JP2007294149A - Vehicular headlamp - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem wherein solenoids and motors are upsized when second switching speed is made faster than first switching speed in a conventional vehicular headlamp. <P>SOLUTION: The vehicular headlamp comprises: a shade changeover device 7 that comprises a stepping motor 34 and switches the posture of first and second shades 5, 6 to a plurality of postures for obtaining a plurality of light distribution patterns; and a control unit 100 that has at least first and second switching for the switching of a plurality of light distribution patterns, drives and controls a stepping motor 34 at a rated current or with constant speed control for first switching, and drives and controls the stepping motor 34 at a current value that is larger than a rated current value or with acceleration control for second switching. As a result, making the second switching speed faster than the first switching speed upsize the stepping motor 34. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a headlamp, a fog lamp, etc., and a plurality of light distribution patterns, for example, a light distribution pattern for passing and a light distribution pattern for highways, a light distribution pattern for passing and a light distribution pattern for traveling, and a light distribution for highways The present invention relates to a projector-type vehicle headlamp that can obtain a pattern, a light distribution pattern for traveling, and the like. In particular, the present invention secures one switching speed at a predetermined speed when there are at least two switching of a plurality of light distribution patterns and one of the switchings places importance on the switching speed with respect to the other switching. Further, the present invention relates to a vehicle headlamp capable of appropriately controlling the switching speed.

  This type of vehicle headlamp has been conventionally used (see, for example, Patent Document 1). Hereinafter, a conventional vehicle headlamp will be described. A conventional vehicle headlamp includes a light source, a reflector that reflects light from the light source, a projection lens that projects reflected light from the reflector forward, and reflected light that travels from the reflector toward the projection lens. A shade for switching to a plurality of beams from which a plurality of light distribution patterns are obtained, and a shade switching device (consisting of a solenoid and a spring) for switching the posture of the shades to a plurality of postures for obtaining the plurality of light distribution patterns; The solenoid plunger is in contact with the shade. Hereinafter, the operation of the conventional vehicle headlamp will be described. By energizing or shutting off the solenoid, the plunger of the solenoid advances and retreats, and the shade is switched to a plurality of postures by the action of the advance and retreat of the plunger and the spring force, and a plurality of arrangements are performed. A light pattern is obtained.

  Here, in a vehicle headlamp, when switching a plurality of light distribution patterns, one switching may place importance on the switching speed relative to the other switching. In this case, one switching speed Must be ensured at a predetermined speed. However, since conventional vehicle headlamps use a solenoid as a shade switching device, in order to ensure one switching speed at a predetermined speed, the solenoid is enlarged and the switching speed is controlled appropriately. Difficult to do. Therefore, it has been proposed to use a motor instead of a solenoid as the shade switching device. In this case, since a normal motor (for example, a DC motor) is used, in order to secure one switching speed at a predetermined speed, as in the case of the solenoid, the motor is enlarged and the switching is performed. It is difficult to control the speed properly.

JP 2003-123514 A

  The problem to be solved by the present invention is that in a conventional vehicle headlamp using a solenoid or a normal motor, there are at least two switching of a plurality of light distribution patterns, and one of the switching is the switching of the other. However, when switching speed is important, in order to ensure one switching speed at a predetermined speed, the solenoid and motor become larger, and it is difficult to control the switching speed properly. is there.

  The present invention (the invention according to claim 1) is composed of a stepping motor, and the shade switching device for switching the posture of the shade to a plurality of postures from which a plurality of light distribution patterns can be obtained, and switching of the plurality of light distribution patterns. Stepping motor having at least first switching and second switching, driving control of stepping motor with rated current or constant speed control to perform first switching, stepping motor with current value larger than rated current value or with acceleration control And a control device that performs second switching by controlling the driving of the motor.

  According to the present invention (the invention according to claim 2), the shade switching device has a mechanism for preventing the posture of the switched shade from returning, and the control device completes the first switching and the second switching. And the current supply to the stepping motor is cut off.

  Further, according to the present invention (the invention according to claim 3), the acceleration time in the acceleration control of the control device is set to the shortest possible time in the range possible in the characteristics of the stepping motor.

  Furthermore, in the present invention (the invention according to claim 4), the first switching controlled by the control device is switching between the light distribution pattern for passing and the light distribution pattern for highway, and the second switching controlled by the control device. The switching is switching between the passing light distribution pattern and the traveling light distribution pattern, or switching between the highway light distribution pattern and the traveling light distribution pattern.

  The vehicle headlamp of the present invention (the invention according to claim 1) uses a stepping motor instead of a solenoid and a normal motor (for example, a DC motor), and drives and controls the stepping motor by a control device. . That is, the vehicle headlamp according to the present invention (the invention according to claim 1) performs the first switching by controlling the driving of the stepping motor at the rated current or the constant speed control by the control action of the control device. The second switching can be performed by controlling the driving of the stepping motor at a current value larger than the value or by acceleration control. For this reason, the vehicle headlamp of the present invention (the invention according to claim 1) has at least two switching (first switching and second switching) of a plurality of light distribution patterns, and one of the switching ( When the switching speed is more important than the second switching (the first switching), the switching speed of one of the switching devices is set to a predetermined value without increasing the size of the stepping motor by driving control of the stepping motor of the control device. And the switching speed can be controlled appropriately.

  In the vehicle headlamp of the present invention (the invention according to claim 2), since the shade switching device has a mechanism for preventing the posture of the switched shade from returning, the control device can perform the first switching and the first switching. Even when the current supply to the stepping motor is interrupted when the two switching is completed, the position of the shade can be fixed. For this reason, the vehicle headlamp according to the present invention (the invention according to claim 2) cuts off the current when the switching is completed, so that the self-heating of the stepping motor can be prevented and the durability of the stepping motor is maintained. Power consumption can be suppressed.

  Further, in the vehicle headlamp according to the present invention (the invention according to claim 3), the acceleration time in the acceleration control of the control device is set to the shortest possible time in the range of the characteristics of the stepping motor. The speed can be further increased, and the switching feeling of the second switching can be improved.

  Furthermore, the vehicle headlamp according to the present invention (the invention according to claim 4) switches between the light distribution pattern for passing and the light distribution pattern for expressway by the first switching under the control of the control device. Switching between the light distribution pattern for driving and the light distribution pattern for traveling, or switching between the light distribution pattern for highways and the light distribution pattern for traveling is performed by the second switching. For this reason, the vehicle headlamp according to the present invention (the invention according to claim 4) is configured to switch between the first switching light distribution pattern and the highway light distribution pattern (the other switching). Switching of light distribution pattern in which switching speed is important, that is, switching between the light distribution pattern for passing in the second switch and the light distribution pattern for traveling (one switch), or the light distribution pattern for the highway in the second switch And the switching speed (one switching) between the traveling light distribution pattern can be secured at a predetermined speed. As a result, the vehicular headlamp according to the present invention (the invention according to claim 4) is changed from a passing light distribution pattern or a highway light distribution pattern to a traveling light distribution pattern when the vehicle travels at a high speed. Therefore, it is possible to secure a field of view at high speed and contribute to traffic safety.

  Hereinafter, three examples of embodiments of a vehicle headlamp according to the present invention will be described in detail with reference to the accompanying drawings. Note that the present invention is not limited to the embodiments. In the drawing, reference sign “VU-VD” indicates vertical lines on the upper and lower sides of the screen. The symbol “HL-HR” indicates the left and right horizontal lines and the left and right horizontal lines of the screen.

  1 to 14 show Embodiment 1 of a vehicle headlamp according to the present invention. Hereinafter, the configuration of the vehicle headlamp according to the first embodiment will be described. 1 to 4, reference numeral 1 denotes a vehicle headlamp according to the first embodiment. The vehicle headlamp 1 is, for example, a projector-type headlamp. The vehicle headlamp 1 includes a discharge lamp 2 as a light source, a reflector 3, a projection lens (condensing lens) 4, a first shade 5 and a second shade 6 as shades, and a shade switching device 7. The frame member 8, the stopper member 9, the shaft 10, and the control device 100 are provided. The vehicle headlamp 1 includes the discharge lamp 2, the reflector 3, the projection lens 4, the first shade 5, the second shade 6, the shade switching device 7, the frame member 8, and the stopper member 9. A lamp unit is configured by assembling the shaft 10.

  The discharge lamp 2 is a so-called high pressure metal vapor discharge lamp such as a metal halide lamp, a high intensity discharge lamp (HID), or the like. The discharge lamp 2 is detachably attached to the reflector 3 via a socket mechanism 11. The light emitting portion 12 of the discharge lamp 2 is located at or near the first focal point (not shown) of the reflector 3. In addition to the discharge lamp 2, the light source may be a halogen bulb or an incandescent bulb.

  A reflective surface 13 is formed on the inner concave surface of the reflector 3 by vapor deposition of aluminum or silver coating. The reflecting surface 13 of the reflector 3 is a reflecting surface based on an ellipse, such as a rotating ellipsoid or a free-form surface (NURBS surface) based on an ellipse (the vertical cross section in FIGS. 1 to 3 is an ellipse). And a horizontal cross section (not shown) is a parabolic surface or a reflective surface having a deformed parabolic surface). For this purpose, the reflecting surface 13 of the reflector 3 has a first focal point and a second focal point (a focal line on a horizontal section, not shown). The reflector 3 is fixedly held by a frame member 8 such as a holder. The free curved surface (NURBS curved surface) of the reflecting surface 13 of the reflector 3 is a NURBS free curved surface (Non-Uniform Rational B) described in “Mathematical Elemennts for Computer Graphics” (Devid F. Rogers, J Alan Adams). -Spline Surface).

  The projection lens 4 is an aspherical convex lens. The front side of the projection lens 4 forms a convex aspheric surface, while the rear side of the projection lens 4 forms a flat aspheric surface. The projection lens 4 is fixedly held on the frame member 8. Although not shown, the projection lens 4 has a focal plane (meridional image plane) on the object space side in front of the second focal point of the reflecting surface 13 of the reflector 3.

  The first shade 5 and the second shade 6 pass reflected light directed from the reflecting surface 13 of the reflector 3 toward the projection lens 4 with a passing light distribution pattern LP (first light distribution pattern) indicated by a solid line in FIG. A low beam (passing beam) that can be obtained, and a mid beam (highway beam) that can obtain a light distribution pattern MP (second light distribution pattern) for a highway (motorway), also indicated by a dotted line in FIG. 9 is switched to a high beam (traveling beam) from which a traveling light distribution pattern HP (third light distribution pattern) indicated by a two-dot chain line in FIG.

  As shown in FIGS. 1 to 4, the first shade 5 includes a main body portion 14, a front shade portion 15, a rear shade portion 16, an engagement portion 17, and left and right portions provided integrally with the main body portion 14. The stopper portion 18, the left and right sub-reflector portions 19, the lower curved portion 32, and the pressing portion 51 are configured. Small circular through holes 20 are provided on the left and right sides of the left and right sub-reflector portions 19, respectively. The sub-reflector unit 19 has predetermined sub-light distribution patterns (not shown) disposed at predetermined positions of the passing light distribution pattern LP, the expressway light distribution pattern MP, and the traveling light distribution pattern HP, respectively. A reflecting surface is formed.

  The front shade portion 15 and the rear shade portion 16 are each composed of a substantially rectangular thin plate member that is long in the lateral direction (left and right direction, horizontal direction). A gap is formed between the front shade portion 15 and the rear shade portion 16. A lower horizontal edge for forming an upper horizontal cut-off line, an oblique cut-off line, and a lower horizontal cut-off line on the passing light distribution pattern LP at the upper end edge of the front shade portion 15 and the upper end edge of the rear shade portion 16, respectively. An oblique edge and an upper horizontal edge are provided.

  As shown in FIGS. 1 to 4, the second shade 6 includes a main body portion 21, a shade portion 22 and an engaging portion 23 that are integrally provided on the main body portion 21, left and right stopper portions 24, and left and right portions. And the bent portion 25. Small circular through holes 26 are respectively provided on the left and right sides of the left and right bent portions 25.

  The shade portion 22 is composed of a substantially rectangular thin plate member that is long in the lateral direction (left-right direction, horizontal direction). The shade portion 22 is disposed in a gap between the front shade portion 15 and the rear shade portion 16 of the first shade 5. The upper edge of the shade portion 22 is provided with a lower horizontal edge, an oblique edge, and an upper horizontal edge for forming an upper horizontal cutoff line, an oblique cutoff line, and a lower horizontal cutoff line of the expressway light distribution pattern MP, respectively. It has been.

  The frame member 8 holds and fixes the projection lens 4 as shown in FIGS. Slits 27 are provided at substantially the center of the left and right side walls of the frame member 8, respectively. Further, swivel shafts 28 are integrally provided at substantially the center of the upper and lower walls of the frame member 8, respectively.

  As shown in FIGS. 1 to 4, the stopper member 9 has a rectangular shape. Slits 29 are respectively provided at substantially the left and right centers of the stopper member 9 so as to correspond to the slits 27 of the frame member 8. Moreover, the stopper part 30 is integrally provided in the lower part of the left and right of the said stopper member 9, respectively.

  The frame member 8 and the stopper member 9 are integrally attached by screws (not shown). The reflector 3 is integrally attached to the frame member 8 and the stopper member 9 by screws (not shown).

  The shaft 10 has a circular cross section as shown in FIGS. Flat portions 31 are respectively provided at both left and right ends of the shaft 10. The flat portion 31 of the shaft 10 is fixed to the slit 27 of the frame member 8 and the slit 29 of the stopper member 28, respectively.

  The first shade 5 and the second shade 6 are rotatably attached to the shaft 10. That is, both left and right circular end portions of the shaft 10 are rotatably inserted into the through hole 20 of the first shade 5 and the through hole 26 of the second shade 6, respectively. As a result, the first shade 5 and the second shade 6 are attached to the reflector 3, the frame member 8, and the stopper member 9 via the shaft 10 so that their postures can be switched.

  In the first shade 5, the front shade portion 15, the rear shade portion 16, and the push portion 51 are located on the rear side (the reflector 3 side) with respect to the shaft 10, while the engagement portion 17, the stopper portion 18, and the bending portion 32 are located on the front side (the projection lens 4 side) with respect to the shaft 10. In the second shade 6, the shade portion 22 is located on the rear side (the reflector 3 side) with respect to the shaft 10, while the engaging portion 23 and the stopper portion 24 are located on the shaft 10. Is located on the front side (projection lens 4 side).

  The shade switching device 7 includes a spring 33, a stepping motor 34, a screw conversion mechanism 35, and an advance / retreat rod 36. The shade switching device 7 changes the postures of the first shade 5 and the second shade 6 into a plurality of light distribution patterns (the light distribution pattern LP for passing, the light distribution pattern MP for highways, and the light distribution for traveling). The pattern HP) is switched to a plurality of postures (low beam posture, mid beam posture, and high beam posture). In addition, the said stepping motor 34 uses what is generally used for vehicles, or for vehicle headlamps.

  The stepping motor 34, the screw conversion mechanism 35, and the advance / retreat rod 36 constitute a motor unit. That is, as shown in FIGS. 1 to 5, the stepping motor 34 is attached to the first bracket 38 by a screw 37. A second bracket 40 is attached to the first bracket 38 by a screw 39. Both end portions of the advance / retreat rod 36 are attached to the first bracket 38 and the second bracket 40 via bearings 41 so as to advance and retract. The first bracket 38 is attached to the frame member 8 by a screw (not shown). Thus, the motor unit including the stepping motor 34, the screw conversion mechanism 35, and the advance / retreat rod 36 is assembled to the reflector 3, the frame member 8, the stopper member 9, and the shaft 10. At this time, since the advance / retreat direction of the advance / retreat rod 36 intersects the optical axes of the projection lens 4 and the reflection surface 13, the motor unit can be compactly assembled to the frame member 8 or the like.

  An input gear 43 is engaged with the output gear 42 of the stepping motor 34. A female screw 44 is provided at the center of the input gear 43. On the other hand, a male screw 45 is provided at an intermediate portion of the advance / retreat rod 36. The female screw 44 and the male screw 45 are engaged with each other to constitute the screw conversion mechanism 35. The screw conversion mechanism 35 constitutes a mechanism that prevents the postures of the switched first shade 5 and second shade 6 from returning. The advance / retreat rod 36 is integrally provided with a rotation stopper 46. The anti-rotation portion 46 is attached to the second bracket 40 so as not to rotate and to be movable in the advance / retreat direction of the advance / retreat rod 36. As a result, the advance / retreat rod 36 is advanced / retracted via the screw conversion mechanism 35 by driving the stepping motor 34 to change the postures of the first shade 5 and the second shade 6 together with the spring 33 into a plurality of postures (low beam). (Posture, mid beam posture, high beam posture). At this time, the advance / retreat rod 36 advances and retracts via the screw conversion mechanism 35 constituted by the female screw 44 and the male screw 45. As a result, the advance / retreat rod 36 is not reversed (advanced or retracted in the reverse direction) by an external force, so that the postures of the first shade 5 and the second shade 6 can be held without difficulty.

  As shown in FIGS. 4, 6, and 7, the spring 33 includes a central U-shaped fixing portion 47, two left and right coil portions 48, and two urging portions 49 at both left and right ends. And is composed of. The two coil portions 48 are wound around the shaft 10. That is, the shaft 10 is inserted through the two coil portions 48. The fixing portion 47 is fixed to the second bracket 40. The two urging portions 49 are in elastic contact with the upper surface of the engagement portion 17 of the first shade 5 and the upper surface of the engagement portion 23 of the second shade 6 and the second transmission portion 61, respectively. ing. As a result, the spring 33 is a so-called torsion spring, and the first shade 5 and the second shade 6 are moved in a predetermined direction, for example, in the direction of the arrow in FIGS. 1 to 3, 6, and 7. Always energize.

  The curved portion 32 of the first shade 5 urged by the spring 33 is in direct contact with one end (upper end) of the advance / retreat rod 36. The force of the spring 33 is transmitted to the advance / retreat rod 36 through the first shade 5 and acts in the direction opposite to the extension direction of the advance / retreat rod 36 (the arrow direction in FIGS. 1 to 3). The force of the spring 33 has a predetermined force that can suppress vibration applied to the first shade 5 and the second shade 6. For example, the force of the spring 33 is greater than the force generated when a vibration of 4.5 G or more is applied to the center of gravity of the first shade 5 and the second shade 6.

  As shown in FIG. 10, the stepping motor 34 of the shade switching device 7 is connected to a light distribution pattern changeover switch 101 and a vehicle running state detection unit 102 such as a vehicle speed sensor or an acceleration sensor via the control device 100. Yes. The light distribution pattern changeover switch 101 outputs an external changeover operation signal 103 to the control device 100 by a manual changeover operation of a driver. The vehicle running state detection unit 102 detects a running state of the vehicle (for example, a vehicle speed state or a vehicle acceleration state) and outputs the detection signal to the control device 100 as an external switching operation signal 103. It is.

  The control device 100 is a control device dedicated to the vehicle headlamp 1, and is a slave ECU or a sub CPU with respect to a vehicle-side control device (for example, a master ECU or a main CPU). As shown in FIG. 10, the control device 100 includes a control unit 104 and a motor drive unit 105. The control unit 104 outputs a pulse drive switching drive signal 106 to the motor drive unit 105 based on the external switching operation signal 103. The motor drive unit 105 drives the stepping motor 34 based on the switching drive signal 106. As a result, the stepping motor 34 is driven to move the advance / retreat rod 36 forward and backward, and the postures of the first shade 5 and the second shade 6 are adjusted by the advance / retreat action of the advance / retreat rod 36 and the spring action of the spring 33. It can be switched to a plurality of postures (low beam posture, mid beam posture, high beam posture). The postures of the first shade 5 and the second shade 6 may be switched manually by the light distribution pattern switching switch 101, automatically switched by the vehicle running state detection unit 102, or a combination of both. But it ’s okay.

  That is, as shown in FIG. 1, when the stepping motor 34 is driven and the advance / retreat rod 36 is located at the first position (retracted or contracted). At this time, the first shade 5 and the second shade 6 are urged in a predetermined direction by the urging action of the two urging portions 49 of the spring 33, and FIG. As shown, the stopper portion 18 of the first shade 5 and the stopper portion 24 of the second shade 6 are in elastic contact with the stopper portion 30 of the stopper member 9, respectively. Accordingly, the first shade 5 and the second shade 6 are in a low beam posture, and the passing light distribution pattern LP is obtained. At this time, the action of the spring 33, the action of the stoppers 18, 24, and 30 and the curved part 32 of the first shade 5 are in direct elastic contact with the tip of the advance / retreat rod 36 by the spring force FL. By the action, the first shade 5 and the second shade 6 can hold the low beam posture without any difficulty. Further, the pressing portion 52 of the first shade 5 is not in contact with the main body portion 21 of the second shade 6.

  Further, as shown in FIG. 2, when the stepping motor 34 is driven and the advance / retreat rod 36 is located at the second position (a state located at a substantially intermediate position). At this time, only the first shade 5 rotates against the spring force of the spring 33 in the direction of the white arrow in FIGS. 2 and 8B, and the stopper portion 18 of the first shade 5 moves. The stopper member 24 is separated from the stopper portion 30 of the stopper member 9, while the stopper portion 24 of the second shade 6 is in elastic contact with the stopper portion 30 of the stopper member 9. As a result, the first shade 5 and the second shade 6 are in a mid-beam posture, and the light distribution pattern MP for the highway is obtained. At this time, the action of the spring 33, the action of the stoppers 24 and 30, and the action of the curved portion 32 of the first shade 5 directly elastically contacting the tip of the advance / retreat rod 36 with a spring force FM. Thus, the first shade 5 and the second shade 6 can hold the mid-beam posture without any difficulty. Further, the pressing portion 52 of the first shade 5 is in a state of being in contact with the main body portion 21 of the second shade 6.

  Further, as shown in FIG. 3, when the stepping motor 34 is driven and the advance / retreat rod 36 is located at the third position (advancing state or extending state). At this time, the pressing portion 52 of the first shade 5 abuts on the main body portion 21 of the second shade 6, and the first shade 5 and the second shade 6 resist the spring force of the spring 33. The stopper portion 18 of the first shade 5 and the stopper portion 24 of the second shade 6 are respectively rotated from the stopper portion 30 of the stopper member 9 by rotating in the directions indicated by white arrows in FIGS. is seperated. Accordingly, the first shade 5 and the second shade 6 are in a high beam posture, and the travel light distribution pattern HP is obtained. At this time, due to the action of the spring 33 and the action in which the bending portion 32 of the first shade 5 is in direct elastic contact with the tip of the advance / retreat rod 36 by a spring force FH, the first shade 5 and the first shade 5 The two shades 6 can hold the high beam posture without any hesitation.

  Here, the bending portion 32 of the first shade 5 is always in direct elastic contact with the tip of the advance / retreat rod 36 by spring forces FL, FM, FH. For this reason, when the forward / backward rod 36 advances and retracts and the postures of the first shade 5 and the second shade 6 are switched, the curved portion 32 of the first shade 5 makes line contact with the tip of the forward / backward rod 36. Therefore, the durability of the bending portion 32 and the advance / retreat rod 36 is improved.

  FIG. 11 shows the rotation angle of the first shade 5 and the second shade 6 (that is, the switched light distribution pattern LP, MP, HP mode) and the first shade 5 in the vehicle headlamp 1. FIG. 6 is an explanatory diagram showing a relative relationship between the rotational load of the second shade 6 (that is, the holding force of the spring 33). The vertical axis indicates the shade rotation load (spring holding force), and the shade rotation load (spring holding force) increases from bottom to top. The horizontal axis indicates the shade rotation angle (light distribution mode), and the shade rotation angle increases from left to right.

  In FIG. 11, the present project structure (three functions) indicated by a solid line A indicates that the first shade 5 and the second shade 6 are placed between a low beam posture (see FIG. 1) and a mid beam posture (see FIG. 2). And the shade rotation load (spring holding force) and shade rotation of the vehicle headlamp 1 rotated between the low beam posture and the high beam posture (see FIG. 3) and between the mid beam posture and the high beam posture. The relative relationship with an angle (light distribution mode) is shown. Further, the conventional structure (two functions) indicated by a broken line B is a shade rotation load (spring) of a vehicle headlamp that rotates one shade between a low beam posture (see FIG. 1) and a high beam posture (see FIG. 3). The relative relationship between holding force) and shade rotation angle (light distribution mode) is shown.

  In the horizontal axis of FIG. 11, “Lo” is a shade rotation angle when the first shade 5 and the second shade 6 or one shade is in a low beam posture (see FIG. 1), and “Motorway” is The shade rotation angle, “Hi”, when the first shade 5 and the second shade 6 are in the mid-beam posture (see FIG. 2) is the “shade rotation angle”, the first shade 5 and the second shade 6 or one shade. The shade rotation angle when in the high beam posture (see FIG. 1) is shown. On the vertical axis, “FL” indicates shade rotation load (spring holding force) when the first shade 5 and the second shade 6 or one shade is in a low beam posture (see FIG. 1), “FM "Is the shade rotation load (spring holding force) when the first shade 5 and the second shade 6 are in the mid-beam posture (see FIG. 2), and" FH '"is one shade in the high-beam posture ( (See FIG. 3) The shade rotation load (spring holding force), “FH” is the shade rotation load (spring) when the first shade 5 and the second shade 6 are in the high beam posture (see FIG. 3). Holding force).

  As shown in FIG. 11, the spring 33 is a so-called torsion spring, and the force in the direction opposite to the extending direction of the advance / retreat rod 36 is always applied to the first shade 5 and the second shade 6. (Arrow FL in FIG. 1, arrow FM in FIG. 2, arrow FH in FIG. 3). That is, the spring 33 always applies a rotational load to the first shade 5 and the second shade 6 in the direction opposite to the white arrow in FIGS. 2 and 3. The spring constant of the spring 33 (the spring holding force on the vertical axis in FIG. 11) is proportional to the rotation angle of the first shade 5 and the second shade 6 or one shade on the horizontal axis in FIG. To do. For this reason, when the first shade 5 and the second shade 6 are rotated from the low beam posture (see FIG. 1) to the high beam posture (see FIG. 3), the shade rotation load (spring holding force) increases. Moreover, the vehicular headlamp 1 has a double shade, that is, two shades, the first shade 5 and the second shade 6 from a mid beam posture (see FIG. 2) to a high beam posture (see FIG. 3). Compared with a conventional vehicle headlight with a conventional structure (dual function) indicated by a broken line B in which one shade is rotated from a low beam posture (see FIG. 1) to a high beam posture (see FIG. 3). As indicated by the solid line A, the shade rotation load (spring holding force) is approximately doubled from the stage at which the first shade 5 and the second shade 6 start interlocking. Thus, as shown in the white arrow C in FIG. 11, the load of the vehicle headlamp 1 increases due to the addition of functions.

  FIG. 12 is an explanatory diagram showing a pull-in output characteristic of the stepping motor 34. That is, FIG. 12 is an explanatory diagram showing the relative relationship between the output (vertical axis) of the stepping motor 34 and the rotation speed, that is, the switching speed (horizontal axis) of the light distribution pattern. The vertical axis represents the torque output by the stepping motor 34, that is, the output (mNm millinewton meter), and the output increases from bottom to top. The outputs “FL”, “FM”, “FH ′”, “FH” on the vertical axis represent “FL”, “FM”, “FH ′” on the shade rotation load (spring holding force) on the vertical axis in FIG. ”And“ FH ”, respectively. The horizontal axis indicates the frequency (pps pulse second) of the pulse signal of the switching drive signal 106 that drives the stepping motor 34. The frequency increases from left to right, and the rotation speed of the stepping motor 34 increases.

  In FIG. 12, the point D indicates a point when one shade of the vehicle headlamp having the conventional structure (dual function) indicated by the broken line B in FIG. 11 is switched from the low beam posture to the high beam posture, that is, one shade. A switching mode between the passing light distribution pattern LP and the traveling light distribution pattern HP is shown. At the point D, the output of the stepping motor 34 is “FH ′” (for example, about 4.8 mNm), and the frequency of the stepping motor 34 is “f1” (for example, about 400 pps). Point E is the point when the first shade 5 and the second shade 6 of the vehicle headlamp 1 of the project structure (three functions) of the solid line A in FIG. 11 are switched from the low beam posture to the high beam posture, that is, A switching mode between the passing light distribution pattern LP and the traveling light distribution pattern HP by the first shade 5 and the second shade 6, or the highway by the first shade 5 and the second shade 6 A switching mode between the light distribution pattern MP for driving and the light distribution pattern HP for traveling is shown. At the point E, the output of the stepping motor 34 is “FH” (for example, about 8.0 mNm), and the frequency of the stepping motor 34 is “f2” (for example, about 350 pps).

  As shown in FIG. 11 and FIG. 12, the shade rotation load (spring holding) when the first shade 5 and the second shade 6 of the vehicle headlamp 1 indicated by the solid line A are switched from the low beam posture to the high beam posture. Force) and the output “FH” of the stepping motor 34 are the shade rotation load (spring holding force) when switching one shade of the vehicle headlamp indicated by the broken line B from the low beam posture to the high beam posture, and the stepping motor 34. Is larger than the output “FH ′”. For this purpose, as shown in FIG. 12, switching between the passing light distribution pattern LP and the traveling light distribution pattern HP by the first shade 5 and the second shade 6 of the vehicle headlamp 1 is performed. The frequency “f2” of the stepping motor 34 in the mode E or the switching mode E between the highway light distribution pattern MP and the travel light distribution pattern HP by the first shade 5 and the second shade 6 is The frequency is lower than the frequency “f1” of the stepping motor 34 in the switching mode D between the passing light distribution pattern LP and the traveling light distribution pattern HP by one shade. As a result, the switching speed between the light distribution pattern LP for passing and the light distribution pattern HP for traveling by the first shade 5 and the second shade 6 of the vehicle headlamp 1 or the first shade 5 The switching speed between the highway light distribution pattern MP and the travel light distribution pattern HP by the second shade 6 is the same as the passing light distribution pattern LP and the travel light distribution pattern HP by one shade. Slower than the switching speed. Thus, as shown in the white arrow F in FIG. 12, the vehicle headlamp 1 decreases the switching speed of the light distribution pattern by adding a function.

  In FIG. 12, as indicated by a point G, the output of the stepping motor 34 when the first shade 5 and the second shade 6 of the vehicle headlamp 1 are switched from the low beam posture to the mid beam posture. “FM” is smaller than the output “FH ′” of the stepping motor 34 when one shade is switched from the low beam posture to the high beam posture. For this purpose, the switching speed between the passing light distribution pattern LP and the highway light distribution pattern MP by the first shade 5 and the second shade 6 of the vehicle headlamp 1 is set to a predetermined switching speed. For example, it can be set slower than the switching speed between the light distribution pattern LP for passing and the light distribution pattern MP for highway by one shade.

  Here, when the vehicle travels at high speed, in order to secure a field of view at high speed, the light distribution pattern HP for passing from the light distribution pattern LP for highway or the light distribution pattern MP for highway at high speed is used. It is necessary to switch. To this end, switching between the passing light distribution pattern LP and the traveling light distribution pattern HP in the second switching (one switching), or the expressway light distribution pattern MP in the second switching and the traveling In switching (one switching) to the light distribution pattern HP, switching speed is more important than switching between the passing light distribution pattern LP and the highway light distribution pattern MP in the first switching (the other switching). The

  Therefore, as shown in FIG. 13, the control device 100 drives and controls the stepping motor 34 with a rated current to perform the first switching between the light distribution pattern LP for passing and the light distribution pattern MP for highway. The second switching between the passing light distribution pattern LP and the traveling light distribution pattern HP by driving and controlling the stepping motor 34 with an overdrive having a current value larger than a rated current value, or the expressway The second switching between the light distribution pattern MP for driving and the light distribution pattern HP for traveling is performed. Accordingly, the vehicle headlamp 1 is configured so that the switching speed between the passing light distribution pattern LP and the traveling light distribution pattern HP by the first shade 5 and the second shade 6 or the first shade is changed. 5 and the second shade 6 are switched between the light distribution pattern MP for the highway and the light distribution pattern HP for travel, and the light distribution pattern LP for passing and the light distribution pattern HP for travel by one shade. And switching speed. Hereinafter, the control of the control device 100 will be described with reference to FIG.

  FIG. 13 shows the pull-in output characteristics of the stepping motor 34 in the case of the rated current and the case of overdrive (the current value is larger than the rated current value), as in FIG. It is explanatory drawing. The vertical and horizontal axes are the same as the vertical and horizontal axes in FIG. In FIG. 13, the same reference numerals as those in FIG. 12 denote the same components. The solid curve in FIG. 13 shows the pull-in output characteristics of the stepping motor 34 in the case of the rated current as in FIG. A dotted line curve indicates a pull-in output characteristic of the stepping motor 34 in the case of overdrive.

  In general, a stepping motor has a certain width in a supply current value. The width of the supply current value in the stepping motor 34 that is widely used for vehicles or for vehicle headlamps is about 400 mA to about 600 mA in consideration of heat generation durability. The vehicle headlamp 1 sets the current value of the rated current to about 400 mA with low power consumption, while the overdrive current value is set to about 600 mA, which is about 1.55 times the rated current value. .

  The control device 100 performs the second switching between the passing light distribution pattern LP and the traveling light distribution pattern HP, or the second switching between the highway light distribution pattern MP and the traveling light distribution pattern HP. When performing 2 switching, the stepping motor 34 is driven and controlled by overdrive. Then, as shown in FIG. 13, the pull-in output characteristic of the stepping motor 34 changes from the output characteristic indicated by the solid line curve to the output characteristic indicated by the dotted line curve. That is, as shown by the arrow H in FIG. 13, the output is improved by overdriving the current value about 1.55 times the rated current value, that is, by temporarily increasing the current value. As a result, the switching speed between the passing light distribution pattern LP and the traveling light distribution pattern HP by the first shade 5 and the second shade 6, or the first shade 5 and the second shade 6 The switching speed between the light distribution pattern MP for the highway and the light distribution pattern HP for traveling is changed from the frequency f2 at the point E to the frequency f1 at the point I in FIG. 13, that is, the light distribution for passing by one shade. The switching speed between the pattern LP and the traveling light distribution pattern HP can be set. On the other hand, as described above, the switching speed between the passing light distribution pattern LP and the highway light distribution pattern MP by the first shade 5 and the second shade 6 is a predetermined switching speed, for example, one The switching speed between the passing light distribution pattern LP and the expressway light distribution pattern MP (shade D in FIG. 13, frequency f1 at I) and slower switching speed (at point E in FIG. 13). The frequency f2) can be set.

  The control unit 104 of the control device 100 outputs a switching drive signal 106 of a pulse signal of a rated current to the motor driving unit 105 when the external switching operation signal 103 is a signal for performing the first switching, and When the external switching operation signal 103 is a signal for performing the second switching, a switching driving signal 106 of an overdrive pulse signal is output to the motor driving unit 105. The motor drive unit 105 of the control device 100 drives the stepping motor 34 with a rated current based on the switching drive signal 106 of a rated current pulse signal, and switches the overdrive pulse signal switching drive signal 106. Based on the above, the stepping motor 34 is driven by overdrive.

  The control device 100 cuts off the current supply to the stepping motor 34 when the first switching and the second switching are completed. That is, as shown in FIG. 10, the vehicle headlamp 1 includes a position detector 107 that detects the low beam posture, the mid beam posture, and the high beam posture of the first shade 5 and the second shade 6, respectively. The position detection unit 107 includes, for example, an optical sensor, a micro switch, and the like, and detects a low beam attitude, a mid beam attitude, and a high beam attitude of the first shade 5 and the second shade 6, respectively, and outputs a position detection signal 108 to the position detection signal 108. The data is output to the control unit 104 of the control device 100.

  Based on the position detection signal 108, the control unit 104 of the control device 100 determines that the first switch 5 and the second shade 6 are in a low beam posture, a mid beam posture, or a high beam posture, and performs the first switching. Then, it is determined that the second switching has been completed, and the output of the switching drive signal 106 to the motor driving unit 105 is cut off. As a result, the motor drive unit 105 of the control device 100 cuts off the current supply to the stepping motor 34. At this time, the screw conversion mechanism 35 of the shade switching device 7 constitutes a mechanism that prevents the postures of the switched first shade 5 and the second shade 6 from returning. Even if the current supply to is interrupted, the switched postures of the first shade 5 and the second shade 6 can be maintained and fixed without returning to the original posture.

  The first switching is switching from the passing light distribution pattern LP to the expressway light distribution pattern MP, and vice versa, from the expressway light distribution pattern MP to the passing light distribution pattern LP. And. Further, the second switching includes switching from the passing light distribution pattern LP to the traveling light distribution pattern HP, and vice versa, from the traveling light distribution pattern HP to the passing light distribution pattern LP. Switching from the highway light distribution pattern MP to the travel light distribution pattern HP, and vice versa, switching from the travel light distribution pattern HP to the highway light distribution pattern MP. .

  The vehicle headlamp 1 according to the first embodiment is configured as described above, and the operation thereof will be described below.

  First, the discharge lamp 2 is turned on. Then, the light from the discharge lamp 2 is reflected by the reflecting surface 13 of the reflector 3. The reflected light is collected at the second focal point of the reflecting surface 13 of the reflector 3, diffused through the second focal point, and projected forward (radiated and irradiated) through the projection lens 4. The projection light (radiated light, irradiation light) is a low beam (passing beam) from which a passing light distribution pattern LP (first light distribution pattern) shown by a solid line in FIG. 9 is obtained, or a dotted line in FIG. The light distribution pattern HP (the second light distribution pattern) shown in FIG. 9 as a mid beam (highway beam) from which a highway (motorway) light distribution pattern MP (second light distribution pattern) is obtained is shown. Each is projected forward as a high beam (running beam) from which (three light distribution patterns) can be obtained.

  Here, when the control device 100 drives the stepping motor 34 based on the external switching operation signal 103 to position the advance / retreat rod 36 in the first position, the advance / retreat action of the advance / retreat rod 36 and the action of the spring 33 cause the first The postures of the first shade 5 and the second shade 6 are switched to the low beam posture. As a result, a passing light distribution pattern LP (first light distribution pattern) indicated by a solid line in FIG. 9 is obtained.

  Further, when the control device 100 drives the stepping motor 34 based on the external switching operation signal 103 to position the advance / retreat rod 36 in the second position, the advance / retreat action of the advance / retreat rod 36 and the action of the spring 33 cause the first The postures of the shade 5 and the second shade 6 are switched to the mid-beam posture. As a result, a highway (motorway) light distribution pattern MP (second light distribution pattern) indicated by a dotted line in FIG. 9 is obtained.

  Further, when the control device 100 drives the stepping motor 34 based on the external switching operation signal 103 to position the advance / retreat rod 36 at the third position, the advance / retreat action of the advance / retreat rod 36 and the action of the spring 33 cause the first The postures of the shade 5 and the second shade 6 are switched to the high beam posture. As a result, a traveling light distribution pattern HP (third light distribution pattern) indicated by a two-dot chain line in FIG. 9 is obtained.

  Furthermore, the control device 100 performs the first switching, that is, switching from the passing light distribution pattern LP to the highway light distribution pattern MP based on the external switching operation signal 103 for performing the first switching, and vice versa. When switching from the highway light distribution pattern MP to the passing light distribution pattern LP, the stepping motor 34 is driven with the rated current. Thereby, the first switching is performed with the pull-in output characteristics of the stepping motor 34 of the solid curve in FIG. The rated current value at this time is about 400 mA in consideration of the heat generation durability of the stepping motor 34 and the like, so that the durability of the stepping motor 34 due to heat generation does not deteriorate.

  Furthermore, the control device 100 performs the second switching, that is, the switching from the passing light distribution pattern LP to the traveling light distribution pattern HP based on the external switching operation signal 103 for performing the second switching, and vice versa. Switching from the light distribution pattern HP for driving to the light distribution pattern LP for passing, switching from the light distribution pattern MP for highways to the light distribution pattern HP for traveling, and vice versa. When switching to the pattern MP, the stepping motor 34 is driven by overdrive. Thereby, the second switching is performed with the pull-in output characteristics of the stepping motor 34 of the dotted curve in FIG. The overdrive current value at this time is about 600 mA in consideration of the heat generation durability of the stepping motor 34 and the like, so there is no possibility that the durability of the stepping motor 34 due to heat generation is deteriorated.

  Furthermore, the control device 100 completes the first switching and the second switching based on the position detection signal 108 when the first shade 5 and the second shade 6 are positioned in the low beam posture, the mid beam posture, or the high beam posture. Therefore, the output of the switching drive signal 106 to the motor drive unit 105 is cut off, and the current supply to the stepping motor 34 is cut off.

  FIG. 14 is a flowchart showing a control process of the control device 100. Hereinafter, the control process of the control device 100 will be described with reference to the flowchart of FIG.

  The operation of the control device 100 is started. Then, the control apparatus 100 inputs the external switching operation signal 103 from the light distribution pattern switching switch 101 or the vehicle running state detection unit 102 (inputting the external switching operation signal 103 S1). The control device 100 determines whether the input external switching operation signal 103 is a signal for performing the first switching or a signal for performing the second switching (is the external switching operation signal 103 a signal for performing the second switching? S2). .

  In S2, when the input external switching operation signal 103 is a signal for performing the second switching, the control device 100 drives the stepping motor 34 by overdrive (drives the stepping motor 34 by overdrive S3). In S2, the control device 100 drives the stepping motor 34 at the rated current (drives the stepping motor 34 at the rated current S4) when the input external switching operation signal 103 is a signal for performing the first switching. .

  Then, the control device 100 determines whether the first switching or the second switching is completed based on whether the position detection signal 108 is input from the position detection unit 107 (whether the position detection signal 108 is input). S5). If the position detection signal 108 is not input in S5, the control device 100 determines that the first switching or the second switching has not been completed yet, and returns to S3 or S4.

  If the position detection signal 108 is input in S5, the control device 100 determines that the first switching or the second switching has been completed, and interrupts the current supply to the stepping motor 34 (stepping). Shut off the current supply to the motor 34 S6). Thereby, the operation of the control device 100 ends.

  The vehicle headlamp 1 according to the first embodiment is configured and operated as described above, and the effects thereof will be described below.

  The vehicular headlamp 1 according to the first embodiment uses a stepping motor 34 instead of a solenoid and a normal motor (for example, a DC motor), and the control device 100 controls driving of the stepping motor 34. That is, the vehicular headlamp 1 according to the first embodiment performs the first switching by controlling the stepping motor 34 with the rated current by the control action of the control device 100, and has a current value larger than the rated current value. The second switching can be performed by drivingly controlling the stepping motor 34 by overdrive.

  For this reason, in the vehicle headlamp 1 according to the first embodiment, switching of a plurality of light distribution patterns is performed for the first switching between the light distribution pattern LP for passing and the light distribution pattern MP for highway, and for passing. The second switching between the light distribution pattern LP and the traveling light distribution pattern HP, or the second switching between the highway light distribution pattern MP and the traveling light distribution pattern HP. In this case, the vehicular headlamp 1 according to the first embodiment has a switching speed with respect to switching between the first switching light distribution pattern LP and the highway light distribution pattern MP (the other switching). Switching of the light distribution pattern where importance is attached, that is, switching between the light distribution pattern LP for passing in the second switching and the light distribution pattern HP for traveling (one switching), or the light distribution pattern for the highway of the second switching The switching speed of switching between MP and traveling light distribution pattern HP (one switching) can be ensured at a predetermined speed as shown from frequency f2 at point E to frequency f1 at point I in FIG. . As a result, the vehicular headlamp 1 according to the first embodiment has a predetermined light distribution pattern HP from the passing light distribution pattern LP or the highway light distribution pattern MP when the vehicle travels at a high speed. Since switching is performed at the speed (frequency f1 in FIG. 13), a field of view in high-speed traveling can be ensured, which can contribute to traffic safety.

  As described above, the vehicular headlamp 1 according to the first embodiment has the control device 100 when one switching (second switching) is more important than the other switching (first switching). By controlling the driving of the stepping motor 34, one of the switching speeds can be secured at a predetermined speed without increasing the size of the stepping motor 34, and the switching speed can be appropriately controlled.

  Further, the vehicle headlamp 1 according to the first embodiment constitutes a mechanism that prevents the screw conversion mechanism 35 of the shade switching device 7 from returning the postures of the switched first shade 5 and second shade 6. Therefore, even if the control device 100 cuts off the current supply to the stepping motor 34 when the first switching and the second switching are completed, the switched postures of the first shade 5 and the second shade 6 are maintained. The posture can be maintained and fixed without returning to the original posture. For this reason, since the vehicle headlamp 1 according to the first embodiment cuts off the current when the switching is completed, self-heating of the stepping motor 34 can be prevented, and the durability of the stepping motor 34 can be maintained. , Power consumption can be suppressed.

  FIGS. 15-17 shows Example 2 of the vehicle headlamp according to the present invention. In the figure, the same reference numerals as those in FIGS. 1 to 14 denote the same components.

  As shown in FIGS. 15 to 17, the vehicle headlamp control device 100 according to the second embodiment is used for passing by controlling the stepping motor 34 by constant speed control instead of the rated current of the first embodiment. First switching between the light distribution pattern LP and the highway light distribution pattern MP is performed, and the stepping motor 34 is driven and controlled by acceleration control instead of the overdrive of the first embodiment, thereby passing the light distribution pattern LP for passing and the distribution for traveling. The second switching between the light pattern HP or the second switching between the highway light distribution pattern MP and the travel light distribution pattern HP is performed. Thereby, the vehicle headlamp according to the second embodiment has a switching speed between the passing light distribution pattern LP and the traveling light distribution pattern HP by the first shade 5 and the second shade 6 or the first shade 5. The switching speed between the highway light distribution pattern MP and the traveling light distribution pattern HP by the second shade 6 is changed to the switching speed between the passing light distribution pattern LP and the traveling light distribution pattern HP by one shade. be able to. Hereinafter, control of the control apparatus 100 according to the second embodiment will be described with reference to FIGS. 15 and 16.

  FIG. 15 is an explanatory diagram illustrating a pull-in output characteristic and a pull-out output characteristic of the stepping motor 34 used in the vehicle headlamp according to the second embodiment. The vertical axis in FIG. 15 indicates the torque (mNm millinewton meter) output by the stepping motor 34, and the torque increases from bottom to top. The horizontal axis of FIG. 15 indicates the frequency f (pps pulse second) of the pulse signal of the switching drive signal 106 that drives the stepping motor 34. The frequency increases from left to right, and the rotation speed of the stepping motor 34 increases. .

  In FIG. 15, the pull-in output characteristics of the stepping motor 34 are output characteristics obtained when the stepping motor 34 is driven and controlled by constant speed control. On the other hand, the pull-out output characteristic of the stepping motor 34 is an output characteristic obtained when the stepping motor 34 is driven and controlled by acceleration control. Further, the “necessary output FH” on the vertical axis in FIG. 15 indicates the second switching between the passing light distribution pattern LP and the traveling light distribution pattern HP, or the highway light distribution pattern MP and the traveling light distribution pattern. For the second switching with the HP, that is, to change the posture of the first shade 5 and the second shade 6 between the low beam posture and the high beam posture, or for switching between the mid beam posture and the high beam posture. The output of the required stepping motor 34 is shown. Further, the “starting frequency f3” on the horizontal axis in FIG. 15 indicates the frequency for driving the stepping motor 34 and the acceleration control when the stepping motor 34 is driven and controlled at a constant speed to perform the first switching. The frequency for starting the stepping motor 34 when the second switching is performed by controlling the driving of the stepping motor 34 is shown. Furthermore, the “operating frequency f4” on the horizontal axis in FIG. 15 is determined by accelerating the stepping motor 34 gradually from the starting time at the constant speed when the stepping motor 34 is driven and controlled by acceleration control. Indicates the frequency for driving. Furthermore, in FIG. 15, the point P1 is an intersection of the required output FH and the starting frequency f3 on the pull-in output characteristics of the stepping motor 34. Furthermore, in FIG. 15, the point P2 is an intersection of the required output FH and the operating frequency f4 on the output characteristics of the pull-out of the stepping motor 34.

  FIG. 16A shows the second switching between the passing light distribution pattern LP and the traveling light distribution pattern HP by driving and controlling the stepping motor 34 at a constant speed control, or the highway light distribution pattern MP and the traveling light. It is explanatory drawing which shows switching time t1 of 2nd switching with the light distribution pattern HP. The vertical axis in FIG. 16A indicates the frequency f (pps pulse second) of the pulse signal of the switching drive signal 106 that drives the stepping motor 34. The frequency increases from the bottom to the top, and the rotation speed of the stepping motor 34 is increased. Will be faster. The horizontal axis in FIG. 16A represents the time for driving the stepping motor 34, the second switching time t between the passing light distribution pattern LP and the traveling light distribution pattern HP, or the highway light distribution pattern MP. The second switching time t (s second) between the driving light distribution pattern HP and the driving time and switching time become longer from left to right.

  When the stepping motor 34 is driven and controlled by constant speed control to perform the second switching, the frequency becomes constant at the starting frequency f3 at the point P1 on the pull-in output characteristics of FIG. For this reason, as shown in FIG. 16A, the switching time t for performing the second switching is t1. That is, by driving the stepping motor 34 at a time t1 with a pulse having a constant starting frequency f3, the advance / retreat rod 36 moves between the first position shown in FIG. 1 and the third position shown in FIG. 3, or in FIG. The position of the first shade 5 and the second shade 6 is changed between the low beam position and the high beam by moving forward (stretching) or retracting (shrinking) between the second position shown in FIG. 3 and the third position shown in FIG. The light distribution pattern is switched between the posture, the mid beam posture and the high beam posture, and the light distribution pattern is between the light distribution pattern LP for passing and the light distribution pattern HP for traveling, or the light distribution for highways. Switching between the pattern MP and the traveling light distribution pattern HP is performed. In FIG. 16A, the area of the pulse number of a horizontally long rectangle (the surface on which dots are given) is between the first position shown in FIG. 1 and the third position shown in FIG. 2 shows the distance advanced (extended) or retracted (shrinked) between the second position shown in FIG. 2 and the third position shown in FIG. The distance (the area of the horizontally long rectangle) is a product of the frequency f3 of the pulse supplied to the stepping motor 34 and the time t1 for supplying the pulse of the frequency f3 to the stepping motor 34. As described above, when the second switching is performed by drivingly controlling the stepping motor 34 with the constant speed control, the time required for the second switching is t1.

  Here, the activation frequency f3 at the point P1 in FIG. 15 is substantially the same as the frequency f2 at the point E in FIGS. For this reason, the second switching speed performed by controlling the stepping motor 34 by constant speed control is slower than the switching speed between the passing light distribution pattern LP and the traveling light distribution pattern HP by one shade. .

  Therefore, as shown in FIGS. 15 and 16B, the control device 100 performs the second switching between the passing light distribution pattern LP and the traveling light distribution pattern HP by drivingly controlling the stepping motor 34 by acceleration control. Alternatively, the second switching between the highway light distribution pattern MP and the travel light distribution pattern HP is performed.

  FIG. 16B shows the second switching between the passing light distribution pattern LP and the traveling light distribution pattern HP by driving and controlling the stepping motor 34 by acceleration control, or the expressway light distribution pattern MP and the traveling distribution. It is explanatory drawing which shows switching time t2 of 2nd switching with the light pattern HP. The vertical axis in FIG. 16B indicates the frequency f (pps pulse second) of the pulse signal of the switching drive signal 106 for driving the stepping motor 34. The frequency increases from the bottom to the top, and the rotation speed of the stepping motor 34 is increased. Will be faster. The horizontal axis of FIG. 16B represents the time for driving the stepping motor 34, the second switching time between the passing light distribution pattern LP and the traveling light distribution pattern HP, or the highway light distribution pattern MP. The second switching time t (s second) with the traveling light distribution pattern HP is shown, and the driving time and switching time become longer from left to right.

  In the acceleration control by the control device 100, first, the stepping motor 34 is activated at the activation frequency f3 at the point P1 in FIG. 15, and then the frequency f is increased to accelerate the rotation speed of the stepping motor 34. This is control for driving the stepping motor 34 at a constant speed at the operating frequency f4 when f reaches the operating frequency f4 at the point P2 in FIG. Further, the acceleration time t3 in the acceleration control of the control device 100 is set to the shortest possible range in terms of the characteristics of the stepping motor 34.

  For this reason, as shown in FIG. 16B, the switching time t for performing the second switching is t2. That is, the stepping motor 34 is driven at an acceleration time t3 with an acceleration pulse from the starting frequency f3 to the operating frequency f4, and is driven at a constant speed time (t2-t3) with a constant speed pulse at the operating frequency f4. 36 advances (extends) between the first position shown in FIG. 1 and the third position shown in FIG. 3 or between the second position shown in FIG. 2 and the third position shown in FIG. ) Or retreat (shrink), and the postures of the first shade 5 and the second shade 6 are switched between a low beam posture and a high beam posture, or between a mid beam posture and a high beam posture, and light distribution is performed. The pattern is switched between the passing light distribution pattern LP and the traveling light distribution pattern HP, or between the expressway light distribution pattern MP and the traveling light distribution pattern HP. In FIG. 16B, the area of the pentagonal Pulse number (the surface on which dots are given) is between the first position shown in FIG. 1 and the third position shown in FIG. FIG. 4 shows the distance advanced (extended) or retracted (contracted) between the second position shown in FIG. 2 and the third position shown in FIG. 3. The distance (pentagonal area) is the sum of the trapezoidal area from activation to acceleration time t3 and the area of a vertically long rectangle from acceleration time t3 to switching completion time t4. The area of the trapezoid is obtained by (starting frequency f3 + operation frequency f4) × acceleration time t3 / 2. Further, the area of the vertically long rectangle is obtained by the operation frequency f4 × (switching completion time t4−acceleration time t3). In this way, when the second switching is performed by controlling the stepping motor 34 by acceleration control, the time required for the second switching is t2.

  The area of the horizontally long pulse number in FIG. 16 (A), that is, the advance / retreat distance of the advance / retreat rod 36 and the area of the pentagonal Pulse number in FIG. 16 (B), ie, the advance / retreat distance of the advance / retreat rod 36. ,equal. For this reason, the switching time t2 by the acceleration control in FIG. 16B is shorter than the switching time t1 by the constant speed control in FIG. That is, the switching speed by the acceleration control of FIG. 16 (B) is faster than the switching speed by the constant speed control of FIG. 16 (A). As described above, the vehicle headlamp according to the second embodiment has the switching speed between the passing light distribution pattern LP and the traveling light distribution pattern HP by the first shade 5 and the second shade 6, or the first shade. The switching speed between the highway light distribution pattern MP and the traveling light distribution pattern HP by the 5 and the second shade 6 is changed to the switching speed between the passing light distribution pattern LP and the traveling light distribution pattern HP by one shade. can do.

  FIG. 17 is a flowchart showing a control process of the control device 100. Hereinafter, the control process of the control device 100 will be described with reference to the flowchart of FIG.

  The operation of the control device 100 is started. Then, the control apparatus 100 inputs the external switching operation signal 103 from the light distribution pattern switching switch 101 or the vehicle running state detection unit 102 (inputting the external switching operation signal 103 S11). The control device 100 determines whether the input external switching operation signal 103 is a signal for performing the first switching or a signal for performing the second switching (is the external switching operation signal 103 a signal for performing the second switching? S12). .

  In S12, when the input external switching operation signal 103 is a signal for performing the second switching, the control device 100 drives the stepping motor 34 by acceleration control (drives the stepping motor 34 by acceleration control S13). In S12, when the input external switching operation signal 103 is a signal for performing the first switching, the control device 100 drives the stepping motor 34 with constant speed control (drives the stepping motor 34 with constant speed control). S14).

  Then, the control device 100 determines whether the first switching or the second switching is completed based on whether the position detection signal 108 is input from the position detection unit 107 (whether the position detection signal 108 is input). S15). If the position detection signal 108 is not input in S15, the control device 100 determines that the first switching or the second switching has not been completed yet, and returns to S13 or S14.

  In S15, if the position detection signal 108 is input, the control device 100 determines that the first switching or the second switching is completed, and interrupts the current supply to the stepping motor 34 (stepping). Shut off the current supply to the motor 34 (S16). Thereby, the operation of the control device 100 ends.

  Since the vehicular headlamp according to the second embodiment is configured and operated as described above, substantially the same effects as those of the vehicular headlamp 1 according to the first embodiment can be achieved. In addition, the vehicular headlamp according to the second embodiment sets the acceleration time t3 in the acceleration control of the control device 100 to the shortest possible range in terms of the characteristics of the stepping motor 34. This can further increase the switching feeling of the second switching. In particular, since the vehicle headlamp according to the second embodiment controls the driving of the stepping motor 34 by the acceleration control of the control device 100, the drive control of the stepping motor 34 is easy, and the control device 100 is inexpensive. Can be used.

  18 and 19 show Example 3 of a vehicle headlamp according to the present invention. In the figure, the same reference numerals as those in FIGS. 1 to 17 denote the same components.

  As shown in FIG. 18, the vehicle headlamp control device 100 according to the third embodiment performs the overdrive in the first embodiment and the acceleration control in the second embodiment when performing the second switching. The stepping motor 34 is driven and controlled to perform the second switching. That is, the output characteristics of the pull-in and pull-out of the stepping motor 34 by the overdrive of the current value of about 1.55 times the rated current value are shown from the output characteristics shown by the one-dot chain line curve to the solid curve. Change (offset) the output characteristics to As a result, the starting frequency increases from f3 to f5, and the operating frequency also increases from f4 to f6. Furthermore, the frequency is increased from the overdrive starting frequency f5 to the higher overdrive operating frequency f6 via the operating frequency f4 of the rated current value by acceleration control.

  FIG. 19 is a flowchart showing a control process of the control device 100. Hereinafter, the control process of the control device 100 will be described with reference to the flowchart of FIG.

  The operation of the control device 100 is started. Then, the control apparatus 100 inputs the external switching operation signal 103 from the light distribution pattern switching switch 101 or the vehicle running state detection unit 102 (inputting the external switching operation signal 103 S21). The control device 100 determines whether the input external switching operation signal 103 is a signal for performing the first switching or a signal for performing the second switching (is the external switching operation signal 103 a signal for performing the second switching? S22). .

  In the above-described S22, when the input external switching operation signal 103 is a signal for performing the second switching, the control device 100 drives the stepping motor 34 by overdrive and acceleration control (the stepping motor 34 by overdrive and acceleration control). Is driven S23). In S22, when the input external switching operation signal 103 is a signal for performing the first switching, the control device 100 drives the stepping motor 34 at the rated current or constant speed control (rated current or constant speed control). To drive the stepping motor 34 (S24).

  Then, the control device 100 determines whether the first switching or the second switching is completed based on whether the position detection signal 108 is input from the position detection unit 107 (whether the position detection signal 108 is input). S25). If the position detection signal 108 is not input in S25, the control device 100 determines that the first switching or the second switching has not been completed yet, and returns to S23 or S24.

  In S25, if the position detection signal 108 is input, the control device 100 determines that the first switching or the second switching is completed, and interrupts the current supply to the stepping motor 34 (stepping). Shut off the current supply to the motor 34 (S26). Thereby, the operation of the control device 100 ends.

  Since the vehicular headlamp according to the third embodiment is configured and operated as described above, the vehicular headlamp 1 according to the first embodiment and the vehicular headlamp according to the second embodiment It is possible to achieve substantially the same effect, and further, a synergistic effect of the effect of the vehicle headlamp 1 according to the first embodiment and the effect of the vehicle headlamp according to the second embodiment.

It is a longitudinal cross-sectional view which shows Example 1 of the vehicle headlamp concerning this invention, Comprising: It is a longitudinal cross-sectional view which shows the state when the attitude | position of a 1st shade and a 2nd shade is a low beam attitude | position. Similarly, it is a longitudinal cross-sectional view showing a state when the posture of the first shade and the second shade is a mid-beam posture. Similarly, it is a longitudinal sectional view showing a state when the posture of the first shade and the second shade is a high beam posture. Similarly, it is a disassembled perspective view which shows a component. Similarly, it is a disassembled perspective view which shows a motor unit. Similarly, it is front explanatory drawing which shows the effect | action of a spring. Similarly, it is side surface explanatory drawing which shows the effect | action of a spring. Similarly, it is explanatory drawing which shows the effect | action of the stopper part of a 1st shade and a 2nd shade, and the stopper part of the stopper member 9. FIG. Similarly, it is explanatory drawing which shows the light distribution pattern for passing, the light distribution pattern for highways, and the light distribution pattern for driving | running | working. Similarly, it is a block diagram of the principal part. Similarly, it is explanatory drawing which shows the relative relationship of shade rotation load (spring holding force) and shade rotation angle (light distribution mode). Similarly, it is explanatory drawing which shows the output characteristic of the pull-in (Pull-in) of a stepping motor. Similarly, it is explanatory drawing which shows the output characteristic of the pull-in (Pull-in) of a stepping motor at the time of driving-controlling a stepping motor by overdrive. Similarly, it is a flowchart which shows the control process of a control apparatus. Description of output characteristics of pull-in and pull-out of a stepping motor when the stepping motor is driven and controlled by acceleration control according to the second embodiment of the vehicle headlamp according to the present invention. FIG. Similarly, it is explanatory drawing which shows the switching time at the time of driving-controlling a stepping motor by fixed control, and the switching time at the time of driving-controlling a stepping motor by acceleration control. Similarly, it is a flowchart which shows the control process of a control apparatus. Embodiment 3 of the vehicle headlamp according to the present invention shows the output characteristics of the pull-in of the stepping motor and the output of the pull-out when the stepping motor is driven and controlled by overdrive and acceleration control. It is explanatory drawing of a characteristic. Similarly, it is a flowchart which shows the control process of a control apparatus.

Explanation of symbols

1 Vehicle headlamp 2 Discharge lamp (light source)
DESCRIPTION OF SYMBOLS 3 Reflector 4 Projection lens 5 1st shade 6 2nd shade 7 Shade switching apparatus 8 Frame member 9 Stopper member 10 Shaft 11 Socket mechanism 12 Light emission part 13 Reflecting surface 14 Main body part 15 Front shade part 16 Rear shade part 17 Engagement part DESCRIPTION OF SYMBOLS 18 Stopper part 19 Sub reflector part 20 Through-hole 21 Main body part 22 Shade part 23 Engagement part 24 Stopper part 25 Bending part 26 Through-hole 27 Slit 28 Swivel shaft 29 Slit 30 Stopper part 31 Flat part 32 Bending part 33 Spring 34 Stepping Motor 35 Screw conversion mechanism 36 Advancing and retracting rod 37 Screw 38 First bracket 39 Screw 40 Second bracket 41 Bearing 42 Output gear 43 Input gear 44 Female thread 45 Male screw 46 Non-rotating portion 47 Fixed portion 48 Illuminating part 49 Energizing part 100 Control device 101 Light distribution pattern changeover switch 102 Vehicle running state detection part 103 External switching operation signal 104 Control part 105 Motor drive part 106 Switching drive signal 107 Position detection part 108 Position detection signal LP Light distribution for passing Pattern MP Light distribution pattern for expressway HP Light distribution pattern for driving FL, FM, FH Spring force VU-VD Vertical vertical line HL-HR Horizontal horizontal line

Claims (4)

In a projector type vehicle headlamp that can obtain a plurality of light distribution patterns,
A light source;
A reflector for reflecting light from the light source;
A projection lens that projects the reflected light from the reflector forward;
A shade that switches reflected light from the reflector toward the projection lens to a plurality of beams from which the plurality of light distribution patterns are obtained;
A shade switching device that is composed of a stepping motor and switches the posture of the shade to a plurality of postures from which the plurality of light distribution patterns are obtained;
The switching of the plurality of light distribution patterns has at least a first switching and a second switching, and performs the first switching by controlling the driving of the stepping motor with a rated current or with a constant speed control. A control device that performs the second switching by driving the stepping motor with a large current value or acceleration control;
A vehicle headlamp characterized by comprising: The shade switching device has a mechanism for preventing the switched posture of the shade from returning.
The control device shuts off the current supply to the stepping motor when the first switching and the second switching are completed.
The vehicle headlamp according to claim 1.   3. The vehicle headlamp according to claim 1, wherein an acceleration time in the acceleration control of the control device is set to a shortest time in a range that is possible in terms of characteristics of the stepping motor.   The first switching controlled by the control device is switching between a light distribution pattern for passing and a light distribution pattern for highways, and the second switching controlled by the control device is for switching between a light distribution pattern for passing and a traveling light distribution pattern. The vehicle headlamp according to any one of claims 1 to 3, wherein the vehicle headlamp is a switch between a light distribution pattern or a switch between a light distribution pattern for an expressway and a light distribution pattern for traveling. .

Images