self-return fixed housings 410 and 410a fixed in relative positions to the corresponding positions of the rotary self-return movable housing 420;
A rotary switch unit (10) comprising a rotary self-return movable housing (420) and a rotary self-return magnet (430) disposed in the rotary self-return fixed housing (410).
5. The method of claim 4,
The rotary self-return magnet 430 includes:
A return movable magnet 433 that is fixedly positioned on the rotary self-return movable housings 420 and 420a and is movable together with the rotary switch module 100;
A rotary switch unit (10) comprising a return fixing magnet (431) which is fixedly positioned on the rotary self-return fixed housing (410, 410a) and forms a preset position.
6. The method of claim 5,
A rotary switch unit (10), characterized in that the longitudinal axis segments opposite to each other of the return movable magnet (433) and the return fixed magnet (431) are substantially perpendicular to the rotation axis of the rotary switch module (100).
6. The method of claim 5,
A rotary switch unit (10), characterized in that the longitudinal axis segments of the return movable magnet (433) and the return fixed magnet (431) facing each other are substantially horizontal to the rotation axis of the rotary switch module (100).
5. The method of claim 4,
The rotary self-return fixed housing 410 includes:
A return fixed housing base 411 disposed in a fixed position on the vehicle;
and a return fixed housing detent receiving portion (413) positioned on the return fixed housing base (411) and accommodating at least a portion of the rotary self detent (300).
9. The method of claim 8,
A rotary switch unit (10) characterized in that a return fixed housing detent fixing portion (419) engaged with at least a portion of the rotary self detent (300) is provided inside the return fixed housing detent receiving portion (413) ).
4. The method of claim 3,
The rotary self detent 300 includes:
A rotary self-detent elastic part 310 having an end fixed in position on the rotary switch module 100 side and allowing a preset elastic deformation;
and a rotary self-detent holder 320 that is fixedly positioned on the rotary self-detent elastic part 310) side;
A rotary self-detent roller 330 mounted to the rotary self-detent holder 320 so as to be rotatably rotated;
Rotary switch unit (10), characterized in that it includes a rotary self-detent body (340) for guiding the position of the rotary self-detent roller (330) in contact with the rotary self-detent roller (330).
11. The method of claim 10,
The rotary self-detent elastic part 310 has both ends fixedly connected to the outside of the rotary switch module 100, and the rotary self-detent holder 320 is fixedly disposed on the outer periphery. switch unit (10).
12. The method of claim 11,
The rotary self-detent elastic portion 310 is a rotary switch unit (10), characterized in that the arc-shaped (弧狀) structure.
13. The method of claim 12,
The rotary self-detent elastic part 310 includes:
A rotary self-detent elastic module mounting part 311 formed at both ends and fixedly connected to the outside of the rotary switch module 100;
A rotary switch unit disposed with the rotary self-detent elastic module mounting part 311 interposed therebetween and comprising a rotary self-detent elastic holder mounting part 313 for connecting the rotary self-detent holder 320 . (10).
14. The method of claim 13,
The rotary self-detent holder 320 includes:
And a detent holder cover 323 located in the rotary self-detent elastic holder mounting portion 313,
The detent holder body 321 is engaged with the detent holder cover 323 with the rotary self-detent elastic part 310 interposed therebetween and is rotatably connected to the rotary self-detent roller 330 . Rotary switch unit (10) comprising a.
15. The method of claim 14,
The detent holder body 321 includes:
a detent holder body main part 3211 that is seated in engagement with the rotary self-detent elastic part 310;
Rotary switch, characterized in that one side is connected to the main part of the detent holder body 3211, and the other side includes a detent holder side 3215 on which the rotary self-detent roller 330 is mounted to be rotatably relative. unit (10).
16. The method of claim 15,
The detent holder side 3215 is provided with a detent holder side roller gripper 32151,
The rotary self-detent roller 330 includes:
A detent roller body 331 capable of being rotated relative to the rotary self detent body 340, and
Rotary switch unit ( 10).
11. The method of claim 10,
The rotary self-detent body 340 includes:
A rotary detent body neutral portion 341 that allows the rotary switch module 100 to reach a preset position on one surface of the rotary self-detent body 340;
Including a rotary detent body restriction portion 343 that limits rotation of the rotary self detent roller 330 by forming a significant step in the contact surface to the outside of the rotary detent body neutral portion 341 Featuring a rotary switch unit (10).

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