JP2023013696A - Lamp unit - Google Patents

Abstract

To provide a lamp unit which achieves reduction of variations in the assembly position which affect light distribution accuracy at low costs.SOLUTION: A lamp unit 10 is mounted on a vehicle. The lamp unit 10 includes: a light source 14 mounted on a substrate 12; a reflector 16 which reflects light from the light source 14 forward; a projection lens 20 which is held by a lens holder 18 and disposed forward of the reflector 16; and a shade 22 for formation of a cutoff line CL which is disposed rearward of the projection lens 20. The lens holder 18, the reflector 16, and the shade 22 are integrally molded to form a lens holder unit 40.SELECTED DRAWING: Figure 3

Description

TECHNICAL FIELD The present invention relates to a lighting unit, and more particularly to a lighting unit used in a vehicle headlamp.

This type of lamp unit includes a light source, a projection lens held by a lens holder, a reflector arranged behind the projection lens for reflecting the light from the light source toward the projection lens, and the reflector as disclosed in Patent Document 1. A configuration is known that includes a shade for blocking part of the light from the reflector to form a cutoff line. Conventionally, as in Patent Document 1, these lens holder, reflector, and shade are separate parts, and the lamp unit is constructed as an assembly.

JP 2015-173096 A

In recent years, there has been a demand for downsizing of lamp units. Under these circumstances, if the lens holder, reflector, and shade are configured as separate parts as in Patent Document 1, the light distribution accuracy will be adversely affected due to variations in the structure and assembly position of each. There is In particular, when the size is reduced, there is a problem that the light distribution accuracy is greatly affected.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a low-cost lamp unit that reduces variation in the mounting position that affects light distribution accuracy.

In order to achieve the above object, a lighting unit according to one aspect of the present invention is a lighting unit mounted on a vehicle, comprising: a light source mounted on a board; and a reflector for reflecting light from the light source forward. a projection lens held by a lens holder and arranged in front of the reflector; and a shade for forming a cut-off line arranged behind the projection lens, wherein the lens holder, the reflector and the shade are , and is configured as a lens holder unit in which all of these are integrally molded.

According to the above aspect, by integrally molding the reflector, the lens holder, and the shade as a lens holder unit, the light source, the reflector, the lens, and the shade can be combined simply by aligning the lens holder unit with the substrate on which the light source is mounted. positional accuracy is improved, and variations in light distribution due to assembly errors are reduced. It is also advantageous if the lighting unit is small. In addition, by integrally molding the reflector, lens holder, and shade, the number of parts can be reduced and the cost can be reduced by using common materials.

In the above aspect, it is also preferable that the lens holder unit is formed with a substrate mounting portion.

In the above aspect, it is also preferable that the lens holder unit has an opening at a position directly facing the shade.

In the above aspect, the shade includes a horizontal reflecting surface that shields part of the light reflected by the reflector to form a cutoff line, and an inclined reflecting surface that tilts forward from the front end of the horizontal reflecting surface. and a sub-reflector is formed in front of the opening of the lens holder unit for reflecting light from the light source to the inclined reflective surface, and the inclined reflective surface reflects light incident from the sub-reflector forward. It is also preferred to reflect to.

In the above aspect, a flange is formed on the outer periphery of the projection lens, the rear surface of which abuts against the front end surface of the lens holder unit, and a positioning projection projecting rearward is formed on the rear surface of the flange. It is also preferable that the front end surface of the lens holder unit is formed with a concave portion matching the positioning projection.

According to the lamp unit according to the aspect described above, it is possible to reduce the variation in the mounting position that affects the light distribution accuracy at low cost.

1 is a front view of a vehicle lamp provided with a lamp unit according to an embodiment of the present invention; FIG. FIG. 2 is a cross-sectional view of the vehicle lamp along line II-II in FIG. 1; 3 is an exploded perspective view of the lamp unit; FIG. It is a back perspective view of the same lamp unit. FIG. 4 is a diagram showing a passing beam light distribution pattern formed by the vehicle lamp. FIG. 4 is a layout diagram of a mold for injection molding a lens holder unit that constitutes the same lamp unit.

A lamp unit 10 according to an embodiment of the present invention will be described below with reference to the drawings. The embodiments are illustrative rather than limiting, and not all features and combinations thereof described in the embodiments are necessarily essential to the invention.

For convenience of explanation and drawing, the drawings may be partially simplified except for essential parts of the invention. Further, in this specification, directions such as front, rear, left, and right refer to directions when the vehicle lamp 1 including the lamp unit 10 is viewed from the front unless otherwise specified. In each figure, arrows Up-Lo indicate the vertical direction, arrows Le-Ri indicate the left-right direction, and arrows Fr-Re indicate the front-back direction.

(Embodiment)
A lamp unit 10 according to the embodiment is a lamp unit that constitutes a vehicle lamp 1 that functions as a passing beam headlamp mounted in front of a vehicle.

1 is a front view of a vehicle lamp 1, and FIG. 2 is a cross-sectional view of the vehicle lamp 1 along line II-II in FIG. 3 is an exploded perspective view of the lamp unit 10, and FIG. 4 is a rear exploded perspective view showing the lens holder unit 40 and the projection lens 20 of the lamp unit 10. As shown in FIG.

As shown in FIGS. 1 and 2, the vehicle lamp 1 includes a passing beam lamp unit 10 , a box-shaped housing 2 with an open front, and a transparent outer lens 3 . The housing 2 is made of opaque resin such as polypropylene or polyethylene. The outer lens 3 is made of transparent resin such as polycarbonate. The lamp unit 10 is provided in a lamp chamber S defined by the outer lens 3 attached to the front surface of the housing 2 so as to block the opening of the housing 2 .

Between the lamp unit 10 and the outer lens 3, there is an opening 11 that matches the shape of the projection lens 20 of the lamp unit 10, which will be described later, to shield the internal structure of the housing 2 from being seen from the outside. An extension member (PES cover) 4 is arranged. In FIG. 1, the rough dashed lines indicate members that are obscured by an opaque member in front. Fine dashed lines indicate members visible through a projection lens 20, which will be described later.

The lamp unit 10 includes a light source 14 mounted on a board 12, a reflector 16 arranged to cover the upper side of the board 12 and reflecting the light from the light source 14 forward, and a lens arranged in front of the reflector 16. A projection lens 20 held by a holder 18 and a shade 22 for forming a cut-off line arranged behind the projection lens 20 are provided.

The light source 14 is a white light emitting diode (LED) having a rectangular light emitting surface. The light source 14 is mounted on the substrate 12 with its light emitting surface facing upward. A concave portion 17 matching the shape of the substrate 12 is formed in the lower portion of the reflector 16 , and the substrate 12 is positioned and held between the concave portion 17 and the rear end portion of the shade 22 . That is, the recess 17 formed in the reflector 16 and the rear end portion of the shade 22 define the board mounting portion 19 . The substrate 12 is positioned on the substrate attachment portion 19 and attached to the base member 24 via the reflector 16 by the screw 21 with the light emitting surface of the light source 14 facing upward. The base member 24 is configured to function also as a heat sink.

The base member 24 is attached to the bracket 26 with screws 27 . The bracket 26 includes a back plate portion 28 extending vertically in a rectangular shape substantially similar to the vehicle lamp 1 when viewed from the front, and a shelf portion 30 extending horizontally forward from the back plate portion 28 . , is fixed to the shelf portion 30 . A ball joint 32 is attached to the upper left portion of the back plate portion 28, and aiming screws 34 are attached to the upper right portion and the lower left portion of the back plate portion 28, respectively. and attached to the housing 2 . As a result, the optical axis of the lamp unit 10 can be adjusted vertically and horizontally.

A rear end portion of the extension member 4 is coupled to the bracket 26 so that the lamp unit 10 and the extension member 4 can rotate integrally.

As can be seen from FIG. 1, four light sources 14 are arranged on the substrate 12 at regular intervals in the horizontal direction. The reflector 16 is divided into four sections in the horizontal direction so as to correspond to the light sources 14 respectively. Each section of the reflector 16 is an ellipsoid of revolution arranged so that each light source 14 is the first focal point, and a first reflecting surface 16a is formed on the inner surface. The first reflecting surface 16a is formed by, for example, sputtering or vacuum deposition of metal such as aluminum. The shade 22 also has four shades arranged side by side. Therefore, the lamp unit 10 has a shape in which four lamp units having the sectional shape shown in FIG. 2 are connected in the left-right direction.

The shade 22 has a horizontal surface 22b whose front end is located at the second focal point of the reflecting surface 16a of the reflector 16, and an inclined surface 22c which is inclined forward from the front end of the horizontal surface 22b. Reflective surfaces 22d and 22e are formed on the horizontal surface 22b and the area extending forward from the horizontal surface 22b by vacuum-depositing a metal such as aluminum. Hereinafter, the reflecting surface formed on the horizontal surface 22b of the shade 22 is referred to as a horizontal reflecting surface 22d, and the reflecting surface formed on the inclined surface 22c is referred to as an inclined reflecting surface 22e. A front end of the horizontal reflecting surface 22d, that is, a boundary between the horizontal reflecting surface 22d and the inclined reflecting surface 22e is called a ridge line 22f.

FIG. 5(A) shows the shape of the vicinity of the ridgeline 22f of the shade 22 viewed from the front. In the drawing, line VV indicates a vertical reference line, and line HH indicates a horizontal reference line. The horizontal plane 22b of the shade 22 has two horizontal planes where the left side of the line VV is higher than the line HH and the right side of the line VV is along the line HH. It has a shape and is configured to form a light distribution pattern of a passing beam shown in FIG. 5(B) to be described later.

The front end of the shade 22 constitutes the projection lens 20 below the lens holder 18 . The upper portion of the lens holder 18 is connected to the front end of a sub-reflector 36, which will be described later.

As shown in FIG. 3, the lens holder 18, reflector 16 and shade 22 are configured as a lens holder unit 40 in which all of these are integrally molded. Walls 42 are formed at both ends of the lens holder unit 40 . An opening 44 is formed in the upper portion of the lens holder unit 40 at a position facing the edge line 22 f of the shade 22 . The opening 44 functions as a heat dissipation port for dissipating the heat generated by the substrate 12 to the outside of the lens holder unit 40 when the vehicle lamp 1 is turned on. In some conventional vehicle lamps, a heat dissipation port is provided, but it is provided forward of the ridge line 22 f of the shade 22 . In the lamp unit 10 of the present embodiment, the opening 44 is provided closer to the substrate 12, which is the heat source, so the heat radiation effect is improved. The inclined surface 22c of the shade 22 may have an opening in a portion other than the inclined reflecting surface 22e. If the opening is provided, the heat dissipation effect of the opening 44 is further improved.

A second reflecting surface 36a is formed on the inner surface of the sub-reflector 36 to reflect light from the light source 14 toward the inclined reflecting surface 22e of the shade 22, as will be described later. The second reflecting surface 36a is formed by vapor-depositing a metal such as aluminum by a technique such as sputtering or vacuum vapor deposition, similarly to the first reflecting surface 16a.

The projection lens 20 is a rectangular projection lens made of a transparent resin such as polymethyl methacrylate (PMMA). A flange 46 is formed on the outer periphery of the projection lens 20 . For convenience of drawing, in FIG. 3, the projection lens 20 is shown as being rectangular in front view and protruding in a semi-cylindrical shape in front and rear of the flange. It has a shape that protrudes back and forth from a rectangular flange in front view, which is cut out in the shape of a flange.

A front end surface of the lens holder unit 40 forms a lens holder 18 that connects to the front ends of the shade 22 and the sub-reflector 36 . The lens holder 18 has a rectangular frame shape in front view that aligns with the flange 46 of the projection lens 20 .

A total of three positioning protrusions 48 are formed on the rear surface of the flange 46, two in the upper part of the projection lens 20 and one in the lower part. The positioning protrusion 48 is formed in a rectangular shape that is similar to the front view shape of the projection lens when viewed from the front.

On the other hand, on the front end surface of the lens holder 18, that is, the lens holder unit 40, at positions corresponding to the positioning projections 48 of the flange 46, there are two concave portions 52 on the top and two on the bottom, which are shaped to match the positioning projections 48. It is formed in one place.

Then, the positioning projections 48 are fitted into the corresponding recesses 52 for positioning, and the rear surface of the flange 46 of the projection lens 20 is brought into contact with the front end surface of the lens holder 18 (lens holder unit 40), and the laser beam is projected. The projection lens 20 is attached to the lens holder unit 40 by welding.

In a conventional lamp unit using a rectangular projection lens, positioning projections are provided on the lens holder, and concave portions matching the projections are provided on the flange of the projection lens to position the projection lens and the lens holder. Therefore, when the lamp is viewed from the front, the colored positioning projections are conspicuous in the flange of the transparent lens, resulting in an unattractive appearance.

In the lamp unit 10 according to the present embodiment, the positioning projections 48 are formed on the rear surface of the flange 46 of the projection lens 20, so that the positioning projections 48 are not directly visible. Moreover, even if the shape of the positioning projection is visually recognized through the transparent flange 46 of the projection lens 20, it is not conspicuous and the appearance is improved. In addition, in the lamp unit 10 according to the present embodiment, the positioning protrusion 48 has a rectangular shape when viewed from the front, so it is less conspicuous than other shapes such as a circular shape. Furthermore, it is also possible to dispose the flange 46 of the projection lens 20 , where the positioning projection 48 is visually recognized, so that it is almost invisible from the front depending on the overlap with the extension member 4 .

The number of positioning protrusions 48 is not particularly limited, but is preferably at least three, and three is advantageous because the configuration is the simplest.

3 and 4, a projection 54 is provided in addition to the positioning projection 48 on the rear surface of the flange 46, and a concave portion 56 matching the projection 54 is provided on the corresponding front end surface of the lens holder 18. It is also preferable to prevent erroneous assembly of the lens holder unit 40 and the projection lens 20, which are slightly different depending on the destination.

Here, the positioning protrusion 48 and the protrusion 54 have different shapes (sizes), but they may have the same shape. The positional relationship between the positioning projections 48 and the projections 54 can be set as appropriate. Further, instead of providing the protrusions 54 and the recesses 56, the positional relationship between the plurality of positioning protrusions 48 and the recesses 52 may be changed to provide a mechanism for preventing incorrect assembly.

In the lamp unit 10 according to the present embodiment, the reflector 16, the lens holder 18, and the shade 22 are integrally formed as the lens holder unit 40. As shown in FIG. As a result, just by aligning the lens holder unit 40 and the substrate 12 on which the light source 14 is mounted, the positional accuracy of the light source 14, the reflector 16, the projection lens 20, and the shade 22 is improved, and assembly error is reduced. The resulting variation in light distribution is reduced. In particular, when the lamp unit 10 is miniaturized, the influence of the assembly error of the constituent members becomes relatively large. The effects of assembly variations do not occur. Further, integral molding (single-color molding) of the reflector 16, the lens holder 18, and the shade 22 reduces the number of parts, and furthermore, the cost can be reduced because the materials can be used in common.

At this time, the substrate 12 on which the light source 14 is mounted may be positioned and fixed to the base member 24 , and the lens holder unit 40 may be attached to the base member 24 . However, if the substrate mounting portion 19 for positioning and holding the substrate 12 on which the direct light source 14 is mounted is formed in the lens holder unit 40 as in the above embodiment, the light source 14, the reflector 16, the lens holder 18, and the shade 22 are formed. This is particularly advantageous because it improves the positional accuracy between and.

Next, functions of the vehicle lamp 1 including the lamp unit 10 will be described with reference to FIGS. 2 and 5A.

The light emitted from the light source 14 is reflected by the first reflecting surface 16a of the reflector 16 and condensed near the edge line 22f of the shade 22. As shown in FIG. The light condensed in the vicinity of the ridgeline 22f is projected forward of the lamp as parallel light L1 while being vertically and horizontally reversed by the projection lens 20 . A dark portion caused by the shade 22 is formed in the light distribution pattern formed at this time.

FIG. 5B is a diagram schematically showing a light distribution pattern of a passing beam formed by the vehicle lamp 1 and projected onto a virtual screen provided in front of the lamp. As can be seen from FIG. 5B, the vehicle lamp 1 forms a light distribution pattern of a passing beam having a cutoff line CL on the upper side. This cutoff line CL is formed so as not to give glare to oncoming vehicles. Therefore, the position of the cut-off line, that is, the shape of the ridgeline of the shade is designed according to whether the vehicle is driving on the right or left. The vehicle lamp 1 is a vehicle lamp for right-hand traffic.

Part of the light emitted from the light source 14 is reflected by the reflective surface of the sub-reflector, and further reflected by the inclined reflective surface of the shade 22 to form parallel light and enter the projection lens 20, thereby forming overhead sign illumination light L2. Form. An overhead sign means a road sign or the like that is positioned above the front of a vehicle and passes over the driver's head as the vehicle travels.

Next, a mold for forming the lens holder unit 40 of the lamp unit 10 according to the embodiment will be described. The lens holder unit 40 is integrally formed by one-color molding of an opaque resin such as polyethylene or polypropylene.

FIG. 6 is a cross-sectional view of a mold 200 for injection molding the lens holder unit 40 of the lamp unit 10 according to the embodiment. The mold 200 includes a cavity side mold 210 , a core side mold 220 and a slide mold 230 . A cavity C<b>1 defining a portion of the reflector 16 having the substrate attachment portion 19 is formed in the dividing plane PL of the cavity side mold 210 and the core side mold 220 .

In addition, the cavity side mold 210 protrudes from the core side mold 220 at a portion corresponding to the opening 44 of the lens holder unit 40, and cooperates with the core side mold 220 and the slide mold 230 to form a lens holder. 18 and a cavity C2 that defines the shade 22. As shown in FIG. The cavity-side mold 210 defines the horizontal surface 22b of the shade 22 and the inclined reflecting surface 22e of the inclined surface 22c. The slide mold 230 defines the lens holder 18 and the inclined surface 22c of the shade 22. A portion other than the inclined reflecting surface 22e is defined.

In addition, the cavity side mold 210 and the slide mold 230 cooperate to form a cavity C3 that defines the sub-reflector 36 and the upper part of the lens holder 18 .

Here, in the lens holder unit 40, the rear end portion 22a of the horizontal surface 22b of the shade 22 is designed to be positioned forward of the front end portion of the reflector 16 in the cross section in the front-rear direction. In addition, the front end portion of the inclined reflecting surface 22 e of the inclined surface 22 c of the shade 22 is designed to be positioned behind the rear end portion of the sub-reflector 36 . Further, the inclination of the inclined surface 22c of the shade 22 with respect to the horizontal is designed to be greater than the inclination of the reflection surface 36a of the sub-reflector 36 with respect to the horizontal.

By designing the lens holder unit 40 in this way, the cavity side mold 210, the core side mold 220, and the slide mold 230 are opened in the directions of arrows A1, A2, and A3, respectively. can be avoided, and the lens holder unit 40, which is a molded product, can be die-cut.

A lighting unit for a low beam needs to have a shade for forming a cutoff line CL. When a shade is provided, if an attempt is made to integrally mold a lens holder unit that integrates a lens holder, a reflector, and a shade, the shade portion may be undercut and the mold may not be formed. In the lamp unit 10 according to the present embodiment, the opening 44 is provided in the upper part facing the shade 22 of the lens holder unit 40, so that the cavity side mold 210, the core side mold 220, and the It becomes possible to define the reflecting surfaces 22d and 22e of the shade with the slide mold 230, and integral molding becomes possible.

When integrally molding the lens holder, reflector and shade, it is not always necessary to provide an opening on the upper surface facing the shade. However, as in the lamp unit 10 according to the embodiment, in the configuration in which the sub-reflector 36 and the shade 22 having the horizontal surface 22b and the inclined reflecting surface 22e are provided and the illumination light for the overhead sign is emitted, if the horizontal surface 22b is formed integrally, and the inclined surface 22c always become an undercut. As in the present embodiment, if an opening 44 is provided on the upper surface facing (the reflective surfaces 22d and 22e of) the shade 22, the reflector 16, the shade 22, and the lens can also be provided with a configuration for irradiating illumination light for an overhead sign. The holder 18 can be integrally molded.

10: Lamp Unit 11: Opening 12: Substrate 14: Light Source 16: Reflector 16a: First Reflecting Surface (Reflecting Surface of Reflector)
17: concave portion 18: lens holder 19: substrate mounting portion 20: projection lens 22: shade 22d: reflecting surface 22d: horizontal reflecting surface 22e: reflecting surface 22e: inclined reflecting surface 36: sub-reflector 36a: second reflecting surface (sub-reflecting surface) reflective surface of the reflector)
40 : Lens holder unit 44 : Opening 46 : Flange 48 : Positioning protrusion 52 : Recess 54 : Protrusion 56 : Recess CL : Cutoff line

Claims (5)

A lighting unit mounted on a vehicle,
a light source mounted on the substrate;
a reflector that forwardly reflects light from the light source;
a projection lens held by a lens holder and arranged in front of the reflector;
A shade for forming a cutoff line arranged behind the projection lens,
A lighting unit, wherein the lens holder, the reflector, and the shade are integrally formed as a lens holder unit. 2. The lamp unit according to claim 1, wherein the lens holder unit is formed with a board mounting portion. 3. The lamp unit according to claim 1, wherein the lens holder unit has an opening at a position facing the shade. The shade has a horizontal reflective surface that shields part of the light reflected by the reflector to form a cutoff line;
and an inclined reflective surface that inclines forward from the front end of the horizontal reflective surface,
A sub-reflector is formed in front of the opening of the lens holder unit for reflecting light from the light source to the inclined reflecting surface,
4. The lamp unit according to claim 3, wherein the inclined reflecting surface reflects forward the light incident from the sub-reflector. A flange is formed on the outer circumference of the projection lens, the back surface of which contacts the front end surface of the lens holder unit,
Positioning protrusions protruding rearward are formed on the rear surface of the flange, and recesses matching the positioning protrusions are formed on the front end surface of the lens holder unit. 5. The lamp unit according to any one of 4.

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