KR100947171B1 - Non-contact type rotary switching device - Google Patents

Abstract

The present invention, the unit housing having an internal space; A unit printed circuit board disposed in an inner space of the unit housing; A rotary knob rotatably disposed on an upper end of the unit housing, a rotary shaft rotating together with the rotary knob, a rotary block movable together with the rotary shaft by the rotary shaft, and a rotary magnet disposed in the rotary block And a rotary switch unit having a rotary sensor disposed on the unit printed circuit board and spaced apart from the rotary magnet at a position corresponding to the rotary magnet.

Description

Non-contact Rotary Switch Unit {NON-CONTACT TYPE ROTARY SWITCHING DEVICE}

The present invention relates to a switch device, and more particularly to a rotary type switch unit which can be operated and positioned by a user.

BACKGROUND ART Vehicles, such as automobiles, require functions as various convenient means for allowing a user to provide a more stable and comfortable driving state beyond the function as a moving means. Accordingly, the vehicle is equipped with various convenience facilities and various switches for operating and controlling them.

In general, when operation in opposite directions is required, a seesaw switch device or sliding switch device is used in which the vertical movement of the window corresponds to the operation of the front and rear ends, for example, opening and closing a window of a vehicle, and each operation is used. Rotary switches are used to select the mode. In particular, since various switch devices and convenience facilities are installed around the driver's seat, these switch devices are required to be compact, and interference prevention between the switch devices is a necessity of the design.

Meanwhile, the rotary switch according to the related art has a structure in which a movable contact is provided on a shaft connected to a knob, and a plurality of fixed contacts are provided on a printed circuit board, or a slider which is pivotable and includes a movable contact is a fixed contact. It has a structure for pivoting on a printed circuit board having a. Such a rotary switch according to the prior art may cause malfunctions when repeated use of the contact due to wear due to contact, and lubricants such as grease used to smoothly operate the slider deteriorate when used in a long time, thereby reducing lubricity. This was accompanied by a problem of causing signal malfunction. In addition, such a configuration also has a problem that the assembly structure is complicated, thereby increasing the assembly process time and lowering the productivity.

Accordingly, an object of the present invention is to provide a non-contact rotary switch unit having a structure capable of preventing malfunction and reducing process time.

The present invention for achieving the above object, the unit housing having an internal space; A unit printed circuit board disposed in an inner space of the unit housing; A rotary knob rotatably disposed on an upper end of the unit housing, a rotary shaft rotating together with the rotary knob, a rotary block movable together with the rotary shaft by the rotary shaft, and a rotary magnet disposed in the rotary block And a rotary switch unit having a rotary sensor disposed on the unit printed circuit board and spaced apart from the rotary magnet at a position corresponding to the rotary magnet.

In the non-contact rotary switch unit, a rotary theft fixing portion disposed coaxially with the rotary shaft and having a plurality of rotary cutting surfaces on the inner surface thereof, the rotary cutting surface being in contact with the rotary cutting surface and movable in a radial direction about the rotary shaft. It may further include a rotary theft pin and a rotary theft pin including a rotary theft pin and a rotary theft elastic member having one end axially rotated together with the rotary shaft to elastically support the rotary theft pin.

In addition, the rotary block may be provided with a rotary theft pin receiving portion formed in the radial direction from the rotary shaft to accommodate the rotary theft pin.

In the non-contact rotary switch unit,. The rotary theft fixing part has a ring structure, but a rotary theft slope may be provided on the outside of the rotary theft surface to allow the rotary theft pin to enter.

In the non-contact rotary switch unit, the rotary shaft is provided with a rotary stopper for axial rotation with the rotary shaft, and the unit housing supports a rotary stopper for limiting rotation of the rotary stopper when the rotary stopper comes into contact with the rotary stopper. An additional part may be provided.

The non-contact rotary switch unit according to the present invention having the configuration as described above has the following effects.

First, unlike the conventional rotary switch unit, the non-contact rotary switch unit according to the present invention can prevent or reduce the occurrence of malfunction due to wear due to contact through the non-contact structure of the rotary magnet and the rotary sensor.

Secondly, the non-contact rotary switch unit according to the present invention may significantly increase the durability of the component through the non-contact structure.

Third, the non-contact rotary switch unit according to the present invention may have a smooth and reliable switch selection structure through the structure of the rotary theft part.

Fourth, the non-contact rotary switch unit according to the present invention can increase the ease of assembly by inducing a smooth mounting of the rotary theft pin through the rotary cutting surface inclined portion and / or rotary theft pin guide.

Hereinafter, a non-contact rotary switch unit according to the present invention will be described with reference to the drawings. 1 is a schematic exploded perspective view of a non-contact rotary switch unit according to an embodiment of the present invention, Figure 2 is a schematic partial cross-sectional view of a non-contact rotary switch unit according to an embodiment of the present invention, Figure 3 In the following is a schematic perspective view of a rotary theft fixture of a non-contact rotary switch unit according to an embodiment of the present invention.

The non-contact rotary switch unit 10 according to an embodiment of the present invention includes a unit housing 100, a unit printed circuit board 300, and a rotary switch unit 200, wherein the unit printed circuit board 300 includes a unit. It is disposed in the interior space of the housing 100, the rotary switch unit 200 is disposed in the unit housing 100 is operable.

The unit housing 100 includes a unit housing cover 110, a unit housing body 120, and a unit housing base 130. The unit housing cover 110 and the unit housing base 130 include a unit housing body 120. It is disposed at both ends of the inner space. The unit housing cover 110 is provided with a cover through hole 111 to allow the following rotary switch unit 200 to penetrate. The cover mounting part 113 is provided on the side of the unit housing cover 110, and the cover mounting part 113 is engaged with the body cover mounting part 123 of the unit housing body 120, which will be described below.

The unit housing body 120 has an inner space together with the unit housing cover 110 and the unit housing base 130. The unit housing body 120 is provided with a body through hole 121 to allow the penetration of some components of the rotary switch unit 200.

The unit housing base 130 forms an inner space together with the unit housing body 120. A base mounting part 131 is provided on the side of the unit housing base 130, and the base mounting part 131 is a unit housing body which will be described below. The inner space is engaged with the body base mounting portion 127 disposed on the lower side of the 120. The unit printed circuit board 300 is disposed in an inner space formed by the unit housing base 130 and the unit housing body 120. The unit printed circuit board 300 includes the unit housing body 120 and the unit housing base 130. ) Is supported and fixed (see FIG. 2).

The unit printed circuit board 300 is disposed in the unit housing 100. The unit printed circuit board 300 is provided in the unit housing base 130 of the unit housing 100 through a board terminal (not shown). Electrical communication with an external electrical device (not shown) is made through a connector (not shown).

The rotary switch unit 200 is mounted to the unit housing 100. The rotary switch unit 200 includes a rotary knob 210, a rotary shaft 220, a rotary block 240, a rotary magnet 250, And a rotary sensor 260. The rotary knob 210 is rotatably disposed on an upper portion of the unit housing 100, that is, on an upper end of the unit housing cover 110. The rotary shaft 220 is operated together with the rotary knob 210, and the rotary shaft 220 is engaged with the rotary knob 210. That is, the rotary shaft 220 is provided with a rotary shaft knob mounting hole 221, and the rotary knob 210 is provided with a rotary knob shaft mounting hole 213, and the rotary knob mounting member 211 has a rotary knob shaft mounting hole. The rotary knob 210 is connected to the rotary shaft 220 by being fastened to the rotary shaft knob mounting hole 221 through 213. The rotary knob mounting member 211 may take a bolt-shaped structure. In this embodiment, the rotary knob 210 and the rotary shaft 220 are separated and have a structure that is fastened to each other through the rotary knob mounting member 211, but the rotary knob 210 and the rotary shaft 220 are integrally formed. Various modifications are possible, such as being able to take the structure which becomes.

Various modifications are possible at the upper end of the rotary knob 210, such as a knob display unit for indicating the rotational position of the rotary knob 210. The rotary knob 210 is provided with a shaft mount 215 and one end of the rotary shaft 220 is accommodated in the shaft mount 215. The outer circumferential surface 223 of the rotary shaft 220 has a polygonal shape and the rotary knob The inner surface of the shaft mounting portion 215 of 210 has a polygonal outer peripheral surface 223 of the rotary shaft 220 has a shape. Therefore, the rotational force transmitted by the rotary knob 210 by the user can be smoothly transmitted through the angular engagement structure.

The rotary block 240 is mounted to the rotary shaft 220, and the rotary block 240 is fixedly mounted to one end of the rotary shaft 220. The end of the rotary shaft 220 is provided with a shaft ring mounting portion 225, the rotary block 240 is inserted through the shaft ring mounting portion 225 side. After the rotary block 240 is mounted at the end of the rotary shaft 220, a block stopper 227, such as an O-ring type, is disposed in the shaft ring mounting portion 225 to rotate the rotary block 240 into the rotary shaft. It is fixed to the 220. In this embodiment, the rotary shaft 220 and the rotary block 240 are configured as individual components, but in some cases, the rotary shaft and the rotary block may have various structures, such as taking an integrated structure.

The rotary block plate 280 may be provided between the rotary block 240 and the unit printed circuit board 300 at the lower end of the rotary block 240. The rotary block plate 280 includes a plate through hole 281, and a rotary magnet 250 to be penetrated through the plate through hole 281 is disposed to face the unit printed circuit board 300. The plate mounting part 283 is provided at the side of the rotary block plate 280, and the plate mounting part 283 is engaged with the fixing part mounting part 443 disposed at the lower end of the rotary theft fixing part 440 to be fixed to each other. Take

The rotary magnet 250 is fixedly mounted to the rotary block 240, and the rotary magnet 250 is disposed on one surface of the rotary block 240 toward the unit printed circuit board 300. A rotary magnet holder 270 is disposed on a lower surface of the rotary block 240. A holder mounting part 271 is provided at an end of the rotary magnet holder 270, and a block mounting part 243 is provided at a side of the rotary block 240. And the holder mounting portion 271 is engaged with the block mounting portion 243. The inner side of the rotary magnet holder 270 is provided with a magnet receiving portion 273, the rotary magnet 250 is a rotary block 240 and the rotary magnet holder 270 is engaged with each other, so that the rotary magnet 250 is a rotary The magnet holder 270 may be stably received. The rotary sensor 260 is spaced apart from the rotary magnet 250 at a position corresponding to the rotary magnet 250, and the rotary sensor 260 faces one surface of the rotary magnet 250 on the unit printed circuit board 300. It is disposed on the top to allow the magnetic force of the rotary magnet 250 can be sufficiently sensed. The rotary sensor 260 is composed of a magnetic sensor such as an anisotropic magneto resistive sensor or a gant magneto resistance sensor. The distance between the rotary magnet 250 and the rotary sensor 260 is preferably selected appropriately in a range to prevent interference between components and to facilitate magnetic sensing. Although not shown here, various configurations are possible on the unit printed circuit board 300, such that other electric elements such as a control unit (not shown), a storage unit (not shown), and an operation unit (not shown) may be further provided. Do.

On the other hand, the non-contact rotary switch unit 10 according to an embodiment of the present invention may take the configuration further comprising a rotary theft section for stealing the rotation of the rotary switch unit 200. The rotary theft part 400 includes a rotary theft fixing part 440, a rotary theft pin 430, and a rotary theft elastic member 420. The rotary theft fixing part 440 is coaxial with the rotary shaft 220. It is disposed on the inner surface and has a plurality of rotary theft surface 441 (see FIG. 3), the rotary block 240 has a rotary theft pin receiving portion 410 that can accommodate the rotary theft pin 430. . That is, the rotary block 240 is provided with a rotary theft pin receiving portion 410 extending in a radial direction from the rotation center of the rotary switch unit 200, in this embodiment the rotary theft pin receiving portion 410 Although shown as being provided with two in the opposite direction to each other, this is only one example, the rotary theft pin receiving portion of the present invention is not limited thereto. In addition, the rotary theft pin receiving portion 410 of the present invention is shown as being provided in the rotary block, the rotary theft pin receiving portion of the present invention can be configured in a variety of configurations in a range that is fixed to the rotary shaft.

The rotary theft pin receiving portion 410 is provided with a rotary theft pin receiving opening 411, the rotary theft pin 430 is accommodated in the rotary theft pin receiving opening 411 to be movable. The rotary theft pin 430 is in contact with the rotary theft surface 441 of the rotary theft fixing part 440 and is arranged to be movable in a radial direction about the rotary shaft 220. The rotary theft pin 430 and the rotary theft pin The rotary theft resilient member 420 is disposed between the inner surfaces of the receiving port 411 to elastically support the rotary theft pin 430 so that the end of the rotary theft pin 430 is the rotary theft surface of the rotary theft fixing part 440 ( 441) and a structure that is radially movable toward the center of the rotary shaft 220. On the other hand, the unit housing body 120 of the unit housing 100 is provided with a space for arranging the rotary theft fixing portion 440, the rotary theft fixing portion 440 is fixed to the unit housing body 120, the rotary shaft To generate relative rotation with 220, the rotary theft fixture 440 takes a ring structure. As shown in FIG. 3, the rotary theft fixing part 440 may further include a rotary theft slope inclined portion 445 that allows the rotary theft pin 430 to enter the outer side of the rotary theft surface 441. . The rotary cutting plane inclined part 445 is formed continuously with the rotary cutting plane 441, but the rotary cutting plane inclined part 445 is inclined with respect to the rotary cutting plane 441 when the rotary cutting plane inclined part 445 is at an angle to the rotary cutting plane 444. do. In addition, a rotary cutting pin guide 447 may be further provided outside the rotary cutting surface inclined portion 445. That is, as shown in FIGS. 3 and 4, the rotary block 240 in which the rotary theft pins 430 are accommodated is mounted to the unit housing body 120 and is disposed at the position of the rotary theft fixing part 440. The theft pin 430 is engaged with the rotary theft pin guide 447 to be guided to contact the rotary theft slope inclined portion 445. When the external force is continuously provided by the operator, the end of the rotary theft pin 430 is guided along the rotary theft slope 445 to be in contact with the rotary theft surface 441. Through such a component, the mounting of the rotary theft pin 430 may be made more smoothly.

In addition, the non-contact rotary switch unit 10 according to an embodiment of the present invention may be further provided with a component for limiting the rotation of the rotary shaft 220. The non-contact rotary switch unit 10 is provided with a rotary stopper 230 and a rotary stopper counterpart 125 for limiting rotation of the rotary shaft 220. That is, as shown in Figure 1 and 2, the rotary stopper 230 is mounted on the rotary shaft 220, the stopper shaft through-hole 231 is provided in the center of the rotary stopper 230 is a rotary shaft ( 220 is disposed through. The outer circumferential surface of the stopper shaft through hole 231 has an angular polygonal shape to enable the rotary stopper 230 and the rotary shaft 220 to rotate together. The outer circumferential surface of the rotary stopper 230 is provided with a stopper operation portion 233 and a stopper groove portion 235, the stopper operation portion 233 has a structure arranged in series with the stopper groove portion 235. The rotary stopper counterpart 125 is provided at a position corresponding to the rotary stopper 230 of the unit housing body 120. The rotary stopper counterpart 125 has a protruding structure and the rotary stopper counterpart 125 is a rotary stopper. It is disposed in the stopper recess 235 of 250. The width of the rotary stopper counterpart 125 has a value smaller than the width of the stopper recess 235. When the rotary stopper 250 pivots with the rotary shaft 220, the rotary stopper counterpart 125 is a stopper. The relative rotational movement is possible in the space of the recess 235. Stopper operation portions 233 are formed at both ends of the stopper recess 235, and the stopper operation portion 233 is in contact with the rotary stopper counterpart 125. That is, when the rotary shaft 220 is provided with an external force to achieve rotation over a preset angle range partitioned by the stopper recess 235, the stopper operating portion 233 of the rotary stopper 230 is a rotary stopper counterpart ( 125) is limited in contact with the rotation. Therefore, it is possible to block the possibility of malfunction due to an absolute position change due to excessive rotation of the rotary knob 210 and the rotary shaft 220, and to prevent damage to the component due to excessive rotation.

Hereinafter, an operation process of the non-contact rotary switch unit according to an embodiment of the present invention will be described with reference to FIGS. 5 to 8.

First, a schematic plan view of the rotary knob 210 is shown in FIGS. 5 and 6, and a schematic partial plan view of the rotary knob 210, the rotary magnet 250, and the rotary sensor 260 is shown in FIGS. 7 and 8. 2, a display unit 215 is provided on one surface of the rotary knob 210 to indicate a rotation state of the rotary knob 210. As shown in FIGS. 5 and 7, when the rotary knob 210 maintains its original position, the rotary theft pin 430 is in contact with the rotary theft surface 441 and is fixed in position. The rotary magnet 250 is disposed in the rotary block 240, and the rotary sensor 260 is disposed on the lower unit printed circuit board 300 of the rotary magnet 250. When an external force is provided by the user through the rotary knob 210, the rotary knob 210 is opposite to A or A about the rotary shaft 220 (see FIG. 1) as shown in FIGS. 6 and 8. Axial rotation is achieved. At this time, the rotary sensor 260 transmits a signal sensed by the magnetic pole of the rotary magnet 250 to the control unit (not shown) and the control unit (not shown) to the operation unit (not shown) and / or storage unit (not shown) The operation state of the rotary switch unit 200 may be grasped through the stimulus signal which is transmitted through calculation and preset, and the rotation position relationship data of the rotary knob 210.

 The above embodiments are examples for describing the present invention, but the present invention is not limited thereto. That is, in the above embodiments, the control unit, the storage unit, the operation unit, etc. are not shown, but may be disposed on the unit printed circuit board to process a signal sensed by the rotary sensor and transmit the signal to an external device. Various modifications are possible in a range in which the rotary sensor and the rotary sensor are spaced apart from each other.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. . Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is a schematic exploded perspective view of a non-contact rotary switch unit according to an embodiment of the present invention.

2 is a schematic partial cross-sectional view of a non-contact rotary switch unit according to an embodiment of the present invention.

3 is a schematic perspective view of a rotary theft fixture of a non-contact rotary switch unit according to an embodiment of the present invention.

4 is a schematic partial cross-sectional view showing a state in which a rotary theft part of a non-contact rotary switch unit according to an embodiment of the present invention is mounted.

5 and 6 are schematic partial plan views showing an operating state of a rotary knob of a non-contact rotary switch unit according to an embodiment of the present invention.

7 and 8 are schematic partial plane projection views showing an operating state of a rotary switch unit of a non-contact rotary switch unit according to an exemplary embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

10 ... non-contact rotary switch unit 100 ... unit housing

110 ... Unit housing cover 120 ... Unit housing body

130 ... Unit housing base 200 ... Rotary switch section

210 ... rotary knob 220 ... rotary shaft

230 ... Rotary Stopper 240 ... Rotary Block

250 ... rotary magnet 260 ... rotary sensor

300 ... unit printed circuit board

Claims (5)

A unit housing having an inner space; A unit printed circuit board disposed in an inner space of the unit housing; A rotary knob rotatably disposed on an upper end of the unit housing, a rotary shaft rotating together with the rotary knob, a rotary block movable together with the rotary shaft by the rotary shaft, and a rotary magnet disposed in the rotary block And a rotary switch unit having a rotary sensor spaced apart from the rotary magnet at a position corresponding to the rotary magnet and disposed on the unit printed circuit board. A rotary theft fixing portion disposed coaxially with the rotary shaft and having a plurality of rotary cutting surfaces on an inner surface thereof; A rotary theft pin in contact with the rotary theft plane and movably disposed radially about the rotary shaft; And a rotary theft portion including a rotary theft elastic member which axially rotates together with the rotary shaft and whose one end elastically supports the rotary theft pin. delete The method of claim 1, The rotary block is a non-contact rotary switch unit characterized in that it comprises a rotary theft pin receiving portion formed in the radial direction from the rotary shaft to accommodate the rotary theft pin. The method of claim 1, The rotary theft fixture takes a ring structure, The non-contact rotary switch unit, characterized in that the rotary cutting surface inclined portion is provided on the outside of the rotary cutting surface to allow the rotary cutting pin to enter. The method of claim 1, The rotary shaft is provided with a rotary stopper for axial rotation with the rotary shaft, and the unit housing is provided with a rotary stopper counterpart for limiting the rotation of the rotary stopper when contacted with the rotary stopper. Unit.

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