JP3653233B2 - Infrared irradiation lamp for automobiles - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an infrared light irradiation lamp for an automobile that is mounted on an automobile and illuminates the front of the vehicle with infrared light, and more particularly, the infrared light for an automobile used in common with a CCD camera having sensitivity to near infrared. It relates to an irradiation lamp.
[0002]
[Prior art]
For example, in this type of lamp, a visible light source and a reflector are arranged in a lamp chamber defined by a lamp body and a front lens, and an infrared light transmitting glove having a surface coated with an infrared light transmitting multilayer film is used as a visible light source. It is arranged so as to cover, and infrared light that has passed through the globe out of the light source light is reflected by the reflector, is transmitted through the front lens, and is distributed forward.
[0003]
Then, the infrared light irradiation area in front of the vehicle is photographed by a CCD camera having sensitivity up to the near infrared provided at the front of the vehicle, processed by an image processing device, and displayed on a monitor screen in the vehicle interior. The driver can see people, lane marks, and obstacles far away on the monitor screen that displays the field of view in front of the vehicle.
[0004]
[Problems to be solved by the invention]
However, the above-described conventional infrared irradiation lamp has the following problems.
[0005]
First, since the infrared light transmission multilayer film cannot completely cut visible light on the long wavelength side around 700 to 800 nm, the lamp appears to light red. For this reason, there is a possibility that the infrared irradiation lamp provided in the front part of the automobile may be mistaken as a tail lamp or a stop lamp, which is a safety problem.
[0006]
Secondly, in the halogen bulb that is a visible light source, the halogen cycle stops functioning, blacking occurs and the amount of light decreases, or the infrared light transmission multilayer film deteriorates and the infrared cut characteristics are reduced. There was a problem of shortening the life of the infrared light transmitting globe.
[0007]
As a result of the inventors examining these causes, the first problem is that the red light component of visible light (visible light transmitted through the infrared light transmitting globe) that could not be cut by the infrared light transmitting globe is reflected by the reflector. Although guided to the whole, the energy (light flux density) of the light reflected from the light source area around the reflector and emitted from near the center part of the front lens is the highest. It was confirmed that it appeared to emit red light.
[0008]
As for the second problem, since the conventional infrared light transmitting globe is arranged so that the rear end thereof is in contact with the reflector, heat generation of, for example, a halogen bulb which is a visible light source in the infrared light transmitting globe. As a result, it was confirmed that the lifetime of the light source and the infrared light transmitting globe is reduced, such as the occurrence of blacking and a decrease in the amount of light, or the infrared light transmitting multilayer film is thermally deteriorated.
[0009]
Therefore, the inventor thinks that the red light component of the visible light that causes the lamp to appear red may be diluted, so that a gap is provided between the rear end of the infrared light transmitting globe and the reflector, and the light source is emitted from the gap. As a part of the light was led directly to the area around the light source of the reflector, it was confirmed that it was effective in diminishing the reddish hue of the lamp and that heat was not trapped in the infrared light transmitting globe. The present invention has been proposed.
[0010]
The present invention has been made on the basis of the problems of the prior art and the knowledge of the inventor described above. The purpose of the present invention is to provide a gap between the infrared light transmitting globe and the reflector so that the lamp can be turned on. An object of the present invention is to provide an infrared light irradiation lamp that is not mistaken for a tail lamp or a stop lamp and that does not accumulate heat in the infrared light transmitting globe.
[0011]
[Means and Actions for Solving the Problems]
  In order to achieve the object, in the infrared light irradiation lamp according to claim 1, a lamp chamber defined by a lamp body and a front lens, a reflector provided inside the lamp body, and the lamp chamber A light source disposed in front of the reflector, and a cylindrical infrared light forming glove that is disposed so as to cover the light source and shields visible light and transmits only infrared light.With
  Infrared light forming gloveIsArranged so that the rear end is separated from the reflectorBeingLight sourceButDirectly led from the gap between the reflector and the rear end of the infrared light forming globe to the light source peripheral area of the reflector.Be burnedlikeA configured infrared light forming glove,
  In front of the globe for forming infrared light, a light-shielding shade for shielding light source light emitted from the front end side opening of the globe is provided apart from the front end side opening of the globe,
A reflection surface is provided on the back side of the light-shielding shade so as to guide the light source light emitted from the opening on the front end side of the globe directly to the light source peripheral region of the reflector without passing through the globe.
[0012]
In addition to the case where the light distribution of the lamp is formed by controlling the light reflected by the reflector in the light distribution control step provided on the front lens, only the reflector without providing the light distribution control step on the front lens. The front lens without the light distribution control step, that is, a so-called front cover, is also included in the front lens here.
[0013]
  (Function) The red light component of visible light (visible light transmitted through the infrared light forming globe) that could not be cut by the infrared light forming globe is reflected by the entire reflector and emitted from the front lens. The energy (light flux density) of the light reflected from the light source peripheral area of the reflector and emitted from the vicinity of the central portion of the front lens corresponding to the light source peripheral area is the highest. For this reason, conventionally, the vicinity of the center of the front lens (the region corresponding to the light source peripheral region in the reflector) appears to emit light in a red ring shape, but in claim 1, after the reflector and the infrared light forming glove A part of the light source light (the light source light that does not pass through the infrared light forming glove) is guided directly from the gap with the end toward the inside of the reflector's light source peripheral region, and the light source light reflected here (white light) Also, the light emitted from the vicinity of the center of the front lens corresponding to the peripheral area of the light source reduces the luminous flux density of the red light component distributed forward from the vicinity of the center of the front lens and dilutes the red light emission of the lamp. Is done.
In addition, air convection over the inside and outside of the infrared light forming glove is generated through a gap between the reflector and the rear end of the infrared light forming glove, and heat in the glove is dissipated outside the glove. . In addition to the gap between the rear end of the infrared light forming globe and the reflector, a gap is also provided between the shading shade and the front end of the infrared light forming globe (the front and rear ends of the globe open). Thus, air convection over the inside and outside of the infrared light forming globe is likely to be generated, and the air convection in the globe becomes active.
Further, the light-shielding shade provided in front of the infrared light forming globe shields the light source light emitted forward from the opening on the front end side of the globe, thereby preventing the generation of glare light.
[0018]
  Claim2In the claim1The infrared light irradiation lamp according to claim 1, wherein the infrared light forming glove is fixed to the reflector or the light-shielding shade on the outer periphery of the rear end portion of the infrared light forming glove. An annular light shielding portion is provided.
[0019]
(Operation) A part of the red light component of the visible light that passes through the infrared light forming globe and travels toward the region around the light source of the reflector is shielded by an annular light shielding portion provided on the infrared light forming globe. Therefore, the total amount of the red light component guided to the light source peripheral region of the reflector is reduced accordingly, and the red light component emitted from the central region of the front lens is further diluted.
[0020]
In addition, since the infrared light forming glove is gripped in the entire circumferential direction by the annular light shielding portion that is a part of the metal holder, the glove is firmly fixed and held without shaking with respect to the reflector.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described based on examples.
[0022]
1 to 5 show an embodiment in which the present invention is applied to a nighttime front vision detection system, and FIG. 1 shows a nighttime front vision detection system using an infrared light irradiation lamp according to a first embodiment of the present invention. FIG. 2 (a) is a schematic diagram of an image in front of the vehicle appearing on the display, FIG. 2 (b) is a diagram showing the video output signal taken out by the image processing analyzer, and FIG. FIG. 4A is an enlarged vertical sectional view of a bulb peripheral region, which is a main part of the infrared light irradiation lamp, and FIG. 4B is a front view of a bulb insertion hole peripheral region in the reflector. FIG. 5 is a diagram showing a processing flow of the CPU of the control unit that controls the lighting of the infrared light irradiation lamp.
[0023]
As shown in FIG. 1, the nighttime front vision detection system includes a pair of headlamps 8 and an infrared light irradiation lamp 10A provided at the front of the vehicle, and a pair of cameras arranged in the upper part of the vehicle interior for photographing the field of view in front of the vehicle. It is mainly composed of CCD cameras 2A and 2B, an image processing analysis device 4 for analyzing images taken by the CCD cameras 2A and 2B, and a head-up display (HUD) 6 for displaying data analyzed by the image processing analysis device 4. ing.
[0024]
A CCD camera for photographing a vehicle front area is composed of a visible light CCD camera 2A having a sensitivity in the visible light region and an infrared light CCD camera 2B having a sensitivity in the infrared light region, and the object to be viewed in front. It is a stereo camera system that can measure the distance. Then, the images taken by both the CCD cameras 2A and 2B are sent to the image processing analysis device 4 so that the two images are compared.
[0025]
That is, the video output voltage of each scanning line (field) is taken out from the video (image) as shown in FIG. 2A photographed by the CCD camera, and the γ characteristics (photoelectric conversion characteristics) of both cameras 2A and 2B are taken into consideration. Above, it is stored as full screen (or main part) data. This correction is necessary to match the sensitivities of both the cameras 2A and 2B and to obtain substantially the same video output with respect to the object on the road. Then, by taking the difference from the two images and taking out the difference from the video that has a certain threshold value or more, a video of distant pedestrians, obstacles and lane marks can be obtained. Then, by performing edge processing and pattern recognition from the difference video, it is possible to easily recognize pedestrians, obstacles, lane marks, and the like.
[0026]
And images of pedestrians, obstacles and lane marks are shown to the driver with a head-up display (HUD) 6, and features of road objects (pedestrians, obstacles, lane marks, etc.) are judged by shape recognition. It is configured to notify the driver by voice.
[0027]
As the CCD camera for photographing the front area of the vehicle, the sensitivity of the near infrared light region and the infrared light region is changed in place of the two CCD cameras of the visible light compatible CCD camera 2A and the infrared light compatible CCD camera 2B. A single CCD camera may be used.
[0028]
As shown in FIG. 3, the infrared light irradiation lamp 10 </ b> A is assembled in a container-shaped lamp body 12 and a front opening of the lamp body 12, and cooperates with the lamp body 12 to define the lamp chamber S. A front lens 14 formed, a parabolic reflector 16 integrally formed on the inner peripheral surface of the lamp body 12, and a light source inserted in a bulb insertion hole 13 provided in the rear top portion of the lamp body 12. The halogen bulb 20 and the infrared light forming globe 30A disposed so as to surround the bulb 20 are mainly configured.
[0029]
The infrared light forming globe 30A is formed in a cylindrical shape that completely covers the bulb 20, and the infrared light that shields visible light and transmits only infrared light over the entire outer peripheral surface of the cylindrical glass globe body. The structure is provided with a transmissive multilayer film. Therefore, when the bulb 20 is turned on, the light L1 and L2 of the light emitted from the filament 22 toward the reflector 16 is transmitted through the globe 30A, but the visible light is transmitted through the globe 30A (infrared light transmission multilayer film). And only infrared light can pass through the globe 30A (infrared light transmitting multilayer film). For this reason, the infrared light guided to the reflector 16 is reflected as indicated by arrows L1 and L2 in FIG. 3, and passes through the front lens 14 to be distributed forward as light substantially parallel to the optical axis L of the lamp. .
[0030]
In addition, the infrared light forming globe 30A is disposed so that the rear end portion thereof is separated from the reflector 16, and a gap 31 is provided between the globe 30A and the reflector 16, and the gap 31 between the globe 31A and the light source peripheral region 16a of the reflector. A part of the light emission of the bulb 20 (filament 22) is directly guided to dilute the red light emission of the lamp.
[0031]
That is, the red light component of visible light that has not been cut by the infrared light forming globe 30A (visible light that has passed through the infrared light forming globe 30A) is reflected by the entire reflector 16 and emitted from the front lens 14. However, the energy (light flux density) of the light reflected from the light source peripheral region 16a of the reflector and emitted from the vicinity of the center portion of the front lens corresponding to the light source peripheral region 16a (the front view ring-shaped region) 14a is the highest. Therefore, conventionally, the vicinity of the center portion of the front lens (the region corresponding to the light source peripheral region 16a in the reflector) 14a appears to emit light in a red ring shape, but in this embodiment, the reflector 16 and the infrared light formation The light source light L3 (the light source light that does not pass through the infrared light forming glove) L3 is guided directly from the gap 31 with the rear end of the light globe 30A toward the inside of the light source peripheral region 16a of the reflector, and the light source light reflected here (White light) L3 is also emitted from the front lens center vicinity 14a corresponding to the light source peripheral region, and the luminous flux density of the red light component distributed forward from the front lens center vicinity 14a is reduced, The red light emission of the lamp is diluted.
[0032]
Further, a fish-eye step 17 which is a diffusion step is provided in the ring-shaped light source peripheral region 16a in front view of the reflector 16 so as to surround the bulb insertion hole 13, as shown in FIGS. 4 (a) and 4 (b). It has been. Therefore, the red light component L2 guided through the infrared light forming globe 30A and the light source light (white light that is visible light) L3 guided through the gap 31 between the globe 30A and the reflector 16 are: As shown in FIG. 4 (a), the light source peripheral area 16a (fisheye step 17) of the reflector 16 is diffusely reflected in the ranges indicated by arrows L21 to L22 and L31 to L32, respectively, near the front lens central portion 14a. Thus, the luminous flux density of the red light component distributed forward is further reduced, and the red light emission of the lamp is further diluted.
[0033]
Further, a light-shielding shade 40 is disposed in front of the globe 30A to block the light source light emitted forward through the front end opening of the globe 30A and prevent the generation of glare light. That is, the light-shielding shade 40 is provided with a blackening treatment 42 that easily absorbs light on the back side thereof, and is formed somewhat larger than the aperture of the globe 30A, and direct light (white light) of the bulb 20 is generated by the globe 30A. It has a structure that does not leak as much as possible from the front end opening.
[0034]
The light-shielding shade 40 is integrated with the reflector 16 by fixing its legs (not shown) to the reflector 16. Further, the globe 30A is fixed around the valve insertion hole 13 of the reflector 16 and the leg of the light shielding shade 40 via a holder (not shown), for example.
[0035]
Further, a gap 31 is formed between the infrared light forming globe 30A and the reflector 16, and a gap 41 is also formed between the globe 30A and the light-shielding shade 40. Air convection (see white arrow in FIG. 4 (a)) between the inside and outside of 30A is generated, and the heat around the valve 20 is carried outside the globe 30A by this air convection and dissipated. Accordingly, there is no possibility that heat will be trapped in the globe 30A, and various problems such as the occurrence of blacking in the bulb 20 and a decrease in the amount of light, or deterioration of the infrared light transmission multilayer film and deterioration of the infrared cut characteristics. There is no.
[0036]
Further, since there is a risk of damaging eyes when infrared light enters the human eye for a long time, in this lamp 10A, a lighting control circuit including a vehicle speed sensor 110 and a control unit 120 having a CPU 122, a storage unit 124, and the like. 100 (refer to FIG. 3), the vehicle speed V is close to 0 such that the bulb 20 is lit, the infrared light may hurt the eyes, or the vehicle stops, only during traveling where the infrared light does not hurt the eyes. At a predetermined speed V0 or less, the valve 20 is automatically turned off.
[0037]
That is, a vehicle speed condition for outputting a stop signal for stopping the lighting of the bulb 20 (lamp 10A) is input and set in the storage unit 124 of the control unit 120 in advance. When it is determined that the vehicle speed V has become equal to or less than a predetermined speed V0 close to 0, a stop signal for turning off the valve lighting switch Sw is output. As a result, the bulb lighting switch Sw is turned off, the supply of current to the bulb 20 is stopped, and the bulb 20 (lamp 10A) is turned off.
[0038]
FIG. 5 shows a processing flow of the control unit 120 (CPU 122) of the lighting control circuit 100, and this routine starts on the premise that the headlamp 8 (passing beam or traveling beam) is turned on.
[0039]
First, in step S1, it is determined whether or not a switch for operating the nighttime front vision detection system is turned on. This system operation switch is pressed as a manual switch when the driver operates while viewing the image of the head-up display 6, but may be configured to be turned on in conjunction with the lighting of the passing beam of the headlamp.
[0040]
If YES in step S1 (night forward visibility detection system operation switch ON), it is determined in step S2 whether or not the vehicle speed V is equal to or less than a predetermined value (V0) close to 0 based on the output of the vehicle speed sensor 110. Is done. If NO in step S2 (V> V0), the process proceeds to step S3, and after outputting to turn on the bulb 20 (infrared light irradiation lamp 10A), the process returns to step S1. On the other hand, if NO in step S1 (when the nighttime forward vision detection system operation switch is not turned on) or YES in step S2 (V ≦ V0), in step S4, the lit bulb 20 (infrared) After outputting to turn off the light irradiation lamp 10A), the process returns to step S1.
[0041]
FIG. 6 shows a second embodiment of the present invention and is a longitudinal sectional view of an infrared light irradiation lamp.
[0042]
In the first embodiment described above, the fish-eye step 17 provided in the light source peripheral region 16a of the reflector 16 is configured to diffuse the red light component L2 and the visible light (white light) L3. In the infrared light irradiation lamp 10B according to the second embodiment, the fish eye diffuses the red light component L2 and the visible light (white light) L3 in the ring-shaped region 14a in the center of the front lens corresponding to the light source peripheral region 16a of the reflector. The structure is provided with step 15.
[0043]
That is, the red light component and the visible light (white light) reflected as indicated by the symbols L2 and L3 at the light source peripheral area (parabolic reflecting surface) 16b of the reflector 16 are transmitted (emitted) through the front lens 14. In doing so, it is diffused by the fish-eye step 15 as indicated by arrows L21, L22, L31, and L32. For this reason, the luminous flux density of the red light component distributed in front of the front lens 14 is reduced, and the lamp does not appear to emit red light.
[0044]
Others are the same as those of the first embodiment described above, and the same reference numerals are given to omit redundant description.
[0045]
Although not shown, as shown in the first embodiment, the fisheye step 17 is provided in the light source peripheral region 16a of the reflector 16, and the ring-shaped region 14a of the front lens 14 corresponding to the reflector light source peripheral region 16a is provided. Alternatively, a fisheye step 15 may be provided.
[0046]
As described above, when the fish-eye steps 17 and 15 are provided on both the reflector 16 and the front lens 14, the red light component L2 and the gap 31 of the visible light guided without being cut by the infrared light forming globe 30A. When the light source light (white light that is visible light) L3 guided through the light is reflected by the reflector 16 (the light source peripheral region 16a), it is diffused by the diffusion step 17 and further emitted from the front lens 14. Furthermore, it is diffused by the diffusion step 15. That is, the red light component L2 and the white light L3 diffusely reflected by the reflector peripheral region 16a are further diffused when transmitted (emitted) through the front lens central region 14a, and thus are distributed in front of the front lens 14. The luminous flux density of the red light component is further reduced, and the lamp never appears to emit red light.
[0047]
FIG. 7 is an enlarged longitudinal sectional view of a bulb peripheral region which is a main part of an infrared light irradiation lamp according to a third embodiment of the present invention.
[0048]
In the infrared light irradiation lamp 10C according to the third embodiment, the back surface of the infrared light irradiation lamp 10C used in the infrared light irradiation lamp 10A shown in the first embodiment is replaced with a light shielding surface having a reflective surface 44 treated thereon. Using the shade 40A, the light source light emitted from the front end opening of the globe 30A is reflected by the reflection surface 44 and guided to the light source peripheral region 16a of the reflector. Others are the same as those of the first embodiment described above, and the same reference numerals are given to omit redundant description.
[0049]
In the third embodiment, the infrared light component L2 of visible light that has passed through the globe 30A is diffusely reflected (see symbols L21 and L22), and the light source light (white light) L3 guided through the gap 31 is reflected. Since the light source light (white light) is guided through the shade 40A to the light source peripheral region 16a of the reflector that diffusely reflects (see symbols L31 and L32 in FIG. 4A), the center portion of the front lens From the vicinity 14a, the visible light components (white light components) L31, L32, L41, and L42 diffused into the diffused red light components L21 and L22 are emitted in a mixed form. Therefore, the luminous flux density of the red light component distributed forward from the central portion 14a of the front lens is further diluted, and the lamp does not appear to emit red light.
[0050]
FIG. 8 is an enlarged longitudinal sectional view of an infrared light irradiation lamp according to the fourth embodiment of the present invention.
[0051]
In the infrared light irradiation lamp 10D according to the fourth embodiment, instead of the shade 40 used in the infrared light irradiation lamp 10B shown in the second embodiment (see FIG. 6), the reflection surface 44 is processed on the back surface. Using the applied shade 40B, the light source light (white light) emitted from the front end opening of the globe 30A is reflected by the reflecting surface 44 and guided to the light source peripheral region 16a of the reflector. Others are the same as those in the second embodiment described above, and the same reference numerals are given to omit redundant description.
[0052]
In the fourth embodiment, the light source light (white light) L4 reflected by the shade 40B and reflected by the light source peripheral region (parabolic reflection surface) 16b of the reflector is also reflected near the front lens central portion 14a. Therefore, when the red light component L2 and the white light components L3, L4 exit from the front lens central portion 14a, as indicated by arrows L21, L22, L31, L32 (see FIG. 6), L41, L42, Each is diffused. For this reason, the luminous flux density of the red light component distributed forward from the front lens central portion 14a is further diluted, and the lamp does not appear to emit red light.
[0053]
9 and 10 show an infrared light irradiation lamp according to a fifth embodiment of the present invention, FIG. 9 is a longitudinal sectional view of the infrared light irradiation lamp, and FIGS. 10 (a) to 10 (c) are the same. It is an expanded longitudinal cross-sectional view of the glove | globe for infrared light formation which is the principal part of a lamp | ramp.
[0054]
In each of the infrared light irradiation lamps 10A to 10D shown in the first to fourth embodiments, the reflector 16 is integrally formed on the inner peripheral surface of the lamp body 12, but the infrared light in this embodiment is used. In the irradiation lamp 10E, the reflector 16 is supported with respect to the lamp body 12 so as to be tiltable by an aiming mechanism (not shown).
[0055]
The infrared light forming globe 30 </ b> C covering the halogen bulb 20 is held by a metal holder 50 fixed to the reflector 16. The holder 50 has a structure in which annular portions 51 and 52 capable of gripping the front end portion and the rear end portion of the globe 30C are integrated with a linear portion 53 extending in the front-rear direction. Claws 54 are provided at three locations. The globe 30C and the holder 50 are integrated by inserting the globe 30C into the annular portions 51, 52 and caulking the claws 54. The annular portion 52 is provided with a pair of left and right legs 55 extending orthogonally, and the globe 30 </ b> C is integrated with the reflector 16 by screwing the legs 55 to the reflector 16. Since the globe 30 </ b> C is gripped in the entire circumferential direction by the annular portion 52 which is a part of the metal holder 50, the globe 30 </ b> C is firmly fixed and held without shaking with respect to the reflector 16.
[0056]
As shown in FIG. 10A, the infrared light transmitting multilayer film 36 formed on the globe 30C gradually changes in thickness in the longitudinal direction of the globe (t1 <t2) (at the root of the bulb 20). The visible light cut rate gradually changes in the longitudinal direction (the thicker the infrared light transmission multilayer film 36 is, the higher the visible light cut rate is). For this reason, light that passes through the globe 30C (infrared light transmissive multilayer film 36) and travels toward the light source peripheral region 16a of the reflector is light that has a large proportion of infrared light that has a large proportion of infrared light (infrared light visible). The light with a small proportion of the light component) is diffused as indicated by the arrow L2 (L21, L22) in the reflector light source peripheral region 16a (fisheye step 17). The light is reflected and emitted from the front lens central region 14a.
[0057]
Further, a gap 31 is formed between the rear end portion of the globe 30C and the reflector 16, and a part of the light source light (white light) is guided from the gap 31 to the light source peripheral region 16a of the reflector, so that the fish It is diffusely reflected by the eye step 17 (see arrow L3). For this reason, the light flux density of the infrared light component L2 (L21, L22) distributed forward from the front lens central region 14a is very diluted.
[0058]
Further, the red light component of the visible light that passes through the globe 30C and travels toward the light source peripheral region 16a of the reflector is shielded by the annular portion 52 that surrounds the rear end portion of the globe 30C, and thus is reflected in the light source peripheral region 16a of the reflector. The total amount of the guided red light component L2 decreases accordingly, and the luminous flux density of the red light component L2 (L21, L22) distributed forward from the central region 14a of the front lens is further diluted, and the lamp Does not appear to emit red light.
[0059]
Reference numeral 18 denotes an extension reflector, and reference numeral 19 denotes a cover attached to a bulb replacement opening at the rear top of the lamp body 12. Others are the same as those of the first embodiment described above, and the same reference numerals are given to omit redundant description.
[0060]
Further, the infrared light forming globe 30C may have a structure as shown in FIGS. That is, in FIG. 10B, the infrared light transmission multilayer film 36 formed on the globe 30C is integrally formed by two types of portions 36a and 36b having different film thicknesses in the longitudinal direction. In FIG. 10C, the globe part 30C1 in which the thin infrared light transmission multilayer film 36a is formed and the globe part 30C2 in which the thick infrared light transmission multilayer film 36b is formed are in contact with both the globe parts 30C1 and 30C2. The globe 30 </ b> C is configured by being integrated by a holder 50 </ b> A in which an annular part 52 </ b> A that holds the part is formed.
[0061]
In FIGS. 10B and 10C, the thickness of the infrared light transmitting multilayer films 36a and 36b is schematically illustrated with different thicknesses in order to show the difference in film thickness. Since the infrared light transmissive multilayer film is formed by vapor deposition, the difference in film thickness between the infrared light transmissive multilayer films 36a and 36b is so small that it is invisible.
[0062]
FIG. 11 is a longitudinal sectional view of an infrared light irradiation lamp according to a sixth embodiment of the present invention.
[0063]
In the infrared light irradiation lamp 10F shown in this embodiment, the reflector 16 is supported by the aiming mechanism (not shown) so as to be tiltable with respect to the lamp body 12, as in the lamp 10E of the fifth embodiment. . Further, the globe 30C transmitted light L2 and the light source light (white light) L3 guided to the light source peripheral region 16a of the reflector are diffusely reflected as indicated by arrows L21, L22, L31, and L32, and the front lens central region 14a. Exits from.
[0064]
In addition, the metal holder 50B for fixing the infrared light forming globe 30C to the reflector 16 is fixedly integrated with a metal second holder 60 provided with heat radiating fins 62 extending behind the reflector 16. In addition to the heat dissipating action by air convection generated inside and outside the globe 30C, the heat dissipating action of the heat dissipating fins 62 further prevents heat from being accumulated in the globe 30C.
[0065]
That is, the second holder 60 is formed in a stepped cylindrical shape that engages with the valve insertion hole 13, and a pair of flanges 63 formed at the front end of the second holder 60 extend inside the rear end of the holder 50 </ b> B. The leg 55A is fixed. The second holder 60 is formed with a disk-shaped radiating fin 62, and the heat transmitted to the globe 30C when the bulb 20 is lit is transmitted from the radiating fin 62 via the holder 50B and the second holder 60. Heat is radiated to the space behind the reflector 16. This avoids various problems associated with the high temperature of the valve 20.
[0066]
The order of assembly between the valve 20, the holder 50B (second holder 60), and the valve insertion hole 13 is arbitrary. After the valve 20 is fixed to the holder 50B (second holder 60), the valve insertion hole 13 is fixed. The valve 20 may be fixed to the holder 50B (second holder 60) after the holder 50B (second holder 60) is assembled to the valve insertion hole 13.
[0067]
Others are the same as the infrared light irradiation lamp 10E (see FIGS. 9 and 10) which is the fifth embodiment, and the same reference numerals are given, and redundant description thereof is omitted.
[0068]
FIG. 12 is a longitudinal sectional view of an infrared light irradiation lamp according to the seventh embodiment of the present invention.
[0069]
An infrared light irradiation lamp 10G shown in this embodiment is configured such that an infrared light forming globe 30C is fixed to a slider 72 of an actuator 70 that can slide back and forth via an annular holder 50C. It is characterized in that it is also configured to function as a traveling (beam forming) lamp. The basic structure of the infrared light irradiation lamp 10G is the same as that of the first embodiment (see FIGS. 3 and 4) and the fifth embodiment (see FIG. 9), and the same parts have the same reference numerals. The duplicate description is omitted.
[0070]
That is, if the infrared light forming globe 30C covering the bulb 20 is at the position shown by the solid line in FIG. 12, the light emission (white light) of the bulb 20 passes through the globe 30C and becomes infrared light and is reflected by the reflector 16. By emitting from the front lens 14, it functions as an infrared light irradiation lamp. The red light component of visible light that could not be cut by the globe 30C is diffusely reflected by the reflector light source peripheral region 16a (fisheye step 17) and emitted from the front lens 14. Further, the light source light is guided from the gap 31 between the globe 30 </ b> C and the reflector 16 to the light source peripheral region 16 a of the reflector, and this light source light (white light) is also diffusely reflected by the fisheye step 17 and emitted from the front lens 14. Accordingly, the luminous flux density of the red light component distributed in front of the front lens central region 14a is reduced, and the lamp does not appear to emit red light.
[0071]
Further, a light shielding portion 26 called a black top is provided at the tip of the glass bulb of the bulb 20 to shield direct light (visible light and infrared light) traveling forward from the bulb 20 and generate glare light. Is blocked.
[0072]
On the other hand, when the infrared light forming globe 30C is moved to the position shown by the phantom line in FIG. 12 by the actuator 70 and is released around the bulb 20, the light emission (white light) of the bulb 20 is reflected without passing through the globe 30C. 16 is guided to the entirety, and a traveling beam is formed.
[0073]
The lamp 10G is used as an infrared light irradiation lamp by a lighting control circuit 100 including a vehicle speed sensor 110, a headlamp light distribution changeover switch 112, and a control unit 120 having a CPU 122, a storage unit 124, and the like. When the vehicle speed is turned on only during traveling, the vehicle is automatically turned off when the vehicle speed V falls below a predetermined speed V0 close to 0, such as when the vehicle is stopped. Furthermore, when the light distribution of the headlamp is a traveling beam, the globe 30C moves forward and only visible light is distributed.
[0074]
That is, a vehicle speed condition for outputting a stop signal for stopping the light emission of the bulb 20 is input and set in the storage unit 124 of the control unit 120 in advance, and the CPU 122 receives the vehicle according to the output from the vehicle speed sensor 110. When it is determined that the speed V is equal to or less than the predetermined speed V0 close to 0, a stop signal for turning off the bulb lighting switch Sw is output. As a result, the bulb lighting switch Sw is turned off, the supply of current to the bulb 20 is stopped, and the bulb 20 (lamp 10G) is turned off.
[0075]
Reference numeral 130 denotes a power conversion circuit composed of a chopper circuit or the like provided in a power supply path to the bulb 20 and does not operate when used as a traveling beam forming lamp, and supplies battery power to the bulb as it is. However, when it is used as an infrared light irradiation lamp, it operates when the power supplied from the battery exceeds a predetermined value (for example, 13V) (for example, the power supply is made into a rectangular wave), and the predetermined appropriate power (For example, 12V) and supplied to the valve 20. Thereby, various problems associated with the heat accumulated in the globe 30C and the temperature of the valve 20 rising can be avoided.
[0076]
FIG. 13 shows a processing flow of the control unit 120 (CPU 122) of the lighting control circuit 100, and this routine starts on the premise that the headlamp (passing beam or traveling beam) is turned on.
[0077]
First, in step S10, based on a signal from the light distribution changeover switch 112, it is determined whether or not the headlamp is lit with a passing beam. If YES in step S10 (lighting of the passing beam), the process proceeds to step S11, and it is determined whether or not a switch for operating the traveling beam nighttime front vision detection system is turned on. This system operation switch is pressed as a manual switch when the driver operates while looking at the image of the head-up display 6, but may be configured to be turned on in conjunction with the lighting of the passing beam.
[0078]
If YES in step S11 (night forward visibility detection system operation switch ON), in step S11A, a signal for setting the power conversion circuit 130 in an operating state is output, and then in step S12, the output of the vehicle speed sensor 110 is output. Based on the above, it is determined whether or not the vehicle speed V is equal to or less than a predetermined value (V0) close to zero. If NO (V> V0) in step S12, the process proceeds to step S13, and output is made to turn on the valve 20, and then the process returns to step S10.
[0079]
On the other hand, if NO (traveling beam lighting) in step S10, the process proceeds to step S15, and an actuator drive signal is output to move the globe 30C forward. And in step S16, it outputs so that the valve | bulb 20 may be lighted. As a result, a traveling beam using only visible light can be obtained.
[0080]
If NO in step S11 (when the nighttime forward vision detection system operation switch is not turned on) or YES in step S12 (V ≦ V0), in step S14, the lit bulb 20 (infrared) After outputting to turn off the light irradiation lamp 10), the process returns to step S10.
[0081]
In the above-described embodiment, the fish-eye steps 17 and 15 are exemplified as the diffusion steps for diffusing the infrared light component provided in the reflector 16 and the front lens 14. It may be a certain cylindrical step or other steps.
[0082]
In the above-described embodiment, the light source peripheral region 16a of the reflector and the central region 14a of the front lens are provided with a diffusion step represented by a fish-eye step 17 for diffusing an infrared light component. However, this diffusion step is not always necessary.
[0083]
【The invention's effect】
As apparent from the above description, according to the first aspect, since the luminous flux density of the red light component emitted from the vicinity of the center portion of the front lens is low, red is not noticeable even when the infrared light irradiation lamp is turned on. Therefore, the driver and the pedestrian do not have the possibility of mistaking the lighting of the infrared light irradiation lamp as the lighting of the tail lamp or the stop lamp, so that driving safety is ensured.
[0084]
In addition, since heat does not accumulate in the infrared light forming globe, the temperature of the light source and the infrared light forming globe can be avoided, and firstly, the life of the light source is extended. Second, since the thermal degradation of the infrared light transmission multilayer film provided in the globe is suppressed, the infrared light transmittance of the globe is assured to be constant over a long period of time, and the infrared light with a stable long-term irradiation light quantity is obtained. An irradiation lamp can be provided.
[0085]
Also,Glare light is not generated while the lamp is on, so it does not bother oncoming vehicles and pedestrians.
[0087]
  Claim2According to the above, the luminous flux density of the red light component emitted from near the center of the front lens is further reduced, and the red light is not noticeable even when the infrared light irradiation lamp is turned on. There is no risk of mistaking the lighting as a tail lamp or a stop lamp, and the driving safety is further secured.
In addition, since the infrared light forming glove is firmly fixed and held against the reflector, it has excellent durability.
[Brief description of the drawings]
FIG. 1 is a diagram showing an overall configuration of a nighttime front vision detection system using an infrared light irradiation lamp according to a first embodiment of the present invention.
FIG. 2A is a schematic diagram of an image in front of a vehicle,
(B) is a diagram showing the video output signal taken out by the image processing analysis apparatus.
FIG. 3 is a longitudinal sectional view of an infrared light irradiation lamp according to the first embodiment of the present invention.
FIG. 4 (a) is an enlarged longitudinal sectional view of a bulb peripheral region which is a main part of the infrared light irradiation lamp;
(B) It is a front view of the valve | bulb insertion hole periphery area | region in a reflector.
FIG. 5 is a diagram illustrating a processing flow of a CPU of a control unit that controls lighting of an infrared light irradiation lamp.
FIG. 6 is a longitudinal sectional view of an infrared light irradiation lamp according to a second embodiment of the present invention.
FIG. 7 is an enlarged longitudinal sectional view of a bulb peripheral region which is a main part of an infrared light irradiation lamp according to a third embodiment of the present invention.
FIG. 8 is a longitudinal sectional view of an infrared light irradiation lamp according to a fourth embodiment of the present invention.
FIG. 9 is a longitudinal sectional view of an infrared light irradiation lamp according to a fifth embodiment of the present invention.
FIG. 10A is an enlarged longitudinal sectional view of an infrared light forming glove which is a main part of the lamp.
(B) It is an expanded longitudinal cross-sectional view of the modification of the glove | globe for infrared light formation which is the principal part of the lamp | ramp.
(C) It is an expanded longitudinal cross-sectional view of the other modification of the glove | globe for infrared light formation which is the principal part of the lamp | ramp.
FIG. 11 is a partially enlarged longitudinal sectional view of an infrared light irradiation lamp according to a sixth embodiment of the present invention.
FIG. 12 is a longitudinal sectional view of an infrared light irradiation lamp according to a seventh embodiment of the present invention.
FIG. 13 is a diagram showing a processing flow of a CPU of a control unit that controls lighting of the infrared light irradiation lamp.
[Explanation of symbols]
2A Visible light CCD camera
2B Infrared CCD camera
10A-10G Infrared light irradiation lamp
12 Lamp body
13 Valve insertion hole
14 Front lens
14a Ring-shaped region corresponding to the region around the reflector light source in the front lens
15 Fisheye step which is a diffusion step
16 reflector
16a Reflector light source area
17 Fish-eye step is a diffusion step
20 Halogen bulb as a light source
22 Filament
30A, 30B, 30C Infrared light forming globe
31 Gap between infrared forming globe and reflector
36, 36a, 36b Infrared light transmission multilayer film
40, 40A, 40B Shading shade
41 Gap between the infrared light forming globe and the shading shade
44 Reflective surface of shading shade
50, 50A, 50B, 50C holder
52 Annular part of glove fixing holder that acts as a shading part
70 Actuator
100 lighting control circuit
110 Vehicle speed sensor
112 Light distribution switch for headlamp
120 Control unit
122 CPU
124 storage unit
S light room
L21, L22 Red diffused light
L31, L32, L41, L42 White diffused light

Claims (2)

A lamp chamber defined by a lamp body and a front lens, a reflector provided inside the lamp body, a light source disposed in front of the reflector in the lamp chamber, and disposed so as to cover the light source, and visible With a cylindrical infrared light forming globe that blocks light and transmits only infrared light ,
The infrared light forming globe is disposed such that a rear end portion thereof is separated from the reflector, and light source light is emitted from a gap between the reflector and the rear end portion of the infrared light forming globe to a light source peripheral region in the reflector. An infrared light forming glove configured to be guided directly ,
In front of the infrared light forming globe, a light-shielding shade for shielding light source light emitted from the front end side opening of the globe is provided apart from the front end side opening of the globe,
On the back side of the light-shielding shade, there is provided a reflective surface for directly guiding the light source light emitted from the front end side opening of the globe to the light source peripheral region of the reflector without passing through the globe Infrared light irradiation lamp. On the outer periphery of the rear end portion of the infrared light forming globe, an annular light shielding portion that is a part of a metal holder for fixing and holding the infrared light forming globe to the reflector or the light shielding shade is provided. The infrared light irradiation lamp for automobiles according to claim 1.

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