BR102012030568A2 - LIGHTING SYSTEM, INCANDING LAMP AND AUTOMOTIVE HEADLIGHT MOUNT - Google Patents

Abstract

LIGHTING SYSTEM, BULB LAMP AND AUTOMOTIVE HEADLIGHT ASSEMBLY. It is an enhanced incandescent light source that can be used in a vehicle headlight to provide front illumination. The lighting system includes a filament coil and an anisotropic reflective assembly. The filament coil is constructed from a coil of wire that is electrically conductive and has a high melting point and the primary geometric axis of the wire coil is substantially aligned with a major geometric axis of the reflector system. The flow of light emitted by the filament coil towards the reflector system is rotationally anisotropic

Description

“LIGHTING SYSTEM, INCANDING LAMP AND MOUNTING

AUTOMOTIVE HEADLIGHT

Background Field of the Invention

Aspects of the present disclosure generally refer to sources of

of incandescent light and in particular to filament structures for use in tungsten-halogen automobile headlights.

Related Art Description Headlights, such as those used to provide front lighting in automobiles and other types of vehicles, generally provide illumination along the direction of travel.

One common type of automotive headlight in use today generates Iuz from an incandescent source. These headlights generate light by passing electricity through a resistive wire length, called a filament, causing it to heat to a very high temperature and emit light. Typical filaments for automotive headlights are formed by coiling a yarn of a suitable material, usually tungsten, to form a substantially circular spool with each individual spool, i.e. yarn separated from the proximate spool by a distance of less than 20 m in width. Langmuir sheath. In general, the Langmuir sheath is a layer of stationary gas, about 0.4 cm thick, that exists around almost all heated filaments. Since its diameter is reasonably constant, the length of the Langmuir sheath is kept short in order to minimize heat transfer from the filament through the Langmuir sheath. The resulting coil filament is circular in cross section and rotationally symmetrical. A single coil is formed when a filament is wound into a series of loops as described above. A coiled coil is a structure in which this single coil is wound itself into a larger coil. This larger coil is also circular in cross section and rotationally symmetrical.

In order to generate more light from incandescent lamps, the filament temperature must be increased. The higher the temperature, the higher the light generated. However, higher temperatures may adversely affect filament life, for example by accelerating the evaporation rate of filament material, usually tungsten. Circle the filament with a clear shell and charge the shell with a small amount of a halogen compound, such as iodine or bromine, 10 together with an inert filler gas that causes evaporated tungsten to be deposited back onto the filament instead. over the transparent shell, considerably increasing the life of the filament. However, the loading gas causes the convective cooling of the filament thereby reducing its effectiveness.

Studies have shown that brighter headlights

significantly improve a driver's ability to detect and recognize objects on the road in front of them. Therefore, it is advantageous to create brighter and safer headlights. While car headlights enhance a driver's vision, there are many factors that limit how bright a car headlight can be, such as the glow to which traffic and pedestrians are subjected, energy consumption, fuel economy and government regulation. . Thus, there is a need for brighter headlamps that comply with regulations and standards and do not consume additional energy.

Typical automotive headlights employ anisotropic reflectors

in which the side portions of the reflectors use light more efficiently than the top and bottom portions. However, the light sources used are isotropic resulting in a significant amount of light flow that is wasted on the less efficient top and bottom portions of the reflector.

Accordingly, it would be desirable to provide a light source for automobile headlamps that address at least some of the problems identified above.

Brief Description of the Invention

As described herein, exemplary embodiments overcome one or more of the above or other disadvantages known in the art.

One aspect of the present disclosure relates to a lighting system. The lighting system includes a filament and an anisotropic reflective mount. The filament is constructed from a coil of wire that is electrically conductive and has a high melting point. As an example, the pure high melting point of tungsten is 3,422 ° C (or 6,192 ° F). A longitudinal longitudinal axis of the wire spool is substantially aligned with a major axis of the reflector system such that the light flux emitted by the filament toward the reflector system is rotationally anisotropic.

Another aspect of the present disclosure relates to an incandescent lamp. The incandescent lamp includes a filament, a substantially transparent housing 20 enclosing the filament having a first end and a second end and a cap fixedly attached to the first end of the housing. The filament is constructed of a wire coil that is electrically conductive and has a high melting point and is shaped and / or positioned so that its emitted light stream is rotationally anisotropic. The cap is configured to hold the filament in a fixed orientation, with the primary geometry axis of the wire spool being substantially aligned with a major geometry axis of an anisotropic reflective assembly. Another aspect of the present disclosure relates to a vehicle headlight assembly which includes an incandescent lamp, an anisotropic reflective assembly having a main geometry axis and a housing. The incandescent lamp includes a filament spool, a substantially transparent housing 5 enclosing the filament spool having a first end and a second end and a cap fixedly attached to the first end of the housing. The filament coil is constructed of a wire coil that is electrically conductive and has a high melting point, and the light flux emitted by the wire coil toward the reflector system is rotationally anisotropic. The cap is removably coupled to the housing and configured to hold the filament spool in a fixed orientation within the reflector such that the primary axis of the wire spool is substantially aligned with the major axis of the reflector system.

These and other aspects and advantages of achievements

Exemplary examples will become apparent from the following detailed description taken in conjunction with the accompanying drawings. However, it is to be understood that the drawings are designed for illustration purposes only and not as a definition of the limits of the invention, to which reference should be made to the appended claims. Additional aspects and advantages of the invention will be set forth in the following description and in part will be obvious from the description or may be learned by practicing the invention. Further, aspects and advantages of the invention may be realized and obtained by means of the instruments and combinations particularly mentioned in the appended claims.

Brief Description of the Drawings

In the drawings:

Figure 1 illustrates a light source and reflector incorporating aspects of the present disclosure;

Figure 2 illustrates the flux contributions to the beam hotspot from typical automotive reflectors;

Figure 3 illustrates a cross section of an oval shaped filament reel incorporating aspects of the present disclosure;

Figure 4 illustrates a perspective view of a single oval coil filament incorporating aspects of the present disclosure;

Figure 5 illustrates a cross section of a rounded rectangular filament reel incorporating aspects of the present disclosure; and

Figure 6 illustrates a perspective view of a rounded rectangular single coil filament incorporating aspects of the present disclosure.

Detailed Description of Revealed Achievements

Aspects of revealed accomplishments are directed toward a

Anisotropic light source that can be used in a light source assembly or headlight assembly for a vehicle. While aspects of the disclosed embodiments are generally described herein in relation to a car, aspects of the disclosed embodiments are not as limited and may include any transport application where an anisotropic light source may be used. These may include, for example, landing lights, flood lights, spotlights and other transport lighting applications suitable for land, sea, air and / or space.

Figure 1 illustrates an exemplary headlight assembly 200, of which an exemplary light source assembly 202 may form a part. Embodiments of the anisotropic light source assembly 202 generally include a filament coil 210 that is longitudinally aligned with a primary optical geometry Z of the headlight assembly 200. In order to leverage the asymmetries commonly encountered in headlight reflectors, Anisotropic light source filament coil 210 does not have a rotationally symmetrical cross section. As used herein, the term "rotationally asymmetrical" refers to a shape whose height is generally larger than its width, for example, an oval and rectangle are "rotationally asymmetrical" while a circle and square are rotationally symmetrical. Instead, in one embodiment, a height of the filament coil 210 is greater than its width such that more of its emitted light stream travels toward the side or quadrant portions of the reflector 204 than toward its edges. top and bottom portions thereby producing a brighter beam for the same amount of emitted light stream.

As shown in Figure 1, the light source assembly 202 generally comprises a sealed housing or bulb 206 containing filament spool 210. Filament spool ends 207, 211 are attached to a guide assembly 208 209. The guides 208, 209 are typically formed from a sturdy conductive metal, which in the embodiment illustrated in Figure 1 is a heavier gauge wire and provides support for the filament coil ends 207, 211 and electrical current. for filament coil 210. Guides 208, 209 are arranged such that they support filament coil 210 in a desired orientation within an anisotropic reflective assembly 204 (hereinafter, "reflective assembly 204").

The reflective assembly 204 is mounted around the light source 202 to reflect the light generated by the filament coil 210, generally along the primary optical geometrical axis Z. In some embodiments, the reflective assembly is generally a parabolic concave mirror with the main geometry of the concave mirror forming the primary optical geometry of the headlamp assembly 200. As used herein, "primary optical geometry Z" refers to the direction in which a beam of Iuz travels emanating from the Iuz 200 assembly and corresponding to the main geometry axis of the reflective assembly 204. The primary optical geometry axis Z is generally located along the direction of travel of the vehicle to which the headlight assembly 200 is mounted. Reflective assembly 204 is constructed of a suitable material 5 such as glass or plastic and has a material lining its front surface 212 and / or rear surface 214 that will reflect at least that portion of light generated by filament coil 210 which lies within the visible region of the electromagnetic spectrum.

In automotive applications, reflective assembly 204 may typically be rotatably mounted (not shown) such that it may be rotated about the horizontal and vertical axes to allow the primary optical geometry axis Z to be properly aligned with the direction of car travel.

The reflective assembly 204 is comprised of one or more, generally 15 parabolic sections configured to form the reflected light in a desired lighting area. Alternatively, reflective assembly 204 may comprise a single parabolic element, discrete reflective elements, subtly transitional reflective elements. One skilled in the art will recognize that any reflective assembly 204 that creates a suitable lighting pattern may be used without departing from the spirit and scope of the present disclosure.

An aperture 216 in the optical center of the reflective assembly 204 is configured to accept the light source assembly 202. The light source 202 may include: a transparent or translucent housing 206 encapsulating the filament coil 210 and / or the ends of filament coil 207, 211, which are electrically coupled to guides 208, 209. In one embodiment, a gas mixture is confined within housing 206. Such gas mixture may comprise a halogen compound, such as, for example, bromine or iodine hydrocarbon mixed with an inert filler gas that is above atmospheric pressure.

The filament coil 210 may comprise a low melting vapor pressure metal wire, preferably tungsten.

The housing 206 may be formed of a material such as fused silica having suitable optical and thermal qualities and / or a material such as aluminosilicate glass having a high melting point.

The guide assembly 208, 209 support the filament reel ends 207, 211, thereby maintaining the filament reel 210 10 in the proper location and orientation. The filament coil 210 may be formed as a single coil or spiral coil of yarn, and is mounted with its longitudinal geometry axis parallel to or substantially parallel to the geometry axis Z. As will be discussed in more detail below, the filament coil 210 of the disclosed embodiments do not have a rotationally symmetrical cross-section 15 and a height of the filament spool 210 is greater than its width.

In one embodiment, housing 206 is fixedly secured to an end cap 218, which is configured to mount the light source assembly 202 to a headlight housing (not shown). End cap 20 218 includes various alignment means 220 configured to be attached to the corresponding headlight housing (not shown) to retain the light source assembly 202 in a fixed orientation relative to reflective assembly 204. The end cap 218 when installed in a standardized bracket (not shown) or suitable headlight housing (not shown) will suitably position and orient the lamp 202 within the reflector 204 such that the primary axis of the filament coil 210 is aligned with the optical geometry axis Z of the headlight assembly 200.

As described above, the reflective assembly 204 is used to redirect the anisotropic light stream generated by the filament coil 210 to form a light beam that will provide a desired illumination pattern. Typical illumination patterns comprise a hotspot or peak brightness area near the middle of the illumination beam 5 pattern gradually reduced at points distant from the hotspot. In some embodiments, the front portion 220 of housing 206 is coated with an opaque material to prevent uncontrolled light from corrupting the beam pattern created by reflective assembly 204.

Figure 2 illustrates a pictorial representation of an exemplary anisotropic reflective assembly 204, which means that different portions of the reflective assembly 204 contribute different amounts of light to the illumination pattern.

To illustrate this fact, headlamp reflective assembly 204 has been divided into four quadrants, generally described as upper quadrant 15 302, lower quadrant 306, right quadrant 304, and left quadrant 308 (hereinafter “quadrants 302 to 308”) , as shown in Figure 2. The different quadrants 302 to 308 of the reflector surface 204 contribute different amounts of light to the active point region of the beam.

Experiments performed to measure the Iuz amount of 20 various quadrants of reflective assembly 204 contribute to the active point clearly demonstrating the anisotropic nature of headlamp reflector assemblies 204. In experiments to determine the contribution of the reflector beam, the amount of flux from each Quadrant reflective assembly 302 to 308 contributed to the active point being measured and recorded as a percentage of the total active point flow. Table 1 shows the results from five typical automotive reflective assemblies along with average values. Averaging all automotive reflective assemblies tested produced the average Iuz flux contribution to the active point for each of the quadrants 302 to 308 to be: greater than 302 = 7%; lower 306 = 17%; right 304 = 41%; and left 208 = 35%. These average contribution values are shown in their respective quadrants 302 to 308 in Figure 3.

As can be seen from Table 1 below, most of the Iuz flow (76.7%) is contributed to the active point by the left quadrant 308 and the right quadrant 304. It should be noted that the relative contribution of the quadrant left 308 and right quadrant 304 can be changed on reflectors designed for use in countries with left- or right-hand traffic. However, the side quadrants 304, 308 of the reflective assembly 204 will always contribute a greater part of the light flow when compared to the top 302 and bottom 306 portions of the reflector. These experiments show that a light source with an anisotropic light distribution, such as the light source assembly 202 of the disclosed embodiments, which emits most of its moon sideways, will provide superior illumination of the hotspot when compared to a isotropic light source of the same brightness that emits light evenly in all directions.

Table 1. Active point flow contribution of the reflector quadrants. Reflector Reflector Reflector Reflector Reflector Reflector Medium Maximum Minimum I Il Ill IV V Left 30.9 33.5 36.1 36.8 40.7 35.6 40.7 30.9 (304) Right 37.7 39.9 45, 5 41.4 41.0 41.1 45.5 37.7 (308) Top 5.7 8.7 9.0 4.5 6.6 6.9 9.0 4.5 (302) Fund 25, 7 17.9 9.4 17.3 11.7 16.4 25.7 9.4 (306) Sides 68.6 73.5 81.6 78.2 81.7 76.7 81.7 68.6 Topo- 31.4 26.5 18.4 21.8 18.3 23.3 31.4 18.3 Background In one embodiment, a source assembly of Iuz 202 with a

Anisotropic light distribution is created by forming a filament coil 210 that has no rotational symmetry. For example, a filament coil 210 formed with a cross section (perpendicular to the z axis) that has a height, i.e. the distance along the x vertical axis, greater than its width, i.e. the distance along of its horizontal y-axis 5, will direct a greater amount of light stream emitted toward the side quadrants 304, 308 than toward the top quadrant 302 and bottom quadrant 306.

A filament spool 210 having its height greater than its width may be formed using cross-sections of various geometric shapes such as, for example, an oval as shown in Figures 3 and 4 or a rounded rectangle as shown in Figures 5 and 6. Those skilled in the art will recognize that other shapes may also be used to create a filament reel 210 having its height greater than its width.

Referring to Figure 3, a filament coil 210 is that

shown has an asymmetrical cross-section formed as an oval shape 400 where the width W along the horizontal y-axis is less than the height H along the vertical x-axis with the primary coil axis, i.e. the axis optical geometric or direction of travel, which is substantially perpendicular to the page. The ends 207, 211 of the filament spool 210 are secured to the guides 208, 209 when the filament spool 210 is installed in the headlight assembly 200 of Figure 2. Figure 4 shows a perspective view of the filament spool 210 shown in Figure 3 having an asymmetrical cross section formed as an oval shape 400.

Figure 5 illustrates an alternative filament coil 210 having

an asymmetrical cross section where the coil cross section has a rounded rectangular shape 500. As described above, the ends

207, 211 of filament spool 210 are attached to guides 208, 209 when filament spool 210 is installed in headlight assembly 200. Figure 6 shows a perspective view of filament spool 210 shown in Figure 5 having a section asymmetrical transverse shape formed as a rounded rectangular shape 500.

The prototypes of 210 oval-shaped filament reels 400

and rounded rectangular 500s have been manufactured and tested. These tests demonstrated that headlamp assemblies 200 comprising filament coils 210 having their height greater than their width provide about 4% to about 25% average improvement over standard filament light sources. The rotationally asymmetric filament reels of Figures 3, 4, 5, and 6 preferably have a height to width ratio H / W of between 1.05 and 5 (1.05 <= H / W <= 5); however, any filament reel 210 having a ratio of height H to width W generally greater than 1.00 may be advantageous and is in the spirit and scope of the present disclosure.

The filament reels 210 shown in Figures 1, and 3 to 6 are,

generally shown and described as single coil filaments. However, it is contemplated to replace the filament yarn 402 with a single spool of yarn having an outside diameter similar to the gauge of single spool filament yarn 402 thereby forming a coiled coil filament, as that term is, 20 generally understood. Forming this spiral coil filament with the coil cross-section geometries described above, such as oval shape 400 or rounded rectangular shape 500, results in spiral coil filaments exhibiting the same anisotropic light emissions with increased efficiency.

In addition to the rotational asymmetry described above, another contributor

For the anisotropic distribution of Iuz from the Iuz source assembly 202 is the location of the guides 208, 209 used to hold the filament spool 210 in place. The guides 208, 209, which are formed as wires in the embodiment illustrated in Figure 1, block a small but significant amount of light flow emanating from the filament coil 210. Placing the guides

208, 209 above or below the filament coil 210, the guides 208, 209 do not block the flow of light emanating towards the sides, that is, which best contributes to the left quadrant 308 and right quadrant 304 of the reflector 204, minimizing, thereby degradation of the hotspot intensity caused by the guides 208, 209. In the embodiment shown in Figure 2, the longest guide 208 used to support the front end 211 of the filament spool 210 is placed below the filament spool 210 and the shortest guide 209 used to support the rear end 207 of the filament spool 210 is positioned above the longest guide 208 and above and behind the filament spool 210. Place the guide 208 below the filament spool 210 instead of above it , also minimizes heating of guide 208 by filament spool 210, thereby reducing the risk of thermal damage to guide 208. Alternatively, it is advantageous in certain embodiments to place the guide longer. 208 above the filament spool 210.

Aspects of the disclosed embodiments provide an anisotropic light source assembly 202 which directs more of its emitted light toward one or more areas 304, 308 of reflective assembly 304 which contribute an additional 20 (or most) of light flow to an active point region of a light beam than one or more other areas 302, 306 of the reflective assembly. The anisotropic light source assembly 202 of the disclosed embodiments generally includes a filament coil 210 with a cross section that is rotationally asymmetrical. The rotationally asymmetric filament coil 210 is aligned with the optical axis of the headlight assembly 200 and emits an anisotropic light distribution that leverages asymmetries in reflector assemblies, which can be used in automobile headlights. Advantageously, the embodiments of the anisotropic Light source assembly 202 described herein will produce a brighter Light beam by generally the same amount of flux emitted as conventional isotropic Light source assemblies.

Thus, while fundamental innovative features of the invention have been shown, described and mentioned as applied to exemplary embodiments thereof, it will be understood that various omissions and substitutions and changes in the shape and details of the illustrated devices and their operation may be made by those skilled in the art. in the art without departing from the spirit and scope of the invention. Further, it is expressly intended that all combinations of these elements, which perform substantially the same function in substantially the same manner to achieve the same results, are within the scope of the invention. Further, it should be recognized that the structures and / or elements shown and / or described in conjunction with any disclosed form or embodiment of the invention may be incorporated into any other disclosed or described form or embodiment as a general design design issue. It is therefore intended to be limited only as indicated by the scope of the appended claims.

Claims (23)

A lighting system comprising: an anisotropic filament coil comprising an electrically conductive wire coil having a longitudinal axis; and an anisotropic reflective assembly having a major geometry axis, wherein the longitudinal geometrical axis of the wire coil is substantially aligned with the main geometrical axis of the anisotropic reflective assembly, and wherein a light stream emitted by the anisotropic filament coil toward anisotropic reflective assembly is rotationally anisotropic. LIGHTING SYSTEM according to claim 1, wherein the anisotropic reflective assembly comprises an upper quadrant, a lower quadrant and a right quadrant, and a left quadrant, and the anisotropic reflective assembly is configured such that the right and left reflect a larger portion of the flow than the upper and lower quadrants. LIGHTING SYSTEM according to claim 2, wherein the anisotropic filament coil emits a larger portion of the flow towards the right and left quadrants than toward the upper and lower quadrants. LIGHTING SYSTEM according to claim 3, wherein a wire spool cross-section has a height and a width, the height being greater than the width. LIGHTING SYSTEM according to claim 4, wherein a wire spool cross-sectional shape comprises an oval shape. LIGHTING SYSTEM according to claim 4, wherein a wire spool cross-sectional shape comprises a rounded rectangular shape. A lighting system according to claim 4, wherein the height of the wire spool cross section is between about 1.05 and about five times the width of the wire spool cross section. A lighting system according to claim 3, wherein the wire spool is a single wire spool. A lighting system according to claim 3, wherein the wire coil is a coiled wire coil. LIGHTING SYSTEM according to claim 3, wherein the anisotropic reflective assembly further comprises a generically parabolic reflective assembly. 11. Incandescent lamp comprising: an anisotropic filament coil; a substantially transparent housing enclosing the filament spool, the housing having a first end and a second end; and a cap fixedly attached to the first end of the housing, wherein the filament coil comprises a wire coil that is electrically conductive, and wherein a light stream emitted by the wire coil is rotationally anisotropic, and the cap is configured. to maintain the anisotropic filament coil in a fixed orientation such that a longitudinal axis of the wire spool is substantially aligned with a major axis of anisotropic reflective assembly. Incandescent lamp according to claim 11, wherein the wire spool has a height and width, wherein the height of the wire spool cross section is greater than the width of the wire spool cross section, and The longitudinal axis of the wire spool is substantially aligned with an optical axis of the lamp. Incandescent lamp according to claim 12, wherein a wire spool cross-sectional shape comprises an oval shape. Incandescent lamp according to claim 12, wherein a wire spool cross-sectional shape comprises a rounded rectangular shape. Incandescent lamp according to claim 12, wherein the height of the wire spool cross section is between about 1.05 and about five times the width of the wire spool cross section. Incandescent lamp according to claim 12, wherein the filament coil comprises a single coil of wire. Incandescent lamp according to claim 12, wherein the filament coil comprises a coiled wire coil. Incandescent lamp according to claim 12, wherein the anisotropic reflective assembly comprises a generically parabolic reflective assembly. 19. AUTOMOTIVE HEADLIGHT ASSEMBLY, the assembly comprising: an incandescent lamp; an anisotropic reflective assembly having a major geometrical axis; and a housing, wherein the lamp comprises: an anisotropic filament coil; a substantially transparent housing enclosing the filament spool, the housing having a first end and a second end; and a cap fixedly attached to the first end of the housing, wherein the anisotropic filament coil comprises a wire coil that is electrically conductive, and wherein a light stream emitted by the wire coil toward the anisotropic reflective assembly is rotationally rotatable. wherein the cap is removably coupled to the housing and configured to hold the anisotropic filament spool in a fixed orientation within the anisotropic reflective assembly such that the longitudinal axis of the wire spool is substantially aligned with one another. main geometrical axis of the anisotropic reflective assembly. The headlamp assembly according to claim 19, wherein a wire spool cross-section has a height and width, the wire spool cross-section height being greater than the wire cross-sectional width. bobbin of thread. The headlamp assembly of claim 20, wherein a wire spool cross-sectional shape comprises an oval shape. The headlamp assembly of claim 20, wherein a wire spool cross-sectional shape comprises a rounded rectangular shape. The headlamp assembly according to claim 20, wherein the height of the wire spool cross section is between about 1.05 and about five times the width of the wire spool cross section.