JP2023051424A - vehicle lamp - Google Patents

Abstract

To provide a vehicle lamp capable of forming an appropriate light distribution pattern for passing while simplifying the shape of a lens.SOLUTION: A vehicle lamp 10 comprises a light source (light source unit 11) provided with a light emitting surface 23, and a lens 12 that projects light emitted therefrom to form a light distribution pattern (light distribution pattern LP for passing). One side of the light emitting surface 23 is a cutoff line part 24. The lens 12 has a central lens part 33, and an outside lens part 34 that is provided outside the central lens part and emits the light after internally reflecting the light from the light source. The central lens part 33 forms a central pattern region PC including a cutoff line CL. The outside lens part 34 forms an outside pattern region PO.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to vehicle lamps.

A known vehicular lamp is a lens direct type (direct project type) in which light from a light source is directly incident on a lens, and the lens forms a desired light distribution pattern for irradiation. Among the light distribution patterns, there is a light distribution pattern for passing each other, which has a cutoff line for preventing glare to an oncoming vehicle (such as its driver).

In the vehicle lamp described above, it is considered to form a passing light distribution pattern by providing a large number of beam shaping surfaces (prisms) on the surface of the lens that irradiates the light from the light source (see, for example, Patent Document 1st prize). In this vehicular lamp, by optically setting each beam-shaping surface, it is possible to form a passing light distribution pattern having a cut-off line at an appropriate position and an appropriate brightness distribution.

Japanese Patent Publication No. 2020-510295

By the way, in order to form a light distribution pattern for passing each other with an appropriate brightness distribution while forming a cut-off line at an appropriate position, the above-mentioned conventional vehicle lamp has many beam shaping surfaces (prisms) on the surface of the lens. are provided, and their positions and angles must be finely adjusted. For this reason, the conventional vehicle lamp has a complicated lens shape, resulting in an increase in cost and difficulty in handling.

The present disclosure has been made in view of the above circumstances, and an object of the present disclosure is to provide a vehicle lamp capable of forming an appropriate light distribution pattern for passing while simplifying the shape of the lens.

A vehicle lamp according to the present disclosure includes a light source provided with a light emitting surface, and a lens that projects light emitted from the light source to form a light distribution pattern. A cut-off line side portion corresponding to the cut-off line in the light pattern, and the lens includes a central lens portion provided on the optical axis for emitting light from the light source, and a central lens portion provided outside the central lens portion for emitting the light from the light source. an outer lens portion that internally reflects light from a light source and then emits the light, wherein the central lens portion forms a central pattern area including the cutoff line in the light distribution pattern, and the outer lens portion and forming an outer pattern area that constitutes the light distribution pattern by being overlapped with the central pattern area.

According to the vehicle lamp of the present disclosure, it is possible to form an appropriate light distribution pattern for passing while simplifying the shape of the lens.

1 is an explanatory diagram showing a configuration of a vehicle lamp as an example according to an embodiment of the vehicle lamp according to the present disclosure; FIG. FIG. 3 is an explanatory diagram showing a state in which the light source portion of the vehicle lamp is viewed from the front side in the optical axis direction; FIG. 4 is an explanatory diagram showing a state in which the lens of the vehicle lamp is viewed from the light source side; It is explanatory drawing which shows a mode that the lens was frontally viewed from the front side of an optical axis direction. It is explanatory drawing which shows a mode that the lens was seen from the back side of an optical axis direction. FIG. 6 is an explanatory diagram showing a cross section taken along the II line shown in FIG. 5; FIG. 6 is an explanatory view showing a cross section taken along line II-II shown in FIG. 5; FIG. 4 is an explanatory diagram showing an upper cutoff region formed by an upper cutoff lens portion in the central lens portion; FIG. 5 is an explanatory diagram showing a lower cutoff region formed by a lower cutoff lens portion in the central lens portion; FIG. 11 is an explanatory diagram showing an upper overlapping area formed by an upper overlapping lens portion in the center lens portion; FIG. 11 is an explanatory diagram showing a lower overlapping area formed by a lower overlapping lens portion in the central lens portion; FIG. 4 is an explanatory diagram showing a central pattern area formed by a central lens portion; 6 is an explanatory view showing a cross section taken along line III-III shown in FIG. 5; FIG. FIG. 6 is an explanatory view showing a cross section taken along line IV-IV shown in FIG. 5; FIG. 6 is an explanatory view showing a cross section taken along line VV shown in FIG. 5; FIG. 4 is an explanatory diagram showing a middle diffusion region formed by a first lens portion in an outer lens portion; FIG. 5 is an explanatory diagram showing a large diffusion area formed by a second lens portion in the outer lens portion; FIG. 4 is an explanatory diagram showing an outer pattern area formed by an outer lens portion; FIG. 4 is an explanatory diagram showing a light distribution pattern for passing light formed by a lens; FIG. 11 is an explanatory diagram showing an upper overlapping region formed by an upper overlapping lens portion in a center lens portion as a comparative example; FIG. 11 is an explanatory diagram showing a lower overlapping area formed by a lower overlapping lens portion in a center lens portion as a comparative example;

Example 1 of the vehicle lamp 10 as one embodiment of the vehicle lamp according to the present disclosure will be described below with reference to FIGS. 1 to 21 . FIGS. 8 to 12 and FIGS. 16 to 21 show a screen where the horizontal line H and the vertical line V intersect with the central position O of the irradiation from the vehicle lamp 10 as the origin by the corresponding light. Each formed region (light distribution) is shown. FIGS. 8 to 12 and FIGS. 16 to 21 show the distribution of brightness in each region (light distribution) as contour lines in which the brightness increases toward the center. Also, in FIGS. 6, 7, and 13 to 15, cross-sectional hatches are omitted in order to make it easier to understand how light rays travel.

The vehicle lamp 10 is used as a lamp for a vehicle such as an automobile, and is used as a headlamp, a fog lamp, or the like, for example. The vehicle lamp 10 constitutes a so-called direct type (lens direct type) lamp unit in which a lens 12 forms a light distribution pattern of direct light from a light source (light source unit 11 described later). The vehicular lamp 10 includes a vertical optical axis adjustment mechanism and a horizontal optical axis adjustment mechanism in a lamp chamber formed by covering the open front end of a lamp housing with an outer lens on both the left and right sides of the front part of the vehicle. Provided through a mechanism. In the following description, in the vehicle lamp 10, the direction in which the optical axis La of the lens 12 extends, which is the direction in which light is emitted, is the optical axis direction (Z in the drawings), and the optical axis direction is along the horizontal plane. The vertical direction is the up-down direction (Y in the drawing), and the horizontal direction (horizontal direction) perpendicular to the optical axis direction and the up-down direction is the left-right direction (X in the drawing).

The vehicle lamp 10 includes a light source portion 11 as a light source, a lens 12, and a heat radiation member 13, as shown in FIG. As shown in FIGS. 1 and 2, the light source unit 11 has an LED package 21 mounted on a substrate 22 . The LED package 21 emits white light for forming a light distribution pattern, and is configured using LEDs (Light Emitting Diodes). The LED package 21 may be composed of an OLE (Organic Light Emitting (organic EL)), an OLED (Organic Light Emitting Diode), or the like. The configuration of this LED package 21 will be described later.

The substrate 22 has a plate shape and is provided with mounting holes and positioning holes on both left and right sides. The LED package 21 is fixed by connecting terminals provided on the substrate 22 to the terminals of the LED package 21, and power can be supplied from a power supply source mounted on the vehicle via a lighting control circuit. It is The substrate 22 is fixed to the heat dissipation member 13 and is capable of releasing heat from the LED package 21 . The light source unit 11 is arranged so that the light emission optical axis (optical axis direction) is in the front direction of the vehicle, and the light emitting surface 23 of the LED package 21 is positioned near the rear focal point of the lens 12 . The light source unit 11 is appropriately lit by supplying power from the lighting control circuit to the LED package 21 through the substrate 22 .

The heat dissipation member 13 is a heat sink member that radiates (releases) heat generated by the light source unit 11, and is formed of a metal material with high thermal conductivity. there is The heat dissipation member 13 has a base portion 13a and a fin portion 13b. The base portion 13a has a plate shape orthogonal to the optical axis direction, and the light source portion 11 is installed on the front side in the optical axis direction, and the fin portion 13b protrudes from the opposite side (rear side in the optical axis direction). there is The fin portions 13b are plate-shaped, and are arranged side by side (parallel) at predetermined intervals.

The LED package 21 is configured by providing a light emitting element and a phosphor on a heat dissipation substrate. A light-emitting element is mounted on the heat-dissipating substrate, and a plurality of LED electrodes are provided, which electrically connect the n-electrode and p-electrode of the light-emitting element to the circuit of the substrate 22 . The phosphor is provided on the light emitting element (on the front side in the optical axis direction) and emits yellow light when excited by the blue light emitted from the light emitting element. The LED package 21 emits white light by combining the blue light from the light emitting element and the yellow light from the phosphor. For this reason, the LED package 21 has a light-emitting surface 23 made of phosphor.

In the LED package 21 of Example 1, as shown in FIG. 2, the light emitting surface 23 (phosphor) has two sides extending in the vertical direction when viewed from the front side in the optical axis direction, and two sides extending in the horizontal direction on the upper side in the vertical direction. and a side that extends. A cut-off line portion 24 is formed by partially notching the remaining one side of the light emitting surface 23 extending in the horizontal direction on the lower side in the vertical direction. The cutoff line portion 24 forms the cutoff line CL in the light distribution pattern LP for passing (see FIG. 19), and has a first horizontal side portion 24a, an inclined side portion 24b, and a second horizontal side portion 24c. . The first horizontal side portion 24a and the second horizontal side portion 24c are parallel to the left-right direction, and the inclined side portion 24b forms an obtuse angle with respect to the first horizontal side portion 24a and the second horizontal side portion 24c, that is, the left-right direction. It is said that The angle of the inclined side portion 24b with respect to the first horizontal side portion 24a is adapted to the angular relationship between the horizontal line Lh and the inclined line Ls in the cutoff line CL of the light distribution pattern LP for passing. This cut-off line side portion 24 can be formed, for example, by partially removing the plate-like phosphor by etching.

In the LED package 21 of Example 1, the vicinity of the joint between the first horizontal side portion 24a and the second horizontal side portion 24c is positioned on the optical axis La, and the first horizontal side portion 24a is positioned along the optical axis. It is along a straight line passing through La and extending in the left-right direction. Here, in Example 1, the vertical direction is the first direction that intersects the cut-off line side portion 24 extending in the horizontal direction as a whole in the direction along the light emitting surface 23 , and the horizontal direction is the first direction in the direction along the light emitting surface 23 . It is the second direction along one horizontal side 24a. Therefore, the light emitting surface 23 is positioned on the positive side corresponding to the vertical upper side of the center of gravity in the first direction with respect to the optical axis La, and the first horizontal side portion 24a as the horizontal side portion is positioned near the optical axis La. is provided along the second direction. The LED package 21 having such a posture enables the light distribution pattern LP (cut-off line CL) for passing to be appropriately formed.

The vehicle lamp 10 has a light source portion 11 attached to a base portion 13a of a heat radiating member 13, and a lens 12 is provided at a predetermined distance from the light source portion 11 on the front side in the front-rear direction. The lens 12 is supported by a support member (lens holder) (not shown) so as to have an appropriate positional relationship with the light source section 11 , and the positional relationship with the light source section 11 and the heat dissipation member 13 is maintained. When the vehicle lamp 10 is assembled in this way, the attitude of the LED package 21 with respect to the lens 12 (its optical axis La) is determined.

The lens 12 is made of a resin member and has a lens body 31 and a pair of mounting pieces 32 as shown in FIGS. The lens body 31 has a substantially circular shape when viewed from the front side in the optical axis direction, and the light emitted from the light source section 11 forms a passing light distribution pattern LP. The mounting pieces 32 protrude from both sides of the lens body 31 in the diametrical direction, and allow the lens 12 to be mounted on the lens holder using the mounting holes 32a provided therein.

The lens body 31 has a central lens portion 33 on the optical axis La and an outer lens portion 34 surrounding it on the outside. The central lens portion 33 emits light (direct light) emitted from the light source portion 11 in a predetermined direction ahead of the vehicle. For this reason, the center lens portion 33 can basically reflect the shape of the light emitting surface 23 in the irradiated area (light distribution), and the LED package having the light emitting surface 23 provided with the cutoff line side portion 24 21 (light source unit 11), the cutoff line CL can be formed using the cutoff line side portion 24. FIG.

The central lens portion 33 forms the central pattern region PC (see FIG. 12) in the light distribution pattern LP for passing (see FIG. 19), and the outer lens portion 34 forms the outer pattern region PO (see FIG. 12) in the light distribution pattern LP for passing. 18). That is, the light distribution pattern LP for passing is formed by overlapping the central pattern area PC and the outer pattern area PO. The central pattern area PC constitutes the periphery of the cutoff line CL in the light distribution pattern LP for passing, and makes the contrast due to the cutoff line CL, that is, the contour of the cutoff line CL clear. The outer pattern area PO forms an outer shape other than the cutoff line CL in the light distribution pattern LP for passing, and is larger than the central pattern area PC.

The central lens portion 33 is divided into four surfaces, one surface passing through the optical axis La and extending in the vertical direction, and the other surface passing through the optical axis La and extending in the horizontal direction, two of which are cutoff lens portions. 35 and the remaining two are overlapping lens portions 36 . In the center lens portion 33, two cut-off lens portions 35 are provided at the upper right and lower left, and two overlapping lens portions 36 are provided at the upper left and lower right in FIG. For this reason, the central lens portion 33 alternately arranges the cutoff lens portion 35 and the overlapping lens portion 36 in the rotation direction about the optical axis La.

Both cutoff lens portions 35 form a cutoff region CC (see FIGS. 8 and 9) in the central pattern region PC, and both overlapping lens portions 36 form an overlapping region CA (FIGS. 10 and 11) in the central pattern region PC. see). That is, the central pattern area PC (see FIG. 12) is configured by overlapping the cutoff area CC and the overlapping area CA. The cutoff area CC forms the shape of the cutoff line CL in the central pattern area PC, while the brightness of the neighborhood (so-called hot spot) of the intersection (hereinafter also referred to as the elbow) between the inclined line Ls and the horizontal line Lh. form a distribution. The overlapping area CA forms the brightness distribution of the central pattern area PC while forming the central pattern area PC.

As shown in FIGS. 3 to 7, the central lens portion 33 is formed so that the central portion of the surface of the lens body 31 on the rear side in the optical axis direction (the surface facing the light source portion 11) is located inside the lens 12 (the surface facing the light source portion 11). has a recessed central entrance face 37 on the opposite side). This central incident surface 37 allows the light (direct light) from the light source section 11 to enter the central lens section 33 (see FIGS. 6 and 7), and has two cut-off surfaces corresponding to the two cut-off lens sections 35 . It has an off entrance surface portion 38 and two overlapping entrance surface portions 39 corresponding to the two overlapping lens portions 36 . On the central incident surface 37, cutoff incident surface portions 38 and overlapping incident surface portions 39 are alternately arranged in the rotational direction about the optical axis La.

Both cutoff incident surface portions 38 have their rear focal points (rear focal points) set in the vicinity of the light source portion 11 , and cooperate with the central exit surface 41 on the opposite side of the central incident surface 37 in the central lens portion 33 . The shape (curvature, etc.) is set so that the light from the light source unit 11 forms the cutoff region CC. The central emission surface 41 is circular in the middle (inside an outer emission surface 46 described later) of the front side surface (light irradiation side surface) of the lens body 31 in the optical axis direction. is a free-form surface that is appropriately set. Both overlapping incident surface portions 39 have rear focal points set in the vicinity of the light source portion 11 , and cooperate with the central emitting surface 41 to form an overlapping area CA with the light from the light source portion 11 (curvature etc.) are set. Therefore, in the central lens portion 33, basically, the difference between the cutoff entrance surface portion 38 and the overlapping entrance surface portion 39 allows the optical setting difference between the cutoff lens portion 35 and the overlapping lens portion 36 to be different. I have decided.

Both the cut-off incident surface portion 38 and the overlapping incident surface portion 39 have central portions (in the vicinity of the optical axis La) that are convexly curved outward (toward the light source portion 11), and have different positions in the optical axis direction. It is said that In the central incident surface 37 of Example 1, both cutoff incident surface portions 38 are located on the rear side (light source portion 11 side) of the double incident surface portion 39 in the optical axis direction. For this reason, both overlapping lens portions 36 are smaller in dimension in the optical axis direction (thinner than both cut-off lens portions 35). As a result, both overlapping entrance surface portions 39 (both overlapping lens portions 36) have a larger focal length than both cutoff entrance surface portions 38 (both cutoff lens portions 35) and have a larger F value.

The central lens portion 33 allows the light emitted from the LED package 21 of the light source portion 11 to enter from both the cutoff entrance surface portion 38 and the double entrance surface portion 39, exit from the central exit surface 41, and be directed forward in the front-rear direction. By advancing the pattern by pressing (see FIG. 6, FIG. 7, etc.), the center pattern area PC is formed. At this time, the central lens portion 33 advances the light from the LED package 21 forward in the front-rear direction while concentrating it in the vertical direction, and diffuses it in the left-right direction while allowing it to travel forward in the front-rear direction. . At this time, the central lens portion 33 has two cutoff entrance surface portions 38 and two overlap entrance surface portions 39 so that the two cutoff lens portions 35 form the cutoff area CC, and the two overlap lens portions 36 form the overlap area CA. Form.

Specifically, as shown in FIG. 6, the upper cut-off lens portion 35 causes the light from the LED package 21 to travel toward the optical axis La little by little. Light passing through the upper cutoff lens portion 35 forms an upper cutoff region CC1, as shown in FIG. The upper cutoff region CC1 is basically elongated in the horizontal direction below the horizontal line H (the horizontal line passing through the center position O), and the upper left side of the center position O is the horizontal line H. It protrudes upwards beyond. Thereby, the upper cutoff region CC1 forms a cutoff line CL (at least partly).

Further, as shown in FIG. 7, the lower cut-off lens portion 35 causes the light from the LED package 21 to travel away from the optical axis La little by little. Light passing through the lower cutoff lens portion 35 forms a lower cutoff region CC2, as shown in FIG. The lower cutoff region CC2 is basically elongated in the horizontal direction below the horizontal line H, and the upper left side of the center position O extends over the horizontal line H and upwards. Thereby, the lower cutoff region CC2 forms a cutoff line CL (at least partly).

As shown in FIG. 7, the upper overlapping lens portion 36 converts the light from the LED package 21 into light that travels toward the optical axis La little by little. The light has a larger angle (approaching degree) with respect to the optical axis La than the light from the upper cut-off lens portion 35 (see FIG. 7). Light passing through the upper overlapping lens portion 36 forms an upper overlapping area CA1, as shown in FIG. The upper overlapping area CA1 is elongated in the horizontal direction below the horizontal line H and extends to the left of both cutoff areas CC.

As shown in FIG. 6, the overlapping lens portion 36 on the lower side causes the light from the LED package 21 to travel away from the optical axis La little by little. The light has an angle (degree of separation) with respect to the optical axis La that is substantially equal to that of the light from the lower cut-off lens portion 35 (see FIG. 7). Light passing through the lower overlapping lens portion 36 forms a lower overlapping area CA2, as shown in FIG. The lower overlapping area CA2 is elongated in the horizontal direction below the horizontal line H and extends to the right of both cutoff areas CC.

The center lens part 33 overlaps the upper cutoff area CC1, the lower cutoff area CC2, the upper overlapping area CA1, and the lower overlapping area CA2 on the screen by irradiating the light from the LED package 21. It will happen. As a result, the central lens portion 33 overlaps them to form the central pattern region PC, as shown in FIG. The center pattern area PC is basically elongated in the horizontal direction below the horizontal line H, and the upper left side of the center position O extends over the horizontal line H and upwards. Thereby, the central pattern area PC forms a cutoff line CL (at least partly). In addition, the center pattern region PC has the above four regions (both CC and both CA) superimposed so that the vicinity of the elbow of the cutoff line CL is the brightest and the brightness gradually decreases with distance from the elbow. distribution. As a result, in the center pattern area PC, the difference in brightness between the inner side and the outer side of the cutoff line CL is increased.

As shown in FIG. 4 and the like, the outer lens portion 34 is divided into two parts in the upper and lower directions by a plane extending in the horizontal direction while passing through the optical axis La. Two lens portions 43 are provided. The first lens portion 42 forms an intermediate diffusion region OM (see FIG. 16) in the outer pattern region PO (see FIG. 18) of the light distribution pattern LP for passing (see FIG. 19), and the second lens portion 43 forms an outer A large diffusion region OB (see FIG. 17) is formed in the pattern region PO. That is, the outer pattern region PO is configured by overlapping the middle diffusion region OM and the large diffusion region OB. The middle diffusion area OM forms a brightness distribution in the vicinity of the elbow of the cutoff line CL (so-called hot spot) in the outer pattern area PO. The large diffusion region OB is wider than the middle diffusion region OM, that is, irradiates an area larger than the middle diffusion region OM, and forms the outer shape of the outer pattern region PO.

The outer lens portion 34 has, as shown in FIGS. 3 and 13 , an annular incident surface 44 surrounding the central incident surface 37 and a truncated conical reflecting surface 45 surrounding the annular incident surface 44 . The annular incident surface 44 is provided so as to protrude toward the light source unit 11 side, and causes light from the light source unit 11 that does not travel to the central incident surface 37 to enter the lens 12 . The reflecting surface 45 is formed at a position where the light entering the lens 12 from the annular incident surface 44 travels (see FIGS. 13 to 15, etc.). When the reflecting surface 45 reflects the light incident from the annular incident surface 44 , the light becomes parallel light traveling substantially parallel to the optical axis Lc of the condenser lens. The parallel light (parallel light) refers to light collimated by being reflected by the reflecting surface 45 after passing through the annular incident surface 44 . The reflecting surface 45 may reflect light using total reflection, or may reflect light by adhering aluminum, silver, or the like by vapor deposition, painting, or the like. The annular incident surface 44 and the reflecting surface 45 are integrated with the first lens portion 42 and the second lens portion 43 .

The outer lens portion 34 has an annular outer emission surface 46 outside the central emission surface 41 on the front side surface (light irradiation side surface) of the lens body 31 in the optical axis direction. The outer emission surface 46 is vertically divided into two parts by a surface passing through the optical axis La and extending in the left-right direction. ing. The first outer emission surface portion 47 refracts parallel light (mainly parallel light passing above the optical axis La) reflected by the reflecting surface 45 after passing through the annular incidence surface 44, thereby The shape (curvature, etc.) is set so as to diffuse toward the front side in the front-rear direction while forming the intermediate diffusion region OM. The outer second emission surface portion 48 refracts parallel light (mainly parallel light passing below the optical axis La) reflected by the reflecting surface 45 after passing through the annular incidence surface 44, thereby ) while proceeding toward the front side in the front-rear direction to form a large diffusion region OB (curvature, etc.). That is, the shape (curvature, etc.) of the outer second emission surface portion 48 is set so as to spread the parallel light along the optical axis La in the horizontal direction more than the outer first emission surface portion 47 (see FIGS. 14 and 15). ).

In the second outer emission surface portion 48 of the first embodiment, the central portion in the horizontal direction (the portion overlapping with the optical axis La when viewed in the vertical direction) is located rearward in the optical axis direction from the central portion of the first outer emission surface portion 47. Displaced (see FIGS. 1, 6 and 7). In addition, both ends of the second outer emission surface portion 48 of the first embodiment in the left-right direction are displaced further forward in the optical axis direction than both ends of the first outer emission surface portion 47 (FIGS. 1, 14, and 14). 15). As a result, the second outer emission surface portion 48 of the first embodiment has a larger curvature than the first outer emission surface portion 47, and has a large inclination with respect to the left-right direction. Therefore, the second outer emission surface portion 48 of the first embodiment has a shape elongated in the optical axis direction compared to the first outer emission surface portion 47 . As a result, when viewed from the front side in the optical axis direction (see FIG. 4), the second outer emission surface portion 48 of the first embodiment has a substantially circular shape while the first outer emission surface portion 47 has a substantially circular shape. The center portion in the direction is curved downward in the vertical direction. With such a configuration, the second outer emission surface portion 48 of Example 1 can spread the parallel light along the optical axis La in the horizontal direction more than the first outer emission surface portion 47 (FIGS. 14 and 14). 15).

The outer lens portion 34 allows the light emitted from the LED package 21 of the light source portion 11 to be incident from the annular incident surface 44, reflected by the reflecting surface 45, and then emitted from the outer emitting surface 46 toward the front in the front-rear direction. Then, the outer pattern area PO is formed. At this time, the outer lens portion 34 converges the light from the LED package 21 in the vertical direction (see FIG. 13), diffuses it in the horizontal direction, and causes it to travel forward in the front-rear direction (FIGS. 14 and 15). reference). Here, in the outer lens portion 34, the first lens portion 42 forms the medium diffusion region OM and the second lens portion 43 forms the large diffusion region OB by the outer first emission surface portion 47 and the outer second emission surface portion 48. Form.

More specifically, as shown in FIG. 14, the first lens portion 42 spreads the light from the LED package 21 in the left-right direction so that the light travels. Light passing through the first lens portion 42 forms an intermediate diffusion region OM as shown in FIG. The intermediate diffusion region OM is elongated in the horizontal direction below the horizontal line H, and is vertically and horizontally larger than the central pattern region PC (see FIG. 12).

Further, as shown in FIG. 15, the second lens portion 43 spreads the light from the LED package 21 in the left-right direction and makes the light travel. The light has a larger angle (degree of expansion) with respect to the optical axis La than the light from the first lens portion 42 (see FIG. 14). Light passing through the second lens portion 43 forms a large diffusion area OB as shown in FIG. The large diffusion region OB is elongated in the horizontal direction below the horizontal line H, and is horizontally larger than the middle diffusion region OM.

By irradiating the light from the LED package 21, the outer lens portion 34 overlaps the medium diffusion region OM and the large diffusion region OB on the screen. As a result, the outer lens portions 34 are overlapped to form the outer pattern region PO, as shown in FIG. The outer pattern area PO is basically elongated in the horizontal direction below the horizontal line H, and is vertically and horizontally larger than the central pattern area PC.

The lens 12 configured in this way overlaps the central pattern area PC and the outer pattern area PO on the screen by irradiating light from the LED package 21 . As a result, the lens 12 overlaps them to form a light distribution pattern LP for passing, as shown in FIG. This light distribution pattern LP for passing each other is basically elongated in the horizontal direction below the horizontal line H, and the upper left side of the center position O at the upper edge is cut to extend upward beyond the horizontal line H. Has offline CL. The light distribution pattern LP for passing each other has a brightness distribution in which the vicinity of the elbow of the cutoff line CL is the brightest and the brightness gradually decreases as the distance from the elbow is increased by overlapping the two cutoff areas CC. It is Thereby, the light distribution pattern LP for passing each other has a large difference in brightness between the inner side and the outer side of the cutoff line CL, and can irradiate a wide range below the horizontal line H in the horizontal direction.

In the vehicle lamp 10 , the LED package 21 (the light emitting surface 23 thereof) is appropriately lit by supplying power from the lighting control circuit to the LED package 21 of the light source section 11 . By this lighting, the vehicle lamp 10 causes the light from the LED package 21 to enter the lens body 31 from the central incident surface 37 and the annular incident surface 44 of the lens body 31 of the lens 12 , and part of the light is reflected by the reflecting surface 45 . The light is emitted from the central emission surface 41 and the outer emission surface 46 while being reflected. Then, the vehicle lamp 10 illuminates the front of the vehicle as the light distribution pattern LP for passing.

At this time, in the lens 12 of the vehicle lamp 10, the central pattern area PC formed by the central lens portion 33 and the outer pattern area PO formed by the outer lens portion 34 form the light distribution pattern LP for passing. . In the central lens portion 33 of the vehicle lamp 10, the cutoff region CC formed by the cutoff lens portion 35 and the overlapping region CA formed by the overlapping lens portion 36 form a central pattern region PC. there is Thus, the vehicle lamp 10 divides the lens 12 into the central lens portion 33 and the outer lens portion 34, and divides the central lens portion 33 into the cut-off lens portion 35 and the overlapping lens portion 36. Different regions (light distributions) are formed as individual optical settings. For this reason, the vehicular lamp 10 has a simpler shape of the lens 12 and an appropriate light distribution pattern for passing, as compared with the conventional arrangement in which a large number of beam shaping surfaces (prisms) are provided on the surface of the lens. LP can be formed.

In particular, in the vehicle lamp 10 , the cutoff region 38 and the overlapped incidence surface 39 of the cutoff lens portion 35 and the overlapped lens portion 36 are different from each other in the optical axis direction. It is assumed that CC and overlapping area CA are formed. Therefore, the vehicular lamp 10 can make the shape of the cutoff line CL and the brightness difference between the inner side and the outer side thereof appropriate while simplifying the shape of the lens 12 . This is due to the following.

As shown by the two-dot chain lines in FIGS. 6 and 7, it is conceivable that both overlapping lens portions 36 have respective overlapping incident surface portions 39 as virtual incident surface portions 39'. Each of the virtual incident surface portions 39' is provided at the same position as the cutoff incident surface portions 38 of both cutoff lens portions 35 in the optical axis direction, and each has a shape (curvature, etc.) so as to form the overlapping area CA. set. Light passing through the upper virtual incident surface portion 39' forms an upper virtual area CV1 as shown in FIG. In the upper virtual area CV1, the upper right side of the center position O projects upward beyond the horizontal line H, which hinders formation of an appropriate cutoff line CL. Similarly, the light passing through the lower virtual incident surface portion 39' forms a lower virtual area CV2 as shown in FIG. The upper right side of the center position O of the lower virtual area CV2 protrudes upward beyond the horizontal line H, which hinders formation of an appropriate cutoff line CL. In this way, each virtual incident surface portion 39' has a limit only by setting the shape (curvature, etc.), and it becomes difficult to form an appropriate light distribution pattern LP for passing.

On the other hand, in the vehicle lamp 10 of the first embodiment, the shape (curvature, etc.) is obtained while displacing the overlapping incident surface portion 39 in the optical axis direction with respect to the cutoff incident surface portion 38 to the opposite side of the light source portion 11 . ) is set so that the focal length and F-number of both overlap entrance surface portions 39 are larger than those of both cutoff entrance surface portions 38 . For this reason, the vehicular lamp 10 makes the image of the LED package 21 (its light emitting surface 23) formed by both overlapping incident surface portions 39 (hereinafter referred to as a light source image) smaller than the light source image formed by both cutoff incident surface portions 38. can be made smaller. As a result, the vehicle lamp 10 can obscure portions that protrude upward, such as the upper right side of both virtual regions CV, in the overlapping region CA. In particular, the vehicle lamp 10 makes the angle of light emitted from the upper overlapping lens portion 36 with respect to the optical axis La lower than the angle of light emitted from the upper cutoff lens portion 35 with respect to the optical axis La. That is, the vehicle lamp 10 makes the degree of downward deflection of light in the overlapping lens portion 36 greater than the degree of downward deflection of light in the cutoff lens portion 35 . Therefore, the vehicular lamp 10 can direct the light passing through the overlapping lens portion 36 below the horizontal line H, and can position the overlapping area CA below the horizontal line H over the entire area. . In other words, in order to form the overlapping area CA below the horizontal line H, the vehicular lamp 10 is arranged in accordance with the position and shape of the LED package 21 (light emitting surface 23) provided with the cut-off side portion 24. The positions and shapes of both cutoff incident surface portions 38 are set. As a result, the vehicular lamp 10 can easily prevent the light passing through the overlapping lens portion 36 from going upward beyond the horizontal line H. cutoff regions (CC1 and CC2 (see FIGS. 10 and 11)) can be formed. Therefore, the vehicle lamp 10 can form an appropriate light distribution pattern LP for passing while simplifying the shape of the lens 12 .

The vehicle lamp 10 of Example 1 can obtain the following effects.

The vehicle lamp 10 projects light emitted from a light source unit 11 having a light emitting surface 23 provided with a cutoff line portion 24 through a lens 12. The lens 12 includes a central lens portion 33 and an outside thereof. and an outer lens portion 34 that internally reflects light from the light source portion 11 and then emits the light. In the vehicular lamp 10, the central lens portion 33 forms a central pattern area PC including the cutoff line CL in the light distribution pattern LP for passing, and the outer lens portion 34 overlaps the central pattern area PC for passing. An outer pattern area PO forming the light distribution pattern LP is formed. Therefore, the vehicular lamp 10 can appropriately form the light distribution pattern LP for passing without providing a large number of beam shaping surfaces (prisms) on the surface of the lens as in the conventional art.

In the vehicle lamp 10, the center lens portion 33 overlaps the cutoff lens portion 35 forming the cutoff region CC near the cutoff line CL in the center pattern region PC, and the center pattern region is formed by overlapping the cutoff region CC. and an overlapping lens portion 36 forming an overlapping area CA that constitutes the PC. Therefore, the vehicular lamp 10 can form the passing light distribution pattern LP more appropriately without providing a large number of beam shaping surfaces (prisms) on the surface of the lens as in the conventional art.

In the central lens portion 33 of the vehicle lamp 10, a central incident surface 37 is divided into four portions centering on the optical axis La. , and the remaining two are defined as overlapping incident surface portions 39 corresponding to the overlapping lens portions 36 . Therefore, in the vehicle lamp 10, the shape (curvature, etc.) can be individually set for each of the two cutoff incident surface portions 38 and the two overlapping incident surface portions 39, so that a complicated shape can be easily formed. Therefore, the cutoff area CC and the overlapping area CA can be properly formed.

In the vehicle lamp 10, the central incident surface 37 has cutoff incident surface portions 38 and overlapping incident surface portions 39 alternately arranged in the rotational direction about the optical axis La. Therefore, in the vehicle lamp 10, the two cut-off incident surface portions 38 can be arranged point-symmetrically, and the two overlapping incident surface portions 39 can be arranged point-symmetrically. can be made easier to form a desired area (light distribution). In particular, in the vehicle lamp 10, the boundaries between the two cutoff incident surface portions 38 and the two overlapping incident surface portions 39 are along the vertical and horizontal directions. Therefore, in the vehicle lamp 10, the shape (curvature, etc.) can be set separately for the upper side and the lower side of the horizontal line passing through the optical axis La. A desired area (light distribution) can be formed easily. This is because the vehicle lamp 10 basically forms a region (light distribution) below the optical axis La.

In the vehicular lamp 10 , the center lens portion 33 has a larger focal length in the overlapping lens portion 36 than in the cutoff lens portion 35 . Therefore, in the vehicle lamp 10 , the cutoff lens portion 35 forms the cutoff area CC having the cutoff line CL, and the overlapping lens portion 36 forms the overlapping area CA below the horizontal line H. As a result, the vehicle lamp 10 can form the central pattern area PC in which the shape of the cutoff line CL and the brightness difference between the inner side and the outer side thereof are appropriate while the shape of the central lens portion 33 is simplified.

In the vehicular lamp 10, the central lens portion 33 has a cutoff incident surface portion 38 and an overlapping incident surface portion 39 at different positions in the optical axis direction. Therefore, the vehicular lamp 10 can have a large focal length of the overlapping lens portion 36 with respect to the cut-off lens portion 35 with a simple configuration, and the center pattern region PC can be properly formed while simplifying the shape of the center lens portion 33. can.

The vehicle lamp 10 divides the outer lens portion 34 into a first lens portion 42 and a second lens portion 43, the first lens portion 42 forming a medium diffusion area OM, and the second lens portion 43 forming a large diffusion area. form an OB. Therefore, the vehicular lamp 10 can appropriately form the outer pattern area PO without providing a large number of beam shaping surfaces (prisms) on the surface of the lens as in the conventional art, and it can be superimposed on the central pattern area PC to pass each other. can form a light distribution pattern LP for In particular, the vehicular lamp 10 has a shape in which the outer second emission surface portion 48 of the second lens portion 43 is elongated in the optical axis direction compared to the outer first emission surface portion 47 of the first lens portion 42. With this configuration, the second lens portion 43 can form a large diffusion area OB that is horizontally larger than the middle diffusion area OM.

The vehicle lamp 10 positions the light emitting surface 23 of the light source (light source portion 11) on the positive side corresponding to the upper side in the vertical direction in the first direction with respect to the center of gravity of the optical axis La. A horizontal side portion 24a is provided along the second direction. Therefore, the vehicle lamp 10 can appropriately form the light distribution pattern LP for passing. This is because the vehicular lamp 10 forms each region (light distribution) on the screen by reversing the vertical positional relationship of the light emitting surface 23 with respect to the optical axis La. It is because it becomes easy to form (light distribution). Here, the outer lens portion 34 has a middle diffusion region OM and a large diffusion region (light distribution) formed by a vertical positional relationship with respect to the optical axis La of the light emitting surface 23 compared to the central lens portion 33 . It greatly affects the vertical positional relationship with respect to the center position O of the area OB. Therefore, the vehicular lamp 10 can easily form the middle diffusion region OM and the large diffusion region OB below the horizontal line H, and can appropriately form the outer pattern region PO of the light distribution pattern LP for passing. can be done.

Therefore, the vehicle lamp 10 of Example 1 as the vehicle lamp according to the present disclosure can form an appropriate passing light distribution pattern LP while simplifying the shape of the lens 12 .

Although the vehicle lamp of the present disclosure has been described above based on the first embodiment, the specific configuration is not limited to the first embodiment, and is outside the gist of the invention according to each claim. Design changes, additions, etc. are permitted unless

For example, in Example 1, the central lens portion 33 has two cutoff lens portions 35 and two overlapping lens portions 36 . However, if the central lens portion 33 has a cutoff lens portion 35 that forms the cutoff region CC and an overlapping lens portion 36 that forms the overlapping region CA, the shape, arrangement relationship, and number can be appropriately set. It is not limited to the configuration of the first embodiment.

Further, in Example 1, in the outer lens portion 34, the outer second emission surface portion 48 of the second lens portion 43 is elongated in the optical axis direction compared to the outer first emission surface portion 47 of the first lens portion 42. It has a shape. However, the second lens portion 43 is not limited to the configuration of the first embodiment as long as it forms a large diffusion region OB horizontally larger than the middle diffusion region OM formed by the first lens portion 42 .

REFERENCE SIGNS LIST 10 Vehicle lamp 11 Light source section (as an example of light source) 12 Lens 23 Light-emitting surface 24 Cut-off line side section 24a First horizontal side section (as an example of horizontal side section) 33 Central lens section 34 Outer lens section 35 Cutoff Lens portion 36 Overlapping lens portion 37 Central incident surface 38 Cutoff incident surface portion 39 Overlapping incident surface portion 42 First lens portion 43 Second lens portion CA Overlapping area CC Cutoff area CL Cutoff line La Optical axis Lh Horizontal line LP (Light distribution pattern Light distribution pattern for passing (as an example) OB Large diffusion area OM Middle diffusion area PC Center pattern area PO Outer pattern area

Claims (8)

a light source provided with a light emitting surface;
a lens that projects the light emitted from the light source to form a light distribution pattern;
one side of the light emitting surface is a cutoff line portion corresponding to the cutoff line in the light distribution pattern;
The lens includes a central lens portion provided on an optical axis for emitting the light from the light source, and an outer lens provided outside the central lens portion for reflecting the light from the light source inside and emitting the light. and
The central lens part forms a central pattern area including the cutoff line in the light distribution pattern,
The vehicle lamp, wherein the outer lens portion forms an outer pattern area that forms the light distribution pattern by overlapping with the central pattern area. The central lens portion includes a cutoff lens portion forming a cutoff region in the vicinity of the cutoff line in the central pattern region, and an overlapping region overlapping the cutoff region to form an overlapping region constituting the central pattern region. 2. The vehicle lamp according to claim 1, further comprising a lens portion. In the central lens portion, a central incident surface facing the light source is divided into four around the optical axis, two of which are cutoff incident surface portions corresponding to the cutoff lens portions, 3. The vehicle lamp according to claim 2, wherein the remaining two are overlapping incident surface portions corresponding to the overlapping lens portions. 4. The vehicle lamp according to claim 3, wherein the central incident surface has the cutoff incident surface portions and the overlapping incident surface portions arranged alternately in a rotational direction about the optical axis. 5. The vehicular lamp according to claim 3, wherein the overlapping lens portion of the central lens portion has a larger focal length than the cut-off lens portion. 6. The vehicular lamp according to claim 5, wherein, in the central lens portion, the positions of the cutoff incident surface portion and the overlapped incident surface portion are different in the optical axis direction. the outer lens portion is divided into a first lens portion and a second lens portion in a first direction that intersects the cutoff line side portion in a direction along the light emitting surface;
the first lens portion forms a middle diffusion region that forms part of the outer pattern region;
7. The second lens portion forms a large diffusion area wider than the middle diffusion area while forming the outer pattern area by overlapping with the middle diffusion area. The vehicle lamp according to any one of Claims 1 to 3. The cut-off line has a horizontal line extending horizontally in the light distribution pattern,
the light source has a horizontal side corresponding to the horizontal line in the cutoff line,
In a first direction that intersects the cutoff line in the direction along the light emitting surface, the side corresponding to the upper side in the vertical direction is defined as the positive side,
A direction along the horizontal side portion in the direction along the light emitting surface is defined as a second direction,
The light emitting surface is provided such that the center of gravity is located on the positive side of the first direction with respect to the optical axis, and the horizontal side portion is arranged along the second direction. Item 7. The vehicle lamp according to any one of Item 6.

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