JP4442452B2 - head lamp - Google Patents

Description

  The present invention relates to a headlamp. In particular, the present invention relates to a headlamp capable of obtaining a suitable light distribution pattern.

  Conventional headlamps have been devised in various ways to optimize the light distribution pattern. For example, in Patent Document 1, in order to improve the light distribution characteristics of a projector-type headlamp, a condensing lens is formed by three horizontal cylindrical lenses, and the three cylindrical lenses are stacked in the vertical direction. Forming. Since the light distribution pattern of the headlamp has a larger spread in the horizontal direction than in the vertical direction, the irradiation light of the headlamp does not need to be diffused in the vertical direction so much. For this reason, by forming the condensing lens by the cylindrical lens of the horizontal tone as described above, it is possible to diffuse the irradiation light in the horizontal direction and not so much in the vertical direction. In addition, when a condensing lens is formed by one cylindrical lens, the thickness of the condensing lens in the front-rear direction or the irradiation direction is increased, so that three thin cylindrical lenses are stacked in the vertical direction. This reduces the overall thickness of the condenser lens and reduces the weight. As a result, the light distribution characteristics were improved while suppressing an increase in the weight of the entire headlamp.

JP 2003-123509 A

  However, in the above-described headlamp, the condensing lens is formed by three cylindrical lenses and the three cylindrical lenses are stacked in the vertical direction, so that the optical axes of the cylindrical lenses are formed in parallel in the vertical direction. It will be. In projector-type headlamps, one of the two focal points of the reflecting surface of the reflector and the focal point of the condensing lens are usually formed at the same position. The focus of at least two of the cylindrical lenses is away from the focus of the reflecting surface of the reflector. For this reason, it may be difficult to obtain an arbitrary light distribution characteristic, and it may be difficult to obtain a desired light distribution pattern.

  The present invention has been made in view of the above, and an object of the present invention is to provide a headlamp that can more reliably obtain a suitable light distribution pattern.

  In order to solve the above-described problems and achieve the object, a headlamp according to the present invention is a projector-type head having a condensing lens that irradiates light from a light source reflected by a reflecting surface of a reflector in a predetermined direction. In the lamp, the condenser lens is formed by combining a plurality of lenses having the same back focus, the same optical axis, and different focal lengths. .

  In the present invention, since a plurality of lenses having different focal lengths are combined, an arbitrary light distribution characteristic can be obtained by adjusting the combination. In addition, since the optical axes of the respective lenses are set to the same position, the focal points of these lenses can be positioned almost at the same position as the focal point of the reflecting surface of the reflector. A desired light distribution pattern can be obtained. As a result, a suitable light distribution pattern can be obtained more reliably.

  In the headlamp according to the present invention, the condensing lens includes a first lens having a short focal length and a second lens having a focal length longer than the focal length of the first lens, and is close to the optical axis. The first lens is disposed in the inner direction of the second lens when the direction is the inner direction and the direction away from the optical axis is the outer direction.

  In this invention, the amount of light emitted from the condenser lens is larger than the amount of light emitted from the outer side of the condenser lens to the outside, that is, the amount of light emitted from the inner part of the condenser lens, that is, from the vicinity of the optical axis to the outside. It has become. In addition, when the focal length of the condenser lens is short, the irradiation light from the condenser lens is easily diffused, and when the focal length of the condenser lens is long, the irradiation light is difficult to diffuse, and the irradiation light is in the irradiation direction. It is easy to concentrate on the center of the optical axis, that is, on the optical axis. For this reason, by disposing the first lens with a short focal length in the inner portion where the light amount is large, the light intensity of the entire irradiation range can be increased with a large amount of light, and the light intensity of the entire light distribution pattern can be increased. In addition, by arranging the second lens having a long focal length in the outer portion where the amount of light is relatively small, the light irradiated to the outside from the portion in the outer direction in the condensing lens is condensed near the center of the irradiation direction. Can do. Thereby, the central luminous intensity can be further improved while increasing the luminous intensity of the entire light distribution pattern. As a result, a suitable light distribution pattern can be obtained more reliably.

  In the headlamp according to the present invention, the condensing lens can be mounted on a vehicle, and the second lens can be mounted on the condensing lens when the second lens is viewed in the optical axis direction. The first lens is disposed inside the U-shape of the second lens, the lower side being open when mounted on the vehicle. And

  In the present invention, the second lens is formed in a U-shape, and the portion where the U-shape is open is provided so as to be positioned below. The first lens is disposed inside the U-shape of the second lens. That is, the second lens is oriented so that the open portion of the U-shape is positioned below, and the first lens is disposed inside the U-shape, so that the first lens is focused. It is arranged at least below the lens. Since the vehicle headlamp irradiates the front and the road surface, the irradiation light irradiates relatively downward. For this reason, a lot of irradiation light from the condenser lens is emitted from the lower half of the condenser lens. Therefore, by locating the first lens below the condenser lens, it is possible to irradiate the entire irradiation range with more light.

  Further, when the traveling beam is irradiated from the headlamp, it is preferable that the luminous intensity of the front center portion is high in order to improve the visibility in the distance. For this reason, by making the second lens U-shaped and arranging the second lens in the upper part of the condensing lens, it is possible to secure the light condensed by the second lens, and more reliably the central luminous intensity. Can be raised. As a result, a suitable light distribution pattern can be obtained more reliably when irradiation is performed with a light distribution pattern that does not require a cut line, such as a traveling beam or a fog lamp.

  The headlamp according to the present invention has an effect that a suitable light distribution pattern can be obtained more reliably.

  Hereinafter, embodiments of a headlamp according to the present invention will be described in detail with reference to the drawings. Note that the present invention is not limited to the embodiments. In addition, constituent elements in the following embodiments include those that can be easily replaced by those skilled in the art or those that are substantially the same. In the following description, the front, rear, left side, right side, upper side, and lower side of a vehicle equipped with the headlamp of the present invention will be described as front, rear, left side, right side, upper side, and lower side in the headlamp. .

  FIG. 1 is a cross-sectional view of a headlamp according to an embodiment of the present invention. The headlamp 1 shown in the figure includes a reflector 10, a discharge bulb 13 as a light source, a condenser lens 20 that is provided in front of the reflector 10 and irradiates reflected light from the reflector 10 in a predetermined direction, and these. The frame 16 is integrally fixed. In this state, the headlamp 1 is mounted on a vehicle (not shown) with the condenser lens 20 side facing forward.

  A reflective surface 11 is formed on the inner surface of the reflector 10 by aluminum vapor deposition or the like. Further, an insertion hole 12 for the discharge bulb 13 is formed near the rear end of the reflector 10, and the discharge bulb 13 is inserted through the insertion hole 12 and fixed to the reflector 10. The discharge bulb 13 is connected to a bulb socket (not shown) that is electrically connected to a power source (not shown). Further, the shape of the reflecting surface 11 has two focal points of a first focal point (pseudo focal point) F1 and a second focal point F2 on the central line (optical axis) 5, and a rotational ellipse having the central line 5 as a central axis. It is a part of the shape based on. The first focal point F1 and the second focal point F2 are optical reference points that are the reference for determining the shape of the reflecting surface 11. The light emitting part 14 of the discharge bulb 13 is located near the first focal point F1.

  A frame 16 is provided in front of the reflector 10, and a condensing lens 20 is provided at the front end thereof, that is, in front of the second focal point F2. The condensing lens 20 is integrally formed by combining the first lens 25 and the second lens 30. The first lens 25 and the second lens 30 are both aspherical lenses and are transparent. It is made of a substance such as glass. The shape is based on a convex lens, and the convex lens is provided with the convex side surface facing forward. Further, the rear side portion of the condenser lens 20 is a plane orthogonal to the center line 5.

  FIG. 2 is an AA arrow view of FIG. The condensing lens 20 has a shape based on a circle when the headlamp 1 is viewed from the front to the rear along the direction of the center line 5, and both ends of the circular left and right direction The shape is removed. For this reason, the end portions 21 positioned at both ends in the left-right direction of the condenser lens 20 have a shape along the vertical direction, and both end portions 21 are formed substantially in parallel.

  The second lens 30 is formed in a substantially U-shape with the lower part opened when viewed in the direction along the direction of the center line 5 from the front to the rear. The 1st lens 25 is arrange | positioned inside the 2nd lens 30 formed in this U shape. In other words, the second lens 30 is formed in a U-shape that is open at the bottom, the inner portion of the U-shape is provided as the first lens engaging portion 31, and the first lens 25 is the second lens It is provided to be engaged with the first lens engaging portion 31 of the lens 30. For this reason, the second lens 30 is positioned in the outer side direction and the upper side in the left-right direction of the first lens 25. Further, these detailed shapes are symmetrical with respect to the vertical center line 35 that is the center in the left-right direction when the condenser lens 20 is viewed from the front. Further, the upper end portion of the first lens 25 and the upper end portion of the first lens engaging portion 31 of the second lens 30 are the center line in the left-right direction that is the center in the up-down direction when the condenser lens 20 is viewed from the front. It is located above 36.

  3 is a cross-sectional view taken along the line BB in FIG. Further, as described above, the second lens 30 has a shape based on a convex lens provided with the convex surface facing forward, and further, a front portion of the second lens 30, that is, irradiation. A portion on the direction side is cut out in the shape of the first lens 25. This notched portion is the first lens engaging portion 31. Similar to the second lens 30, the first lens 25 has a shape based on a convex lens provided with the convex surface facing forward as described above. Further, the shape of the portion of the first lens 25 facing the second lens 30, that is, the shape of the rear side and the upper side portion of the first lens 25 is a shape along the shape of the first lens engaging portion 31. It is formed with.

  The first lens 25 and the second lens 30 are formed so that both optical axes 37 are at the same position. The upper end portion of the first lens 25 and the upper end portion of the first lens engaging portion 31 are located above the optical axis 37. Further, when the condensing lens 20 is incorporated in the headlamp 1, the optical axis 37 of the condensing lens 20 is provided so as to be at the same position as the center line 5. The thickness of the lens 20 in the front-rear direction is a shape in which both the first lens 25 and the second lens 30 are based on a convex lens, so the portion through which the optical axis 37 passes is the thickest.

  The optical axis 37 here is a straight line that passes through the center of curvature of each curved surface when both surfaces of the lens are curved, and when one surface of the lens is curved and the other surface is flat. Means a straight line that passes through the center of curvature of the curved surface and is perpendicular to the plane.

  FIG. 4 is a comparison diagram of reference shapes of the first lens and the second lens. Since the first lens 25 and the second lens 30 have a shape based on a convex lens, both have a focal point and a principal point. The focal point of the first lens 25 is the first lens focal point 26 and the first lens. A principal point 25 is a first lens principal point 27, a focal point of the second lens 30 is a second lens focal point 32, and a principal point of the second lens 30 is a second lens principal point 33. Further, when comparing the first lens 25 and the second lens 30 with convex lenses having respective reference shapes, the back focus Fb which is the distance from the rear end portion of the first lens 25 to the first lens focal point 26 is The length is equal to the back focus Fb, which is the distance from the rear end portion of the second lens 30 to the second lens focal point 32. That is, the back focus Fb is the same between the first lens 25 and the second lens 30.

  Further, comparing the focal lengths, the first lens focal length L1, which is the distance from the first lens principal point 27 to the first lens focal point 26, is the distance from the second lens principal point 33 to the second lens focal point 32. It is shorter than a certain second lens focal length L2. For this reason, the focal length is different between the first lens 25 and the second lens 30, and the second lens focal length L2 is longer than the first lens focal length L1.

  FIG. 5 is a diagram illustrating the shape of the first lens when the condenser lens is formed. FIG. 6 is a diagram showing a light distribution pattern of the first lens shown in FIG. In addition, the inner line of the light distribution pattern shown in the figure is an isoluminous curve, and the light intensity increases toward the inside. The first lens light distribution pattern 41, which is the light distribution pattern of the irradiation light emitted from the first lens 25 in the shape of the first lens 25 when the condenser lens 20 is formed, covers a wide range in the left-right direction. In the vertical direction, more light is irradiated downward than upward. Specifically, when the first lens 25 is viewed in the direction of the optical axis 37, the width in the left-right direction is formed with a predetermined width, and most of the first lens 25 is below the center line 36 in the left-right direction. While being positioned, the upper end portion is located above the left-right direction center line 36 and is formed in a shape that is line-symmetric about the up-down direction center line 35.

  The first lens light distribution pattern 41 by the irradiation light emitted from the first lens 25 having this shape is formed both above and below the HH line, which is a horizontal line having the same height as the optical axis 37. The irradiation range is wider in the lower part than in the upper part. The first lens light distribution pattern 41 is formed in a wide range over both the horizontal direction of the VV line, which is a vertical line having the same position in the horizontal direction as the optical axis 37. The luminous intensity is the highest near the intersection of the HH line and the VV line, and the luminous intensity decreases as going outward, that is, away from the HH line or VV line. ing.

  FIG. 7 is a diagram illustrating the shape of the second lens when the condenser lens is formed. FIG. 8 is a diagram showing a light distribution pattern of the second lens shown in FIG. In addition, the inner line of the light distribution pattern shown in the figure is an isoluminous curve, and the light intensity increases toward the inside. The second lens light distribution pattern 42, which is the light distribution pattern of the irradiation light emitted from the second lens 30 in the shape of the second lens 30 when the condenser lens 20 is formed, has a horizontal direction and a lower range. It is narrower than the first lens light distribution pattern 41. Specifically, when the second lens 30 is viewed in the direction of the optical axis 37, the second lens 30 is formed in a substantially U-shaped shape with the lower portion opened, and the inner portion of the U-shape. Is formed with a predetermined width in the left-right direction, and an upper end portion thereof is located above the center line 36 in the left-right direction. Further, the second lens 30 is formed in a shape that is line symmetric about the vertical center line 35. Note that the second lens 30 is different from the second lens 30 in the configuration of the condensing lens 20, and both ends in the left-right direction remain in the shape of a convex lens that is the basis of the second lens 30. Is arcuate.

  The second lens light distribution pattern 42 by the irradiation light emitted from the second lens 30 having this shape is formed above and below the HH line, and the first lens light distribution pattern both above and below. The range is narrower than 41. The second lens light distribution pattern 42 is formed in the left-right direction of the VV line, and its range is narrower than the range of the first lens light distribution pattern 41 in the left-right direction. . That is, the second lens light distribution pattern 42 has a narrower range in the vertical direction and a range in the horizontal direction than the first lens light distribution pattern 41. Similarly to the first lens light distribution pattern 41, the luminous intensity is the highest in the vicinity of the intersection of the HH line and the VV line, and as it goes outward, that is, the HH line or VV. It decreases as the distance from the −V line increases. At that time, since the second lens light distribution pattern 42 has a smaller area irradiated with the irradiation light than the first lens light distribution pattern 41, the irradiation light is concentrated and irradiated. For this reason, the second lens light distribution pattern 42 generally has a higher luminous intensity than the first lens light distribution pattern 41.

  The headlamp 1 according to this embodiment is configured as described above, and the operation thereof will be described below. When the headlamp 1 is turned on, first, the light emitting unit 14 in the discharge bulb 13 is turned on. When the light emitting unit 14 is turned on, a part of the light from the light emitting unit 14 is directed toward the reflecting surface 11 of the reflector 10 and reflected by the reflecting surface 11. The shape of the reflecting surface 11 is formed in a part of a shape based on a rotation ellipse having the first focal point F1 and the second focal point F2 as optical reference points, and is therefore located near the first focal point F1. When the light from the light emitting unit 14 is reflected by the reflecting surface 11, the reflected light travels in the direction of the second focal point F2.

  Further, since the reflecting surface 11 is formed based on the ellipse as described above, the light reflected by the reflecting surface 11 intersects at the second focal point F2. For example, light reflected by the upper half portion of the reflecting surface 11 is reflected toward the lower direction, and light reflected by the lower half portion of the reflecting surface 11 is reflected toward the upper direction. Of the light, the light traveling in the direction of the second focal point F2 after reflection intersects when passing through the second focal point F2. Thus, after passing through the second focal point F2, the light reflected by the upper half portion of the reflecting surface 11 proceeds in the lower direction, and the light reflected by the lower half portion of the reflecting surface 11 proceeds in the upper direction. .

  The light reflected by the reflecting surface 11 and passing through the second focal point F <b> 2 is directed toward the condenser lens 20. That is, the light reflected by the reflecting surface 11 travels to the second focal point F2 while condensing to the second focal point F2, and diffuses after passing through the second focal point F2 in the direction of the condenser lens 20. move on. Then, when the light reaches the condensing lens 20 and passes through the condensing lens 20, the direction of the light is changed, and the light is irradiated in the forward direction as substantially parallel light.

  The direction of the light after passing through the second focal point F2 can be changed when it passes through the condenser lens 20. The condenser lens 20 is integrated by combining the first lens 25 and the second lens 30. Is formed. Further, after passing through the second focal point F2, the direction of the light that is changed by the condenser lens 20 and irradiated from the condenser lens 20 is a central portion when the condenser lens 20 is viewed from the front, that is, the center in the vertical direction. The amount of light irradiated from the vicinity of the intersection of the line 35 and the center line 36 in the left-right direction is the largest. For this reason, the amount of light near the optical axis 37 is the largest, and the amount of light decreases as the distance from the optical axis 37 increases. Moreover, since the headlamp 1 irradiates the front and the road surface, the light irradiated from the condenser lens 20 is more than the amount of light irradiated from the upper half side of the condenser lens 20 so that the road surface direction can be irradiated. However, the amount of light emitted from the lower half is larger.

  The light radiated from the condenser lens 20 has the largest amount of light radiated from the vicinity of the optical axis 37 as described above, and then the lower portion thereof is large. In the condensing lens 20, the first lens 25 is disposed in such a portion where the amount of irradiation light is large, and the second lens 30 is generally disposed around the first lens 25. For this reason, the amount of light emitted from the first lens 25 is greater than the amount of light emitted from the second lens 30. The amount of light irradiated from the first lens 25 is increased in this way, but the first lens light distribution pattern 41 that is the light distribution pattern of light irradiated from the first lens 25 is wide as described above. Since it is formed in the range, the irradiation light from the first lens 25 irradiates a wide range with a large amount of light.

  On the other hand, the light amount of the irradiation light from the second lens 30 is smaller than the light amount of the irradiation light from the first lens 25, but the light distribution pattern of the irradiation light from the second lens 30 is the first. The two-lens light distribution pattern 42 has a smaller area than the first lens light distribution pattern 41, and is concentrated near the intersection of the HH line and the VV line, or near the optical axis 37. . For this reason, the irradiation light from the second lens 30 irradiates near the center in front of the vehicle or near the optical axis 37 with a small amount of light.

  FIG. 9 is a diagram showing a light distribution pattern of the headlamp shown in FIG. Since the condensing lens 20 is formed by combining the first lens 25 and the second lens 30, the traveling light distribution pattern 45, which is the light distribution pattern from the condensing lens 20, is the first lens. The light distribution pattern 41 and the second lens light distribution pattern 42 are overlaid. That is, the traveling light distribution pattern 45 is formed over both the upper and lower sides of the H-H line, and the irradiation range is wider below the upper side, and the left and right sides of the V-V line. It is formed over a wide range in both directions, and the overall luminous intensity is high. Further, the luminous intensity near the intersection of the HH line and the VV line is particularly high.

  The condensing lens 20 is designed so that the end portions 21 located at both ends in the left-right direction are shaped in the vertical direction and the both end portions 21 are formed substantially in parallel. Due to the characteristics of the lamp 1, a large amount of light emitted from the condenser lens 20 is emitted from the vicinity of the intersection of the vertical center line 35 and the horizontal center line 36 and below. For this reason, even if both ends in the left-right direction are formed in such a shape, the light distribution pattern 45 for travel is hardly affected. In other words, even when the end 21 of the condensing lens 20 is not formed in the above shape and both ends in the left-right direction are also formed in a part of the shape of the circular convex lens, The light distribution pattern 45 can be obtained.

  In the headlamp 1 described above, the condensing lens 20 is integrally formed by combining the first lens 25 and the second lens 30 having different focal lengths. Is changing. Since the first lens 25 forms the first lens light distribution pattern 41 and the second lens 30 forms the second lens light distribution pattern 42, the light distribution pattern 45 for travel is formed by overlapping these. . The condensing lens 20 is formed by combining the first lens 25 and the second lens 30 so that the optical axis 37 of the first lens 25 and the optical axis 37 of the second lens 30 are at the same position. Therefore, both the first lens focal point 26 and the second lens focal point 32 can be positioned at substantially the same position as the second focal point F2. Thereby, the desired first lens light distribution pattern 41 and the second lens light distribution pattern 42 can be easily obtained, and the traveling light distribution pattern 45 can be easily changed to the desired light distribution pattern. As a result, a suitable light distribution pattern can be obtained more reliably.

  The focal length between the first lens 25 and the second lens 30 is shorter in the first lens focal length L1 than in the second lens focal length L2. Further, the first lens 25 is arranged at a position near the optical axis 37, and the second lens 30 is arranged around the first lens 25. Here, when the focal length of the lens is short, the light distribution pattern at the time of lighting the headlamp 1 tends to spread, and when the focal length is long, the light distribution pattern tends to be small. Further, the irradiation light emitted from the condenser lens 20 has a larger amount of irradiation light when the headlamp 1 is turned on in the portion near the optical axis 37 in the condenser lens 20, and as the distance from the optical axis 37 increases. The amount of irradiation light when the headlamp 1 is turned on is reduced.

  Therefore, by disposing the first lens 25 near the optical axis 37, it is possible to irradiate a wide range with a large amount of light, and by disposing the second lens 30 around the first lens 25, It is possible to condense the light of a portion with a small amount of light and to collect it near the center of the irradiation direction, that is, near the optical axis 37. Thereby, the so-called hot zone 46 can be positioned near the center in the irradiation direction. Therefore, the central luminous intensity can be further improved while increasing the luminous intensity of the entire traveling light distribution pattern 45, and the hot zone 46 can be positioned near the center in the irradiation direction. As a result, a suitable light distribution pattern can be obtained more reliably.

  Further, the second lens 30 is formed in a U-shape with the lower side open, and the first lens 25 is disposed inside the second lens 30. The irradiation light emitted from the condenser lens 20 when the headlamp 1 is turned on has the largest amount of light near the center of the condenser lens 20, that is, the intersection between the vertical center line 35 and the horizontal center line 36. A lot of irradiation light is irradiated from below. For this reason, by disposing the first lens 25 at this portion, it is possible to irradiate the entire wide irradiation range with more light, and the luminous intensity of the entire first lens light distribution pattern 41 can be improved.

  In addition, the second lens 30 is formed in a U shape with the lower side open, and the second lens 30 is disposed in the upper part of the condenser lens 20, so that the second lens 30 collects the second lens 30. Light to shine can be secured. For this reason, the central luminous intensity can be increased more reliably, and the luminous intensity of the hot zone 46 can be increased. In the traveling beam, the hot zone 46 is preferably located in the vicinity of the center in front of the vehicle in order to improve the visibility at a distance, but the second lens 30 is provided on the condenser lens 20 to provide the second lens. By making 30 into the shape described above, the hot zone 46 can be positioned near the center in front of the vehicle, and the luminous intensity of the hot zone 46 can be improved. Therefore, the luminous intensity of the hot zone 46 can be further improved while improving the luminous intensity of the entire traveling light distribution pattern 45, and as a result, a more suitable luminous intensity distribution pattern can be obtained.

  Further, since the first lens 25 is located not only on the lower half side of the condensing lens 20 but also on the upper side of the center line 36 in the left-right direction, the first lens 25 more reliably emits light with a large amount of light. Can be irradiated. Thereby, the light intensity of the entire travel light distribution pattern 45 can be improved more reliably. As a result, a suitable light distribution pattern can be obtained more reliably.

  FIG. 10 is a front view of a condenser lens provided in a headlamp according to a modification. In the headlamp 1 according to the embodiment, the second lens 30 has a U-shaped shape with an open bottom, and the first lens 25 is disposed inside the U-shaped. However, the first lens 25 and the second lens 30 may be formed in a shape other than this shape. For example, as shown in FIG. 10, the first lens 25 and the second lens 30 are separated from the vertical center line 35 or the horizontal center line 36 at a position inclined about 45 ° about their intersection. The first lens 25 and the second lens 30 may be provided alternately. In the case of forming in this way, it is preferable that the first lens 25 is located at a portion located on the vertical center line 35 on the lower half side of the condenser lens 20. Even when the first lens 25 and the second lens 30 are arranged in this way, the first lens 25 is located at the center of the lower half side of the condenser lens 20 in the left-right direction. Since the second lenses 30 are provided at both ends, the hot zone 46 can be positioned near the center in front of the vehicle while improving the luminous intensity of the entire light distribution pattern. As a result, a suitable light distribution pattern can be obtained more reliably.

  In the headlamp 1 according to the embodiment, the shade is not provided, and the headlamp 1 that irradiates the traveling beam is described. However, a movable shade (not shown) is provided near the second focal point F2. The headlamp 1 of the present invention may be applied to a projector-type headlamp 1 that is arranged and switched to irradiate a traveling beam and a passing beam with one headlamp 1 by operating a shade. In this case, when the shade is operated to irradiate the traveling beam, the hot light distribution pattern 45 as a whole has a high luminous intensity, and the hot zone 46 having a high luminous intensity can be located near the center in front of the vehicle. In addition, the luminous intensity of the entire light distribution pattern can be increased even when the passing beam is irradiated. As a result, a suitable light distribution pattern can be obtained more reliably.

  In the headlamp 1 according to the embodiment, the headlamp 1 that emits the traveling beam is described. However, the back focus Fb is the same, the optical axis 37 is in the same position, and the focal lengths are different. The lamp having the condenser lens 20 formed by combining these lenses may be a lamp other than the headlamp 1. For example, a projector-type lamp such as a projector-type fog lamp is provided with the condensing lens 20 having the above-described configuration, whereby a suitable light distribution pattern can be obtained more reliably.

  Further, the headlamp 1 according to the embodiment uses the discharge bulb 13 as a light source, but the light source may be a light bulb other than the discharge bulb 13 such as a halogen bulb or an incandescent bulb. Even when a light source other than the discharge bulb 13 is used, by positioning the light emitting portion of the light source in the vicinity of the first focal point F1, it is possible to irradiate light from the light source toward the outside from the condenser lens. Can be obtained.

  As described above, the headlamp according to the present invention is useful for a projector-type headlamp, and is particularly suitable for improving light distribution characteristics.

It is sectional drawing of the headlamp which concerns on the Example of this invention. It is an AA arrow line view of FIG. It is BB sectional drawing of FIG. It is a comparison figure of the reference shape of the 1st lens and the 2nd lens. It is a figure which shows the shape of the 1st lens at the time of condensing lens formation. It is a figure which shows the light distribution pattern of the 1st lens shown in FIG. It is a figure which shows the shape of the 2nd lens at the time of condensing lens formation. It is a figure which shows the light distribution pattern of the 2nd lens shown in FIG. It is a figure which shows the light distribution pattern of the headlamp shown in FIG. It is a front view of the condensing lens with which the headlamp concerning a modification is equipped.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Headlamp 5 Centerline 10 Reflector 11 Reflecting surface 12 Insertion hole 13 Discharge bulb 14 Light emission part 16 Frame 20 Condensing lens 21 End part 25 1st lens 26 1st lens focus 27 1st lens principal point 30 2nd lens 31 1st lens 1 lens engaging portion 32 second lens focal point 33 second lens principal point 35 vertical direction center line 36 horizontal direction center line 37 optical axis 41 first lens light distribution pattern 42 second lens light distribution pattern 45 travel light distribution pattern 46 Hot zone F1 First focus F2 Second focus Fb Back focus L1 First lens focal length L2 Second lens focal length

Claims (1)

In a projector-type headlamp having a condenser lens that irradiates light from a light source reflected by a reflecting surface of a reflector in a predetermined direction,
The condensing lens has the same back focus and the same optical axis, and the first lens and the second lens having a focal length longer than the focal length of the first lens are combined. Furthermore, the shape when the condensing lens is viewed in the optical axis direction is symmetric with respect to the vertical center line that is the center in the left-right direction when mounted on the vehicle. ,
The second lens is formed in a U-shape in which the lower side is opened when the second lens is viewed in the optical axis direction.
The first lens is disposed inside the U-shape of the second lens so that the direction closer to the optical axis is the inner direction and the direction away from the optical axis is the outer direction. It is arranged inside the second lens, and the upper end portion is located above the center line in the left-right direction that becomes the center in the up-down direction when the condenser lens is viewed in the optical axis direction . Headlamp characterized by.

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