KR100817331B1 - Indicating switch and indicating switch device with the same - Google Patents

Abstract

A direction indication switch and a direction indication switching device are provided to detect the movement of a lever in a non-contact manner using an optical sensor and a light blocking unit. A direction indication switch includes a housing, a lever unit, and a PCB(600). The lever unit includes a lever and a lever switch unit. The lever is movably mounted on the housing. The lever switch unit includes plural switch surfaces on which the lever is operated. The PCB(Printed Circuit Board) is arranged inside the housing. An optical sensor unit is arranged on one surface of the PCB. An optical blocking unit is formed on the lever unit. The optical blocking unit is connected to the lever and controls a detection signal from the optical sensor according to movement of the lever.

Description

Direction switch and direction switch device {INDICATING SWITCH and INDICATING SWITCH DEVICE WITH THE SAME}

1 is a schematic exploded perspective view of a direction indicating switch according to an embodiment of the present invention.

2 and 3 are schematic partial perspective views of the direction indicating switch of the present invention.

4 is a schematic perspective view of another direction of a directional switch according to an embodiment of the present invention.

5 is a schematic front view of a part of a direction indicating switch according to an embodiment of the present invention.

6 is a schematic partial perspective view of a portion of a direction indicating switch according to an embodiment of the present invention.

7 is a schematic cross-sectional view of a theft block of the direction indicating switch according to an embodiment of the present invention.

8 is a schematic vertical cross-sectional view of a theft block of a direction indicating switch according to an embodiment of the present invention.

9 to 11 are schematic partial plan views of the rotation state of the direction indicating switch according to an embodiment of the present invention.

12 and 13 are schematic partial front and partial enlarged perspective views of an upward tilting state of a direction indicating switch according to an exemplary embodiment of the present invention.

14 and 15 are schematic partial front and partial enlarged perspective views of a downward tilting state of a direction indicating switch according to an exemplary embodiment of the present invention.

16 is a schematic block diagram of a direction indicating switch device according to another aspect of the present invention.

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

1 ... directional switch device 10 ... directional switch

20 ... Steering angle sensor 30 ... Control part

40.Calculation unit 50 ... Storage unit

60 ... direction indicator 100 ... housing

110 ... housing cover 120 ... housing base

200 ... Lever 210

220 ... Lever 240 ... Lever pivot hinge

250 ... Lever tilting hinge 320 ... Rotating hinge Light blocking part

400 ... guide plate 500 ... tilting slider

600 ... Printed Circuit Board 700 ... Terminal Terminal

The present invention relates to a switch, and more particularly, to a direction indicating switch having a structure that can increase the service life.

Vehicles such as automobiles are required to function beyond various functions as a moving means as various convenient means for allowing a user to provide a more stable and comfortable driving state. Therefore, the vehicle is equipped with various facilities and various switches for operating and controlling the same, and in consideration of the driver's operability, various switches show a tendency to be concentrated in the steering unit.

For example, a steering wheel of a recently produced vehicle has a window switch for opening and closing a window, a steering light switch for turning on / off a steering light, an audio switch for driving audio, and a turn signal flashing or off (mode) Or a direction indicator switch for driving the head lamp up for the upward operation of the head lamp is disposed.

On the other hand, in addition to these various switch devices, components such as a steering roll connector (SRC) and a slip ring (SRC) for powering the switches are disposed at the bottom of the steering wheel. In terms of volume, compactness of other components such as switches mounted on the steering wheel is required in order to efficiently use the limited space of the steering section.

In general, the light switch and the direction indicating switch are formed in a lever type and are arranged on the left or right side of the driver. In the case of the switch type, the light switch and the direction indicating switch are configured by the driver by moving the lever up and down with respect to the rotation center. An electrical signal for the mode can be generated to drive various components. In particular, the direction indicating switch selects an operation mode (state) for the direction in which the driver intends to drive according to the state of movement, and the direction indicating switch according to the prior art takes the switch structure upon contact, thereby causing wear of the switch due to continuous operation. High probability of contact failure. In addition, a lubricant such as grease is used to reduce contact abrasion between the switches, which may cause malfunction of the switch due to entanglement of grease with foreign substances such as dust.

In addition, the configuration of the contact switch has been accompanied with the problem of causing an increase in the process time and manufacturing cost due to the increase of the components.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and an object thereof is to provide a compact directional switch having a simple structure that can increase durability, improve operability and assembly, and reduce manufacturing cost.

The present invention for achieving the above object, the housing portion; A lever unit having a lever movably mounted relative to the housing unit, and a theft block having a plurality of theft surfaces to steal the movement of the lever; And a printed circuit board disposed inside the housing part, wherein an optical sensor part is disposed on one surface of the printed circuit board, and the lever part is connected to the lever and detects the optical sensor part by the movement of the lever. It provides a direction indicating switch is provided with a light blocking unit for controlling the.

In the direction switch, a lever transmission hole is provided on one surface of the lever facing the theft block, a lever pin elastic member is disposed in the lever transmission hole, and between the lever pin elastic member and the theft block. A lever pin in contact with the theft block may be arranged. The lever part may include a lever pivot hinge through which a tip of the lever penetrates and one side is hinged to the housing part to pivot with the lever, and the light shield is a pivot hinge mounted to the lever pivot hinge. An optical blocking unit may be included, and the optical sensor unit may include a rotating hinge optical sensor disposed to correspond to the rotating hinge optical blocking unit. The rotating hinge optical sensor may include a rotating hinge optical sensor transmitting unit and a rotating hinge optical sensor receiving unit, and the rotating hinge optical sensor transmitting unit and the rotating hinge optical sensor receiving unit may be integrally formed.

In addition, two pivoting hinge optical sensors may be provided, and the theft block may include a plurality of pivotal cutting planes with respect to a pivoting plane of the lever, and a pivotal projection projection disposed between the pivotal projection planes.

In the directional switch, the lever unit: a lever tilting hinge that receives the front end of the lever and is rotatably mounted to the lever pivot hinge, and is connected to the lever tilting hinge to slide by a tilting motion of the lever tilting hinge And a tilting slider for moving, wherein the light blocking unit further includes a tilting hinge light blocking unit mounted to the tilting slider, and the optical sensor unit further includes a tilting hinge optical sensor disposed corresponding to the tilting hinge light blocking unit. Alternatively, a guide plate for guiding the tilting slider may be further provided between the printed circuit board and the lever pivoting hinge. The tilting hinge connection part may be provided at one surface of the tilting slider toward the lever tilting hinge, and the lever tilting hinge may be provided at the tilting hinge connection counterpart which is formed toward the tilting slider and engages with the tilting hinge connection part.

The tilting hinge optical sensor may include a tilting hinge optical sensor transmitter and a tilting hinge optical sensor receiver, and the tilting hinge optical sensor transmitter and the tilting hinge optical sensor receiver may be integrally formed.

According to another aspect of the invention, the direction indicator light, the housing portion; A lever unit having a lever movably mounted relative to the housing unit, and a theft block having a plurality of theft surfaces to steal the movement of the lever; And a printed circuit board disposed inside the housing part, wherein an optical sensor part is disposed on one surface of the printed circuit board, and the lever part is connected to the lever and senses a detection signal of the optical sensor part by the movement of the lever. A control unit for controlling the direction indicator in accordance with an electrical signal received from the direction indicator switch, a direction indicator switch having a light blocking unit for controlling the steering wheel, a steering angle sensor for detecting a steering angle of the steering wheel, and an electrical signal received from the direction indicator switch And a storage unit configured to store a preset steering angle of the steering wheel and to be in electrical communication with the controller, and a calculator configured to compare the steering angle change from the steering angle sensor and the preset steering angle according to a control signal of the controller. Provide an indication switch device.

Hereinafter, a direction switch and a direction switch device according to the present invention will be described with reference to the drawings.

1 is a schematic exploded perspective view of a direction switch 10 according to an embodiment of the present invention, Figures 2 and 3 is a schematic view of a direction switch 10 according to an embodiment of the present invention A partial perspective view is shown, and FIG. 4 shows a schematic perspective view from another point of view of the direction indication switch 10 according to an embodiment of the invention. The direction indication switch 10 according to an embodiment of the present invention includes a housing part 100, a lever part 200, and a printed circuit board 600. The printed circuit board 600 includes a housing part 100. ), Optical sensor parts 610, 620, and 630 are disposed on the printed circuit board 600, and the light blocking part 320. 520 is included in the lever part 200.

 The housing part 100 includes a housing cover 110 and a housing base 120, and the housing cover 110 meshes with the housing base 120 to form a housing interior space. The cover mounting opening 111 is provided at the outside of the housing cover 110, and the base mounting protrusion 121 is provided at the housing base 120, and the base mounting protrusion 121 is inserted into the cover mounting opening 111. The configuration is engaged with each other to form a coupling between the housing cover 110 and the housing base 120. Here, although the protrusion structure is formed on the housing base side and the recess structure is formed on the housing cover side, the coupling structure of the housing base and the housing cover of the present invention is not limited thereto, and may be arranged interchangeably. Various modifications are possible depending on the specification. Although not indicated by reference numerals, the outer side of the housing cover 110 may further include a direction indicating switch mounting part for mounting the direction indicating switch 10 according to the present invention.

On the outer side of the housing base 120, a base side surface portion 123 is formed to form a through hole through which the lever 210 inserted into the housing portion 100 passes. The terminal terminal part 125 is disposed below the housing base 120, and the terminal terminal hole 124 is formed in the terminal terminal part 125, and the terminal terminal 700 is disposed through the terminal terminal hole 124. A printed circuit board 600 is disposed in an inner space formed by the housing cover 110 and the housing base 120, and an electric element (not shown) and a circuit wiring (not shown) are disposed on the printed circuit board 600. In addition, the terminal terminal 700 communicates with the circuit wiring through the control unit 30 (see FIG. 16) and transmits an electrical signal according to the operation mode (state) of the lever selected by the user through the lever unit. 60, see FIG. 16).

The lever part 200 includes a lever 210 and a theft block 260, the lever 210 is inserted into the inner space formed by the housing cover 110 and the housing base 120 one end, the lever The other end of the 220 is discharged to the outside of the housing part 100. The other end of the lever 210 may be further provided with various switches 215 for changing the operating state of the direction indicating switch 10. The lever unit 200 is provided with a component for stealing the movement of the lever 210, the lever unit 210 includes a lever elastic member 230 and the lever pin 220. As shown in FIG. 2, a lever transfer hole 211 is provided at an end of the lever 210 inserted into the housing part 100, and the lever transfer hole 211 is provided with a theft block 260. It is provided on one side facing. The lever pin elastic member 230 is inserted into the lever transmission hole 211, and the lever pin 220 is disposed between the lever pin elastic member 230 and the theft block 260. The lever pin 220 has a pin protrusion 221 and a pin body 222, the pin protrusion 211 is formed at the tip of the lever pin 220 toward the pin protrusion 211 of the theft block 260. It contacts the formed theft surface. The pin body 222 is formed at the rear end of the lever pin 220 and inserted into the lever transfer hole 211 to contact the lever elastic member 230.

 The lever elastic member 230 is inserted into the lever transmission hole 211 and is disposed in the lever pin to restore the elastic restoring force generated according to the position displacement of the lever pin 220 generated during the movement of the lever 210, that is, the rotational movement and the tilting movement. Serves to deliver to (220). Here, the rotational movement is defined as a hinge movement that rotates axially about a vertical axis across the housing, the printed circuit board, and the like to select an operation mode of the direction indicator, and the tilting movement defines an operation mode such as a headlight upward. In order to select, it is defined as a hinge movement that rotates up and down about a direction perpendicular to the vertical axis. In one embodiment of the present invention, the lever elastic member 230 is configured as a coil spring type, but is not limited to this in the range that can provide elastic restoring force to the lever pin 220 toward the axial direction of the lever 210 Deformation can be achieved.

The lever 210 of the lever part 200 is disposed to be movable with respect to the housing part 100, and the lever 210 is capable of rotating and tilting with respect to the housing part 100. Here, the rotational movement represents a hinge movement with respect to the housing portion 100 on a plane perpendicular to the axis where the housing cover 110 and the housing base 120 are coupled, and the tilting movement represents the housing cover 110 and the housing base. The hinge movement in the longitudinal direction of the axis to which 120 is coupled is shown.

The lever unit 200 includes a lever pivot hinge 240, which allows the pivot pivot 240 to rotate during the movement of the lever 210. A lever pivot hinge inner space 242 is provided inside the lever pivot hinge 240, and a lever mounting portion 243 is formed at a side of the lever pivot hinge 240. The lever pivot hinge inner space 242 has at least one surface facing the lever 210, one surface facing the theft block 260 and one surface facing the lower printed circuit board 600, one end of the lever 210, That is, one end provided with the lever pin 220 penetrates through the lever pivot hinge inner space 242 of the lever pivot hinge 240 to be in contact with the theft block 260. At this time, the lever mounting counterpart 213 is provided at a corresponding position of the lever mounting part 243 to the side of the lever 210, and the lever mounting counterpart 213 is engaged with the lever mounting part 243. The lever mounting portion 243 and the lever mounting correspondence portion 213 are sides of the lever pivot hinge 240 and the lever 210, respectively, and are formed in parallel with a plane formed by the rotational movement of the lever 210. The lever 210 and the lever pivot hinge 240 rotate together by the rotational movement of the lever, but the lever pivot hinge 240 is tilted in the vertical direction during the tilting movement of the lever 210 in the vertical direction. Only the lever 210 without the tilting movement is possible.

A rotating hinge protrusion 241 is provided at an outer upper end of the lever pivot hinge 240, and a rotation hinge protrusion receiving groove (not shown) formed toward the lever pivot hinge 240 is provided at an inner lower surface of the housing cover 110. The rotation hinge protrusion 241 is rotatably accommodated in the rotation hinge protrusion receiving groove so that the rotation movement of the housing 210 of the lever 210 can be smoothly achieved.

In addition, the lever unit 200 may further include a lever tilting hinge 250 that enables the tilting movement of the lever 210. That is, as shown in Figure 2, the lever unit 200 has a lever tilting hinge 250, the lever tilting hinge 250 has a tilting hinge guide 251 on the inside and a tilting hinge projection on the outer surface 252. A lever tilting protrusion 212 is provided on the outer side of the lever 210, and a tilting hinge protrusion receiving groove 245 is provided at the side of the lever pivoting hinge 240, and the lever tilting protrusion 212 is a lever tilting hinge 250. The tilting hinge guide 251 is inserted into the tilting hinge guide 251, and the tilting hinge protrusion 252 is rotatably engaged with the tilting hinge protrusion receiving groove 245. Therefore, when the tilting motion, that is, the vertical force in the up-down direction is applied to the lever 210, the lever 210 corresponds to the lever mounting counterpart 213 by engaging the lever mounting counterpart 213 and the lever mounting counterpart 243. And a tilting movement based on the lever mounting portion 243, and the tilted lever 210 transmits a force to the lever tilting hinge 250 by engaging the lever tilting protrusion 212 and the tilting hinge guide 251. . The lever tilting hinge 250, which receives the force through the tilting hinge guide 251, is tilted based on the engagement between the tilting hinge protrusion 252 and the tilting hinge protrusion receiving groove 245. Such a tilting movement of the lever may be made through the lever tilting hinge 250.

The lever unit 200 may further include a tilting slider 500. The tilting slider 500 is disposed below the lever tilting hinge 250 and is connected to the lever tilting hinge 240. The tilting slider 500 slides by a tilting motion of the lever tilting hinge 250. The upper surface of the tilting slider 500 is provided with a tilting hinge connection part 510 and a tilting hinge at the lower end of the lever tilting hinge 240. The connection counterpart 253 is provided. The tilting hinge connection counterpart 253 is inserted into the tilting hinge connection part 510 so that a force is transmitted to the lever 210 to achieve tilting in the up-down direction so that the force transmitted when the lever tilting hinge 250 is tilted. As a result, the tilting slider 500 slides. The tilting hinge connection part 510 is formed in an arc shape, and when the lever 210 rotates, the pivoting hinge 250 attached to the lever pivoting hinge 240 that rotates together with the lever 210 smoothly rotates. To achieve this. Here, the tilting hinge connecting portion 510 is configured as a recess or through-hole type, and the tilting hinge connection counterpart 253 is configured as a protrusion type, but this may take a structure formed opposite to each other as an example for explaining the present invention. The configuration of the present invention is not limited thereto.

The printed circuit board 600 is disposed between the housing cover 110 and the housing base 120, and various electric elements (not shown) and circuit wiring (not shown) are formed in the printed circuit board 600. According to the operating position of the lever selected by the user, the circuit wiring of the printed circuit board 600 is directly connected to the turn signal lamp 60 (see FIG. 16) through the terminal terminal 700 or indirectly through an electric device or the like. Apply.

The direction indication switch 10 according to the present invention may further comprise a component for guiding the movement of the lever pivoting hinge and the lever tilting hinge. That is, as shown in Figures 1 and 3, the guide plate 400 is provided between the housing cover 110 and the printed circuit board 600 into the housing 100, the guide plate 600 A plate connecting through hole 420 penetrating the tilting hinge connection counterpart 253 is provided, and a tilting hinge connection counterpart 253 penetrates the plate connecting through hole 420 to provide a tilting hinge connection part of the tilting slider 500. 510 is connected. In addition, the guide plate 400 may be further provided with a component for guiding the rotation of the lever pivot hinge 240. That is, as shown in Figure 1, the outer rotation lower hinge hinge projection projection 244 is provided on the outer lower end of the lever pivot hinge 240, one surface of the guide plate 400 toward the lever pivot hinge 240 is rotated Hinge guide protrusion receiving portion 410 is provided. The rotation hinge guide protrusion receiving portion 410 includes a guide protrusion receiving portion groove 412 defined by the guide protrusion receiving portion guide 411 and the guide protrusion receiving portion guide 411. Guide protrusion receiving groove 412 is divided into arcs (상) can stably guide the rotational movement of the lever pivot hinge. Here, although a protrusion is formed on the lever pivot hinge and a recess or a through hole is formed in the guide plate, a different modification may be taken according to design specifications, such as a different configuration.

On the other hand, the direction indication switch 10 according to the present invention includes an optical sensor unit (610, 620, 630) and the optical sensor blocking unit (320, 520). One embodiment according to the present invention, the optical sensor unit 610, 620, 630 includes a rotating hinge optical sensor (610, 620) and the tilting hinge optical sensor 630, the optical sensor blocking unit 320, 520 is a rotating hinge light blocking unit 320 And a tilting hinge light blocking unit 520, which is only one example for explaining the present invention and the present invention does not correspond to the present embodiment. That is, the rotating hinge optical sensor and the tilting hinge optical sensor of the present invention, the rotating hinge light blocking portion and the tilting hinge light blocking portion may take a variety of configurations, such as each may be provided separately, but in the present embodiment Described as being constructed together.

The rotating hinge optical sensors 610 and 620 are formed on one surface of the printed circuit board 600. The rotating hinge optical sensors 610 and 620 include the rotating hinge optical sensor transmitters 611 and 621 and the rotating hinge optical sensor receivers 612 and 622. . The rotating hinge optical sensor transmitters 611 and 621 emit light, and the rotating hinge optical sensor receivers 612 and 622 receive light. The rotating hinge optical sensor transmitters 611 and 621 and the rotating hinge optical sensor receivers 621 and 622 may be formed separately from each other, but may have a structure that is integrally formed. The rotating hinge optical sensor transmitters 611 and 621 and the rotating hinge light The sensor receivers 621 and 622 are integrally formed, thereby eliminating interference between components that may occur during the progress of the light blocking unit for blocking or passing the light emitted from the rotating hinge optical sensor transmitter due to the reduction of the assembly process and the uniformity of the gap between the two. It may be.

The rotating hinge light blocking unit 320 is formed at one end of the lever rotating hinge 240, and the rotating hinge extension protrusion 310 is provided at the front end of the lever 210. A rotating hinge light blocking part 320 disposed toward the printed circuit board 600 is disposed at an end portion of the rotating hinge extension protrusion 310. The rotating hinge light blocking unit 320 moves through the spaces 613 and 623 between the rotating hinge optical sensor transmitters 611 and 621 and the rotating hinge optical sensor receivers 621 and 622 disposed to face each other. When the guide plate 400 is provided between the lever pivot hinge 240 and the printed circuit board 600, the light blocking part through hole 430 that allows the light blocking part 320 to penetrate through the guide plate 400 is provided. It may be provided. As shown in FIGS. 9 and 10, the rotating hinge light blocking unit 320 includes a rotating hinge light blocking region 321 and a rotating hinge light transmitting region 322, and the rotating hinge light blocking region 321 is formed. The light from the pivoting hinge light sensor transmitters 611 and 621 of the pivoting hinge sensors 610 and 620 is blocked, and the light from the pivoting hinge light sensor receivers 621 and 622 of the pivoting hinge light sensors 610 and 620 is transmitted. It penetrates. Since the pivoting hinge 240 pivots about the pivoting hinge protrusion 241, the pivoting hinge optical sensors 621 and 620 and the pivoting hinge light blocking part 320 are preferably disposed or formed in an arc shape. .

5 is a partial front view of a configuration including a tilting hinge optical sensor and a tilting hinge light blocking unit of the direction indicating switch 10 according to an embodiment of the present invention, and FIG. A schematic partial enlarged view of the portion indicated by. The tilting hinge optical sensor 630 is disposed on a surface of the printed circuit board 600 adjacent to the sliding area of the tilting slider 500, and the tilting hinge optical sensor 630 is parallel to the sliding direction of the tilting slider 500. It is disposed on the side of the tilting slider 500. The tilting hinge optical sensor 630 includes a tilting hinge optical sensor transmitter 631 and a tilting hinge optical sensor receiver, which are disposed to face each other but are integrally formed with each other to achieve an assembly process more smoothly. The possibility of malfunction due to a position error between the receiver and the receiver can be prevented.

The tilting hinge light blocking part 520 is formed at one side of the tilting slider 500 and is formed on a surface parallel to the sliding direction of the tilting slider 500, and the tilting hinge light blocking part 520 is a tilting hinge light blocking area 521. ) And the tilting hinge light transmitting region 523. The tilting hinge light transmitting region 523 is partitioned by the tilting hinge light blocking region 521. The tilting hinge light blocking unit 520 moves between the tilting hinge optical sensor transmitter 631 and the tilting hinge optical sensor receiver 632 of the tilting hinge optical sensor 630 as the tilting slider 500 slides. .

Meanwhile, the theft block 260 (see FIGS. 7 and 8) is disposed in an inner space formed by the housing cover 110 and the housing base 120, which is taken along the line I-I of FIG. 1. In cross section, there is shown a cross section of the theft block 260 viewed in a plane perpendicular to the vertical axis of the housing portion 100, and FIG. 8 is a cross section taken along the line II-II of FIG. 1, and the vertical axis of the housing portion 100 is shown. It shows the cross section of the theft block 26 viewed on a plane parallel to. One surface facing the lever 210 of the theft block 260 is provided with a plurality of the cutting surface 262, the cutting surface 262 includes a rotating theft surface (262H) and a tilting theft surface (262T), The face is shown in FIG. 7, and the tilting section is shown in FIG. 8. Rotating theft surface 262H is shown in a V-shape formed to be inclined with each other. The lever pin 220 of the lever 210 is in contact with the rotating theft surface 262H and forms a rotational movement. In this embodiment, the rotational positions of the lever 210 are "L", "L / C", and "N". , "R / C" and "R". Here, "L" indicates a direction indication in the left direction, "L / C" indicates a temporary direction indication in the left direction, "N" indicates a neutral state, and "R / C" indicates a right direction. "R" indicates the direction direction in the right direction, "L / C" and "R / C" is kept on when selected by the user, but the external force applied to the lever 210 If it is removed, it indicates that the turn signal is switched off immediately. The rotating theft surface 262H has a V-shape so that the rotated lever 210 is "N" when the external force applied to the lever 210 by the driver is removed by the elastic restoring force of the lever elastic member 230. In the original position, the projection projections 262 protruding from the rotation theft surface 262H in the "L / C" and "R / C" on the rotation theft surface 262H so that the user can accurately recognize the rotated position of the lever. Is provided.

The tilting cutaway surface 262T has a plurality of tilting movement positions for the vertical tilting movement of the lever 210 by forming a protruding and inclined surface, the tilting movement positions being partitioned into PD, PN, and PU, respectively. As a result, the lever 210 is capable of an upward tilting motion and a downward tilting motion. The PD-PN is provided with a theft protrusion (theft mount) to maintain the upward tilting state of the lever 210 (theft mount structure). When the lever 210 is located at PD1, the headlamp ( A signal for operating the head lamp upward driver 70 (FIG. 16) that enables upward irradiation of the not shown is generated from the controller (not shown) and transmitted to the head lamp upward driver 70 (see FIG. 16). That is, a protruding surface is provided between the PN and the PD to prevent unwanted position movement between the PN and the PD when a predetermined force is not provided by the user. When the lever 210 is tilted to the PU position, the head lamp upward driving unit transmits a driving signal to irradiate the head lamp upward. An external force by the user applied to the lever 210 is provided with an inclined surface between the PN and the PU. When this is removed, the lever 210 is automatically returned to the position of PN by the elastic restoring force of the lever pin 220 and the lever pin elastic member 230 of the lever 210. In addition, while maintaining the position of the PD with respect to the tilting theft surface 262T during the downward tilting motion, the R, R / C, N, L / C, respectively, for the rotating theft surface (262H, see Figure 7) The state of L may also be formed.

Hereinafter, an operation process of the direction indication switch 10 and the direction indication switch device 1 according to an embodiment of the present invention will be described with reference to FIGS. 9 to 15, and FIGS. 9 to 11 illustrate one embodiment of the present invention. A schematic plan view of a rotational movement state of the direction indication switch 10 according to an example is shown, and FIGS. 12 to 15 show schematic front and partial enlarged perspective views of a tilting movement state of the direction indication switch 10. do.

First, the case where the lever of the direction indication switch 10 makes a rotational motion is demonstrated. As shown in FIG. 9, when the lever 210 (see FIG. 2) is in the N state, the lever pin 220 makes contact with the PN of the theft block 260 (see FIG. 7), and the lever pivot hinge ( The rotating hinge light blocking area 321 of the rotating hinge light blocking unit 320 attached to 240 is disposed outside the two rotating hinge light sensors 610 and 620, and the rotating hinge light transmitting area 322 is between the rotating hinge light sensors. By being disposed in, to form the on signal of the rotating hinge optical sensor (610,620). Here, although shown as being provided with two pivoting hinge sensor, various modifications are possible, such as may be provided with a variety of rotational hinge optical sensor in some cases. In this embodiment, rotation from the N state to the clockwise direction is shown toward the R state and counterclockwise rotation is shown to the L state, but it is obvious that the reverse configuration may be taken.

When the lever 210 rotates clockwise from the N state, the lever 210 is engaged by the lever mounting counterpart 213 of the lever 210 and the lever mounting part 243 of the lever pivot hinge 240. Rotation is transmitted to the lever pivot hinge 240 and the lever pivot hinge 240 rotates with the lever 210. As the lever pivot hinge 240 rotates, the pivot hinge light blocking portion 320 formed at one end of the lever pivot hinge 240 also rotates the optical hinge transmitters 631 and the pivot hinge light of the pivoting optical sensors 610 and 620. At the same time as moving between the sensor receivers 632, the lever pin 220 is located in the PRC (see Fig. 7) of the rotating theft surface 262H beyond the theft projection. The lever pin is displaced toward the lever hole 211 by the lever elastic member which is elastically deformed in the process of over the theft projection 261. The lever pin is repositioned from the lever hole 211 by the elastic restoring force of the lever elastic member. With respect to the lever 210 rotated by RC, one of the two pivoting hinge optical sensors 610 and 610 is an off signal and the other 620 forms an on signal. At this time, when the external force transmitted to the lever 210 by the user is removed, the lever 210 is returned to the N state by the elastic restoring force of the lever pin elastic member 230 and the lever pin is in contact with the PN position.

When the lever 210 rotates further clockwise from the RC state, the lever pin 220 is in contact with the PR position indicating the R state. At this time, the rotation hinge optical sensors (610, 620) both form an off state (see Fig. 11).

In addition, although not shown, when the lever 210 rotates counterclockwise from the N state, the rotation hinge optical sensor 610 indicated by reference numeral 610 in the L / C state forms the L / C and L states. Signal, the other rotating hinge light sensor 620 indicates an off signal, and in the L state, the rotating hinge light sensor 610 and the rotating hinge light sensor 620 indicate an off signal are illustrated in the above embodiment. It is apparent from 9 and 11.

12 to 15 are schematic partial front and partial enlarged perspective views of the tilting hinge light sensor 630 and the tilting hinge light blocking unit 520 which are operated during the tilting motion of the lever. Is a partially enlarged front view of a portion of the lever during the upward tilting movement of the lever, FIG. 13 is a partially enlarged perspective view of reference numeral A of FIG. 12, and FIG. 14 is a portion of the lever during the downward tilting movement of the lever. 15 is a partially enlarged perspective view of the portion A in FIG. 14.

When the lever 210 is tilted in the vertical direction by the user, when the lever 210 moves upward by the tilting movement of the lever (up arrow direction in FIG. 5), the lever mounting counterpart of the lever 210 By engaging the 213 and the lever mounting portion 243 of the lever pivot hinge 240, the lever 210 makes a relative tilting movement with respect to the lever pivot hinge 240 (see Fig. 1). When the lever 210 performs the tilting motion, the lever tilting protrusion 212 formed at the tip of the lever 210 engages the tilting hinge guide 251 to apply a force to the tip of the lever tilting hinge 250. In this case, as shown in FIG. 12, the lever tilting hinge 250 rotates about the tilting hinge protrusion 252 formed on the side of the lever tilting hinge 250 with respect to the lever pivoting hinge 240. The tilting hinge connection counterpart 253 formed at the end of the tilting lever tilting hinge 250 is connected to the tilting slider 500 to slide the tilting slider 500. In this case, the tilting slider 500 moves with respect to the tilting hinge optical sensor 630, and the tilting hinge light blocking unit 520 formed on the tilting slider 500 is tilted of the tilting hinge optical sensor 630 disposed to face each other. It moves between the hinge optical sensor transmitter 631 and the tilting hinge optical sensor receiver 632. The tilting hinge light blocking unit 520 may include a tilting hinge optical sensor transmitting unit 631 and a tilting hinge light sensor receiving unit 632 when the lever pin is in contact with the cutting surface of the PN position. The tilting hinge optical sensor 630 is disposed at the to generate an on signal. When the tilting hinge optical sensor blocking region 521 is disposed between the transmitter and the receiver by the upward tilting motion, the tilting hinge optical sensor ( 630 generates an off signal. At this time, when the external force applied by the user is removed, the lever 210 is N by the elastic restoring force of the inclined region PN-PU and the lever pin elastic member 230 of the tilting cutting surface 262T. Automatic return to state (see Figure 8)

On the contrary, when the lever 210 moves downward, the tilting slider 500 slides in a direction opposite to that of the upward tilting motion as shown in FIGS. 14 and 15. The tilting hinge light blocking area 522 of 520 is disposed between the transmitter and the receiver of the tilting hinge light sensor 630 so that the tilting hinge light sensor 630 generates an off signal. At this time, the lever 210 for downward tilting movement is different from the upward tilting movement of the tilting diagram 262T, unlike the upward tilting movement, which is self retrun when the external force applied by the driver is applied to the lever 210. By means of the theft projection (theft mountain) disposed in the PD section, even if the driver removes the external force applied to the lever 210, the lever pin 220 forms a theft fixed state to maintain the PD state, thereby A sustain signal may be applied to the head lamp upward driver 70 which is configured to maintain the upward driving state of the lamp. Accordingly, the lever pin 220 is rotated by the lever 210 by the elastic action between the lever pin 220 and the lever pin elastic member 230 (see FIG. 1) when the driver provides an external force in a direction opposite to the downward tilting motion. The lever 210 (see FIG. 1) may be switched from the PD state to the PN state by maintaining the contact between the lever pin 220 and the tilting cutting surface 262T with the lever hole 211.

Therefore, the signal states of the rotating hinge optical sensor and the tilting hinge optical sensor for the operating state (mode) of the rotating motion and the tilting motion according to the present embodiment are summarized as follows.

Rotary hinge optical sensor (610) Rotating Hinge Light Sensor (620) Tilting Hinge Optical Sensors (630) Whether to return R / C off On On Auto return R off off On Auto return L / C On off On Auto return L off off On Auto return N On On On Upward tilting On On off Auto return Downward tilting On On off Theft Mountain

However, such an on / off state of the optical sensor unit is only one example of the present invention, and the present invention is not limited thereto.

On the other hand, another embodiment of the present invention provides a direction indicating switch device having the above-described direction indicating switch. The direction indicating switch device 10 includes a direction indicating switch 10, a steering angle sensor 20, a control unit 30, an operation unit 40, a storage unit 50, and a direction. The indicator lamp 60 is provided, but the direction indicator switch 10 is described in the above-described embodiment, and description thereof will be omitted. The turn signal lamp 60 is a light bulb that blinks according to an applied electrical signal, and may be integrally formed adjacent to a head lamp that irradiates light toward the front of the vehicle, and may be attached to a side end of a side mirror (not shown). The type and arrangement of the turn indicators can be variously modified according to design specifications. The steering angle sensor 20 detects the amount of rotation of the steering wheel (steering wheel) which is steered by the driver. The steering angle sensor 20 is disposed coaxially with the steering wheel and has a plurality of slits (through holes) formed therein. A slit plate (not shown) and one or more photo sensors (not shown) disposed above the slit of the slit plate may take the structure. The controller 30 is connected to the direction switch 10 to control the blinking operation of the turn signal 60 in accordance with the electrical signal received from the direction switch 10. The storage unit 40 stores a preset steering angle for the steering wheel (not shown). The preset steering angle is a minimum change amount of the steering wheel required to grasp the driver's turn indicator blinking as a steering wheel rotation angle change value. For example, the preset steering angle may have various values according to design specifications and driving conditions. The storage unit 50 may be embodied in the form of EEPROM (Electrically erasable and programmable read only memory), and may be implemented in a form changeable form. It may be. The calculator 40 is in electrical communication with the controller 30 and compares the steering angle signal obtained from the steering angle sensor 20 with the preset steering angle according to a signal from the controller 30, and transmits the steering angle signal to the controller 30.

The operation process of the direction indicating switch device 10 according to the present invention is as follows. The direction indication switch device 10 transmits a signal for the operation mode of the direction indicator / head lamp upward driver selected by the user to the controller 30. The steering angle sensor 20 detects a rotation angle due to the rotation of the steering wheel (not shown), and the steering angle sensor 20 is in electrical communication with the controller 30 to steer the steering angle of the steering wheel steered by the driver. It passes to the control unit 30. The optical sensor units 610 and 620 of the direction switch 10 and the steering angle sensor 20 are detected at predetermined intervals. In the present embodiment, the signals for the L and R states in the pivoting hinge optical sensors 610 and 620 are set to have off signals for the two pivoting hinge optical sensors, and the distinction for the L and R states is defined by the pivoting hinge. It is determined as an operation signal for a step before a detection cycle of the optical sensors 610 and 620. That is, in the present embodiment, when both of the rotating hinge optical sensors 610 and 620 generate an off signal, if the rotating hinge optical sensor 620 at the step before the detection cycle is on, the operating mode selected by the user is R. The control unit 30 determines that the state is.

In addition, the controller 30 transmits a control signal to the turn signal 60 according to whether the turn signal returns to the off state. As described above, since the theft block of the direction indicating switch according to the present invention has a V-shaped pivoting section, when the external force applied to the lever is removed by the driver, it automatically returns to the N state for all states (modes). Take the structure that becomes. In the case of R / C and L / C, the control part applies a control signal to blink the turn indicator 60 only when the rotating hinge light sensors 610 and 620 are in an on / off or off / on state, and the lever returns to its original position. The blinking of the turn signal 60 is also turned off. On the other hand, in the case of the R, L state, even if the automatic return by the operation of the rotating theft surface and the lever is made, there is a case that the blinking state of the direction indicator 60 is to be maintained. Therefore, when the R, L state is selected to flash the turn signal 60, the controller 30 blinks the turn signal 60 and detects a change in the steering angle of the steering wheel through the steering angle sensor at regular intervals. When the change in the steering angle before and after the blinking of the turn indicator 60 is greater than the preset steering angle previously stored in the storage unit 50, the blinking state of the turn indicator 60 is released and the change in the steering angle is less than or equal to the preset steering angle. It is determined to maintain the blinking state of the indicator 60 and transmits a control signal corresponding thereto to the direction indicator 60.

In addition, the direction switch device 1 may be further provided with a head lamp upward drive unit 70. The headlamp upward driving unit 70 may be implemented by an electric motor or the like that rotates the steering direction of the headlamp (not shown), and may operate the headlamp (not shown) by operating by a control signal from the controller 30. Here, the head lamp upward driving unit 70 is illustrated as being connected to the control unit 30, but may have a structure that operates directly by a signal from the tilting hinge optical sensor of the direction indicating switch without passing through the control unit 30.

The above embodiments are examples for describing the present invention, but the present invention is not limited thereto. That is, the direction indication switch according to the present invention may be equipped with an optical sensor and an optical sensor blocking unit which are operated at the time of the rotational movement and the tilting movement at the same time, or may have a configuration in which only one is selected. In addition, although it has been shown that the two sensors for the rotational movement of the lever and the light blocking portion and the two sensors for each of the off, low, high, ste, etc. to perform the above on / off operation, the rotation hinge of the present invention The sensor may be in a different on / off combination, and various modifications are possible in the range including a non-contact direction indicating switch for generating an electrical signal by detecting the lever operation by the rotational movement / tilting movement of the lever.

The direction indicating switch according to the present invention having the configuration as described above has the following effects.

First, the direction indicating switch according to the present invention has a non-contact sensing structure including an optical sensor unit and a light blocking unit for detecting the movement of the lever, thereby resulting in poor contact or contact due to abrasion occurring in the contact switch structure. It is possible to provide a direction switch that prevents malfunction due to poor contact due to inflow of dust or the like with lubricants such as grease used and increases durability and service life.

Second, the direction indicating switch according to the present invention, by excluding the complex contact structure for the electrical connection and simply take a non-contact sensing structure to take the structure of detecting the movement of the lever according to whether the light is blocked, the direction indicating switch more It can also be configured compactly.

Third, the direction indicating switch according to the present invention, by detecting the operating state of the direction indicating switch with a non-contact sensing means, it is possible to reduce the manufacturing cost according to the increase in productivity due to the shortening of the assembly process according to the reduced component and the material cost.

Net material, the direction indicating switch according to the present invention, having a transmitting unit and a receiving unit, but having a configuration that is integrally installed to prevent performance degradation due to assembly error and may have a manufacturing cost reduction effect according to the number of assembly processes reduced. .

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

Claims (10)

A housing part; A lever unit having a lever movably mounted relative to the housing unit, and a theft block having a plurality of theft surfaces to steal the movement of the lever; A printed circuit board disposed in the housing part; An optical sensor unit is disposed on one surface of the printed circuit board, and the lever unit includes a light blocking unit connected to the lever and intermittently detecting a detection signal of the optical sensor unit by the movement of the lever. The method of claim 1, A lever transmission hole is provided on one surface of the lever facing the theft block, a lever pin elastic member is disposed in the lever transmission hole, and a lever pin contacting the theft block between the lever pin elastic member and the theft block. Direction indication switch, characterized in that disposed. The method of claim 1, The lever unit has a lever pivot hinge which penetrates the front end of the lever and one side is hinged to the housing to pivot with the lever. And the light blocking unit includes a rotating hinge light blocking unit mounted to the lever rotating hinge, and the optical sensor unit includes a rotating hinge optical sensor disposed corresponding to the rotating hinge light blocking unit. The method of claim 3, wherein The pivoting hinge optical sensor includes a pivoting hinge optical sensor transmitter and a pivoting hinge optical sensor receiver, wherein the pivoting hinge optical sensor transmitter and the pivoting hinge optical sensor receiver are integrally formed. The method of claim 4, wherein The rotating hinge optical sensor is provided with two, And wherein the theft block includes a plurality of pivotal cutting planes and a pivotal theft projection disposed between the tilting planes with respect to the pivoting plane of the lever. The method of claim 3, wherein The lever part: A lever tilting hinge accommodating the tip of the lever and rotatably mounted to the lever pivot hinge; And a tilting slider which is connected to the lever tilting hinge and slides by a tilting motion of the lever tilting hinge. The light blocking unit further includes a tilting hinge light blocking unit mounted to the tilting slider, and the optical sensor unit further comprises a tilting hinge optical sensor disposed corresponding to the tilting hinge light blocking unit. The method of claim 6, And a guide plate for guiding the tilting slider between the printed circuit board and the lever pivoting hinge. The method of claim 6, The tilting hinge connecting portion is provided on one surface of the tilting slider toward the lever tilting hinge, and the lever tilting hinge is formed toward the tilting slider and has a tilting hinge connection corresponding portion engaged with the tilting hinge connecting portion. Indicator switch. The method of claim 6, The tilting hinge optical sensor includes a tilting hinge optical sensor transmitter and a tilting hinge optical sensor receiver, wherein the tilting hinge optical sensor transmitter and the tilting hinge optical sensor receiver are integrally formed. With turn signals, A housing part; A lever unit having a lever movably mounted relative to the housing unit, and a theft block having a plurality of theft surfaces to steal the movement of the lever; And a printed circuit board disposed inside the housing part, wherein an optical sensor part is disposed on one surface of the printed circuit board, and the lever part is connected to the lever and senses a detection signal of the optical sensor part by the movement of the lever. A direction indicating switch provided with a light blocking portion for intermitting; A steering angle sensor for detecting a steering angle of the steering wheel, A control unit connected to the direction indicating switch and controlling the direction indicator in accordance with an electrical signal received from the direction indicating switch; A storage unit for storing a preset steering angle of the steering wheel and in electrical communication with the control unit; And a computing unit configured to compare a steering angle change from the steering angle sensor and the preset steering angle according to a control signal of the controller.

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