This invention relates to theatrical lighting fixtures.
Multi parameter theatrical lighting fixtures are generally known in the art.
U.S. Published Patent application no. US 2003/0227774 to Martin provides a segmented reflector 212 which includes a plurality of reflector segments. (Martin, paragraph 46). In Martin, each reflector segment “ . . . is a region that is optimized for an emitting area on a post facet (e.g., one or more LED sources on the post face) . . . . Each reflective segment can be a smooth simple surface, a smooth complex surface, or divided into a number of sub-segments called facets.” (Martin, paragraph 46).
However, Martin does not disclose that one reflector segment is physically separate from another reflector segment. Rather, a single physically integrated reflector, such as reflector 312 is provided, which has segments located thereon, such as segments 314-1 and 314-3. (Martin paragraph 57, FIG. 3B)
Thus each of Martin reflective segments of a single integrated segmented reflector, such as segmented reflector 312 or 212, are not physically moveable with respect to other reflective segments of the same single integrated segmented reflector. In fact, Martin expressly states: “Accordingly, the light pattern of the lamp is changed without physical mechanism”. (Martin, paragraph 13).
Martin is directed to a physically integrated segmented reflector, i.e. where the segments cannot physically move with respect to each other, particularly as used for automobiles, and particularly as used for headlamps. For example, Martin states: “ . . . in automotive applications, it is critical to design headlamps that do not generate glares into oncoming traffic.” (Martin, paragraph 5, second sentence). Martin refers to “automotive” application (Martin, paragraph 42), and use of the single physically integrated segmented reflector for “conventional automotive headlamp” (Martin, paragraph 58, last two sentences) or “conventional headlamp” (paragraph 59, fourth sentence; paragraph 60; second sentence; paragraph 60, third sentence; paragraph 60, second to last sentence).
One skilled in the art would recognize that Martin uses the term “segmented reflector” in the sense of a physically integrated segmented reflector (where the segments do not physically move with respect to each other), as shown for example in “Segmented Reflector Design—Automotive reflector design process with ASAP and ReflectorCAD”, ASAP Technical Publication, Mar. 24, 2008, https://www.breault.com/sites/default/files/bropn1150_reflector.pdf. That article refers to “automotive segmented reflector design process”, and shows an individual reflector segment which is physical integrated with the overall segmented reflector, such that the individual reflector segment does not move with respect to other reflector segments of the same overall segmented reflector.
U.S. Published Patent Application no. US 2019/0320514 to Edwards provides a lighting tower 138 including multiple LED light source extending in a direction indicated by numeral 139. (Edwards, paragraph 51). Edwards does not disclose physically moving the lighting tower 138. Rather: “The lighting tower 138 is fixed relative to the chassis 132 and the PAR 134. In traditional lighting systems using a parabolic optic, to adjust a beam angle, a bulb disposed in the parabolic optic is moved 2-3 inches relative to the parabolic optic using a mechanical actuator. For the lighting assembly 130, instead of moving the light source, the activated LEDs (e.g., the activated lighting elements of the illustrated embodiment) change, altering the location of the source of the light digitally by simply selecting different LEDs of the lighting tower 138 to illuminate. By lighting more LEDs in different locations, the lighting assembly 130 has more flexibility to change the beam shape.” (Edwards, paragraph 51, first four sentences).
U.S. Pat. No. 8,845,136 to Savage et al. provides a reflector 120 which may comprise a single continuous sheet of reflective material or multiple sheets of reflective material, wherein a piece of reflective material may be attached to a movable structure. (Savage et al., col. 5, Ins. 11-20).
Savage et al. states: “In this way, the movable part of the support structure 130 may move independently of the stationary part of the support structure 130 and/or independently of another movable portion of the support structure 130. This independent movement enables a variety of configurations of the reflector 120.” (Savage et al., col. 4, Ins. 46-51; FIG. 3a). Savage et al. refers to a central stationary skeletal structure 135 to which a strobe 22 is fixed by a strobe support 110, and to outer movable structures 170 and 175. (Savage et al., col. 3, In. 52-col. 4, In. 2; FIG. 3a). Savage et al. provides movement of the structures 170 and 175, and related reflector portions, up and down, parallel to the predominant direction of reflected light, due to the strobe 22, from the reflector portion fixed to central stationary skeletal structure 135. (Id.)
A lighting fixture primarily used for theatrical effect including the ability to change color, control beam angle, pan and tilt, and vary the light output from a dim glow to full power continuously.
The fixture, in at least one embodiment, may include a main overall reflector that has four segments with each segment paired to an independently controllable light source. Each light source may include multiple light emitting diode emitters typically including Red, Green, Blue, and White devices. The light sources may be other colors such as warm white, cool white, lime, amber, yellow, violet, cyan, and ultraviolet.
In at least one embodiment, a theatrical lighting apparatus is provided comprising a plurality of light sources including a first light source and a second light source; and a plurality of reflector segments including a first reflector segment and a second reflector segment; wherein the plurality of light sources are centrally located between the plurality of reflector segments; wherein each of the plurality of reflector segments has a focal point; wherein the first light source is located approximately the focal point of the first reflector segment; and wherein the second light source is located approximately the focal point of the second reflector segment.
The plurality of light sources may be comprised of at least one white light emitting diode light source.
The plurality of light sources may be fixed to a single heat exchanger centrally located between the plurality of reflector segments.
The heat exchanger may be configured to be moved relative to the plurality of reflector segments by an actuator.
The heat exchanger may be comprised of a liquid cooling system.
The plurality of reflector segments may include one or more further reflector segments in addition to the first reflector segment and the second reflector segment; and at least two of the plurality of reflector segments may be individually moveable by an actuator in relation to the other reflector segments of the plurality of reflector segments by an actuator.
The theatrical lighting apparatus may be further comprised of a positioning system to direct the light emitted from the plurality of light sources directed by the plurality of reflector segments.
The present invention, in at least one embodiment also provides a method comprising: providing a plurality of light sources including a first light source and a second light source; and providing a plurality of reflector segments including a first reflector segment and a second reflector segment; wherein the plurality of light sources are centrally located between the plurality of reflector segments; wherein each of the plurality of reflector segments has a focal point; wherein the first light source is located approximately the focal point of the first reflector segment; and wherein the second light source is located approximately the focal point of the second reflector segment.
The plurality of light sources may be comprised of one or more light sources as previously described and may be configured as previously described. The heat exchanger and the plurality of reflector segments may be configured as previously described.
The method may further include directing the light emitted from the plurality of light sources by use of the plurality of reflector segments through a positioning system.
The heat-exchanger 10 is located in the center of the combination of the reflector segments 2, 4, 6, and 8 or in the center of reflector segments 2′, 4′, 6′, and 8′, and can move in and out of the focal point providing a zoom effect transitioning from converging rays to collimated rays to diverging rays. This effect can be either collective by moving the heat-exchanger 10 as shown by the movement from
Each of the light sources or light emitting diodes 12a, 12b, 12c, and 12d is configured to be controlled by a computer processor. This allows for animated effects such as simulated rotation and random shadows. The corresponding light source and reflector segment, such as for example light source 12c projects its light rays, primarily or entirely, onto corresponding reflector segment 2, can be used to create complex color combinations and variable beam angles. Similarly, or identically, light source 12b projects its light rays, primarily or entirely, onto corresponding reflector segment 8; light source 12a projects its light rays, primarily or entirely, onto corresponding reflector segment 6; and light source 12d projects its light rays, primarily or entirely, onto corresponding reflector segment 4
The control system, including a computer processor, may be a control system from any one of U.S. Pat. Nos. 10,344,944; 10,718,486; 10,551,034; and 9,404,641, which are incorporated by reference herein. The control system and/or computer processor is configured to be programmed by computer software in accordance with the present invention, to control a motor for moving one or more of the plurality of segments 2, 4, 6, and 8 or one or more of the plurality of segments 2′, 4′, 6′, and 8′, and to control lights of light source or light emitting diodes 12a-d.
The reflector segments 2, 4, 6, and 8 or 2′, 4′, 6′, and 8′ are spaced apart such that the focal point for each of these reflector segments is located at the face of its corresponding light source on one of the four sides of the heat-exchanger 10. Each side of the heat-exchanger 10 will have one segment of the overall reflector. The entire assembly including the overall reflector (including all of segments 2, 4, 6, and 8 or all of segments 2′, 4′, 6′, and 8′) and heat-exchanger 10 will be mounted in a motorized yoke 16, which is mounted to a base 18, allowing the pan and tilt of the fixture 1 or 1′.
Two different layouts of two different overall reflectors in the lamp housing 14 are provided by fixture 1 or 1′. Although a square head is shown for the lamp housing 14, other shapes such as a circular arrangement can be employed in alternative embodiments.
In
For a theoretical point light source 102, light rays, such as light rays R1a, R2a, R3a, and R4a, emanate from point light source 102 and reflect off of parabolic light reflector 104 to form light rays R1b, R2b, R3b, and R4b, respectively, as shown in
However, if one uses two flat light sources 202a and 202b, spaced apart and attached to a housing 202 as in
For the light sources 202a and 202b, with the square housing 202 substantially at the focal point of the parabolic reflector 104, light rays, such as light rays from light source 202a, such as light rays R1a′ and R2a′ emanate from and reflect off of parabolic light reflector 104 to form light rays R1b′ and R2b′, respectively; and light rays from light source 202b, such as light rays R3a′ and R4a′ emanate from and reflect off of parabolic light reflector 104 to form light rays R3b′ and R4b′, respectively.
Because the light sources 202a and 202b are not point light sources, the reflected light rays R1b′, R2b′, R3b′, and R4b′ are not parallel to each other, i.e. are not collimated.
One can form the segments 304a-d and position the segments 304a-d by cutting the parabolic reflector 104 into quadrant segments 104a, 104b, 104c, and 104d (shown by dashed lines in
Positioning the segments 304a-d, for example by cutting the reflector 104 into segments 104a-d and moving those segments outwards to form and position segments 304-d as shown in
Note that instead of cutting an integrated reflector 104 to form segments 304a-d, in accordance with another embodiment of the present invention, a reflector segment 304a can first be formed, for example, and then each of reflector segments 304b-d can be formed as duplicates of the segment 304a, and then segments 304a-d are configured to be appropriately rotated, oriented, and/or positioned as in
In
In at least one embodiment, the segment 404a is connected to the segment 404b by member 405a which, in at least one embodiment, may be made of any suitable spacing material such as including polymers such as polymethyl methacrylate (PMMA), polycarbonate, or a metal substrate. Similarly, the segment 404b is connected to the segment 404c by member 405b which may be made of a similar or identical material as segment 404a. Similarly, the segment 404c may be connected to the segment 404d by member 405c which may be made of a similar or identical material as segment 404a. Similarly, the segment 404d may be connected to the segment 404a by a member 405d which may be made of a similar or identical material as segment 404a.
The combination of reflector segments 404a-d in the diagram 400 of
The apparatus 400 shown in
Although a square or rectangular housing 402 is shown for the heat exchanger of the apparatus 400 and a square and/or rectangular housing 10 is shown for the heat exchanger of the apparatus of
For example a triangular heat exchanger may be provided with three sides which would have three corresponding reflector segments in at least one embodiment.
In at least one embodiment, each of a plurality of reflector segments, such as segments 2, 4, 6, and 8 shown in
For example, reflector segment 2 is spaced apart a horizontal distance of D1 from adjacent reflector segments 4 and 8, and is spaced apart a horizontal distance from reflector segment 6, wherein the direction of the spacing of the horizontal distance, such as D1, is perpendicular or substantially perpendicular to the direction of a beam of reflected light, from reflector segments 2, 4, 6, and 8, due to light from plurality of light sources 12-d, as shown in
Similarly, or identically, reflector segment 4 is spaced apart a horizontal distance of D1 from adjacent reflector segments 2 and 6, and is spaced apart a horizontal distance from reflector segment 8, wherein the direction of the spacing of the horizontal distance, such as D1, is perpendicular or substantially perpendicular to the direction of a beam of reflected light, from reflector segments 2, 4, 6, and 8, due to light from plurality of light sources 12-d, as shown in
Similarly, or identically, reflector segment 6 is spaced apart a horizontal distance of D1 from adjacent reflector segments 4 and 8, and is spaced apart a horizontal distance from reflector segment 2, wherein the direction of the spacing of the horizontal distance, such as D1, is perpendicular or substantially perpendicular to the direction of a beam of reflected light, from reflector segments 2, 4, 6, and 8, due to light from plurality of light sources 12-d, as shown in
Similarly, or identically, reflector segment 8 is spaced apart a horizontal distance of D1 from adjacent reflector segments 2 and 6, and is spaced apart a horizontal distance from reflector segment 4, wherein the direction of the spacing of the horizontal distance, such as D1, is perpendicular or substantially perpendicular to the direction of a beam of reflected light, from reflector segments 2, 4, 6, and 8, due to light from plurality of light sources 12-d, as shown in
The light sources 12a-d are located substantially at the focal points of the first reflector segments 6, 8, 2, and 4, respectively.
The configuration of
Similarly or identically, as shown in
Similarly or identically, as shown in
Similarly or identically, as shown in
Similarly or identically, as shown in
In at least one embodiment, each of the reflector segments are spaced apart from one or more adjacent reflector segments of the plurality of reflector segments by a distance of at least a dimension of a housing to which the plurality of light sources are fixed. For example, reflector segment 404a is spaced apart by D6 from adjacent segments 404b and 404d, and the spacing D6 may be equal to or greater than the width, D5, of a housing 402 wherein the housing 402 may be part of or the same as a heat exchanger 402. Similarly, or identically, In the embodiment of
In at least one embodiment, a plurality of reflector segments are movable in a vertical direction with respect to each other, wherein the vertical direction is perpendicular to the horizontal direction. For example, the segments 2, 4, 6, and 8 may be configured to be movable in a vertical direction U1 or a vertical direction D1 as shown by
Similarly or identically, each of the segments 404a-d may be configured to be movable in a vertical direction, with respect to each other, and with respect to housing or heat exchanger 402, which is perpendicular to a horizontal direction, where the horizontal direction is perpendicular to the direction of a beam from reflected light from the segments 404a-d, due to light from light sources 402a-402d.
In at least one embodiment, each of the plurality of light sources, such as light sources 402a-402d, is mounted to a housing, such as housing or heat exchanger 402 which is at a center formed by the plurality of reflector segments 404a-d, such that there is a horizontal gap between the housing 402 and any reflector. This configuration in at least one embodiment, helps to optimize collimation of light rays, such as shown for example, in
In at least one embodiment, each of the plurality of reflector segments, such as 404a-d shown in
In at least one embodiment, the housing, such as housing 402 is configured so that the housing 402 does not overlap any reflector in the horizontal direction. This may also be done to help optimize collimation of light rays, such as shown for example in
In
Although the invention has been described by reference to particular illustrative embodiments thereof, many changes and modifications of the invention may become apparent to those skilled in the art without departing from the spirit and scope of the invention. It is therefore intended to include within this patent all such changes and modifications as may reasonably and properly be included within the scope of the present invention's contribution to the art.
The present application is a continuation in part of and claims the priority of U.S. patent application Ser. No. 17/114,587 titled “THEATRICAL STROBE APPARATUS AND LIGHT SOURCES WITH OPTIMIZED FOCUS THEREOF”, filed on Dec. 8, 2020.
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ASAP Technical Publication, BROPN1150 (Mar. 24, 2008), Segmented Reflector Design Automotive reflector design process with ASAP and Reflector CAD. |
https://anomet.com/reflectors; Lighting Componenets; printed May 3, 2021. |
Number | Date | Country | |
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20220178516 A1 | Jun 2022 | US |
Number | Date | Country | |
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Parent | 17114587 | Dec 2020 | US |
Child | 17325259 | US |