ES1057599U - Light emitting device. (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Light emitting device, comprising: an LED, the LED being operative to emit light substantially along an optical output axis; and a reflector, the reflector having a reflective surface, characterized in that the reflective surface includes a curve section, the curve section being arranged in the predetermined relationship with respect to a main axis, the main axis being in non-parallel relationship with the axis optical output. (Machine-translation by Google Translate, not legally binding)

Description

Light emitting device

Field of invention

This invention relates, in general, to alarm light emitting devices, and more particularly, at a  alarm light emitting device that includes a diode of light emission (LED).

Background of the invention

The light emitted from an LED can be highly directional. This directionality has been detrimental when it try to couple the LEDs with parabolic reflectors conventional. The directionality of an LED, taken together with the desire to configure the light emission in different modes and with Opposite frequency of meeting the specifications of performance of various regulations associated with alarm lights, has resulted in alarm lighting systems with LED that frequently use lens elements, in addition to reflectors to configure the beam. These reflector systems of LED-lens may suffer from optical efficiency poor. U.S. Patent No. 6,318,886 describes a method by which the beam pattern is produced with light source LED and a variation of a conventional reflector.

Description of the invention

The invention provides a set of light that It can include an LED and a reflector. The LED is arranged with with respect to the reflector, so that the optical output axis of the LED is in an intersection relation, of deviation with respect to a main axis of a reflective surface of the reflector, such that the output shaft is in non-parallel relationship with the main axis of the reflective surface. The reflective surface may include a linear curved section. The curved section can be defined by A parabolic equation. The relationship between the LED and the surface Reflective can facilitate beam configuration and improve light collection efficiency.

The reflector can take advantage of the LED directionality to guide and steer substantially all the light from the LED to the areas where desired and at levels Light output suitable for each area. As a result, the reflector design of the invention can have an efficiency extremely high optics

These and other features of this invention will be apparent to a person skilled in the art after reading the detailed description, in conjunction with the drawings They accompany each other.

Brief description of the drawings

Figure 1.- It is an elevation view of a useful LED in connection with the present invention.

Figure 2.- It is a graph of relative intensity (percentage) with respect to angular displacement (degrees) for a Luxeon® LED.

Figure 3.- It is a sectional view of a set of conventional light that includes a conventional reflector and an LED described very schematically as a source of points.

Figure 4.- It is a sectional view of a set of light according to the present invention which includes a parabolic reflector surface and a very described LED Schematic as a source of points.

Figure 5.- It is a perspective view of the light assembly of figure 4.

Figure 6a.- It is an isoluminic diagram of light emitted from the light assembly of figure 4.

Figure 6b.- It is a cross-sectional view of along line B-B in figure 6A of the light emitted from the light assembly of figure 4.

Figure 6c.- It is a cross-sectional view taken along line C-C in figure 6a of the light emitted from the light assembly of figure 4.

Figure 7.- It is a perspective view of another embodiment of a light assembly according to the present invention

Figure 8a.- It is an isoluminic diagram of light emitted from the light assembly of figure 7.

Figure 8b.- It is a cross-sectional view taken along line B-B in figure 8a of the light emitted from the light assembly of figure 7.

Figure 8c.- It is a cross-sectional view taken along line C-C in figure 8a of the light emitted from the light assembly of figure 7.

Figure 9.- It is another embodiment of a light assembly according to the present invention.

Figure 10a.- It is an isoluminic diagram of light  emitted from the light assembly of figure 9.

Figure 10b.- It is a cross-sectional view taken along line B-B of figure 10a of the light emitted in the light assembly of Figure 9.

Figure 10c.- It is a cross-sectional view taken along line C-C of figure 10a of the light emitted from the light assembly of Figure 9.

Figure 11.- It is an exploded, orderly view of  another embodiment of a light assembly according to the present invention

Figure 12.- It is a front elevation view of the light assembly of figure 11.

Figure 13.- It is a cross-sectional view taken along line A-A in figure 12 of the light assembly of figure 11.

Figure 14.- It is a cross-sectional view taken along line B-B in figure 12 of the light assembly of figure 11.

Figure 15a.- It is an isoluminic diagram of light  emitted from the light assembly of figure 11.

Figure 15b.- It is a cross-sectional view taken along line B-B in figure 15a of the emitted light of the light assembly of Figure 11; Y

Figure 15c.- It is a cross-sectional view taken along line C-C in figure 15a of the light emitted from the light assembly of Figure 11.

Detailed description of the preferred embodiments of the invention

Referring to figures 1 and 2, shows the pattern of space radiation from an LED 25 of typical high emission along with a graphic representation of light emitted from LED 25. The radiation pattern clearly demonstrates that the highest light emission occurs at approximately 40 ° from both directions from an optical output axis of the LED (shown in figures 1 and 2 as axis of 0 ° 30), and that most of the light is produced within 60 ° from both directions from the axis output 30. The output shaft 30 can extend substantially through the center of the LED lens face through a virtual focal point 32 of the LED. Since the focus which produces the light on the LED is a finite size, the focal point virtual 32 can be a theoretical point within the LED, from which most of the light rays emitted by focus. It is also evident from Figures 1 and 2 that the LED space light emission characteristics are independent of color.

The radiation curve is shown in Figure 2 space for a red, green, cyano, blue and blue emitting diode Roval

The length of the arrows in figure 1 Describe the relative intensity of the light.

Figure 3 shows the amount of light coming of an LED that is captured by a conventional reflector system, and Figure 4 shows the amount captured by a reflector system in accordance with the present invention. As shown in the Figures 3 and 4, the reflector of the invention can capture and redirect a significantly larger amount of light to from an LED that the same LED used in a reflector system  conventional parabolic.

With reference to figure 5, a embodiment of a light assembly 40 according to the present invention The light assembly 40 may include a reflector 42 and an array of LEDs 44. Reflector 42 includes a reflective surface 46. The LED array 44 includes a plurality of LEDs 48. In this embodiment, LEDs 48 are arranged in three sets 51, 52, 53 of three LEDs each, to a total of nine LEDs 48. An example of an LED suitable for use in the present invention is the Luxeon® LED as described in the U.S. Patent Application No. 10 / 081,905, filed on February 21, 2002, and titled "LED Light Assembly", where all its contents are incorporated here by reference. The light assembly 40 may also include other components, such as a power supply and a heat sink, by example.

LEDs 48 are placed in a relationship substantially aligned with each other, so that your points virtual focal points are substantially aligned along a axis. As a result, the optical output axis of each LED 48 is also similarly aligned, thus defining a point axis virtual focal point and an optical output axis for the LED matrix. I know understand that in other embodiments, the light set It can include an LED or a different number of LEDs.

Referring to figure 3, in a system conventional reflector, reflector 54 may comprise at least a portion of a parable of revolution around an axis main 55. The LED or LED array 56 is arranged so that its optical axis is substantially aligned with the main axis 55 of reflector 54.

Referring to figure 4, the surface Reflective 46 includes a linear curved section 60. In this form of embodiment, the curved section 60 is parabolic. In this figure reference 49 indicates the area of non-reflected rays that conventionally occupy 58 ° and reference 50 indicates the zone of reflected rays that conventionally occupy 31 °. The equation for The parabolic curve in this example is: y2 = 1.22x, where x is take along a horizontal main axis 70 of the section parabolic 60 e and is taken along a vertical axis and 72 which is  perpendicular to the main axis 70. The axis and 72 is parallel to a guideline 74 of the parabolic section 60. A focus 76 of the section parabolic 60 is arranged coincident with the focal point axis 80 virtual LED series. The output shaft 82 of the matrix of LED is substantially parallel with the y-axis 72 and the guideline 74 of the parabolic section 60. The size of the parabolic curve can be based on the angular limits of the emitted light of the matrix of LED and the physical size limits of the application in which it is intended for use, for example, the light assembly.

In this example, a first end 90 of the parable 60, which is closer to LED 48, is in a first angle 94 from the output shaft 82, while a second end 92, which is further apart from LED 48, is in a second angle 96 from the output shaft 82. The first angle 94 is measured between the output shaft 82 and a line 98 that extends between the axis of the focal point 80 and the first end 90. The second angle 96 it is measured between the output shaft 82 and a line 99 that extends to through the focal point axis 80 and the second end 92. In this embodiment, the first angle 94 is equal to 60 °, and the Second angle 96 is equal to 50 °.

The ends 90, 92 may constitute a compromise between physical size and maximum light collection, since most of the light emitted from the conventional LED is typically concentrated between these two angular values (see Figure 1). From these limits, a number can be created Infinite parabolic curves. The parabolic curve is completely limited by placing the first endpoint 90 of the curve closest to the LED vertically above the plus point high of the LED structure. This placement will ensure that the light reflected from this end point 90 will not be prevented substantially by the LED housing. In other ways of embodiment, the reflector may have a parabolic section with one or both of the ends arranged in different places.

In figure 4 reference 101 indicates the zone maximum flow, reference 102 the area of reflected rays that span 110 °.

Referring to figure 5, to build the reflective surface 46, the parabolic curve section 60 is swept along a focal axis 100 to create the surface reflexive The focal axis 100 is positioned coincident with the focus of the curve section 60 and perpendicular to a plane of the curve a through the main axis 70 and the focal axis 100, as shown in Figure 4. Referring to Figure 5, LEDs 48 are arranged in a linear series with its virtual focal points coincident with the focal axis 100.

Referring to figure 4, substantially all the light emitted from the LED series, is directed towards the reflector 42, so that substantially all the light emitted from the LED array is contacted with the reflective surface 46 and is reflected by it, being substantially collimated light by the reflective surface 46. Only a portion 104 of the light emitted by the LED array is not is reflected by reflector 42. In this embodiment, the portion 104 of the non-reflected light emitted by the LED array it is arranged in a 10 ° arc segment adjacent to the segment of arc defined by the second angle 96. The vector component vertical of all light rays 105 that leave the LED hitting in the reflector, that is, the light emitted in the area covered by the arc segments defined by the first angle 94 and the second angle 96 (an arc segment 110 ° in this example), is directed to the front 106 of the set 40 due to the parabolic configuration of the reflective surface 46, while that the components of the non-vertical vector remain unchanged of lightning This results in a beam of light 110 which is very narrow in a vertical direction 112 but quite wide in a horizontal direction 114, as shown in figure 6. Making reference to figure 6a-6c, the light emission is sample in the form of an isoluminic diagram with graphs to the right and below that show cross sections through of the light beam 110.

With reference to figure 7, another one is shown embodiment of a light assembly 140 according to the present invention The light assembly 140 includes a reflector 142 and an array of LED 144. The reflector 142 may include a reflective surface 146 having a plurality of portions Reflective 221, 222, 223, 224, 225, 226, 227, 228, 229. The number Reflective portions may correspond to the number of LED 148 included in the 140 light assembly. In this case, the LED matrix 144 includes nine LEDs 148. Each reflective portion can be defined by a parabolic curve section that is rotated on an arc default around its main axis to form a part of a paraboloid. The parabolic curve section can be the same that the parabolic curve section 60 of the reflector 42 of the figure Four.

Referring to Figure 7, the size of each reflective portion 221, 222, 223, 224, 225, 226, 227, 228, 229 can be related to the space of adjacent LEDs 148 with the main axis of a particular reflective portion that extends to through the virtual focal point of the LED with which the Particular reflective portion. The extent of each portion reflective along the focal axis 200 can be delineated by its intersection with immediately adjacent reflective portions to this. For example, the fourth reflective portion 224 may include a parabolic section 160 that is rotated about its axis main 170 over a predetermined arc 178. Extreme points 184, 185 of arc 178 are defined by the points where the arc 178 intersects arcs 186, 187 of the third and fifth portions adjacent reflexive 223, 225, respectively. The extension exterior of each extreme reflexive portion 221, 229, extends preferably enough to capture substantially all the light emitted by the respective end LED 148a, 148b in a respective outer direction 230, 231 along the focal axis 200.

The reflective surface 146 can extend all the path to a plane 234 defined by the LED assembly. The rays of light left by the LED matrix 144, which affect the reflector 142, can be directed to the front part 236 of the set 140 for the parabolic surface configuration reflective 146. This reflector 142 can give rise to a beam of light 210, as shown in Figure 8, which is narrower and more concentrated than the light beam 110 shown in the figure 6a-6c. The light beam 210 (figures 8a-8c) may be suitable for applications that they require a beam of the "point" type. The light set 140 of Figure 7 may be similar in other aspects of the set of light 40 of figure 5.

With reference to Figure 9, another embodiment of a light assembly 340 according to the present invention is shown. The light assembly 340 of Figure 9 includes a reflector 342 and an LED array 344. The reflector 342 includes a reflective surface 346. The LED array 344 includes a plurality of LEDs 348. The reflective surface 346 has a body portion 354 flanked by two end portions 356, 357. The body portion 354 includes a parabolic section that is similar to that of the reflector 42 of the light assembly 40 of Figure 5. Each end portion 356, 357 can be defined by rotating a parabolic curve around its main axis over a predetermined arc. The main axis of the parabolic curve of each end portion 356, 357 can intersect the optical output axis 382 of the end LED 48 a , 48 b with which the respective end portion 356, 357 is associated.

The reflector 342 of Figure 9 may be useful, since it produces a beam of light 310 that can satisfy the National Fire emergency alarm light specifications Protection Association (NFPA) and the General Services Administration The body portion 354 can produce a wide horizontal light distribution 311, as shown in the Figures 10a-10c. The extreme portions 356, 357 they can produce a high intensity light distribution, narrow 312 visible in the center of the isolumin diagram shown in figures 10a-10c. The current invention can use the light distribution characteristics of the array of LED and reflective surface settings to provide controlled beam configuration to meet a specification default

With reference to the figures 11-14, another embodiment of a light assembly 440 according to the present invention. The figure 15 shows the light emission characteristics of the set of light 440 of Figure 11. Referring to Figure 11, the light assembly 440 may include a reflector 442 (such as those of the Figures 12-14), an array of LED 446 available inside reflector 444, a LED power supply box 445 mounted to reflector 442 and electrically connected to the matrix LED 444, and a heat sink 449 mounted to reflector 442 and operatively arranged with LED matrix 444

Referring to the figures 12-14, reflector 442 may include a housing 454 defining an opening 455 and an inner cavity 456. The reflector 442 may include a reflective surface 446 that acts to define a portion of the cavity. LED matrix 444 can be disposed within the cavity 456 of the reflector 442. The heatsink Heat 449 may be mounted to a bottom side of the reflector, so that the LED matrix 444 is in overlapping relationship with this. The power supply box 445 can be mounted to the reflector 442 adjacent to its rear end 450. The end Rear 450 may oppose opening 455 of reflector 442.

Referring to figure 12, the surface  Reflective 446 includes a 457 body portion and two portions extreme flanks 458, 459. Referring to the figure 13, body portion 457 may include a curve section parabolic 460 comprising a plurality of curve segments parabolic 461, 462, 463, 464. In this embodiment, the 457 body portion includes four parabolic curve segments to define the parabolic curve section. The four segments parabolic 461, 462, 463, 464 of the curve portion 457 can define each one by a different parabolic equation. The segments define the parabolic curve section 460 and set discontinuities 465, 466, 467 between them. The curve section parabolic 460 can extend along the focal axis 400 over a predetermined amount to define the body portion 457. The parabolic curve segments 461, 462, 463, 464 may have different main axes.

In other embodiments, two or more segments of a curve section can be joined without any discontinuity between them. In other embodiments, two or more of the segments can have the same parabolic equation. In still other embodiments, two or more of the segments They can have the same main axis.

The size and configuration of each segment of parabolic curve can be determined through a process iterative creation of a surface, performing a simulation of computer-assisted surface ray tracing, and repeating the preceding stages until a surface area that substantially matches or exceeds specification. The reflective surface associated with each of these parabolic curve segments can direct the light up to a specific space area.

Referring to figure 14, the second end portion 459 may include a parabolic curve section 484 comprising a plurality of parabolic curve segments 485, 486, 487, 488, 489. In this embodiment, the section of curve 484 of the second end portion 459 includes five parabolic curve segments. The parabolic curve segments 485, 486, 487, 488, 489 can be defined by different equations parabolic The segments of the end portion 459 can be joined in a similar way to how many parabolic segments of the body portion 457 are attached. The second extreme portion 459 can be defined by rotating the parabolic curve segments 485, 486, 487, 488, 489 around its main axes respective over a predetermined arc between the edge that makes stop 498 (figure 12) of body portion 457 and opening 470 of reflector 442. The first end portion 458 is similar to the second extreme portion 459, the first extreme portion being a symmetric image of the second extreme portion. In other ways of realization, the first and second may be different from each other Extreme portions

Referring to figure 15, the effect combined of the body portion and the first and second portions ends of the reflector of figure 12, is to produce a pattern of light distribution 410 capable of matching a specification default lighting performance.

The use of the terms "one" and "the" and "el" and similar referents in the context of the description of the invention should be construed to cover both the singular as the plural, unless otherwise indicated here or  Contradict the context clearly. All the described methods here they can be done in any suitable order unless it is indicate otherwise here or be clearly contradicted by the context. The use of each and every one of the examples, or exemplary language (for example, "as is") provided here is intended to clarify the invention and not to set limits within the scope of the invention, unless claimed otherwise. Should not interpret the language in the specification as an indication of any element not claimed as essential for the practice of the invention.

The embodiments are described here Preferred of the invention. They can become apparent variations of these preferred embodiments for the technicians in the field after reading the description preceding. The inventors expect technicians in the field employ such variations as appropriate, and the inventors they intend that the invention be implemented in another way other than specifically described here. Therefore, this invention includes all modifications and equivalents of the subject matter indicated in the claims attached to this allowed by applicable law. In addition, any combination of the elements described above in all its variations possible is encompassed by the invention unless another is indicated thing here or is clearly contradicted otherwise by the context.

Claims (33)

1. Light emitting device, comprising: an LED, the LED being operative to emit light substantially along an optical output axis; Y a reflector, the reflector having a reflective surface, characterized in that the reflective surface includes a curve section, the curve section being arranged in the predetermined relation with respect to a main axis, the main axis being in non-parallel relationship with the axis of optical output 2. Light emitting device, in accordance with the claim 1, wherein the main axis is substantially perpendicular to the optical output axis. 3. Light emitting device, in accordance with the claim 1, wherein the LED has a virtual focal point, extending the optical output axis through the focal point virtual, and extending the main axis through the focal point virtual. 4. Light emitting device, in accordance with the claim 1, further comprising a matrix of LEDs 5. Light emitting device, in accordance with the claim 4, wherein each LED includes a virtual focal point, the LEDs being arranged so that the focal points virtual extend along a focal axis. 6. Light emitting device, in accordance with the claim 5, wherein the virtual focal points are substantially aligned with each other. 7. Light emitting device, in accordance with the claim 4, further comprising a source of power supply operatively arranged with the LED array, of so that the LED matrix is operated operatively to emit the light. 8. Light emitting device, in accordance with the claim 7, further comprising a heat sink arranged operably with the LED matrix. 9. Light emitting device, in accordance with the claim 1, wherein the curve section comprises a section of parabolic curve. 10. Light emitting device, in accordance with the claim 9, wherein the parabolic curve section is defined by a parabolic equation, the parabolic equation being y2 = nx, where x is taken along the main axis, and is taken at along an axis and perpendicular to the main axis, and n is a default coefficient. 11. Light emitting device, in accordance with the claim 10, wherein the y axis is substantially parallel to optical output shaft 12. Light emitting device, in accordance with the claim 10, wherein the parabolic curve section has a focus, the LED has a virtual focal point, the focus substantially coinciding with the virtual focal point. 13. Light emitting device, in accordance with the claim 9, wherein the LED includes a virtual focal point, extending the optical output axis through the focal point, the Parabolic curve section includes a first end and a second end, arranged the first and second ends in relation to the LED, so that substantially all the light emitted from the LED contacts the reflective surface. 14. Light emitting device, in accordance with the claim 13, wherein the first end and the virtual focal point that defines a first line, defining the first line and the axis of optical output a first angle, defining the second end and the virtual focal point a second line, defining the second line and axis of optical output a second angle. 15. Light emitting device, in accordance with the claim 14, wherein the first angle is different from the second angle. 16. Light emitting device, in accordance with the claim 15, wherein the first angle is approximately 60 ° and The second angle is 50 °. 17. Light emitting device, in accordance with the claim 5, the reflective surface is defined, at least in part, extending the curve section along the focal axis a predetermined amount 18. Light emitting device, in accordance with the claim 1, wherein the reflective surface includes at least a reflexive portion, defined by the reflexive portion by the curve section that is rotated around the main axis on a predetermined amount 19. Light emitting device, in accordance with the claim 18, further comprising an array of LEDs and a plurality of reflexive portions. 20. Light emitting device, in accordance with the claim 19, wherein the number of LEDs corresponds to the number of reflexive portions. 21. Light emitting device, in accordance with the claim 20, wherein each LED includes a virtual focal point, extending the main axis of each reflective portion through of the virtual focal point of a respective LED. 22. Light emitting device, in accordance with the claim 1, wherein the reflective surface includes a portion of body that has the curve section. 23. Light emitting device, in accordance with the claim 22, where the body section is defined extending the curve section along an axis that is perpendicular to the main axis and the optical output axis. 24. Light emitting device, in accordance with the claim 22, wherein the reflective surface includes first and second extreme portions, the body portion being arranged intermediate in the extreme portions. 25. Light emitting device, in accordance with the claim 1, wherein the curve section includes a plurality of segments, at least one segment being defined by an equation Mathematics that is different from at least one other segment. 26. Light emitting device, in accordance with the claim 25, wherein the segments are defined by the parabolic equations. 27. Light emitting device, in accordance with the claim 26, wherein at least one of the segments has an axis main that is different from at least one other segment. 28. Light emitting device, in accordance with the claim 26, wherein the reflective surface includes a body portion and first and second extreme portions, the body portion including a plurality of segments, the first extreme portion including a plurality of segments, and the second end portion having a plurality of segments 29. Light emitting device, in accordance with the claim according to claim 28, wherein the body portion has four parabolic curve segments, each segment of the body curve having a parabolic equation different, the first extreme portion has five segments of parabolic curve, having each first segment of extreme curve a different parabolic equation, the second portion being extreme a symmetrical image of the first extreme portion. 30. Light emitting device, according to claim 1 comprising: One LED, the LED can be operated to emit light substantially along an optical output axis; Y a reflector, the reflector having a reflective surface, including the reflective surface a section  of curve, the section of curve extended along an axis a predetermined amount; where the LED is placed so that the axis optical is in relation to intersection with the surface reflective 31. Light emitting device, in accordance with the claim 30, wherein the curve section is parabolic. 32. Light emitting device, according to claim 1 comprising: an LED, the LED being operable to emit light substantially along an optical output axis, having the LED a virtual focal point, extending the optical output axis to through the virtual focal point; Y a reflector, the reflector having a reflective surface, including the reflective surface a curve section, the curve section being arranged in relation  predetermined with respect to a main axis, extending the curve section substantially along the main axis, the extended curve section a predetermined amount along of an axis perpendicular to the main axis to define at least one portion of the reflective surface, extending the main axis through the virtual focal point of the LED, the main axis being in relation to intersection with the optical output axis. 33. Light emitting device, in accordance with the claim 32, wherein the curve section is parabolic.