Patent Publication Number: US-9851063-B2

Title: Vehicle lamp

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is based on and claims priority from Japanese Patent Application No. 2014-135840, filed on Jul. 1, 2014, with the Japan Patent Office, the disclosure of which is incorporated herein in its entirety by reference. 
     TECHNICAL FIELD 
     The present disclosure relates to a projector type vehicle lamp. 
     BACKGROUND 
     Conventionally, there is known a projector type vehicle lamp that is configured to irradiate light from a light source located behind a projection lens forward through the projection lens. 
     Japanese Patent Laid-Open Publication No. 29830 discloses a configuration of a vehicle lamp, in which a peripheral edge of a projection lens is formed with an upright wall surface having a greater longitudinal inclination angle than the front surface of the projection lens. 
     SUMMARY 
     In a case where the upright wall surface is formed on the peripheral edge of the projection lens as in the vehicle lamp described in Japanese Patent Laid-Open Publication No. 2014-29830, the light internally reflected from the upright wall surface of the projection lens may be irradiated forward depending on the configuration of the lamp. This light, however, is uncontrolled stray light, thus causing light distribution unevenness. 
     The present disclosure has been made in consideration of such a situation and has an object to provide a projector type vehicle lamp capable of preventing generation of light distribution unevenness even in a case where an upright wall surface is formed on a peripheral edge of a projection lens. 
     The present disclosure is to achieve the object described above by providing a configuration including a light control member. 
     A vehicle lamp according to the present disclosure includes a projection lens, and a light source located behind the projection lens so that light emitted from the light source is irradiated forward through the projection lens. The projection lens includes a sidewall surface which is smoothly curved to be a substantially flat surface having a longitudinally elongated shape when viewed from a front side thereof. Moreover, the sidewall surface has a greater inclination angle with reference to a plane perpendicular to an optical axis of the projection lens than a front surface of the projection lens when viewed in a horizontal cross section. A light control member is provided on both left and right side portions of an inner circumferential surface of a lens holder supporting the projection lens to protrude closer to each other toward the optical axis behind the projection lens when viewed in a horizontal cross section such that the light reflected in a direction away from the optical axis by a reflector is shielded by the light control member, thereby suppressing light incident toward the projection lens from the light source, from being internally reflected by the sidewall surface toward the optical axis of the projection lens via total reflection. 
     The vehicle lamp according to the present disclosure may be configured such that the light emitted from the light source is incident on a projection lens as incident light. Alternatively, the vehicle lamp may be configured such that the light emitted from the light source is reflected by a reflector to be incident on the projection lens. 
     The kind of the “light source” is not specifically limited and, for example, a light emitting device such as, for example, a light emitting diode or a laser diode, or a light source bulb may be employed. 
     The “upright wall surface” is not particularly limited in terms of a detailed shape thereof so long as it has a greater longitudinal inclination angle than the front surface of the projection lens. In addition, the “upright wall surface” may be formed over the peripheral edge of the projection lens or on a portion of the peripheral edge of the projection lens. 
     The “light control member” is not particularly limited in terms of a detailed configuration and arrangement thereof so long as it is configured to prevent light incident on the projection lens from the light source from being internally reflected by the upright wall surface. 
     As illustrated in the above-described configuration, the vehicle lamp according to the present exemplary embodiment is configured as a projector type lamp unit, the projection lens of the vehicle lamp includes the upright wall surfaces formed on the peripheral edge and having a greater longitudinal inclination angle than the front surface of the projection lens. However, since a light control member is arranged behind the projection lens to prevent the light incident on the projection lens from the light source from being internally reflected by the upright surface, the following acting effects may be achieved. 
     That is, due to the existence of the light control member, the light incident on the projection lens is not internally reflected by the upright wall surfaces. Thus, it is possible to forestall the problem that the light internally reflected by the upright wall surfaces of the projection lens is irradiated as stray light, as is conventionally encountered. In this way, it is possible to forestall the problem that light distribution unevenness is generated. 
     According to the present disclosure as described above, in the projector type vehicle lamp, it is possible to forestall the generation of light distribution unevenness, even in a case where the upright wall surface is formed on the peripheral edge of the projection lens. 
     In the configuration, while the concrete shape of the upright wall surface is not specifically limited as described above, in a case where the maximum height of the upright wall surface is set to a value of ½ or more of the maximum thickness of the projection lens, the quantity of light internally reflected by the upright wall surface is considerably increased. Therefore, it is particularly effective to employ the configuration of the present disclosure. 
     At this time, in a case where the maximum height of the upright wall surface is set to a value of ⅔ or more of the maximum thickness of the projection lens, it is more effective to employ the configuration of the present disclosure. 
     In the configuration, when the light control member is configured by a lens holder that supports the projection lens, the acting effects can be acquired without an increase in the number of parts. 
     In the configuration, in a case where the light source is a light emitting device supported on a heat sink, the acting effects can be acquired without an increase in the number of parts when the light control member is configured by the heat sink. 
     In the configuration, in a case where the lamp includes a reflector that reflects light emitted from the light source to the projection lens and a shade that shields some of reflected light from the reflector, the front surface of the shade may be formed with irregularities. When this configuration is employed, it is possible to effectively suppress the reflected light, reflected from the reflector and then surface-reflected by the rear surface of the projection lens, from being reflected by the front surface of the shade to be incident again on the projection lens. Consequently, it is possible to effectively suppress the light, reflected by the front surface of the shade to be incident again on the projection lens, from being irradiated forward as stray light. 
     The foregoing summary is illustrative only and is not intended to be in any way limiting. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features will become apparent by reference to the drawings and the following detailed description. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a sectional side view illustrating a vehicle lamp according to one exemplary embodiment of the present disclosure. 
         FIG. 2  is a sectional view taken along line II-II in  FIG. 1 . 
         FIG. 3  is a view taken in the direction of arrow III in  FIG. 1 . 
         FIG. 4  is a perspective view illustrating a low-beam light distribution pattern formed on a virtual vertical screen located at a position 25 m ahead the vehicle lamp by light irradiated forward from the lamp. 
         FIG. 5  is a view equal to  FIG. 1  illustrating a vehicle lamp according to a modification of the exemplary embodiment. 
         FIG. 6  is a view equal to  FIG. 3  illustrating the vehicle lamp according to the modification. 
     
    
    
     DETAILED DESCRIPTION 
     In the following detailed description, reference is made to the accompanying drawing, which form a part hereof. The illustrative embodiments described in the detailed description, drawing, and claims are not meant to be limiting. Other embodiments may be utilized, and other changes may be made, without departing from the spirit or scope of the subject matter presented here. 
     Hereinafter, the exemplary embodiments of the present disclosure will be described with reference to the drawings. 
       FIG. 1  is a side sectional view illustrating a vehicle lamp according to one exemplary embodiment of the present disclosure,  FIG. 2  is a sectional view taken along line II-II in  FIG. 1 , and  FIG. 3  is a view taken in the direction of arrow III in  FIG. 1 . 
     As illustrated in  FIGS. 1 to 3 , the vehicle lamp  10  according to the present exemplary embodiment is a low-beam lamp unit that is used in an inserted state as a portion of a headlamp, and is configured as a projector type lamp unit. 
     That is, the vehicle lamp  10  includes a projection lens  12  having an optical axis Ax extending in the longitudinal direction of a vehicle, a light emitting device  14  serving as a light source located behind a rear focal point F of the projection lens  12 , a reflector  16  located to cover the light emitting device  14  from the upper side to reflect light from the light emitting device  14  toward the projection lens  12 , a shade  18  configured to shield some of the light reflected from the reflector  16 , a lens holder  20 , and a heat sink  22 . 
     Upon being inserted into a headlamp, the vehicle lamp  10  is located such that its optical axis Ax extends downward by about 0.5° to 0.6° in relation to the longitudinal direction of the vehicle. 
     The projection lens  12  is a plano-convex aspherical lens having a convex front surface  12   a  and a flat rear surface  12   b . The projection lens  12  is configured to project a light source image, formed on a rear focal plane that is a focal plane including the rear focal point F, to a virtual vertical screen in front of the lamp as a reversed image. 
     The projection lens  12  includes a pair of left and right upright wall surfaces  12   c  formed on the peripheral edge thereof and has a vertically elongated outer shape when viewed from the front side of the lamp. In addition, an outer circumferential flange  12   d  is formed over the entire peripheral edge of the projection lens  12  to protrude to the outer circumferential side along the rear surface  12   b.  
         Each sidewall surface  12   c  is smoothly curved to be a substantially flat surface having a longitudinally elongated shape when viewed from a front side of the projection lens, and has a greater inclination angle with reference to a plane perpendicular to an optical axis of the projection lens than the front surface  12   a  of the projection lens  12  when viewed in a horizontal cross section. At this time, the front edge (i.e. the ridgeline as the intersection line with the front surface  12   a ) of each sidewall surface  12   c  is formed to linearly extend in the vertical direction when viewed from the front side of the lamp. In addition, each surface  12   c  is formed to extend in a backward direction from the front edge by an inclination angle of 80° or more (e.g., about 85°) with reference to a plane perpendicular to the optical axis Ax. In addition, each sidewall surface  12   c  has the maximum thickness h 1  in a forward and backward direction of the projection lens  12  that is set to a value of ½ or more (more specifically, ⅔ or more, e.g., about ¾) of the maximum thickness H 1  of the projection lens  12  in a forward and backward direction thereof.       

     The projection lens  12  is supported, at the outer circumferential flange  12   d  thereof, by the lens holder  20  and the lens holder  20  is supported on, for example, the heat sink  22  via a support member (not illustrated). 
     The lens holder  20  has an annular shape and supports the outer circumferential surface and the rear surface of the outer circumferential flange  12   d  of the projection lens  12 . The lens holder  20  includes a pair of left and right inner circumferential flanges  20   b  formed on both left and right side portions of the inner circumferential surface  20   a  thereof to protrude closer to each other. Each inner circumferential flange  20   b  is formed such that its front surface extends in the vertical direction along the rear surface  12   b  of the projection lens  12 . 
     In addition, a panel member  24  is disposed around the projection lens  12  to cover the outer circumferential flange  12   d  of the projection lens  12  and the lens holder  20  in an annular form from the front side. 
     The light emitting device  14  is a white light emitting diode and has a laterally elongated rectangular light emitting surface  14   a . In addition, the light emitting device  14  is disposed such that its light emitting surface  14   a  extends in the transverse direction to face upward on the horizontal plane including the optical axis Ax. The light emitting device  14  is supported on the heat sink  22 . 
     A reflective surface  16   a  of the reflector  16  is formed in a curved surface of an approximately elliptical shape, a first focal point of which is the light emission center of the light emitting device  14 , and the eccentricity of the reflective surface  16   a  is set to gradually increase from the vertical cross section to the horizontal cross section. In this way, the reflector  16  is configured to converge light from the light emitting device  14  to a point located slightly ahead the rear focal point F in the vertical cross section, and move the converged position greatly forwardly in the horizontal cross section. The reflector  16  is supported on the heat sink  22 . 
     The shade  18  has an L-shape in the sectional side view and the upper surface of the shade  18  is configured as an upward reflective surface  18   a  subjected to a metal deposition processing. A left region of the upward reflective surface  18   a  located at the left side of the optical axis Ax (the right side when viewed from the front side of the lamp) is configured as a horizontal surface, and a right region of the upward reflective surface  18   a  located at the right side of the optical axis Ax is configured as a horizontal surface that is located one level lower than the left region via a short inclined surface. A front edge  18   a   1  of the upward reflective surface  18   a  is forwardly curved from the rear focal point F toward both left and right sides. The shade  18  is supported on the heat sink  22 . 
     The upward reflective surface  18   a  of the shade  18  is configured to shield some of reflected light directed from the reflective surface  16   a  of the reflector  16  to the projection lens  12  and then reflect the light upward, so as to cause the light to be introduced into the projection lens  12  and emitted as downward light from the projection lens  12 . 
     A plurality of irregularities  18   a  is formed, in a vertical stripe pattern, on a front surface  18   b  of a front wall extending downward from the front edge  18   a   1  of the upward reflective surface  18   a  of the shade  18 . At this time, upper edges of the respective irregularities  18   s  are located slightly below the optical axis Ax. The irregularities  18   s  are configured to diffuse and reflect, in the transverse direction, some of reflected light from the reflector  16  reflected by the rear surface  12   b  of the projection lens  12  and reaching the front surface  18   b  of the shade  18 , and as a result, to suppress reintroduction of the light reflected by the front surface  18   b  to the projection lens  12 . 
     As illustrated in  FIG. 2 , light, emitted from the light emission center of the light emitting device  14  (i.e. the center position of the light emitting surface  14   a ) and reflected by the reflector  16 , is converged near the optical axis Ax, while light, emitted from edge positions in the transverse direction of the horizontally elongated light emitting surface  14   a  and reflected from the regions of the reflective surface  16   a  of the reflector  16  close to the optical axis laterally opposite to the edge positions, is diffused in the direction away from the optical axis Ax. 
     At this time, assuming that the lens holder  20  is not formed with the pair of left and right inner circumferential flanges  20   b , the light reflected in the direction away from the optical axis Ax by the reflective surface  16   a  of the reflector  16 , as represented by two-dot chain line in  FIG. 2 , is introduced to the projection lens  12  from both side edge regions of the rear surface  12   b  of the projection lens  12 . Thereafter, the light reaches the pair of left and right upright wall surfaces  12   c  and is internally reflected by via total reflection in the upright wall surfaces  12   c . Then, the light internally reflected by the respective upright wall surfaces  12   c  is emitted, as uncontrolled stray light, forward from the front surface  12   a  of the projection lens  12  in the greatly transversely deviated direction. 
     However, in the present exemplary embodiment, the respective inner circumferential flanges  20   b  formed on the lens holder  20  is configured to shield the reflected light reflected from the reflector  16  to be incident on the projection lens  12  from the side edge regions of the rear surface  12   b  of the projection lens  12 , thereby preventing the reflected light from reaching the respective upright wall surfaces  12   c  and thus, preventing the reflected light from being internally reflected by the upright wall surfaces  12   c.    
       FIG. 4  is a perspective view illustrating a low-beam light distribution pattern PL formed on a virtual vertical screen, located at a position 25 m ahead the vehicle, by light irradiated forward from the vehicle lamp  10 . 
     The low-beam light distribution pattern PL is a low-beam light distribution pattern for left light distribution and has left and right unlevel cutoff lines CL 1  and CL 2  in the upper edge thereof. The cutoff lines CL 1  and CL 2  horizontally extend with a height difference at the left and right sides of a boundary line V-V vertically passing a vanishing point H-V in front of the lamp. An opposite lane side portion at the right side of the line V-V is formed as the lower level cutoff line CL 1  and an own lane side portion is formed as the upper level cutoff line CL 2 , of which the level is raised from the lower level cutoff line CL 1  via a slope. 
     The low-beam light distribution pattern PL is formed by projecting a light source image of the light emitting device  14 , which is formed on the rear focal plane of the projection lens  12  by the light emitted from the light emitting device  14  and reflected by the reflector  16 , to the virtual vertical screen by the projection lens  12  as a reversed image. The cutoff lines CL 1  and CL 2  of the low-beam light distribution pattern PL are adapted to be formed as a reversed projection image of the front edge  18   a   1  of the upward reflective surface  18   a  of the shade  18 . 
     In the low-beam light distribution pattern PL, an elbow point E that is an intersection point of the lower end cutoff line CL 1  and the line V-V is located below H-V by about 0.5° to 0.6°. This is caused since the optical axis Ax extends in a direction directed downward by about 0.5° to 0.6° in relation to the longitudinal direction of the vehicle. 
     Small light distribution patterns (i.e. light distribution patterns represented by two-dot chain lines in  FIG. 4 ) located at the left and right sides of the low-beam light distribution pattern PL are light distribution patterns formed by the light internally reflected by the pair of left and right upright wall surfaces  12   c  of the projection lens  12  when it is assumed that the lens holder  20  is not formed with the pair of left and right inner circumferential flanges  20   b . The two light distribution patterns P′ are formed to vertically across the positions of the cutoff lines CL 1  and CL 2  at the left and right sides of the low-beam light distribution pattern PL. 
     Next, the acting effects of the present exemplary embodiment will be described. 
     The vehicle lamp  10  according to the present exemplary embodiment is configured as a projector type lamp unit. The projection lens  12  of the vehicle lamp  10  includes the upright wall surfaces  12  formed on the peripheral edge and having a greater longitudinal inclination angle than the front surface  12   a  of the projection lens  12 . However, since the inner circumferential flanges  20   b  of the lens holder  20  are arranged behind the projection lens  12  and serve as a light control member to prevent the light, which is incident on the projection lens  12  from the light emitting device  14 , from being internally reflected by the upright wall surfaces  12   c.    
     That is, due to the existence of the inner circumferential flange portions  20   b  of the lens holder  20 , the light incident on the projection lens  12  is not internally reflected by the upright wall surfaces  12   c . Thus, it is possible to forestall the problem that the light internally reflected by the upright wall surfaces  12   c  of the projection lens  12  is irradiated as stray light, as is conventionally encountered. In this way, it is possible to forestall the problem that light distribution unevenness is generated in the low-beam light distribution pattern PL. 
     Through the present exemplary embodiment as described above, it is possible to forestall the generation of light distribution unevenness in the projector type vehicle lamp  10 , even in a case where the upright wall surfaces  12   c  are formed on the peripheral edge of the projection lens  12 . 
     At this time, in the present exemplary embodiment, the maximum height h 1  of each upright wall surface  12   c  is set to a value of ½ or more of the maximum thickness H 1  of the projection lens  12  and the quantity of light internally reflected by each upright wall surface  12   c  is considerably increased. Therefore, it is very effective to employ the configuration of the present exemplary embodiment. 
     In particular, in the present exemplary embodiment, the maximum height h 1  of the upright wall surface  12   c  is set to a value of ⅔ or more of the maximum thickness H 1  of the projection lens  12 . Therefore, it is more effective to employ the configuration of the present exemplary embodiment. 
     Moreover, in the present exemplary embodiment, the light control member is configured by the lens holder  20  that supports the projection lens  12 . Therefore, the acting effects may be obtained without increasing the number of parts. 
     In the present exemplary embodiment, the lamp includes the reflector  16  that reflects light emitted from the light emitting device  14  toward the projection lens  12  and the shade  18  that shields some of reflected light from the reflector  16 . The irregularities  18   s  are formed on the front surface  18   b  of the shade  18 . Therefore, the following acting effects may be achieved. 
     Since the irregularities  18   s  are formed on the front surface  18   b  of the shade  18 , it is possible to effectively suppress the reflected light reflected from the reflector  16  and then surface-reflected by the rear surface  12   b  of the projection lens  12 , from being reflected by the front surface  18   b  of the shade  18  to be incident again on the projection lens  12 . Consequently, it is possible to effectively suppress the light, reflected from the front surface  18   b  of the shade  18  to be incident on the projection lens  12 , from being irradiated as stray light. 
     In the present exemplary embodiment, from a point of view of achieving a greater amount of reflected light from the reflector  16  (i.e. light reflected in the direction near the optical axis Ax to thereby reach the projection lens  12 ), which contributes to formation of the low-beam light distribution pattern PL, it is preferable that the lateral protrusion of each inner circumferential flange  20   b  configuring the light control member may be reduced as much as possible within a range capable of preventing light reflected in the direction away from the optical axis Ax by the reflector  16  from reaching each upright wall surface  12   c.    
     In the exemplary embodiment, although it has been described that the light control member is configured by the lens holder  20  supporting the projection lens  12 , the light control member may be configured by a new separate member. 
     In the exemplary embodiment described above, although it has been described that the irregularities  18   s  are formed in the vertical stripe form on the front surface  18   b  of the shade  18 , the same acting effects may be acquired in a case where the irregularities are formed by performing an embossing process or a frost processing on the front surface  18   b  of the shade  18 . 
     In the exemplary embodiment, although descriptions have been made on the projector type lamp unit configured to reflect light emitted from the light emitting device  14  by the reflector  16 , a projector type lamp unit configured to make light emitted from the light emitting device  14  directly incident on the projection lens  12  may be adopted. 
     Next, a modification of the exemplary embodiment will be described. 
       FIGS. 5 and 6  are views corresponding to  FIGS. 1 and 3  illustrating a vehicle lamp  110  according to a modification. 
     As illustrated in  FIGS. 5 and 6 , the vehicle lamp  110  is configured as a projector type lamp unit to reflect light from the light emitting device  14  by the reflector  16 , like the vehicle lamp  10  of the exemplary embodiment. However, the configurations other than the light emitting device  14  and the reflector  16  are different from those in the exemplary embodiment. 
     That is, although a projection lens  112  of the present modification is configured as a plano-convex aspherical lens having a convex front surface  112   a  and a flat rear surface  112   b , a pair of upper and lower upright wall surfaces  112   c  is formed on the peripheral edge of the projection lens  112  and has a laterally elongated external shape when viewed from the front side of the lamp. In addition, an outer circumferential flange  112   d  is formed over the entire peripheral edge of the projection lens  112  to protrude to the outer circumferential side along the rear surface  112   b.    
     Each upright wall surface  112   c  is configured as a curved surface like a flat surface and having a greater longitudinal inclination angle than the front surface  112   a  of the projection lens  112 . At this time, the front edge of each upright wall surface  112   c  is formed to linearly extend in the horizontal direction when viewed from the front side of the lamp. In addition, each upright wall surface  112   c  is formed to extend rearward from the front edge thereof by an inclination angle of 80° or more in relation to a plane perpendicular to the optical axis Ax. In addition, the maximum height h 2  of each upright wall surface  112   c  is set to a value of ½ or more of the maximum thickness H 2  of the projection lens  112 . 
     The projection lens  112  is supported, at the outer circumferential flange  112   d  thereof, by the lens holder  120 . The lens holder  20  is formed in an annular shape and supports the outer circumferential surface and the rear surface of the outer circumferential flange  112   d  of the projection lens  12 . However, the inner circumferential surface  120   a  of the lens holder  20  is not formed with a flange corresponding to the inner circumferential flange  20   b  of the lens holder  20  of the exemplary embodiment. 
     A shade  118  of the present modification is formed in a flat plate shape and the upper surface of the shade  118  is configured as an upward reflective surface  118   a  subjected to a metal deposition processing. The upward reflective surface  118   a  has the same surface shape as the upward reflective surface  18   a  of the exemplary embodiment. In addition, the front edge  118   a   1  of the shade  118  has the same shape as the front edge  18   a   1  of the exemplary embodiment. The shade  118  is supported on a heat sink  122 . 
     The front surface of the heat sink  122  is configured as an inclined surface that is downwardly inclined to extend forward. A shield piece  122   a  having an L-shape in a sectional side view is formed on the lower end of the heat sink  122  integrally with the heat sink  122 . 
     The shield piece  122   a  is located below the optical axis Ax and horizontally extends forward from the heat sink  122  and then extends upward. A plurality of irregularities  122   s  is formed in a vertical stripe pattern on the front surface  122   a   1  of the shield piece  122   a . At this time, the front surface  122   a   1  of the shield piece  122   a  is located in front of a middle point between the rear focal point F and the rear surface  112   b  of the projection lens  112  and the upper edge of the front surface  122   a   1  is located somewhat lower than the optical axis Ax. 
     In addition, an annular panel member  124  is located around the projection lens  112  to cover the outer circumferential flange  112   d  of the projection lens  112  and the lens holder  120  in an annular form from the front side. 
     As illustrated in  FIG. 5 , light, emitted from the light emitting device  14  and reflected by a region of the reflective surface  16   a  of the reflector  16  relatively close to the front edge, is directed toward the projection lens  112  by a relatively large downward angle. 
     At this time, assuming that the heat sink  122  is not formed with the shield piece  122   a , as represented by a dot-dot-dashed line, some of reflected light from the reflector  16  is introduced to the projection lens  112  from a lower edge region of the rear surface  116   b  of the projection lens  112  and, thereafter, internally reflected by the upright wall surface  112   c  at the bottom of the projection lens  112  via total reflection. In addition, the light internally reflected by the upright wall surface  112   c  is irradiated, as uncontrolled stray light, forward from the front surface  112   a  of the projection lens  112  in the greatly upwardly deviated direction. 
     However, in the present modification, the heat shield  122   a  formed on the heat sink  122  is configured to shield the reflected light, which is reflected from the reflector  16  to be incident on the projection lens  112  from the lower edge region of the rear surface  112   b  of the projection lens  112 , thereby preventing the reflected light from being internally reflected by the upright wall surface  112   c  at the lower side of the projection lens  112 . 
     Meanwhile, the reflected light, which reaches the projection lens  112  without being shielded by the shield piece  122   a , is incident on the projection lens  112  to be projected forward from the front surface  112   a  of the projection lens  112 . At this time, even if some of the reflected light from reflected the reflector  16  and then internally reflected by the rear surface  112   b  of the projection lens  112   b  reaches the light shield piece  122   a , the light is diffused and reflected in the transverse direction by the irregularities  122   s  formed on the front surface  122   a   1  of the light shield piece  122   a . In this way, the reflected light is effectively suppressed from being incident again on the projection lens  12 . 
     In the present modification, the light field piece  122   a , which serves as a light control member integrally formed with the heat sink  122 , may prevent the reflected light incident on the projection lens  112  from the reflector  16 , from being internally reflected by the upright wall surface  112   c  at the lower side of the projection lens  112 , thereby preventing generation of stray light that causes generation of light distribution unevenness. 
     In addition, in the present modification, due to the existence of the irregularities  112   s  formed on the front surface  122   a   1  of the light shield piece  122   a , the reflected light reflected from the reflector  16  and surface-reflected by the rear surface  112   b  of the projection lens  112  may be diffused and reflected in the transverse direction. Therefore, the reflected light is effectively suppressed from being incident again on the projection lens  112 . 
     In addition, in the exemplary embodiment and the modification thereof, numerical values described as data are merely given by way of example and, of course, may be properly set to different values. 
     From the foregoing, it will be appreciated that various embodiments of the present disclosure have been described herein for purposes of illustration, and that various modifications may be made without departing from the scope and spirit of the present disclosure. Accordingly, the various embodiments disclosed herein are not intended to be limiting, with the true scope and spirit being indicated by the following claims.