KR20140032729A - Headlamp lighting derection controller - Google Patents

Abstract

The present invention relates to an apparatus for switching a headlamp light radiation direction, which switches the direction of light radiated from a light source of a headlamp by comprising: a shield bracket which is installed in the front of a light source; a shield plate which is combined with the shield bracket in order to eccentrically rotate, and shields part of light radiated from the light source as adhering to the shield bracket in an overlapping state; an actuator which eccentrically rotates the shield plate; a torsion spring which provides elasticity for the shield plate in order to return the shield plate; and a damper which is placed in the shield bracket in order to dampen impact by the shield plate as adhering to the shield plate returned by the torsion spring. The damper comprises: soft damping rubber whose one side is hung on the shield bracket in a penetrating state and whose the other side adheres to the shield plate as facing the shield plate; and a damping protrusion which protrudes by forming an identical object on the other side of the damping rubber and buffers the impact in the shield plate as being elastically deformed by the impact by the shield plate. Through the present invention, the damping protrusion forming the damper firstly buffers the impact on the shield plate as being elastically deformed. The damping rubber secondly buffers the impact by adhering to the shield plate. Therefore, the apparatus for switching a headlamp light radiation direction can promote safe driving through reduced light shaking of the light source by significantly reducing vibration and noise due to the impact on the shield plate.

Description

Irradiation direction changer for headlamps {HEADLAMP LIGHTING DERECTION CONTROLLER}

The present invention relates to a headlamp irradiation direction switching device, and more particularly, headlamp irradiation for switching the light to the upper or lower light by blocking or opening a portion of the light irradiated from the light source of the headlamp installed in the vehicle. It relates to a turning device.

Headlamps, also commonly referred to as headlights, are lights that illuminate the front of a vehicle and require brightness to identify obstacles that exist within a distance of 100m at night.

These headlamps are divided into a low-light which is usually lit at night and an high-light that is lit on a secluded road without oncoming vehicles. In the past, headlamps were provided with uplight lamps and downlight lamps, respectively, and irradiated with light through respective reflectors and lenses, but each component had to be installed two bars, which required a lot of installation space.

In order to improve such a problem, a head lamp device disclosed in Korean Patent Laid-Open Publication No. 10-2011-120715 has recently been proposed.

The headlamp device of the prior art as shown in FIG. 1 has a light source unit 110 that irradiates light through the lens unit 120, and a bracket unit installed between the light source unit 110 and the lens unit 120. 130 and a driving unit rotatably mounted to the bracket unit 130 to rotate the shield unit 140 and the shield unit 140 to shield a part of the light supplied from the light source unit 110 to the lens unit 120. It consists of 150.

The headlamp of the prior art has a configuration in which the light emitted from the light bulb member 120 constituting the light source unit 110 is reflected at various angles through the reflecting unit 114 and supplied to the lens unit 120. According to the operation of 140, as shown in (a) of FIG. 1, only the light is supplied downward to the lens unit 120, or as shown in (b), the lens unit 120 is simultaneously upward and downward. To supply.

Specifically, the shield unit 140 closes the light upward while being closely attached to the bracket unit 130 as shown in (a) of FIG. 1, and as shown in (b) of FIG. 1. The upward light is opened while rotating by the driving unit 150. The shield unit 140 blocks the upward light while returning to the bracket unit 130 by the driving unit 150 or the return spring not shown.

At this time, the shield 140 is in close contact with the bracket 130 by the rotation to generate a shock and noise, and further has a problem of causing the light shaking phenomenon by vibrating the light source 130.

Accordingly, the recently developed headlamp is provided with a cushioning rubber 200 in the bracket portion 130 as shown in Figure 2 to cushion the shock of the shield portion 140.

By the way, the conventional buffer rubber 200 is formed in a planar state as shown in Figure 2 is in close contact with the shield portion 140 configuration to significantly reduce the vibration and noise caused by the shield portion 140 There is no problem.

Specifically, the maximum vibration by the conventional shock absorbing rubber 200 was measured as 9.69 m / s ² as shown in Figure 3, the number of vibration was measured four times.

In addition, the maximum noise by the conventional buffer rubber 200 was measured as 59.3dB as shown in FIG.

KR 10-2011-120715 A

The present invention is to solve the problems of the prior art as described above, a head lamp that can reduce vibration and noise by buffering the impact of the rotation of the shield plate to shield or open a portion of the light irradiated from the light source The purpose is to provide a device for changing the irradiation direction.

The headlamp irradiation direction switching device of the present invention for achieving the above object is a headlamp irradiation direction switching device for switching the irradiation direction of light irradiated from the light source of the headlamp, which is provided in front of the light source Shield brackets; A shield plate coupled to the shield bracket so as to be uniaxially rotated, and shielding a portion of light emitted from the light source while being in close contact with the shield bracket; An actuator coupled to the shield bracket and configured to press a portion of the shield plate to uniaxially rotate the shield plate to supply a portion of the light shielded by the shield plate to the front of the shield bracket; A torsion spring for providing an elastic force to the shield plate that is uniaxially rotated by the actuator to return the shield plate to the shield bracket in an overlapping state; And a damper provided in the shield bracket to be in close contact with the shield plate returned by the torsion spring and damping an impact caused by the shield plate, wherein the damper is fitted into one side of the shield bracket in a penetrating state. Damping rubber which is in close contact with the shield plate while the other side facing the shield plate; And a damping protrusion protruding to form the same body on the other side of the damping rubber, and buffering the impact of the shield plate while elastically deforming by the impact of the shield plate.

In addition, the damper is formed in a groove shape on one side of the damping rubber to form a damping space at the rear of the damping protrusion, and attenuates the reaction force of the damping rubber due to the impact of the shield plate to the elastic deformation of the damping protrusion It can be configured to further include a damping pocket to allow.

In addition, the damper is provided on the other side of the damping rubber along the circumference of the damping protrusion while facing the damping pocket, and the damping protrusion elastically deformed by the shielding plate to the inside of the damping rubber. It may further comprise a; groove-shaped projection trap to reduce the contact area of the damping rubber in close contact with the shield plate while recessed.

And, the present invention is integrally provided in the shield plate and rotates together with the shield plate, formed of a reflector to bend the light irradiated from the light source or to reflect the light irradiated toward the shield plate; It can be configured to include.

According to the irradiation direction switching device for a head lamp of the present invention as described above, the damping protrusion constituting the damper buffers the shock of the shield plate primarily while elastically deformed, while the damping rubber adheres to the shield plate to cushion the shock secondly. Therefore, the vibration and noise due to the impact of the shield plate can be significantly reduced, and thus the light tremor of the light source is reduced, thereby improving the visibility of night driving and promoting safe driving.

In particular, as the reaction force of the damping rubber due to the impact of the shield plate is attenuated by the damping pocket, the damping protrusion may be smoothly elastically deformed to cushion the shock of the shield plate.

Furthermore, as the damping protrusion is elastically deformed and recessed into the damping rubber by the projection trap, the damping rubber that is in close contact with the shield plate is in close contact with the shield plate in a state where the adhesion area is reduced, thereby further reducing vibration and noise.

In addition, since the inclined plate is provided on the shield plate and rotates together with the shield plate, it is possible to identify road signs by reflecting the light of the light source in a bent state in the downlight mode. Can perform functions such as soaring or taillights.

1 is a longitudinal sectional view showing a headlamp according to the prior art.
Figure 2 is a longitudinal sectional view showing a buffer rubber of the prior art.
Figure 3 is a graph showing the vibration generated by the buffer rubber shown in FIG.
Figure 4 is a graph showing the noise generated by the buffer rubber shown in FIG.
Figure 5 is a longitudinal sectional view showing the irradiation direction switching device for a head lamp according to the present invention.
6 is a perspective view of the switching device shown in FIG.
7 is a longitudinal cross-sectional view showing a damping process of the damper shown in FIG.
8 is a longitudinal sectional view showing another embodiment of the damper shown in FIG.
9 is a graph showing the generation of vibration according to the present invention.
10 is a graph showing the generation of noise according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted.

Irradiation direction switching device for a head lamp according to the present invention is a shield bracket 10, the shield plate 20, the actuator 30, the torsion spring 40 and the damper 50 as shown in FIG. It is configured to include.

The shield bracket 10 is installed vertically in front of the light source 5 constituting the head lamp as shown in FIG. Here, the light source 5 is composed of a lamp 5a and a reflector 5b as described with reference to FIG. 1, and the reflector 5b reflects the light irradiated from the lamp 5a to reflect the light upward and downward. 6).

On the other hand, the shield bracket 10 is shielded by a connecting housing (not shown) connecting the reflector 5b of the light source 5 and the lens 6.

The shield plate 20 is a member for shielding or opening a part of light irradiated from the light source 5 toward the lens 6, and a rotating shaft coupled to the shield bracket 10 as shown in FIGS. 5 and 6 ( 20a) is coupled to the rotary shaft 20a while rotating uniaxially to block a part of the light of the light source 5 or supply it to the lens 6.

Specifically, the shield plate 20 protrudes to the upper end of the shield bracket 10 in a state overlapping with the shield bracket 10 as shown in FIG. As shown in (b) of FIG. 5, the actuator 30 rotates about the rotation shaft 20a by the actuator 30 to be described later to achieve an upward light mode while supplying upward light to the lens 6.

That is, the light of the light source 5 is irradiated downward only by the rotation of the shield plate 20 or simultaneously irradiated downward and upward.

The actuator 30 is a component that rotates the shield plate 20 about the rotation shaft 20a by pressing one side of the shield plate 20, and one side of the shield bracket 10 as shown in FIG. 6. It is fixed to, and is connected to a part of the shield plate 20 through the rod (30a).

The actuator 30 is a member in which a conventional solenoid is built and the rod 30a moves by the electromagnetic force of the solenoid, and as shown in FIG. 5, one side of the shield plate 20 is pulled through the rod 30. Works. Accordingly, the shield plate 20 opens the front of the light source 5 while rotating uniaxially about the rotation shaft 20a by the operation of the actuator 30 as shown in FIG.

The torsion spring 40 is provided on the rotation shaft 20a as shown in FIG. 5 to provide elastic force to the shield plate 20 while returning the shield plate 20 while elastically compressing according to the rotation of the shield plate 20. That is, the shield plate 20 is rotated by the actuator 30 as shown in (b) of FIG. 5, and as shown in FIG. 5 (a) as the electromagnetic force of the actuator 30 is extinguished. The elastic force of the torsion spring 40 returns to the overlapping state with the shield bracket 10.

Damper 50 is a component for damping the shock generated as the shield plate 20 is in close contact with the shield bracket 10 while rotating to the original position by the torsion spring 40, for example shown in FIG. As described above, the damping rubber 51 and the damping protrusion 53 may be configured.

Damping rubber 51 is formed of a soft rubber material, as shown in Figure 6 is provided with a hook-shaped locking jaw 51a on one side as shown in Figure 7 shield bracket 10 through the locking jaw (51a) ), The other side is in close contact with the shield plate 20 while facing the shield plate 20.

The damping protrusion 53 is formed in the same manner as the damping rubber 51, as shown in Figure 6 and protrudes on the other side of the damping rubber 51, as shown in Figure 7 to the impact of the shield plate 20 This cushions the impact of the shield plate 20 while elastically deforming.

That is, the damper 50 is in close contact with the shield plate 20 through the damping protrusion 53 in accordance with the return of the shield plate 20 as shown in (b) of FIG. 7 while the impact of the shield plate 20. Is buffered primarily, and as shown in FIG. 7 (c), the damping rubber 51 is closely adhered to the shield plate 20 according to the elastic deformation of the damping protrusion 53 to cushion the shock secondary.

The damping protrusion 53 buffers the impact of the shield plate 20 while elastically deforming smoothly by the damping pocket 57 as shown in FIG. 7.

The damping pocket 57 is formed in a groove shape on one side of the damping rubber 51 to form a damping space at the rear of the damping protrusion 53, as shown in FIG. 7C. As described above, damping of the reaction force of the damping rubber 51 allows the elastic deformation of the damping protrusion 53. That is, the damping protrusion 53 buffers the shield plate 20 primarily while smoothly deforming as the rigidity of the damping rubber 51 is weakened by the damping pocket 57.

Meanwhile, the damper 50 may further include a protrusion trap 55 as shown in FIGS. 6 and 7.

The protrusion trap 55 is provided in a groove shape on the other side of the damping rubber 51 along the circumference of the damping protrusion 53 while facing the damping pocket 57 as shown in FIG. 7.

The protrusion trap 55 recesses the damping protrusion 53 elastically deformed by the shield plate 20 to the inside of the damping rubber 51, as shown in FIG. 7C, and the damping protrusion 53. In accordance with the depression of the damping rubber 51 in close contact with the shield plate 20 to reduce the contact area. That is, as shown in (c) of FIG. 7, the protrusion trap 55 contacts the damping rubber 51 to the shield plate 20 in a line contact state while the damping protrusion 53 is in close contact with the shield plate 20. To cushion the shocks of the secondary.

Therefore, the damper 50 buffers the shock of the shield plate 20 primarily through the elastic deformation and the depression of the damping protrusion 53, and the shock rubber 51 secondly impacts the shock damping state in a state in which the contact area is minimized. Since the buffer, the vibration and noise due to the impact of the shield plate 20 can be reduced.

Here, the projection trap 55 may be provided with a reinforcing rib 55a as shown in FIG. 8 to reinforce rigidity.

On the other hand, the damping rubber 51, as shown in Figure 8 is embossed close contact protrusion 51b protrudes along the edge of the other side is in close contact with the shield plate 20 in the point contact state of the shield plate 20 Shock can also be cushioned. Accordingly, the damping rubber 51 may further reduce vibration and noise caused by the shield plate 20 as the adhesion area with the shield plate 20 is further reduced.

On the other hand, the above-described damping protrusion 53, as shown in FIG. 8, the auxiliary protrusion 53a protrudes to double the shock of the shield plate 20, otherwise the damping groove 53b is provided As the rigidity is weakened, the deformation of the shield plate 20 may be buffered while smoothly elastically deforming.

In addition, the shield plate 20 may be integrally provided with the inclined plate 60 as shown in FIG. 6.

The inclined plate 60 is made of a reflector, is provided in an inclined state on one side of the shield plate 20 as shown in Figure 6 and rotates together with the shield plate 20, as shown in Figure 5 (a) In the downlight mode, the light irradiated through the reflector 5b described above is reflected in a bent state and bent to the upper portion of the lens 6. Accordingly, the headlamp can easily identify road signs and traffic lights by the inclination plate 60 even in the downlight mode.

In addition, as shown in (b) of FIG. 5, the inclined plate 60 reflects external light that is irradiated toward the shield plate 20, such as a tail light or a vehicle width lamp without lighting of the light source 5. Can function.

The operation and operation of the present invention including the above-described components will be described.

Shield plate 20 is normally projected in the superimposed state on the shield bracket 10 as shown in Figure 5 (a) to perform a downlight mode by shielding the upward light, a quiet road without an oncoming vehicle As shown in FIG. 5 (b), the upward light is opened to supply the lens 60 to the upper lamp mode.

At this time, the shield plate 20 performs a single lamp rotation by rotating about the rotation shaft 20a as the rod 30a is pulled by the electromagnetic force of the solenoid embedded in the actuator 30.

Then, the actuator 30 dissipates the electromagnetic force as the upward light mode ends, so that the shield plate 20 is rotated by the elastic force of the torsion spring 40, as shown in (a) of FIG. In close contact with (10).

At this time, the damping protrusion 53 constituting the damper 50 is first in close contact with the shield plate 20, as shown in Figure 7 (b) is elastically deformed by the rotation of the shield plate 20 to impact By damping the car, the damping rubber 51 is in close contact with the shield plate 20 through the rim in accordance with the depression of the damping protrusion 53 as shown in FIG.

Here, the damping protrusion 53 is recessed to the inside of the damping rubber 51 by the projection trap 55 while smoothly elastically deformed by the damping pocket 57, the damping rubber 51 to the projection trap 55 As a result, the adhesion area with the shield plate 20 is reduced.

Accordingly, the shield plate 20 is cushioned by the damping protrusions 53 and the damping rubbers 51, and the shocks are secondarily cushioned, and the shielding plate 20 is in close contact with the damping rubbers 51 having the close contact area minimized by the protrusion traps 55. Therefore, the generation of vibration and noise can be minimized.

That is, the maximum vibration by the damper 50 of the present invention was measured at 7.76 m / s ² as shown in Figure 9, the number of vibration was measured in two times.

In addition, the maximum noise by the damper 50 of the present invention was measured as 52.3dB as shown in FIG.

As such, the damper 50 of the present invention significantly reduces vibration and noise caused by the shield plate 20 with respect to the prior art.

As described above, the headlamp irradiation direction switching device of the present invention buffers the impact of the shield plate 20 primarily while the damping protrusion 53 constituting the damper 50 elastically deforms, and damping rubber 51 Since the shock absorbing secondary to the shield plate 20, the shock absorbing secondary to the shield plate 20 can be significantly reduced vibration and noise due to the impact of the shield plate 20, thereby reducing the light vibration of the light source, thereby improving visibility of night driving Therefore, safe driving can be achieved.

In particular, as the reaction force of the damping rubber 51 due to the impact of the shield plate 20 is damped by the damping pocket 57, the damping protrusion 53 smoothly elastically deforms and cushions the impact of the shield plate 20. Can be.

Further, as the damping protrusion 53 is elastically deformed and recessed into the damping rubber 51 by the protrusion trap 55, the damping rubber 51 closely contacting the shield plate 20 is in a state where the adhesion area is reduced. Since it is in close contact with the shield plate 20, vibration and noise can be further reduced.

In addition, since the inclined plate 60 is provided on the shield plate 20 and rotates together with the shield plate 20, the downlight mode reflects the light of the light source 5 in a bent state to identify road signs and the like. In the shield plate 20 by reflecting the light irradiated toward it can perform a function such as a traffic light or taillight.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be apparent to those skilled in the art that various changes, substitutions, and alterations can be made therein without departing from the spirit of the invention.

5: light source 5a: lamp
5b: Reflector 6: Lens
10: shield bracket 20: shield plate
20a: axis of rotation 30: actuator
30a: load 40: torsion spring
50: damper 51: damping rubber
51a: engaging jaw 51b: close contact
53: damping protrusion 53a: auxiliary protrusion
55: protrusion trap 55a: reinforcing rib
57: damping pocket 60: inclined plate

Claims (4)

In the irradiation direction switching device for a head lamp to switch the irradiation direction of the light irradiated from the light source of the head lamp,
A shield bracket installed in front of the light source;
A shield plate coupled to the shield bracket so as to be uniaxially rotated, and shielding a portion of light emitted from the light source while being in close contact with the shield bracket;
An actuator coupled to the shield bracket and configured to press a portion of the shield plate to supply a portion of the light shielded by the shield plate to the front of the shield bracket while uniaxially rotating the shield plate;
A torsion spring for providing an elastic force to the shield plate that is uniaxially rotated by the actuator to return the shield plate to the shield bracket in an overlapping state; And
And a damper provided in the shield bracket to be in close contact with the shield plate returned by the torsion spring and damping an impact caused by the shield plate.
The damper includes:
A damping rubber of a soft material, one side of which is inserted into the shield bracket in a penetrating state and the other side of the shield bracket faces the shield plate while being in close contact with the shield plate; And
And a damping protrusion protruding to form the same body on the other side of the damping rubber and buffering the impact of the shielding plate while elastically deforming by the impact of the shielding plate. 2. The damper according to claim 1,
A damping pocket provided on one side of the damping rubber to form a damping space at the rear of the damping protrusion, and damping the reaction force of the damping rubber due to the impact of the shield plate to allow elastic deformation of the damping protrusion; Irradiation direction switching device for a head lamp further comprising. The method of claim 2, wherein the damper,
The damping protrusion is provided on the other side of the damping rubber along the circumference of the damping protrusion while facing the damping pocket, and the damping protrusion elastically deformed by the shielding plate is in close contact with the shielding plate. And a groove-shaped protrusion trap for reducing the contact area of the damping rubber. The method of claim 1,
And an inclined plate which is integrally provided in the shield plate and rotates together with the shield plate and is formed of a reflector to bend the light emitted from the light source or reflect the light irradiated toward the shield plate. Irradiation direction change device.

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