JP7025387B2 - Lighting structure - Google Patents

Description

The present invention relates to a lighting device structure.

Patent Document 1 describes a multi-stage reflector type headlight device in which a reflector of a high beam light and a reflector of a low beam light are arranged one above the other.

International Publication No. 2016/159893

By the way, in Patent Document 1, a structure is adopted in which the space between the upper reflector and the lower reflector is concealed by a part of the light housing, but there is a problem that the housing structure is complicated. There is also a desire to increase the degree of freedom in designing reflectors with the same structure.

The present invention has been made in view of the above circumstances, and provides a lighting device structure that improves the degree of freedom in designing a reflector and improves the appearance with a simple structure.

As a means for solving the above problems, the invention according to claim 1 includes a first light emitting unit (32A) and a second light emitting unit (32B) arranged in the first direction of each other, and the first light emitting unit (32A) is provided. The first light source (37A1), the first reflector (37A) that distributes the light of the first light source (37A1) toward one side in the second direction intersecting the first direction, and the first light source (37A). A first substrate (37A2) on which 37A1) is mounted is provided, and the second light emitting unit (32B) directs the light of the second light source (37B1) and the second light source (37B1) to one side in the second direction. A second reflector (37B) that distributes light toward the surface and a second substrate (37B2) on which the second light source (37B1) is mounted are provided, and the first substrate (37A2) and the second substrate (37B2) are provided. Is arranged so as to face each other in the first direction, and the first reflector (37A) and the second reflector (37B) are the first substrate (37A2) and the second substrate (37B2). The first reflector (37A) is arranged between the first flat plate portion (42) on which the first substrate (37A2) is installed and the light of the first light source (37A1) on one side in the second direction. The second reflector (37B) is a second flat plate portion on which the second substrate (37B2) is installed. The first is provided with (47) and a second reflecting portion (45Z) forming a second reflecting surface (45) that distributes the light of the second light source (37B1) to one side in the second direction. The first reflecting portion (41Z) of the reflector (37A) and the second reflecting portion (45Z) of the second reflector (37B) are arranged adjacent to each other in the first direction, and the first light emitting portion (32A). ) And the second light emitting unit (32B) are used as a low beam light, the first reflector (37A) and the second reflector (37B) are arranged in the vertical direction with each other, and the first reflecting unit (41Z) is The first reflecting surface (41) is inclined upward, and the second reflecting portion (45Z) is characterized in that the second reflecting surface (45) is inclined downward .
According to this configuration, it is not necessary to dispose either or both of the first substrate and the second substrate between the first reflector and the second reflector. Therefore, it is not necessary to secure the space required for arranging the substrate between the first reflector and the second reflector. As a result, both reflectors can form an integral reflective surface, and the degree of freedom in designing the entire reflector can be increased.
Further, the reflecting portions of both reflectors are arranged so as to be adjacent to each other, and the flat plate portion and the substrate are retracted from between the adjacent reflecting portions. As a result, both reflectors can form an integral reflective surface, and the degree of freedom in designing the entire reflector can be increased.
Further, both light sources of the low beam light, which is often used for constant lighting, are arranged so as to be separated from each other with both reflectors interposed therebetween. As a result, the light sources that generate heat can be distributed and arranged in the lamp, and the thermal influence between the light sources can be reduced. In addition, the arrangement dimension of the low beam light can be increased to improve visibility.

According to the second aspect of the present invention, at least one of the adjacent portions of the first reflector (37A) and the second reflector (37B) has an overlapping portion overlapping the other when viewed from one side in the second direction. It is characterized by having 37A4).
According to this configuration, it is possible to hide the gap between the adjacent portions of both reflectors without providing a separate shielding member or the like. As a result, it is possible to suppress an increase in the number of parts and improve the appearance, and to reduce the arrangement interval between the two reflectors to reduce the size of the lamp.

In the invention described in claim 3 , the first reflector (37A) located on the upper side has a wider left-right width than the second reflector (37B) located on the lower side, and the second reflector (37B) is It is characterized in that it has a shape in which the left-right width is widened toward the upper side toward the first reflector (37A).
According to this configuration, the width of the second reflector is widened as it is closer to the wider first reflector, so that the continuity of both reflectors is enhanced. As a result, when both light emitting portions are turned on, a sense of unity in the light emitting region can be obtained, and visibility and light distribution can be improved by the large light emitting area.

According to the fourth aspect of the present invention, the lower end portion of the first reflector (37A) is located on one side in the second direction with respect to the upper end portion of the second reflector (37B), and the lower end portion thereof is located on one side in the second direction. It is characterized in that it overlaps with the upper end portion of the second reflector (37B).
According to this configuration, it is possible to hide the gap between the adjacent portions of both reflectors without providing a separate shielding member or the like. As a result, it is possible to suppress an increase in the number of parts and improve the appearance. Further, since the lower end portion of the first reflector on the upper side overlaps the upper end portion of the second reflector on the lower side from one side in the second direction (visible side), the adjacent portion of both reflectors is more difficult to see and looks even better. Can be improved.

According to the present invention, it is possible to provide a lighting device structure that improves the design freedom of the reflector and improves the appearance with a simple structure.

It is a front view which shows the vehicle body front part of the saddle-riding type vehicle provided with the headlight device in embodiment of this invention. It is a right side perspective view of the front part of the vehicle body of the saddle-riding type vehicle. It is a front view of the headlight device of the saddle-riding type vehicle. It is a front view of the state where the mask member of the headlight device is removed. It is a left side perspective view of FIG. FIG. 4 is a sectional view taken along line VI-VI of FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The orientations of the front, rear, left, right, etc. in the following description shall be the same as the orientations in the vehicle described below unless otherwise specified. Further, in the appropriate place in the figure used in the following description, an arrow FR indicating the front of the vehicle, an arrow LH indicating the left side of the vehicle, an arrow UP indicating the upper part of the vehicle, and a line CL indicating the center of the left and right sides of the vehicle body are shown.

FIG. 1 shows a front view (front view) of the front part of the vehicle body of a saddle-riding vehicle (for example, a motorcycle) 1 provided with the headlight device 30 of the embodiment, and FIG. 2 shows a right perspective view of the front part of the vehicle body.
The front portion of the vehicle body of the saddle-riding vehicle 1 is covered with a vehicle body cover (for example, a front cowl) 2. At the center of the front end of the vehicle body cover 2, a headlight device 30 having two upper and lower lamps is arranged. The headlight device 30 is supported inside the vehicle body cover 2. The headlight device 30 has lens surfaces 31 and 34 that are vertically divided and exposed on the outer surface of the vehicle body cover 2. The front surface portion 3 of the vehicle body cover 2 is formed with openings 3a and 3b that expose the lens surfaces 31 and 34. The headlight device 30 is symmetrical with the left-right center line CL of the vehicle body as the axis of symmetry.

The front surface portion 3 of the vehicle body cover 2 has a slanted nose shape in which the front end 3c of the cover projects forward so that the upper portion is located rearward in a side view. The front end portion 3 has a shape (V-shaped) that is inclined so that the outer portion in the left-right direction is located rearward even in the top view (planar view) because the front end 3c of the cover projects forward (not shown). .. The left and right sides of the upper lens surface 31 (hereinafter referred to as the upper lens surface 31) are inclined along the front surface portion 3. The lower lens surface 34 (hereinafter referred to as the lower lens surface 34) is arranged below the cover front end 3c at the same front-rear direction position as the cover front end 3c.

The upper lens surface 31 has a horizontally long shape having a wide left-right width with respect to the vertical width, and has a shape of being suspended so that the outer side portion in the left-right direction is located upward in the front view. The upper lens surface 31 is inclined backward so that the upper portion (outer portion in the left-right direction) is located rearward from the vehicle body center line CL when viewed from the side.

The lower lens surface 34 has a horizontally long shape having a wider left-right width with respect to the vertical width, and the width in the left-right direction is smaller than the upper lens surface 31. The lower lens surface 34 is inclined downward with respect to the vertical surface below the front end 3c of the cover protruding forward, and is located in front of the upper lens surface 31. A portion of the front surface portion 3 including the front end 3c of the cover crosses between the upper lens surface 31 and the lower lens surface 34.

As shown in FIG. 3, the headlight device 30 includes a housing 35 that opens toward the front of the vehicle and a lens cover 33 that opens toward the rear of the vehicle. The headlight device 30 abuts the front end opening of the housing 35 and the rear end opening of the lens cover 33, and integrally connects the housing 35 and the lens cover 33. The headlight device 30 forms a substantially sealed lamp chamber. The first light emitting unit 32A, the second light emitting unit 32B, and the third light emitting unit 32C constituting the high beam light and the low beam light are housed in the lamp chamber of the headlight device 30.

The first light emitting unit 32A includes a first light source 37A1 (see FIG. 6) and a first reflector 37A corresponding to the low beam light. The second light emitting unit 32B includes a second light source 37B1 (see FIG. 6) and a second reflector 37B corresponding to the low beam light and the high beam light. The third light emitting unit 32C includes a third light source 37C1 (see FIG. 6) and a third reflector 37C corresponding to the high beam light.

With reference to FIGS. 3 and 4, the first reflector 37A, the second reflector 37B, and the third reflector 37C are arranged side by side in the order of 37A, 37B, and 37C from the upper side to the lower side. The first reflector 37A and the second reflector 37B are arranged side by side in the vertical direction in a range where they overlap with the upper lens surface 31 in the front view. The first reflector 37A is provided so as to overlap the upper half of the upper lens surface 31 in front view. The second reflector 37B is provided so as to overlap the lower half of the upper lens surface 31 in front view. The third reflector 37C is provided so as to overlap the lower lens surface 34 in front view.

Each of the reflectors 37A, 37B, and 37C has a horizontally long shape having a wide left-right width with respect to the vertical width.
The first reflector 37A has a shape having a wider left-right width than the second reflector 37B when viewed from the front. The second reflector 37B has a shape having a wider left-right width than the third reflector 37C when viewed from the front.

The first reflector 37A has a first reflecting portion 41Z forming a first reflecting surface 41 curved in a concave shape when viewed from the front (light distribution direction), and an upper wall extending forward from the upper edge of the first reflecting portion 41Z. A portion (first flat plate portion) 42 is provided. The first reflecting portion 41Z inclines the first reflecting surface 41 upward. The first reflecting surface 41 extends to the lower front end of the first reflector 37A. The lower front end of the first reflector 37A is located in front of the upper front end (front end of the upper wall portion 42) of the first reflector 37A.

Above the upper wall portion 42, a first substrate 37A2, which is an LED substrate on which an LED, which is a first light source 37A1, is mounted, is arranged. The upper wall portion 42 is formed with an upper opening (notch) 42a that allows the LED (first light source 37A1) to face below the upper wall portion 42 (first reflecting surface 41). The light of the first light source 37A1 is irradiated downward, and then reflected and distributed forward by the first reflecting surface 41.

The first reflector 37A partitions a plurality of (three in the figure) reflection regions 44a, 44b, 44c in the length direction of the horizontally long shape in the front view. Corresponding to each reflection region 44a, 44b, 44c, the first reflection surface 41 is partitioned into a plurality of (three in the figure) divided reflection surfaces 41a, 41b, 41c. Stepped surfaces 41d and 41e generally along the front-rear direction of the vehicle are formed between the adjacent divided reflection surfaces 41a, 41b and 41c.

The first reflection surface 41 is located on the left outer side in the vehicle width direction and further to the left outer side in the vehicle width direction with respect to the divided reflection surface 41a at the center position in the vehicle width direction (left-right direction). The divided reflection surfaces 41b are formed in a continuous step shape. The first reflective surface 41 has a stepped surface 41e located on the right outer side in the vehicle width direction and a divided reflective surface 41c further on the right outer side in the vehicle width direction with respect to the divided reflective surface 41a located at the center in the vehicle width direction. It is formed in a stepped shape with a series of.

A plurality of (three in the figure) upper openings 42a are formed in the upper wall portion 42 corresponding to the respective reflection regions 44a, 44b, 44c. A plurality of (three in the figure) LEDs (first light source 37A1) are mounted on the first substrate 37A2 corresponding to the respective reflection regions 44a, 44b, 44c. The first light source 37A1 and the reflection regions 44a, 44b, 44c are arranged so as to be used as a low beam light.

In the first reflector 37A, the upper wall portion 42 is arranged substantially horizontally. The upper wall portion 42 is formed over a plurality of reflection regions 44a, 44b, 44c so as to form a substantially straight line when viewed from the front.
The lower front end of the first reflector 37A is formed in a substantially V shape in front view. The lower front end of the first reflector 37A is linearly inclined in front view so as to be located upward so as to be located on the left and right outer sides. At the lower front end of the first reflector 37A, the central portion corresponding to the reflection region 44a is located below the left and right outer portions corresponding to the reflection regions 44b and 44c.
The stepped surfaces 41d and 41e are formed over the upper and lower ends of the first reflecting surface 41. The stepped surfaces 41d and 41e are linearly inclined in front view so as to be located on the left and right outer sides as they are located upward.

The second reflector 37B has a second reflecting portion 45Z forming a second reflecting surface 45 curved in a concave shape when viewed from the front, and a lower wall portion (second flat plate) extending forward from the lower edge of the second reflecting portion 45Z. Part) 47 and. The second reflecting portion 45Z inclines the second reflecting surface 45 downward. The second reflecting surface 45 extends to the upper front end of the second reflector 37B. The upper front end of the second reflector 37B is located slightly behind the lower front end (front end of the lower wall portion 47) of the second reflector 37B. The lower front end of the second reflector 37B is located in the same front-rear direction as the lower front end of the first reflector 37A.

Below the lower wall portion 47, a second substrate 37B2, which is an LED substrate on which an LED, which is a second light source 37B1, is mounted, is arranged. The lower wall portion 47 is formed with a lower opening (notch) 47a that allows the LED (second light source 37B1) to face above the lower wall portion 47 (second reflecting surface 45). The light of the second light source 37B1 is irradiated upward, and then reflected and distributed forward by the second reflecting surface 45.

The second reflector 37B partitions a plurality of (three in the figure) reflection regions 48a, 48b, and 48c in the length direction of the horizontally long shape in the front view. Corresponding to each reflection region 48a, 48b, 48c, the second reflection surface 45 is partitioned into a plurality of (three in the figure) divided reflection surfaces 45a, 45b, 45c. Between the adjacent divided reflection surfaces 45a, 45b, 45c, partition walls 45d, 45e that stand up substantially along the vehicle front-rear direction are formed. The reflection regions 48a, 48b, and 48c are separated from each other by the partition walls 45d and 45e.

The second reflective surface 45 includes a partition wall 45d located on the left outer side in the vehicle width direction and a split reflective surface 45b further on the left outer side in the vehicle width direction with respect to the divided reflective surface 45a located at the center in the vehicle width direction. It is formed so as to be continuous. The second reflective surface 45 includes a partition wall 45e located on the right outer side in the vehicle width direction and a split reflective surface 45c further located on the right outer side in the vehicle width direction with respect to the divided reflective surface 45a located at the center in the vehicle width direction. It is formed so as to be continuous.

A plurality of (three in the figure) lower openings 47a are formed in the lower wall portion 47 corresponding to the respective reflection regions 48a, 48b, and 48c. A plurality of (three in the figure) LEDs (second light source 37B1) are mounted on the second substrate 37B2 corresponding to the respective reflection regions 48a, 48b, and 48c. The second light source 37B1 and the reflection region (low beam reflector portion) 48a located at the center in the vehicle width direction are arranged so as to be used as a low beam light. The second light source 37B1 and the reflection regions 48b and 48c located outside in the vehicle width direction are arranged so as to be used as, for example, a high beam light.

In the second reflector 37B, the lower wall portion 47 is arranged in a substantially horizontal direction. The lower wall portion 47 is formed over a plurality of reflection regions 48a, 48b, and 48c so as to form a substantially straight line when viewed from the front.
The upper front end of the second reflector 37B is formed in a substantially V shape, for example, when viewed from the front. The upper front end of the second reflector 37B is formed, for example, along the lower front end of the first reflector 37A.
The partition walls 45d and 45e are formed over the upper and lower ends of the second reflecting surface 45. The partition walls 45d and 45e are linearly inclined in front view so as to be located on the left and right outer sides as they are located upward.

The third reflector 37C has a third reflecting portion 49Z forming a third reflecting surface 49 curved in a concave shape when viewed from the front, and an upper wall portion 51 extending forward from the upper edge of the third reflecting portion 49Z. I have. The third reflecting portion 49Z inclines the third reflecting surface 49 upward. The third reflecting surface 49 extends to the lower front end of the third reflector 37C. The lower front end of the third reflector 37C is located in front of the upper front end (front end of the upper wall portion 52) of the third reflector 37A. The lower front end of the third reflector 37C is located slightly behind the lower front end of the first reflector 37A and the lower front end of the second reflector 37B.

Above the upper wall portion 51, a third substrate 37C2, which is an LED substrate on which an LED, which is a third light source 37C1, is mounted, is arranged. The upper wall portion 51 is formed with an upper opening (notch) 49a that allows the LED (third light source 37C1) to face below the upper wall portion 51 (third reflecting surface 49). The light of the third light source 37C1 is irradiated downward, and then reflected and distributed forward by the third reflecting surface 49.

The third reflector 37C partitions a plurality of (two in the figure) reflection regions 53a and 53b in the length direction of the horizontally long shape in the front view. Corresponding to the respective reflection regions 53a and 53b, the third reflection surface 49 is divided into a plurality of (two in the figure) divided reflection surfaces 49a and 49b. A ridge line 49f extending in the vertical direction is formed between the adjacent divided reflection surfaces 49a and 49b in the front view.

The third reflecting surface 49 is symmetrical, and the left and right divided reflecting surfaces 49a and 49b are both formed at the same positions in the front-rear direction.
A plurality of (two in the figure) upper openings 51a are formed in the upper wall portion 51 corresponding to the respective reflection regions 53a and 53b. A plurality of (two in the figure) LEDs (third light source 37C1) are mounted on the third substrate 37C2 corresponding to the respective reflection regions 53a and 53b. The third light source 37C1 and the reflection regions 53a and 53b are arranged so as to be used as high beam lights.

In the third reflector 37C, the upper wall portion 51 is arranged in a substantially horizontal direction. The upper wall portion 51 is formed over a plurality of reflection regions 53a and 53b so as to form a substantially straight line when viewed from the front. The lower end of the third reflecting surface 49 is located in front of the front end of the upper wall portion 51.

With reference to FIG. 6, the first reflector 37A includes an upright wall 37A3 that stands up from the front edge of the upper wall portion 42. The upright wall 37A3 hides the first substrate 37A2 arranged above the upper wall portion 42 from the front so that the first substrate 37A2 cannot be seen from the front of the vehicle.
The first reflector 37A includes a hanging wall (overlapping portion) 37A4 that hangs downward from the lower front end edge. The hanging wall 37A4 hides the upper front end of the second reflector 37B from the front so that it cannot be seen from the front of the vehicle.

The second reflector 37B includes a hanging wall 37B4 that hangs downward from the front end edge of the lower wall portion 47. The hanging wall 37B4 hides the second substrate 37B2 arranged below the lower wall portion 47 from the front so that the second substrate 37B2 cannot be seen from the front of the vehicle.
The third reflector 37C includes an upright wall 37C3 that stands up from the front end edge of the upper wall portion 51. The upright wall 37C3 hides the third substrate 37C2 arranged above the upper wall portion 51 from the front so that the third substrate 37C2 cannot be seen from the front of the vehicle.

With reference to FIG. 3, a mask member 61 having an opening 61a having a shape overlapping the first reflector 37A and the second reflector 37B when viewed from the front is provided in the lamp chamber.
The opening 61a has a substantially T-shaped contour in front view, and has a contour shape corresponding to the reflection regions 44a, 44b, 44c of the first reflector 37A and the reflection region (low beam reflector portion) 48a of the second reflector 37B. The mask member 61 makes the reflection region 48a of the first reflector 37A and the second reflector 37B visible on the upper lens surface 31. Even when the headlight device 30 is viewed from the front by the mask member 61, the lamp chamber is not visible from the opening 3a except for the reflection areas 44a, 44b, 44c of the first reflector 37A and the reflection area 48a of the second reflector 37B.

For example, on the left and right outer sides of the opening 61a in the mask member 61, a transmissive portion 63 that is translucent and transmits light in the reflection regions 48b and 48c of the second reflector 37B is provided. The transmission portion 63 is formed in an inclined shape so that the outer side in the vehicle width direction is located upward corresponding to the reflection regions 48b and 48c of the second reflector 37B. For example, the transmission unit 63 is not limited to the one used as a high beam light, but may be used as a daytime running light that is always lit.

The lower end of the mask member 61 is located above the upper end of the third reflector 37C. The lower end of the mask member 61 is covered with a portion of the front surface portion 3 including the front end 3c of the cover. The mask member 61 terminates above the third reflector 37C in front view and does not overlap with the third reflector 37C.

With reference to FIGS. 4 to 6, a reflector support member 65 for supporting the reflectors 37A, 37B, and 37C is provided in the lamp chamber. The reflector support member 65 is supported by the housing 35. The reflector support member 65 supports the reflectors 37A, 37B, and 37C on the front surface side. The reflector support member 65 includes the reflectors 37A, 37B, and 37C to form a reflector assembly 66.

With reference to FIG. 6, a drive driver (driver board) 75 is attached to the housing 35. The drive driver 75 drives the first light emitting unit 32A, the second light emitting unit 32B, and the third light emitting unit 32C by boosting or lowering the supply power. The drive driver 75 is located on the rear side of the reflector support member 65 and on the rear side of the second light source 37B1 in the front-rear direction. As a result, the distance from the drive driver 75 to each of the light sources 37A1, 37B1, 37C1 can be equalized.

As described above, in the lighting device structure of the present embodiment, the first reflector 37A and the second reflector 37B arranged in the vertical direction are arranged between the first substrate 37A2 and the second substrate 37B2.
According to this configuration, it is not necessary to dispose either or both of the first substrate 37A2 and the second substrate 37B2 between the first reflector 37A and the second reflector 37B. Therefore, it is not necessary to secure the space required for arranging the substrates 37A2 and 37B2 between the first reflector 37A and the second reflector 37B. As a result, both reflectors 37A and 37B can form an integral reflective surface, and the degree of freedom in designing the entire reflector in the headlight device 30 can be increased.

Further, in the present embodiment, the first reflecting portion 41Z (first reflecting surface 41) of the first reflector 37A and the second reflecting portion 45Z (second reflecting surface 45) of the second reflector 37B are arranged with both light emitting portions. They are arranged adjacent to each other in the direction (vertical direction).
According to this configuration, the reflecting portions 41A and 45Z of both reflectors 37A and 37B are arranged so as to be adjacent to each other, and a flat plate portion (upper wall portion 42 and lower wall portion 47) is provided between the adjacent reflecting portions 41A and 45Z. In addition, the substrates 37A2 and 37B2 are retracted. This makes it possible to form an integral reflective surface with both reflectors 37A and 37B, and it is possible to increase the degree of freedom in designing the entire reflector in the headlight device 30.

Further, in the present embodiment, since the first light emitting unit 32A and the second light emitting unit 32B are used as the low beam light, both the light sources 37A1 and 37B1 of the low beam light, which are often used for constant lighting, are the first reflector 37A and the first reflector 37A. The two reflectors 37B are arranged so as to be separated from each other in the vertical direction with the reflector 37B interposed therebetween. As a result, the light sources that generate heat can be distributed and arranged in the headlight device 30, and the thermal influence between the light sources 37A1 and 37B1 in the lighting chamber of the headlight device 30 can be reduced.

Further, in the present embodiment, since the low beam light, which is often used for constant lighting, is arranged across the adjacent first light emitting unit 32A and the second light emitting unit 32B, the arrangement dimension of the low beam light in the vertical direction is increased. However, visibility can be improved.
Further, in the present embodiment, since the entire first light emitting unit 32A and the reflection region (low beam reflector unit) 48a in the left and right center portions of the second light emitting unit 32B are used as the low beam light, they are visually recognized due to the irregularly shaped light emitting area. It is possible to improve the property and light distribution.

Further, in the present embodiment, at the lower front end of the first reflector 37A, a hanging wall (overlapping portion) 37A4 which is arranged in front of the upper front end of the second reflector 37B and overlaps with the upper front end of the second reflector 37B in front view is provided. I have.
According to this configuration, since the hanging wall (overlapping portion) 37A4 hides the upper front end of the second reflector 37B from the front, the boundary between the lower front end of the first reflector 37A and the upper front end of the second reflector 37B is separately set. It is not necessary to provide a shielding member or the like to hide it. As a result, it is possible to suppress an increase in the number of parts and improve the appearance, and reduce the arrangement interval between the reflectors 37A and 37B to reduce the size of the headlight device 30.

Further, in the present embodiment, the first reflector 37A located on the upper side has a wider left-right width than the reflection region 48a in the left-right center portion of the second reflector 37B located on the lower side, and the reflection region 48a of the second reflector 37B. Has a shape in which the left-right width is widened toward the upper side toward the first reflector 37A.
According to this configuration, the reflection region 48a in the left and right central portions of the second light emitting unit 32B is widened so as to be closer to the first light emitting unit 32A, so that the continuity of both light emitting units 32A and 32B is enhanced. When both light emitting units 32A and 32B are used as low beam lights, the low beam lights, which are often used for constant lighting, emit light in a substantially T shape. As a result, the continuity between the first light emitting unit 32A and the second light emitting unit 32B is improved, the sense of unity between them is increased, and the visibility and light distribution can be improved.

Further, in the present embodiment, a hanging wall 37A4 is formed at the lower front end of the first reflector 37A, and the hanging wall 37A4 is located in front of the upper front end of the second reflector 37B, and the second reflector 37B is viewed from the front. It overlaps the upper front end.
According to this configuration, it is not necessary to provide a separate shielding member or the like to hide the boundary between the first reflector 37A and the second reflector 37B. As a result, it is possible to suppress an increase in the number of parts and improve the appearance.

It should be noted that the present invention is not limited to the above embodiment, and for example, in the embodiment, an example applied to the headlight device has been described, but the present invention is not limited to this. For example, in addition to headlights, it may be applied to lighting equipment including fog lamps, winkers and the like. Further, the present invention is not limited to a lamp facing the front of the vehicle, and may be applied to a lamp such as a tail light or a brake lamp facing the rear of the vehicle. The arrangement direction of the reflectors is not limited to the vertical direction but may be the horizontal direction.
The saddle-riding vehicle includes all vehicles in which the driver straddles the vehicle body, and includes not only motorcycles (including motorized bicycles and scooter-type vehicles) but also three-wheeled vehicles (one front wheel and two rear wheels). , Front two-wheeled and rear one-wheeled vehicles) or four-wheeled vehicles are also included. It also includes vehicles that include electric motors in their prime movers.
The configuration in the above embodiment is an example of the present invention, and various changes can be made without departing from the gist of the present invention, such as replacing the constituent elements of the embodiment with well-known constituent elements.

1 Saddle-mounted vehicle 30 Headlight device 32A First light emitting unit 32B Second light emitting unit 37A First reflector 37B Second reflector 37A First reflector 37A1 First light source 37A2 First substrate 37A4 Hanging wall (overlapping part)
37B Second reflector 37B1 Second light source 37B2 Second substrate 41 First reflecting surface 41Z First reflecting portion 42 Upper wall portion (first flat plate portion)
45 Second reflective surface 45Z Second reflective portion 47 Lower wall portion (second flat plate portion)
48a Reflection area

Claims (4)

It is provided with a first light emitting unit (32A) and a second light emitting unit (32B) arranged in the first direction of each other.
The first light emitting unit (32A) distributes the light of the first light source (37A1) and the light of the first light source (37A1) toward one side in the second direction intersecting the first direction (the first reflector (37A1). 37A) and a first substrate (37A2) on which the first light source (37A1) is mounted.
The second light emitting unit (32B) includes a second light source (37B1), a second reflector (37B) that distributes the light of the second light source (37B1) toward one side in the second direction, and the first light source. A second board (37B2) on which the two light sources (37B1) are mounted is provided.
The first substrate (37A2) and the second substrate (37B2) are arranged so as to face each other in the first direction.
The first reflector (37A) and the second reflector (37B) are arranged between the first substrate (37A2) and the second substrate (37B2).
The first reflector (37A) distributes the light of the first flat plate portion (42) on which the first substrate (37A2) is installed and the light of the first light source (37A1) to one side in the second direction. A first reflecting portion (41Z) forming a reflecting surface (41) is provided.
The second reflector (37B) distributes the light of the second flat plate portion (47) on which the second substrate (37B2) is installed and the light of the second light source (37B1) to one side in the second direction. A second reflecting portion (45Z) forming the second reflecting surface (45) is provided.
The first reflecting portion (41Z) of the first reflector (37A) and the second reflecting portion (45Z) of the second reflector (37B) are arranged adjacent to each other in the first direction.
The first light emitting unit (32A) and the second light emitting unit (32B) are used as low beam lights.
The first reflector (37A) and the second reflector (37B) are arranged vertically with respect to each other.
The first reflecting portion (41Z) tilts the first reflecting surface (41) upward, and the first reflecting portion (41Z) is inclined upward.
The second reflecting portion (45Z) is a lighting device structure characterized in that the second reflecting surface (45) is inclined downward . At least one of the adjacent portions of the first reflector (37A) and the second reflector (37B) is provided with an overlapping portion (37A4) that overlaps the other when viewed from one side in the second direction. The lighting structure according to claim 1 . The first reflector (37A) located on the upper side has a wider left-right width than the second reflector (37B) located on the lower side.
The lighting structure according to claim 1 or 2 , wherein the second reflector (37B) has a shape in which the left-right width is widened toward the first reflector (37A). The lower end of the first reflector (37A) is located on one side in the second direction with respect to the upper end of the second reflector (37B), and the second reflector (37B) is viewed from one side in the second direction. The lamp structure according to any one of claims 1 to 3 , wherein the lamp structure overlaps the upper end portion of the above.

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