Patent Publication Number: US-2011063835-A1

Title: Led lighting apparatus

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation in part of U.S. patent application Ser. No. 11/462,921 filed on Aug. 7, 2006; which issued on Jul. 20, 2010 as U.S. Pat. No. 7,759,876 which is a continuation of U.S. patent application Ser. No. 10/668,905 filed on Sep. 23, 2003 which now issued as U.S. Pat. No. 7,114,834 on Oct. 3, 2006, which claims priority under 35 U.S.C. 119e from provisional application Ser. No. 60/412,692 filed on Sep. 23, 2002. This application also claims priority from provisional application Ser. No. 61/345,066 filed on May 14, 2010, and provisional application 61/351,834 filed on Jun. 4, 2010 the disclosures of all of these applications being hereby incorporated by reference in their entirety. 
    
    
     BACKGROUND OF THE INVENTION 
     The invention relates to an LED light that is disposed within a housing having a reflector disposed therein. Multiple different embodiments all disclose LED lights in combination with reflectors. 
     SUMMARY OF THE INVENTION 
     The invention relates to a lighting device comprising a housing, a plurality of LED lights coupled in an array inside of the housing, and a reflective protrusion or simply a reflector coupled inside the cylindrical prismatic housing wherein the reflective protrusion is for reflecting light from the LED lights out of the cylindrical prismatic housing. 
     One of the benefits of at least one embodiment of the invention is to provide the appearance of an even, omni-directional light source extending in a 360 degree manner to create uniform light distribution about a room. Lighting with Fluorescent light bulbs provides a substantially even glow in an omnidirectional manner so that there are no unlit areas (or dead spots) around the outside cylindrical area were light bulb emits light. The fluorescent light radially emits light at 360 degrees about its cylindrical radius. Therefore, at least one design is designed to approach a uniform, omnidirectional lighting source, wherein by using LED lights, this is accomplished in a more efficient manner than with ordinary incandescent bulbs. 
     The housing can comprise a first end; a second end; and a cover coupling the first end to said second end. The cover is translucent. In one embodiment, a first LED array is coupled to a first end of the housing and a second LED array is coupled to a second end of the housing. 
     The housing can be formed in many shapes. For example, the housing can be substantially tubular shaped or formed with a circular cross section such as bowl shaped or formed with a substantially oval cross section. In addition, the protrusion can be formed in many different shapes as well. For example, the protrusion can be dome shaped, pyramidal shaped or spherical. There can also be a stand-alone reflector in the form of a sphere or semi-spherical design. Furthermore, the protrusion can be formed with rounded or angled sides. 
     To further increase the reflectiveness and the scattering of light the translucent cover comprises a plurality of prismatic lenses which can be in a sheet that assist in scattering the light as it is emitted by the LED lights. 
     To prevent the housing or the circuitry relating to the LED lights from overheating, the LED light array is coupled to a heat sink. In many cases, this heat sink is disposed in an end region of the housing. 
     The circuitry relating to this LED light array can include a power source such as a connection to an AC or DC input. If the connection is to an AC input, the device can also include an AC/DC converter coupled to the power source for receiving an input from the AC power source. In this way, the LED array receives a consistent flow of DC current that will not result in the degradation or burning out of LED lights. In addition, each of the LED lights in each of the LED arrays is coupled to an adjacent LED light in both series and in parallel, so that if one LED light burns out, the adjacent LED lights do not burn out. To prevent this LED array from burning out, there is also a current regulator for controlling a current running through this LED array. The current regulator can, for example regulate that only the current required by the LED passes through the array. This current regulator allows the device to connect to many different power sources with different input voltages. The circuitry relating to the LED light array uses a constant current design which is highly efficient and results in very minor heat losses. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       Other objects and features of the present invention will become apparent from the following detailed description considered in connection with the accompanying drawings which disclose at least one embodiment of the present invention. It should be understood, however, that the drawings are designed for the purpose of illustration only and not as a definition of the limits of the invention. 
       In the drawings, wherein similar reference characters denote similar elements throughout the several views: 
         FIG. 1A  is a side cross-sectional view of a first embodiment 
         FIG. 1B  is a side cross sectional view of the view in  FIG. 1A  taken along line I-I; 
         FIG. 1C  is a side view of the device which includes a prismatic film disposed on tube; 
         FIG. 1D  is a perspective view of the device shown in  FIG. 1C ; 
         FIG. 1E  is a side view of the device shown in  FIG. 1D ; 
         FIG. 2A  is a perspective view of a second embodiment of the invention; 
         FIG. 2B  is a perspective view of the view of  FIG. 2A  with a cover removed; 
         FIG. 2C  is a side view through the housing with the cover shown in dashed lines; 
         FIG. 3A  is a side view of the third embodiment of the invention; 
         FIG. 3B  is a detailed view of an end section shown in  FIG. 3A ; 
         FIG. 3C  is a perspective view of an end section as shown in  FIG. 3A ; 
         FIG. 3D  is a bottom-side perspective view of the embodiment shown in  FIG. 3A ; 
         FIG. 4A  is a side view of the embodiment shown in  FIG. 2A ; 
         FIG. 4B  is a side view of another embodiment of the invention; 
         FIG. 5A  is an end view of an end piece shown in  FIG. 1A ; 
         FIG. 5B  is a side view of the end piece shown in  FIG. 5A ; 
         FIG. 5C  is a perspective view of the end piece shown in  FIG. 5A ; 
         FIG. 6A  is a side view of another embodiment of the invention; 
         FIG. 6B  is a perspective view of the embodiment shown in  FIG. 6A  with the cover removed; 
         FIG. 6C  is a side view of the embodiment shown in  FIG. 6B ; 
         FIG. 6D  is a perspective view of the embodiment shown in  FIG. 6A  with the cover on; 
         FIG. 7A  is a perspective view of another embodiment of the invention with a cover removed; 
         FIG. 7B  is a top view of the embodiment shown in  FIG. 7A ; 
         FIG. 7C  is a side transparent view of the device shown in  FIG. 7A ; 
         FIG. 8A  is a perspective view of another embodiment of the invention; 
         FIG. 8B  is a top view of the embodiment shown in  FIG. 8A ; 
         FIG. 8C  is a side transparent view of the embodiment shown in  FIG. 8A ; 
         FIG. 9A  is a perspective view of another embodiment of the invention; 
         FIG. 9B  is a top view of the view shown in  FIG. 9A ; 
         FIG. 9C  is a side cross-sectional view of the embodiment shown in  FIG. 9A  taken through section A-A; 
         FIG. 9D  is a side cross-sectional view of another embodiment of the invention; 
         FIG. 9E  is a perspective view of the device shown in  FIG. 9D ; 
         FIG. 10A  is a perspective view of another embodiment of the device; 
         FIG. 10B  is a side view of the device shown in  FIG. 10A ; 
         FIG. 11A  is a perspective view of a new reflector; 
         FIG. 11B  is a perspective view of the reflector of  FIG. 11A  inserted into a tube; 
         FIG. 11C  is an end view of the device in  FIG. 11B ; 
         FIG. 11D  is a side view of the device shown in  FIG. 11C ; 
         FIG. 12A  is an end view of one of the endcaps; 
         FIG. 12B  is a perspective view of the endcaps shown in  FIG. 12A ; 
         FIG. 12C  is a cross-sectional view through line XII-XII of the endcaps shown in  FIG. 12A ; 
         FIG. 12D  is a cross sectional view of the device with the endcaps removed showing the collimating effect of the lens; 
         FIG. 13A  is a top view of the device inserted into a lighting housing for mounting in a ceiling; 
         FIG. 13B  is a perspective view of the device shown in  FIG. 13A ; 
         FIG. 14A  is a side view of the device shown in  14 A with a section of the cover removed; 
         FIG. 14B  is a close-up view of one of the prisms in a prism sheet; 
         FIG. 15  is a side view with a center section of the tube removed for viewing a reflector; 
         FIG. 16  is a schematic diagram of a circuit for use with the device; and 
         FIG. 17A  is a perspective view of the device showing a uniform light distribution pattern; 
         FIG. 17B  is a side view of the device showing a uniform light distribution pattern; 
         FIG. 17C  is a side view of the device rotated 90.degree. showing a uniform light distribution pattern; and 
         FIG. 18A  is a perspective view of another embodiment; 
         FIG. 18B  is a side transparent view of the embodiment shown in  FIG. 18A ; 
         FIG. 18C  is a side view of the reflector material; 
         FIG. 19  is a side cross-sectional view of a first embodiment of a light system; 
         FIG. 20A  is a top perspective view of a reflector for use in a light system; 
         FIG. 20B  is a top view of the reflector shown in  FIG. 20A ; 
         FIG. 20C  is a cross-sectional view of the reflector shown in  FIG. 20A and 20B ; taken along the line A-A in  FIG. 20D ; 
         FIG. 20D  is an end view of the reflector; 
         FIG. 21A  is a top view of a second light system; 
         FIG. 21B  is a center view of a dual reflector taken within Detail D of  FIG. 21A ; 
         FIG. 21C  is a side end view of the light shown in  FIG. 21A ; 
         FIG. 21D  is a close up view of Detail E of  FIG. 21C ; 
         FIG. 22A  is a top view of a light with a heat sink for use with the light system of  FIG. 20A ; 
         FIG. 22B  is a perspective view of the light/heat sink as shown in  FIG. 22A ; 
         FIG. 22C  is an exploded perspective view of the light/heat sink shown in  FIG. 22A  and  FIG. 22B ; 
         FIG. 22D  is an end view of the light/heat sink; 
         FIG. 22E  is a side cross-sectional view of the light taken along the line A-A in  FIG. 22D ; 
         FIG. 23  is a top perspective exploded view of another embodiment of a light system; 
         FIG. 24A  is a side view of a light/heat sink shown in  FIG. 25A ; 
         FIG. 24B  is a side view of a light/heat sink shown in  FIG. 25A ; 
         FIG. 24C  is a side view of a connection between a light and a reflector shown in  FIG. 25A ; 
         FIG. 24D  is a side view of a reflector shown in  FIG. 25B  taken along the line H-H; 
         FIG. 24E  is an end view of a heat sink/circuit board taken along section J-J of  FIG. 25C ; 
         FIG. 24F  is an end view of the heat sink and reflector taken along the line I-I of  FIG. 25B ; 
         FIG. 24G  is a side view of the light system taken along the line L-L; 
         FIG. 26A  is a top transparent view of another lighting system; 
         FIG. 26B  is a view of the lighting system of  FIG. 26A  taken across section B-B; 
         FIG. 26C  is a cross-sectional view taken along another section; 
         FIG. 26D  is a side transparent view of the device shown in  FIG. 26A ; 
         FIG. 26E  is a side cross-sectional view taken along section line A-A shown in  FIG. 26A ; 
         FIG. 27A  is a top view of a lens and heat sink combination shown in  FIG. 26A ; 
         FIG. 27B  is an end view of this light/heat sink combination; 
         FIG. 27C  is a perspective view of this light/heat sink combination; 
         FIG. 27D  is a view of the lens taken along section line B-B shown in  FIG. 27B ; 
         FIG. 27E  is a side cross-sectional view taken along section line A-a shown in  FIG. 27A ; 
         FIG. 28A  is a top view of another type of light/heat sink combination shown in  FIG. 26A ; 
         FIG. 28B  is a side cross-sectional view of the light/heat sink combination shown in  FIG. 28A  taken along section line A-A; 
         FIG. 28C  is a perspective view of the light/heat sink combination shown in  FIG. 28A ; 
         FIG. 28D  is an end view of the light/heat sink combination with the light removed;  FIG. 28E  is a cross-sectional view of the heat pipe; 
         FIG. 29A  is a top view of a reflector which is configured to be used with the design of  FIG. 26A ; 
         FIG. 29B  is a cross-sectional view of the reflector taken along section line A-A shown in  FIG. 29C ; 
         FIG. 29C  is an end view of the reflector of  FIG. 29A ; 
         FIG. 29D  is a perspective view of the reflector of  FIG. 29A ; 
         FIG. 29E  is another embodiment of a reflector having a differently shaped second reflector section than the reflector shown in  FIG. 29A ; 
         FIG. 30A  is a back perspective view of a lens; 
         FIG. 30B  is a front perspective view of the lens of  FIG. 30A  and also of  FIG. 26A ; 
         FIG. 30C  is a side cross-sectional view of the lens taken along section line A-A of  FIG. 30D ; 
         FIG. 30D  is an end view of the lens of  FIG. 30A ; 
         FIG. 31A  is a bottom view of the lens/heat sink combination using reflector and heat sink and light; 
         FIG. 31B  is an end cross-sectional view taken along line C-C shown in  FIG. 31A ; 
         FIG. 31C  is a view of this lens/light/heat sink/and reflector combination shown in  FIG. 31A and 31E  taken at detail E of  FIG. 31E ; 
         FIG. 31D  is a view of the light/heat sink combination taken at detail B of  FIG. 31E ; 
         FIG. 31E  is a perspective view of the light/reflector/lens/heat sink combination of  FIG. 31A  with some of the reflectors removed; 
         FIG. 32A  is a side cross-sectional view of a light system; 
         FIG. 32B  is a side cross-sectional view taken of Detail B shown in  FIG. 32A ; 
         FIG. 32C  is a perspective exploded view of the light system of  FIG. 32A ; 
         FIG. 32D  is a view of the light/heat sink/reflector combination shown in  FIG. 32C ; 
         FIG. 33A  is a perspective view of a reflector system for use with a light system; 
         FIG. 33B  is a top view of the reflector shown in  FIG. 33A ; 
         FIG. 33C  is a side view of the reflector shown in  FIG. 33A ; 
         FIG. 33D  is an end view of the reflector shown in  FIG. 33A ; 
         FIG. 34A  is a top perspective view of a light system with a translucent cover removed; 
         FIG. 34B  is a perspective view of the light system with the cover on; 
         FIG. 35  is a top perspective view of another embodiment of the light system; 
         FIG. 36A  is a top view of another embodiment; 
         FIG. 36B  is a view taken along the line A-A; 
         FIG. 37A  is a top transparent view of another embodiment of a light system; 
         FIG. 37B  is a side transparent view of another embodiment; 
         FIG. 37C  is a side cross-sectional view taken along the line A-A; 
         FIG. 37D  is a perspective view of this design; 
         FIG. 38A  is a top transparent view of another embodiment; 
         FIG. 38B  is a side transparent view of the design of  FIG. 38A ; 
         FIG. 38C  is a top perspective view of the design shown in  FIG. 38A ; 
         FIG. 38D  is a bottom perspective view of the design shown in  FIG. 38A ; 
         FIG. 39A  is a top view of another embodiment; 
         FIG. 39B  is a top perspective view of the design shown in  FIG. 38A ; 
         FIG. 39C  is a side transparent view of the device shown in  FIG. 39A ; 
         FIG. 39D  is a side cross-sectional view taken along line A-A of  FIG. 39C ; 
         FIG. 39E  is a detail B close up view shown in  FIG. 39D ; 
         FIG. 40A  is a top view of another design; 
         FIG. 40B  is a top perspective view of this design shown in  FIG. 40A ; 
         FIG. 40C  is a side transparent view of the design shown in  FIG. 40A ; 
         FIG. 40D  shows a side cross-sectional view taken along line A-A of  FIG. 40C ; 
         FIG. 40E  is a detail B section taken from  FIG. 40D ; 
         FIG. 41A  is a side transparent view of the light design shown in  FIG. 40A ; 
         FIG. 41B  is a side cross-sectional view taken along line A-A of  FIG. 41A ; 
         FIG. 42A  is a top view of the heat sink/light combination shown in  FIG. 41A ; 
         FIG. 42B  is a detail B taken from  FIG. 42A ; 
         FIG. 42C  is a side perspective view of the heat sink/light combination of  FIG. 42A ; 
         FIG. 42D  is a view of this light/heat sink combination being combined with a reflector; 
         FIG. 42E  is a perspective view of a light/heat sink combination shown in  FIG. 42C ; 
         FIG. 43A  is a side view of another embodiment; 
         FIG. 43B  is an end view of the embodiment shown in  FIG. 43A ; 
         FIG. 43C  is a perspective view of the embodiment shown in  FIG. 43A ; 
         FIG. 44A  is a front transparent view of another design; 
         FIG. 44B  is a side transparent view of the design of  FIG. 44A ; 
         FIG. 44C  is a perspective view of the design shown in  FIG. 44A ; 
         FIG. 45A  is a front view of another design; 
         FIG. 45B  is a perspective view of the design shown in  FIG. 45A ; 
         FIG. 46A  is a top perspective transparent view of another design; 
         FIG. 46B  is a top perspective view of the design of  FIG. 46A ; 
         FIG. 47A  is a perspective view of another design; 
         FIG. 47B  is a side transparent view of the view of  FIG. 47A ; 
         FIG. 47C  is a side transparent view of the design of  FIG. 47A  taken from another view as shown in  FIG. 47B ; 
         FIG. 47D  is a side cross-sectional view taken along line B-B of  FIG. 47B ; 
         FIG. 47E  is a side cross-sectional view taken along line A-A of FIR.  47 C; 
         FIG. 48A  is a side cross-sectional view of another design taken alon line B-B of  FIG. 48D ; 
         FIG. 48B  is an exploded view of components of this design; 
         FIG. 48C  is a perspective view of this design with a section of the heat sink being exposed; 
         FIG. 48D  is a side view of the design; 
         FIG. 48E  is a side close up view of section C shown in  FIG. 48A ; 
         FIG. 49A  is a side transparent view of another embodiment; 
         FIG. 49B  is a side perspective view of the embodiment shown in  FIG. 49A ; 
         FIG. 49C  is a side transparent view of the design shown in  FIG. 49A ; 
         FIG. 49D  is a side cross-sectional view taken along line B-B shown in  FIG. 49A ; 
         FIG. 49E  is a side-cross-sectional view of the device taken along section line A-A of  FIG. 49C ; 
         FIG. 50A  is a perspective view of a first pattern of light beams; 
         FIG. 50   b  is a second view of this pattern of light beams taken along line A-A in  FIG. 50C   
         FIG. 50C  is an end view of this design which can be in the form of the design of  FIGS. 29A ,  26 D and  19 ; 
         FIG. 51A  is a perspective view of another view of another set of light beams; 
         FIG. 51B  is a cross sectional view taken along line A-A of  FIG. 51C ; 
         FIG. 51C  is an end view; 
         FIG. 52A  is another view of another light pattern; 
         FIG. 52B  is a close up view of the light pattern; 
         FIG. 52C  is an end view; 
         FIG. 53A  is a perspective view of the light pattern; 
         FIG. 53B  is a side view of this light pattern of  FIG. 53A  and  FIG. 53C  is an end view. 
     
    
    
     DETAILED DESCRIPTION 
     Turning now in detail to the drawings,  FIG. 1A  is a side cross-sectional view of a first embodiment of the invention. This view shows from an outside perspective, a design similar to that of a phosphorescent or florescent tubular bulb. With this device  10  there is a housing formed from a translucent-prismatic lens  11  and end caps  15  and  16  attached at each end. Inside of cover or tube  11 , is a reflective sphere  19 , which is used to reflect light from LED lights  30  which are embedded into a lighting housing  35  in end caps  15  and  16 . LED lights  30  are arrayed in lighting housing  35  so that they shine a light onto a common point on collimator lens  100 . For example, there are a plurality of different LED arrays disposed at precise angles with a first array in the form of array  30   a  comprising a plurality of lights arranged around a rim of lighting housing  35 . This first set of LED lights in array  30   a  are set at a first angle to shine on a central region of lens  100 . A second set of LED lights in array  30   b  are arrayed around the rim of lighting housing  35  and are set at a different angle than that of first array  30   a.  LED lights in arrays  30   a,    30   b  and  30   c  are all set in lighting housing  35  at different angles than the respective remaining arrays. In this way, the LED lights from these different arrays all shine on a central region of lens  100  wherein this light is then collimated by collimating lens  100 . LED array  30   f  is in the form of a backplate which houses a series of lights disposed at a precise angle around this back plate. These LEDs are directed radially inward to a central region on lens  100 . In this way, there is little light lost due to reflection because all of the lights are directed towards a central region of collimating lens  100 . The reflective sphere  19  has a round or substantially round shape. This reflector  19  has a shape taken from the group comprising or consisting of: rounded, spherical, semi-spherical, dome shaped, or a shape having at least one portion that is, or is at least substantially rounded, dome shaped or spherical shaped. 
     To achieve this result of little light loss, LED lights  30  are positioned at different angles in an aluminum housing that also serves as heat sink to create a common point for convergence of the light. The heat collected by the aluminum housing is absorbed by a non-conducting insulating pad  30   h  and transferred to a secondary heat sink  30   i  which dissipates heat to the surroundings. Lens  100  is a collimating lens, which is disposed in tube  11  and is used to focus the light so that it creates a common light pattern with virtually no loss of light. For example, if two or more beams are shined on a common object, the two or more beams could flow in the same path out of phase so that the result would be an amplification of total light for each beam added without much loss. However, if two or more beams are shined on an object and flowing along the same path and in phase, then there is no additional gain of light from this feature. 
     Thus, lens  100  is disposed inside of cover  11  so to act as a collimator so that it can be used to collimate the light emanating from LED lights  30  so that the different rays of light do not flow along a substantially same path. LED lights  30  can be of any color but would preferably be used to give the appearance of white light. 
       FIG. 1B  is a cross-sectional view of the tube  11  taken along line I-I. In this view there is shown a copy of the tube  11  with a prismatic film  101  inserted therein. Prismatic Film  101  is in the form of a semi-transparent, translucent film which is designed to reflect, and refract the light to provide the effect of a uniformly distributed light pattern. Prismatic film  101  can be in the form of a prismatic film that refracts light to create a consistent flow of light out of film  101 . 
       FIG. 1C  is a side view of the device  10  which includes a prismatic film or texture  102  disposed on an outside of tube  11 . With this design there is spherical reflector  19  coupled therein wherein a central region of this prismatic film  102  is shown removed for the purpose of showing spherical reflector  19 . Endcaps  15  and  16  are coupled to tube  11  wherein these endcaps show lens  100  and a plurality of LED arrays extending around in rings. Each LED array includes LED lights  30  which are angled at lens  100  at the same angle with the angles of the LED lights differing between the different LED arrays. For example, in the first LED array  30 A, the LED lights are pointed at lens  100  at a 39.degree. angle. In the second LED array  30 B, the LED lights are pointed at lens  100  at a 24.degree. angle. In the third LED array  30 C the LED lights are pointed at lens  100  at a 15.degree. angle. 
     These lights then shine in a radial inward pattern pointed at a center region on lens  100 .  FIG. 1D  shows a full perspective view of this embodiment, while  FIG. 1E  shows as side view of the embodiment in  FIG. 1D . 
       FIG. 2A  is a light whose source of light originates from the left end and the right end. This light is then shone onto the center reflector. The light distribution pattern generated is illustrated in  FIG. 4   a.    
       FIG. 2A  is a side perspective view of the embodiment of this design wherein this view shows cover  11   a  which is coupled to a housing base section  12 . Cover  11   a  can be tubular or semi-tubular and can attach to base section  12 .  FIG. 2B  is a perspective view of the view of  FIG. 2A  with cover  11   a  removed. In this view, there are two ends  15   a  and  16   a  coupled together via base section  12 . Base section  12  is formed with a semi-circular cross-section with a reflective inner face to reflect light out of the housing through prismatic translucent cover  11   a.    
     A reflective protrusion  20  which has a minor surface  20  is coupled to base section  12  and is in the form of a substantially dome shaped element. There is also a first LED array  30   g  coupled to first endcap  15   a  so that first LED array  30   g  shines light from LED lights into the housing so that it is reflected from the inner face of base section  12  and protrusion  20 . 
     In addition,  FIG. 2C  is a side view through the housing with the cover shown in dashed lines, in this view, a second LED array  30   f  is shown coupled to second end  16   a  so that light from this LED array can be shined or shone through the housing and out of the housing so that it can illuminate a room. 
     Essentially in this design, light emanates from LED arrays  30   f  and  30   g  and reflects off of reflective dome  20 . This reflected light then emanates out of the prismatic cover  11   a.  In addition, light which emanates from LED arrays  30   f  and  30   g  also passes through cover  11   a  to light a room without reflecting off of reflector  20 . This reflector has a shape taken from the group comprising or consisting of: rounded, spherical, semi-spherical, dome shaped, or a shape having at least one portion that is, or is at least substantially rounded, dome shaped or spherical shaped. 
     For example, this light could either pass directly from the associated LED array through cover  11  or it could reflect off of reflective support or base section  12  which has a highly reflective interior surface. 
       FIG. 3A  is a light whose source of light originates at the center light. This light is then shone onto the right and left reflectors. The light distribution pattern generated is illustrated on  FIG. 4   b.    
     In this case, there are different style end pieces  15   b,  and  16   b  which can be of different shapes for example having a sloped front surface  37  and  38  (See  FIGS. 3B and 3C ) which form a reflector for reflecting light that is sent. As shown in  FIG. 3D , there are also unique intermediate lighting housings  39  having a sloped front section and a plurality of LED lights coupled therein. 
       FIGS. 4A and 4B  show two different types of designs for two different types of reflective protrusions. For example,  FIG. 4   a  shows device  10  having a reflective protrusion  20 . Reflective protrusion  20  is formed as semi-spherical as shown in  FIGS. 2B   2 C.  FIG. 4B  shows a device  13  having a reflective protrusion  21  which is oblong in shape wherein this reflector  21  has a substantially mirrored surface and is used to reflect light from this surface. 
       FIGS. 5A ,  5 B and  5 C disclose at different viewing angles an LED array  30   f  and  30   g,  which includes LED lights  30  coupled therein. This LED array  30   f  and  30   g  includes a spacer which aligns an LED cluster into a single point or region and brings all the light coming from each LED into a central region so that maximum light output is realized at the focal point where all the light comes together. 
       FIGS. 6A ,  6 B,  6 C and  6 D involve another embodiment of the design  40 , wherein in this design, there is a new type base section  14  which includes a central reflecting protrusion  20 , but base section  14  is not tubular in shape as in base section  12  in  FIG. 2A . Instead, this base section  14  has a semi-oval cross-section wherein there is a flattened, or slightly rounded base plate  14   a  and rounded sides  14   b  which can be used to receive a correspondingly shaped cover  11   b.  Protrusion  20  is coupled to base plate  14   a  and also two sides  14   b  to provide a continuous reflective surface for reflecting light emanating from the coupled in LED arrays  39  which are patterned after endcaps  15   a  and  15   b  shown in  FIGS. 3A ,  3 B and  3 C. This set of LED arrays create a different version of the overall uniform light distribution pattern. 
       FIGS. 7A ,  7 B and  7 C disclose another design, which involves a base section  50  having a reflective base plate  52 , and a set of side walls  54 . Base section  52  is concave in shape and forms a bowl or recess as shown in  FIG. 7C . Reflective protrusion  22  extends out from base section  52  and is shaped in an oblong manner so that it has an oblong semi-cylindrical body  22   a  and rounded end caps  22   b  and  22   c.  LED lights  30  are coupled into side walls  54  and form a new LED array  60  wherein these LED lights point to reflective protrusion  22  so that once light shines on this protrusion  22 , it is reflected out from base section  50 . In this case, an interior region of base section  50  including side walls  54 , base plate  52  and protrusion  22  are all made from a reflective surface such as a mirror reflector, however reflective protrusion  22  may be made from a different reflective material than the remaining interior reflective material on base section  50 . Reflective protrusion has a shape taken from the group comprising or consisting of: rounded, spherical, semi-spherical, dome shaped, or a shape having at least one portion that is, or is at least substantially rounded, dome shaped or spherical shaped. 
       FIGS. 8A ,  8 B and  8 C disclose another embodiment of the invention  70  wherein this embodiment includes a base section  71  which is shaped as a bowl having a rounded top. Inside base section  71  are side walls  73  with a plurality of holes  72  for receiving LED lights. These side walls dip down to form a deep bowl shaped product. In addition, there is a reflective protrusion  74  shaped as a dome which is coupled to a bottom end  75 . Reflective dome shaped protrusion has a series of holes  76  which allow LED lights to fit through. Thus, these LED lights can fit through both holes  72  in side walls  73 , and holes  76  in dome  74 . Reflective dome  74  also includes a pre-dome section  78  which provides a transition area between bottom section  75  and dome section  74 . 
       FIG. 8B  shows a top view of this same embodiment showing that holes  72  and holes  76  are spaced opposite each other so that they can be used to light the surrounding reflective surface of base section  71 . Base section  71  is reflective and can be made from a minor finish material. In one embodiment however, reflective dome  74  can be made from a mirror finish material while the remaining reflective material can be made from a different material.  FIG. 8C  also discloses a side cross sectional view of this embodiment which shows that base section  71  also contains an outer wall  79  forming an outer peripheral rim cover for any LED lights that are coupled in. Base section forms a first reflective section while reflective dome  74  forms a second reflective section. 
       FIGS. 9A ,  9 B and  9 C show a similar design as described above, however this design does not include holes  76  so that a new dome  74   a  is formed wherein this dome  74   a  is formed as an entirely reflective dome. 
       FIG. 9D  shows a cross-sectional view of another embodiment of the device  90 . In this view there is a base cap  91  which includes LED array  30   f  which sends light into a substantially translucent light housing  92  shaped substantially like a light bulb. This light housing has a reflective protrusion  94  which is shaped as a dome made from material having a reflective material finish which then reflects light out into a room to create the effect of a substantially uniform light source in all directions. In addition a prismatic film such as prismatic film  101  or  102  shown in  FIG. 1B  or  1 C may be incorporated into housing  92  to increase the illuminating effect of LED lights  30 .  FIG. 9E  shows a perspective view of this device as well. 
       FIGS. 10A and 10B  show another embodiment of the invention  124  which includes an additional intermediate LED station  125  which includes LED lights  30  coupled therein as well as a surrounding reflective housing. With this design, LED light points out in two directions from LED stations  125 . In a first direction, light emanates from station  125  towards reflector  20 . In the second direction, light emanates out from stations  125  and on to side reflectors  126   a  and  126   b  which are formed as slanted, rounded reflectors which reflect light down into a room. 
       FIGS. 11A ,  11 B,  11 C and  11 D show another type of reflector  120  that can be inserted into tube  11 . Reflector  120  can be formed as three concave reflectors  120   a,    120   b,  and  120   c  that can have a mirror or substantially mirror type finish that allows light to be reflected out from tube  11 . This reflector  120  is designed to intersect a spherical reflector  19  in a central region as shown in  FIG. 11A  with an opposite set of reflectors  120  intersecting spherical reflector  120  on an opposite side. 
       FIGS. 12A ,  12 B and  12 C disclose three different views of endcaps  15 , and  16 .  FIG. 12A  is an end view of endcaps  15  and  16 ,  FIG. 12B  is a perspective view, while  FIG. 12C  is a cross-sectional view through line XII-XII. These endcaps are formed as substantially cylindrical endcaps having a first cylindrical connecting section  110 , a flange or heat sink  112   a  coupled to connecting section  110  and a back support section  114  coupled to flange  112   a.  Connecting section  110  is sized to fit into a tube or housing wherein connecting section  110  has a circular cross section. Flange or heat sink  112   a  extends radially out from connecting section  110  and is used to dissipate heat away from the LED lights coupled into back support section  114 . 
     Back support section  114  has a plurality of holes  116  which are adapted to receive a plurality of LED lights  30  forming arrays  30   a,    30   b,    30   c,  and  30   f  which extend in and shine in at an angle. Disposed between these holes are additional optional flanges represented by dashed lines  112   b,    112   c  and  112   d  wherein these flanges also act as heat sinks. In addition, connecting section  110  is also adapted to receive a lens  100  (See also  FIG. 1A ), wherein lens  100  focuses and allows light to extend out from endcaps  15  and  16 . Extending out from back support section  114  is a back electrical connection  116  containing prongs  118  for connection to an electrical light socket such as a light socket for fluorescent bulbs. 
       FIG. 12D  shows a side cross-sectional view of the device wherein the light housing has been removed and this view reveals LED arrays  30   a,    30   b,  and  30   f  all showing light being sent in from LED lights  30  into a central region of lens  100  wherein this light is then collimated and then sent as a steady stream to reflector  19 . 
       FIG. 13A  shows a plan view of two of the devices  10  coupled into a lighting housing  90  which can be similar to a florescent lighting housing. In this view, device  10  has end caps  15 , and  16  which are coupled into tube  11  and shine light on a substantially oval shaped reflector  119 , which is disposed in a central section of tube  11 . 
       FIG. 13B  shows a perspective view of a substantially similar design to that shown in  FIG. 13A , however, this design includes spherical reflector  19  shown in  FIG. 1A . In this design, lighting housing  90  includes end plates  92  as well. In one of these devices  10 , there is no cover or tube  11  which has been removed to reveal spherical reflector  19 . In the other device there is at least a partial view of a cover or tube  11   b,  which includes a prismatic covering  102  which is used to reflect, and refract light to amplify the appearance of light. In addition, in this view, lenses  100  are also shown disposed adjacent to LED lights  30 . 
       FIG. 14A  shows a closer view of this prismatic lens covering  102 , which is used to deflect light. For example,  FIG. 14B  shows an even closer view of prismatic lens system  102  wherein this prismatic lens system includes a plurality of extensions  103  spikes, or pyramidal shaped tetrahedrons, which provide unique features in reflecting light. 
       FIG. 15  shows that prismatic lens system  102  extends substantially across tube  11  from endcap  15  to encap  16 , over reflector  119  and adjacent to lens  100 . The prismatic lens system  102  does not need to extend all the way to cover lens  100  because lens  100  acts as a collimator of light which focuses light emanating from LED lights  30  across tube  11  so that light extends through the tube to reflector  119 . 
       FIG. 16  shows a schematic electronic circuit diagram for the electronic circuitry for controlling power which is used to light the LED lights. This circuit  160  can be disposed in end section  116  in either endcap  15  or endcap  16 . Circuit  160  can include a power input connector  161  which can be in the form of prongs  118  extending out from back end section  116  (See  FIG. 12C ). 
     The circuit can also include an AC/DC converter  162 , a current regulator  170  and an LED load section  180  including a plurality of LED arrays. The power, which in all likelihood is AC power, can then feed into AC/DC converter  162 , which converts the AC current into DC current. In an alternative embodiment, this AC/DC converter can be in the form of a DC/DC converter as well. In either case, there is a bridge rectifier  164  to convert the current from AC to DC and at least one capacitor  166  to smooth out the waves to provide a reasonably steady current. To protect bridge rectifier  164  there is a surge protector  165  coupled in parallel with bridge rectifier  164  to provide protection against sudden surges in power. This power flows down a circuit line  168  and feeds into current regulator  170 . Current regulator  170  is designed to regulate the current flowing through the circuit so that LED lights  30  are not blown. In a preferred embodiment the current is regulated to be approximately  20  ma. 
     Current regulator  170  can be used to regulate the current so that there is always a consistent amount of current flowing through the circuit. This current regulator cannot provide an absolutely consistent current but rather provides a relatively narrow current range for current flowing through the circuit. This current regulator receives current flowing through circuit  160  and includes two transistors. The bridge rectifier  164  provides a DC input. Capacitor  166  provides smoothing of the DC input. Zener diode or surge protector  165  provides input surge protection for the electronics. The proper operating voltage range is established through voltage dropping resistor  171  (R 1 ) and transistor  172  (Q 1 ). Transistor  174  (Q 2 ) regulates the current through resistor  190  (R 2 ) and provides the required current to operate an LED array with the specific selected LED&#39;s operating current requirements. This regulated current then flows down line  168  into LED arrays  182 ,  184 ,  185 ,  186 ,  187  and  188  for powering LED lights  30 . 
     LED load section  180 , which includes LED arrays  182 ,  184 ,  185 ,  186 ,  187 ,  188 . Each of the LED arrays are coupled both in series and in parallel so that if one LED array is blown or destroyed the remaining LED arrays can receive power. In addition, each of the LED lights in each LED array is coupled in both series and parallel so that if one individual LED light is blown the remaining LED lights in each individual array can still shine. 
     With this design, the device can be coupled to a plurality of different power units, which can each have different voltage inputs. For example, power units having voltages in the order of 12V, 24V, 37V, 48V, 76V, 95V or 120V can be used to power this device because the current is always regulated by current regulator  170 . 
     With this design, device  10  having a reflector  19  or  20  and a set of LED arrays coupled into endcaps  15  or  16  can be used to create an omnidirectional light which creates a uniform light distribution pattern flowing from LED lights as shown in  FIGS. 17A ,  17 B and  17 C. This design with the circuit above is then adaptable to different power inputs such as those on cars trains or in houses to provide a lighting design that is inexpensive to operate. 
       FIG. 18A  shows a perspective view of another embodiment which discloses a two part bulb  201  having a first part  202 , and a second part  203 . First bulb  202  is bound by heat sinks  204  and  205  while second bulb  203  is bound by bulbs  205  and  206 . 
       FIG. 18B  shows a side view which shows two bulbs  202  and  203  wherein inside of each of these bulbs is a first reflector  210 , a middle reflector  211  and another reflector  212 . Each of these reflectors are bound by a heat sink  204  and  205 , wherein disposed inside of each of these heat sinks is a light (not shown).  FIG. 18C  shows these reflectors  210 ,  211 , and  212  in greater detail. Reflectors  210  and  212  are substantially conical or partially conical in shape, while reflector  211  is substantially or partially spherical in shape. First reflector  210  forms a first reflective section having a shape taken from the group comprising or consisting of: substantially conical, sectional conical, frusto-conical, or rounded, or at least has a portion that is, or is at least substantially conical, sectional conical, frusto-conical, or rounded. Reflector  211  forms a second reflective section having a shape taken from the group comprising or consisting of: rounded, spherical, semi-spherical, dome shaped, or a shape having at least one portion that is, or is at least substantially rounded, dome shaped or spherical shaped. The second reflective section has at least a portion which has a steeper slope compared to the first reflective section taken along a longitudinal axis of the reflector. 
       FIG. 19  shows a side cross-sectional view of a portion of the reflector shown in  FIG. 18B . In this view, there is shown reflectors  210 ,  211 , and  212  which are bound at each end by heat sinks  204  and  205 , wherein coupled to each of these heat sinks  204  and  205  are respective lights  214 , and  215 . These lights can be in the form of any sufficient lights but in at least one embodiment are LED lights. To prevent these LED lights from overheating, heat sinks  204  and  205  are provided. Heat sinks  204  and  205  can be made from any suitable material but in this case are made from either aluminum, copper or some form of metallic substance such as an aluminum or copper alloy having a sufficient heat conductivity to prevent the associated lights  214  and  215  from overheating. These lights, and reflectors are all housed inside of housing  213 . 
     In addition, these lights and reflectors are bounded or covered by a translucent and even transparent cover  222 . In this case cover  222  can be translucent and/or transparent, with the definitions for translucent and transparent provided above applying herein. 
       FIG. 20A  shows a side perspective view of the reflector which is embedded in a support structure  220 . Support structure  220  allows reflector  210 ,  211  and  212  to be coupled to an adjacent support structure. 
     The shapes of reflectors  210 ,  211  and  212  are shown in the previous drawings, but are also disclosed in  FIGS. 20A ,  20 B,  20 C and  20 D which show a partially conically shaped reflector such as reflector  210  leading into a partially or substantially spherically shaped reflector. The substantially conically shaped reflector such as reflector  210  and  211  creates a more shallow angle of intersection for the light into the substantially spherically shaped reflector  211 . This keeps the light from being absorbed or retained inside of the housing, instead, the light is dispersed from this housing to the surrounding area. There is also a side panel  220  which is used to secure the reflector inside of a housing such as inside of housing  213 . 
       FIG. 21A  shows a top plan view of another embodiment which shows a bulb comprising four continuous reflectors positioned end to end, wherein these four continuous reflectors are bound by heat sinks  204 ,  205 ,  206 ,  207  and  208 .  FIG. 21B  shows heat sink  206  taken from detail D shown in  FIG. 21A  wherein heat sink  206  includes two different lights  216   a  and  216   b  disposed opposite each other.  FIG. 21C  shows another detail which shows two different lights  217  and  218  wherein these two different lights are positioned at different angles relative to lights  216   a,  and  216   b  and are positioned to point at an angle transverse to the angle presented by end lights  216   a  and  216   b.  For example these two lights  217  and  218  are essentially side lights which are coupled to side panel  220  and which are angled point such that the focal point of these lights intersect on the reflector such as reflectors  210  and  211 . 
     There are also two additional side reflectors  219  and  221  wherein these side reflectors are also coupled to side panel  220  and are positioned to have their focal points intersect at the reflectors. 
       FIGS. 22A-22E  show differing views of the heat sinks which in this embodiment is shown as reference numeral  230 , however these heat sinks  230  are substantially the same or the same as heat sinks  204 ,  205 ,  206 ,  207 , and  208  shown in  FIGS. 21A . 
     In this case heat sink  230  includes a body section  231 , and fins  232 . In addition, there is a lens  240  which is coupled to body section  231  as shown in  FIG. 22B . There is also a screw hole  245  which is used to couple the heat sink to a housing or to another adjacent heat sink. There is a light  240  which includes a lens  241 , and a LED light  242  which includes a circuit board  242   a,  and a light such as a LED light section  242   b.  Both circuit board  242   a  and light section  242   b  are covered by a lens cover  241 , wherein this entire device is inserted into hole or housing  244 .  FIG. 22D  shows this heat sink  230  which has a bisecting line A-A wherein the cross-sectional view is shown in greater detail in  FIG. 22E , which shows body  230  and light  240 . 
       FIG. 23  shows a perspective view of another embodiment of a light system  260  which shows end piece  262  which is in the form of a cylindrical heat sink  262 . 1 , having a plurality of fins, there is also an LED circuit board  262 . 2  a lens plate  262 . 3  and a cover base  262 . 4  and a cylindrical tube  262 . 5 . There is also a cylindrical cover  261  which covers lover lights  266 . 2 ,  266 . 3 ,  266 . 4  which are in a light array  266 . 1  and which are housed underneath reflective housing  267 . 1  having holes  267 . 2 ,  267 . 3 ,  267 . 4  which are configured to receive the lights. There is also a spherical reflector  268  and oppositely spaced reflector  269 . A backing  265  is also coupled to this light array. Reflector  267 . 1  forms a first reflective section while reflector  268  forms a second reflective section. The first reflective section  267 . 1  has a shape taken from the group comprising or consisting of: substantially conical, sectional conical, frusto-conical, or rounded, or at least has a portion that is, or is at least substantially conical, sectional conical, frusto-conical, or rounded. The second reflective section  268  has a shape taken from the group comprising or consisting of: rounded, spherical, semi-spherical, dome shaped, or a shape having at least one portion that is, or is at least substantially rounded, dome shaped or spherical shaped. 
     This light system shown in  FIG. 23  can be incorporated into an endless light system which includes both light system  260  along with additional light systems  270 ,  280  which are similar to light system  260  and which are coupled to end pieces  263 ,  271 , and  271   
       FIG. 24A  shows a view of detail E from  FIG. 25A-D  which shows end light  262 , having a heat sink  261 . 1 , a plurality of fins  262 . 12  and a lens  262 . 3 . In addition, there is also shown  FIG. 24B  which shows detail F which shows a double sided light  263 , which shows a base heat sink  263 . 1 , a plurality of fins  263 . 2 , and lenses  263 . 3 , and  263 . 4 . 
       FIG. 24C  shows detail G which shows cover  261 , along with tongue  269  formed above a groove  269 . 1  wherein this groove is configured to receive electrical connector  280  therein. This connection end therefore allows for the physical and electrical connection of end lights such as light  262 , or light  263  to the body of the light system  260 .  FIG. 24D  shows a side cross-sectional view taken along the line H-H showing spherical reflector  268 .  FIG. 24E  shows an end view of a heat sink such as heat sink  273  having a first body section  273 . 1 , a second body section  273 . 2  a central connection section  273 . 3 , a base  273 . 4 . 
       FIG. 24E  is as side view of the backing plate  273 . 1  and the setting plate  273 . 2  wherein this setting plate  273 . 2  is designed to support LED lights. There is also a base  273 . 4  wherein this back plate is secured by coupling holes  273 . 5  which are configured to receive a lens body.  FIG. 24F  shows an end view which shows a spherical ball reflector  267 . 3  positioned along a line, and in line with light. 
       FIG. 24G  shows a side cross-sectional view through the section L-L which shows reflective surface  267 . 1 , lights  267 . 2 ,  267 . 3 , and  267 . 4  which are coupled to reflective surface  267 . 1 . These lights can be in the form of LED lights or any other type of available lights as well. 
       FIG. 25A  is a side cross-sectional view of a light system  260  taken along the line B-B which includes light systems  260 ,  270  and  280 . Light system  260  includes end lights  262 , and  263 . Light systems  270  includes lights from double ended light  263  and  271 . Light system  380  includes double ended light  271  and end light  272 .  FIG. 25B  shows a top view of this light system.  FIG. 25C  shows another side view, while  FIG. 25D  shows a top cross-sectional view through line K-K. 
       FIG. 26A  shows a bottom view of a light system  310  which includes an end  312  and an opposite end  314 . End  312  includes prongs  312   a  and  312   b  which are configured to connect to a power source. End  314  includes prongs  314   a  and  314   b.  In addition, there is a cover  316 , which is made from a translucent material which allows light to shine therethrough. There are also two lights  320  and  322  which are disposed opposite each other with light  320  being coupled to end  312 , and light  322  being coupled to end  314 . 
       FIG. 26B  shows an end view taken through the line B-B shown in  FIG. 26A . This view shows the cover  316  as well.  FIG. 26C  shows an end view of this light system which shows cover  316  as well. 
       FIG. 26D  shows a side view of the light system which shows ends  312  and  314  including prongs  312   a  and  314   a,  along with lights  320  and  322  disposed opposite each other. Lights  320  and  322  are configured as LED lights which have acrylic lenses coupled to each of these lights. Each of these lights  320  and  322  has a heat pipe  324  coupled to these lights. Heat pipe  324   a  and  324   b  are configured as L-shaped heat pipes which are configured to funnel heat from the light down to a heat sink. In this case, heat pipe  324  is configured to pass this heat to a heat sink  330 . Heat sink  330  is disclosed in greater detail in  FIGS. 27A-27D  and comprises a plurality of fins coupled to the heat pipe. Heat sink  330  including the fins can be made from any suitable material but in at least one embodiment is made from aluminum. Heat pipe  324  (See  FIG. 27C ) can be made from any suitable material but in at least one embodiment comprises copper or a copper alloy. 
     Reflector  340  is configured as an intermediate reflector and which can be configured as a substantially conical or oval shaped reflector which extends into a substantially dome shaped or spherical reflector  342 . A first style reflector is explained in greater detail in  FIGS. 29A-29E  while at least a second style reflector is explained in greater detail in  FIGS. 33A-33D , and a third style reflector is explained in greater detail in  FIG. 35 . 
       FIG. 26E  shows a side cross-sectional view of the light system  310  which includes lights  320  and  322 , as well as ends  312  and  314  along with heat pipes  324  extending below reflectors  340  and  342 . With this design, the heat sink  330  is disposed between reflector sections  342  and  344  and housing section  301   a  which is configured to be mountable on structure, such as a wall, or ceiling, a beam or pipe. (See  FIG. 31B ). This design provides a system where heat is dissipated at a distance away from the LED light, allowing a highly efficient cooling system which is disposed at a distance spaced away from the light. This design allows for not just radial heat transfer through a block or heat sink but also transfer through a heat pipe such as heat pipe  324  as well. 
       FIG. 27A  is a top plan view of the heat sink system, which shows end  312  coupled to light  320 . As shown in  FIG. 27B  which shows an end view, this end  312  includes a light stand  315 , coupled to a light holder  317 . Light stand  315  can be made of any suitable material but in this case is made from aluminum. In addition light holder  317 , is also configured as a circuit board coupled to light stand  315 . 
     As described above, light  320  includes a LED light  320   a  (See  FIG. 2E ) which is coupled to an acrylic lens body  320   b.  LED light is coupled to circuit board  317  and sends light into lens body  320   b  which in at least one embodiment is a solid acrylic body (See also  FIGS. 30A-30D ). Lens  320   b  includes a lens cap  321  which is configured as a locating ring. In at least one embodiment, this lens encases the entire LED, such that this encasement will eliminate light leakage to the sides.  FIG. 27C  shows a perspective view of the heat sink system which shows fins  330  coupled to heat pipe  324  with the heat pipe  324  ( 324   a,    324   b ) extending through these fins, such that heat pipe  324  is configured to dissipate heat into fins  330 .  FIG. 27E  shows this as well. Fins  330  also can include stands  331  which are ends of fins  330  bent in a substantially perpendicular manner. 
     As shown in  FIG. 28A , there is a double ended heat sink system which includes two sets of fins  330  with at least some of these fins  330  having stands  331 . Light stand  315  is shown coupled to lights  320   a  and lenses  320   b.  This double ended view is also shown in  FIGS. 28B and 28C .  FIG. 28D  shows an end view of this type system. 
       FIG. 28E  is another view of the heat pipe, which shows an outer tubing  324 . 1 , an inner tubing  324 . 2 , a channel  324 . 3 , and a first hole or feed  324 . 4  which allows a fluid  324 . 5  to cycle through or circulate within heat pipe  324  and a second hole  324 . 6  which allows the fluid to flow back into the cooling chamber once it has condensed. The end with hole  324 . 6  is adjacent to the light while the end with the hole  324 . 4  is opposite the end with the light. The fluid that can circulate within heat pipe  324  can be for example, ammonia, water or any other suitable fluid. The fluid is configured to be heated into a steam or gas at the heated end adjacent to the light, while the fluid is configured to condensate and feed back to the heated side at the opposite cooling side. The changing states of the fluid from liquid into gas, at the heated end and from gas back to liquid at the cooling end allows for rapid heat transfer away from the light. 
     With this design, the heat sink is disposed in a position offset from the location of the light  320   a.    
       FIG. 29A  shows as top plan view of a reflector  340  comprising a plurality of different sections. For example, there is a first section comprising sides  341   a  and  341   b  forming a first skirt, a central substantially conical or elongated oval shaped reflector  342  which extends into a substantially spherical region  344 . The reflector  340  is made from a light reflecting material such as a substantially light or white polymer. 
     There is also a secondary skirt section  345 , along with a light clearance section comprising first clearance section  346  and a second clearance section  347 . 
     Skirt  341   a,  and  341   b  is part of a first reflective portion or section comprising reflective section  341   a,    341   b,  and  342  along with reflective portion  345  and  349 . These skirts extend in an upward sloping manner towards each end. For example, at the end near spherical reflector  344 , the skirt slopes up into a ridge in sections  343   a  and  343   b.  In addition, at the terminal ends  349  adjacent to the lights, the reflector skirt slopes up as well as shown in cross-sectional view  29 B which is taken along section A-A in  FIG. 29C . These features are also shown in  FIG. 29D  as well. This first section has a shape taken from the group comprising or consisting of: substantially conical, sectional conical, frusto-conical, or rounded, or at least has a portion that is, or is at least substantially conical, sectional conical, frusto-conical, or rounded. 
     Reflector section  344  forms a second reflector section spaced apart from a light by first reflective section. This second reflective section has a greater slope than the first reflective section relative to a longitudinal axis L-L extending parallel to a light path of a light and a center direction of the light path. This second section has a shape taken from the group comprising or consisting of: rounded, spherical, semi-spherical, dome shaped, or a shape having at least one portion that is, or is at least substantially rounded, dome shaped or spherical shaped. 
       FIG. 29E  shows a side cross-sectional view of another type reflector  344   a  which substitutes for reflector  344 . In this view, reflector  344   a  is angled up to a ridge  344   b  which keeps reflector  344   a  from forming a top substantially flat dead zone in terms of light reflection. This design is substantially similar to a spherical or dome design, with a center section or slice taken out of it, and with each reflective end then pressed together. An example of this slice is shown by dashed lines in reflector  344  in  FIG. 29C . This reflector has a first section  342   a  and a second section  344   a.  First section  342   a  has a shape taken from the group comprising or consisting of: substantially conical, sectional conical, frusto-conical, or rounded, or at least has a portion that is, or is at least substantially conical, sectional conical, frusto-conical, or rounded. Second section  344   a  has a shape taken from the group comprising or consisting of: rounded, spherical, semi-spherical, dome shaped, or a shape having at least one portion that is, or is at least substantially rounded, dome shaped or spherical shaped. 
       FIG. 30A  is a first perspective view of a lens  320   b,  while  FIG. 30B  is a second perspective view of this lens.  FIG. 30C  is a side cross-sectional view of the lens  320   b  taken along the line A-A shown in  FIG. 30D . In this view, the different sections of lens  320   b  are shown, wherein there is a body section  320   b,  which has a inner bore or hole  320 . 1 , and a convex inner face  320 . 2 . There is also a recess  320 . 3  for receiving a bulb of a LED light.  FIG. 30D  also shows this bore  320 . 1   
       FIG. 31A  is a top cross sectional view of the light system shown in  FIG. 29A .  FIG. 31B  is an end view of this light system taken along the line C-C. In this view, there is shown cover  316 , reflector  344 , which can be spherical, substantially spherical or simply rounded. In addition there is also shown intermediate reflector  343   b.  Heat sink  330  is also shown underneath this reflector. 
       FIG. 31C  shows a cut away detail E while  FIG. 31D  shows a cut-away detail B taken from  FIG. 31E . Cutaway detail E shows light  320  resting on reflective surface  340  having a rounded resting surface  348  supporting light  320 . Cutaway detail B shows light  320  coupled to base  315  which is coupled to heat sink  330  via the heat pipe. This device is then disposed inside of a vented housing  339 . Vented housing can be made from any suitable material but in this case the material is made from metal. 
       FIG. 31D  shows the structure, of the LED light/lens  320  which is coupled to base/body or support  315 . Body or support  315  acts as a heat sink to draw away heat from LED  320 ,  320   a  and circuit board or base  317  (See  FIG. 27C ). In addition, spaced apart from this base or body  315  is a heat sink  330  which acts as a second heat sink. This second heat sink is not directly connected to the LED  320   a,  or to the circuit board  317 . Instead a heat pipe  324  is used to transfer heat from base or body  315  to heat sink  330 . Thus, with this cooling means there is a transfer of heat through a heat pipe from a first position adjacent to light  320   a,  and/or circuit board  317  to a second position spaced apart from this first position but connected by the heat pipe. In this design as well, there is at least one heat sink  330  disposed in a path of a light beam or light emission of light  320 . However, disposed along this path is at least one reflector  340  covering this heat sink  330 . 
       FIGS. 32A and 32B  show a light which can be configured to house a light such as that shown in  FIG. 19 . In this case, light  360  includes a body section  361 , a neck  362  and a base  363 . Body section  361  includes a backing  364 , a lens  365  and side clips  366  and  367  shown in FIG.  32 A and  32 C.  FIG. 32C  shows another view which shows body section  361  having openings or vents  368  and  369  as well. In addition, there is shown a light  370 , which has two end heat sinks,  371  or  379 . Coupled to these heat sinks  370  and  379  are lights  372  and  378 . 
     In addition, back body sections  373  are coupled to lights  372  and  379  respectively. In addition, reflectors  375  and  377  are coupled to back body sections  373  and  374  respectively. Furthermore, there is a central reflector  376  disposed between reflectors  375  and  377 . Reflectors  375  and  377  are substantially mirror images of each other are which are partially conically shaped. These two reflectors extend into a substantially spherically-shaped reflector  376 , which forms substantially dome-shaped reflector. On the ends of heat sinks  379  and  371  are electrical contacts  379   a  and  371   a  (See  FIG. 32D ) which are used to connect electrically to end pieces  367  and  366 . 
       FIGS. 32C and 32D  show a lamp light configuration including reflectors  375  and  377  along with spherical reflector  376 . Lights  372  and  378  are also included. This design is included in a light housing  361  having electrical contact ends  367 , and  366  along with top lights  368  and  369 . When the light is inserted into the housing, ends  367  and  366  are coupled to light electrical ends  371   a,  and  379   a  of ends  371  and  379 . 
       FIG. 33A  shows a side perspective view of another type of reflector system  350  which includes two sets of reflectors  350   a  and  350   b.  First reflector set  350   a  includes a skirt section  351   a  with a substantially conical shaped reflector  352   a  extending from the light end, and expanding towards a substantially spherical shaped, or dome shaped reflector  354   a.  In addition, there is a central connector  356  which connects first reflector set  350   a  with a second reflector set  350   b.  Reflector set  350   b  is substantially identical to reflector set  350   a.  Therefore, this reflector set  350   b  includes a skirt  351   b,  a conical shaped reflector  352   b,  a dome shaped or spherical shaped reflector  354   b  coupled to the conical shaped reflector  352   b,  with these sections coupled to central connector  356 . Reflector  352   a  forms a first reflective section while reflector  354   a  forms a second reflective section. This second reflective section  354   a  has across a portion of the shape a greater slope than the first reflective section based upon a longitudinal axis, which extends along a light beam of an associated light. This first reflective section  352   a  has shape taken from the group comprising or consisting of: substantially conical, sectional conical, frusto-conical, or rounded, or at least has a portion that is, or is at least substantially conical, sectional conical, frusto-conical, or rounded. The second reflective section has a shape taken from the group comprising or consisting of: rounded, spherical, semi-spherical, dome shaped, or a shape having at least one portion that is, or is at least substantially rounded, dome shaped or spherical shaped. 
     As shown in  FIGS. 33B and 33C , lights can then be inserted into positions  357   a  and  357   b  adjacent to these reflectors  350   a  and  350   b.    
       FIG. 33D  shows that each of these reflectors  350   a  and  350   b  can be angled offset from each other at a predetermined angle such as at a 30 degree angle offset from each other, an approximately 45 degree angle offset from each other or any other angle necessary to reflect light into a room. 
       FIG. 34A  shows these reflectors  350   a  and  350   b  inserted into a housing showing these lights angled offset from each other to produce a uniform light which is extended into a room. 
     These reflectors can then be covered by a light cover  383   b  as well. 
     For example,  FIGS. 34A-34D  show another embodiment of a light in the form of a substantially cylindrical light  380  having angled sets of reflectors shown in  FIGS. 33A-33D . These angled reflectors include a first reflecting section  352   a  and  352   b  which is rounded and which has a first section disposed adjacent to a light such as an LED light. There is a second section  354   a,  and  354   b  which is also reflective and which is coupled to the first section and which is disposed at a distal end from the first end where the first section is adjacent to the LED light. Second end section is in at least one embodiment a rounded section. In at least one embodiment this section is shaped spherical, semi-spherical, or substantially spherical, with at least a portion of the section having a rounded, dome like, or spherical section. The first section  352   a  and  352   b  includes at least one section that is also rounded or substantially rounded and which in at least one embodiment has a shape taken from the group consisting of or comprising: conical, substantially conical, sectional conical, frusto-conical, or rounded. These reflectors are held in place by a body section  383   a  as shown in  FIG. 34C . These reflectors and lights are covered by a translucent or transparent cover  383   b.  In addition as shown in  FIG. 34D , there are electronics  389   a  disposed beneath reflectors  350   a,  and  350   b  as well as contained by body section  383   a.  These electronics  389   a  are designed to control whether the light turns on or off and also there are also optional electronics configured to shut the light off if the heat becomes too intense. 
       FIG. 35  discloses another embodiment  390  which can be in the form of an overhead lamp including a housing  390 . This additional embodiment includes a lamp set which includes ends  390   a,  and  390   b.  These light sets include reflector sets which each include reflectors  392   a,    392   b,  and  393  forming in at least one embodiment a single reflector having multiple sections. For example, there is a first section which has a first end disposed adjacent to the lights  391   a,  and  391   b,  and which has at least one shape taken from the group comprising or consisting of: conical, substantially conical, sectional conical, frusto-conical, or rounded or at least a portion that is or is substantially conical, sectional conical, frusto-conical or rounded. Disposed at an end distal from the first end is a second section which has a shape taken from the group comprising or consisting of: rounded, spherical, semi-spherical, dome shaped, or a shape having at least one portion that is rounded, dome shaped or spherical shaped or at least substantially, rounded, dome shaped or spherical shaped. While this design can be a singular design, in at least one embodiment, this design is repeated in sets  394   a,    394   b,  and  394   c  and disposed inside of a housing such as housing  395 . 
       FIG. 36A  discloses a top view of another embodiment which is similar to the embodiment shown in  FIG. 35 . In this view, there is shown another embodiment  395 , which includes a first heat sink design  395   a,  and a second double ended heat sink design  395   b.  First heat sink design  395   a  has at least two LED lights and can include a design similar to that shown in  FIGS. 22A-22E ,  24 A,  24 B,  27 A- 27 D, and  28 A and  28 D. With this exemplified embodiment, there are two different reflector sets  396   a,  and  396   b  are repeated in different reflector groups  397   a,    397   b  and  397   c.  Each reflector set such as reflector set  396   a,  includes a first section  396 . 1  which has a first end disposed adjacent to the heat sink or light  395   a,  or  395   b  and a second end disposed at a distal end and coupled to or adjacent to a second reflector or reflector section  396 . 2  First reflector section has a shape taken from the group comprising or consisting of, substantially conical, sectional conical, frusto-conical, or rounded, or at least has a portion that is or is at least substantially conical, sectional conical, frusto-conical, or rounded. The second section has a shape taken from the group comprising or consisting of: rounded, spherical, semi-spherical, dome shaped, or a shape having at least one portion that is, or is at least substantially rounded, dome shaped or spherical shaped. 
       FIG. 36B  shows a side cross-sectional view of this design. In this case, this design includes housings  399   a,  and  399   b  and houses the above identified reflector sets  341   a - 343   b.    FIG. 28C  shows the corresponding cross-sectional view. In this view, the spherical reflectors as well as the conical shaped reflectors are spaced separate from each other in a substantially parallel spacing.  FIGS. 27A and 27B  however show that the spherical reflector  323  is essentially a combination of two spherical shaped reflectors placed together, with each of the conical shaped reflectors  323 , and  322  converging on the combined spherical reflector. 
       FIG. 37A  shows a top view of a light system  400  including three light tubes each associated with a LED light. Each of these light tubes  401 ,  402 ,  403  can comprise translucent material which can be in the form of a plastic material or glass or any other type of transparent, semi-transparent or translucent material. Transparent material, allows viewing through the material, translucent allows light through the material while partially or substantially limiting visibility. 
     An array of lights are positioned on a board  404  as shown in  FIG. 37C , this array comprises lights  405 ,  406 , and  407 , wherein these lights are orientated so that the corresponding light tubes  401 ,  402 ,  403  are positioned with their extending cylinders concentrical with an associated light. For example, tube  401  is concentrical with light  405  while tube  402  is concentrical with light  406  and tube  403  is concentrical with light  407 . Board  404  is essentially a circuit board wherein this board is coupled to a power board  408  and stored inside of housing  409  which housed inside of housing  411  and which is associated with connector  410 . Connector  410  essentially comprises an electrically conductive connector that functions as a screw on connector. These different features are also shown in  FIGS. 37B ,  37 C and  37 D. 
       FIG. 38A  shows a top view of another embodiment  420  which comprises a six sided shaped light component comprising sections  421 ,  422 ,  423 ,  424 ,  425 , and  426 . There is also a central light  427  which contains an array of lights therein as well. In addition, there is a connector  430  which is essentially a screw-on connector for connecting the light to a lamp. The different views of this embodiment  420  shown in  FIGS. 38B ,  38 C and  38 D show a lighting device having a heat sink  428  having a light  428   a  and an opposite reflector for each section 
       FIG. 39A  is a top view of another embodiment which shows a substantially round design comprising an outer cover  442 , including a central light fixture  441 , comprising an array of lights including lights  441   a,    441   b,    441   c,    441   d,    441   e,    441   f,    441   g,  and  441   h.  There is also a frusto-conical shaped cover  443  (See  FIG. 39C ) which essentially comprises a translucent material such as clear or frosted plastic, or glass. In addition, cover  442  having associated reflective surfaces adjacent to each light such as reflective surfaces  442   a,    442   b,    442   c,    442   d,    442   e,    442   f,    442   g,  and  442   h  (See  FIG. 39B ), is coupled to back cover  443 , wherein this cover comprises a plurality of openings  444  (See  FIG. 39E ), which allows air to vent in and out of the cover. 
       FIG. 40A and 40B  discloses a top view which shows a substantially circular shaped device which includes a central light fixture, comprising a plurality of lights  452  wherein this lights  452  are coupled to a heat sink  451  and housed inside a housing  453 . This housing  453 , includes a heat sink  454 , and a cover  455 . Heat sink  454  includes vents  454   a  shown in detail B. (See  FIG. 40E ).  FIGS. 40B ,  40 C and  40 D show different views of this type of embodiment. In this embodiment, there are also different reflective arrays  453   a,    453   b,    453   c,    453   d,    453   e,    453   f,    453   g,  and  453   h,  each having its own separate light array  457   a,    457   b,    457   c,    457   d,    457   e,    457   f,    457   g,    457   h,  wherein this light array comprises LED lights which shine through corresponding holes in the cover. 
       FIG. 41A  discloses another embodiment which includes a substantially circular light design  500  comprising a heat sink  510  having a base section  512 , an extended section, and a cover  520 . The second heat sink forms a stem or base, while the first heat sink  510  is in the form of a bowl. The light fixture is essentially in the form of a bulb which comprises a base section  512 , an extended section  514 , an array section  515 , comprising a plurality of lights  516 .  FIG. 41B  shows a side cross-sectional view of this device as well. This view shows cover  540  having vents as well as cover  520  and 
       FIGS. 42A-42D  show this embodiment in greater detail which shows another light embodiment  500  which includes a light central housing  510  and an outer housing  540 . As shown in  FIG. 42D , this central housing  510  includes a base section  512  and a body section having a plurality of fins  514  shown in  FIG. 39B  which is a top view of detail B of  FIG. 42A . As shown in  FIG. 42C  are a plurality of lights,  530   a,    530   b,    530   c,  and  530   d  coupled to this body section  510 . These lights can be in the form of LED lights. 
       FIG. 42D  shows an encasement  540  including a flower petal style section comprising a plurality of reflective petal style reflectors  541 .  FIG. 42E  shows a top perspective view of the light central housing  510 , which includes a board  515  which can be in the form of a circuit board, and which receives a plurality of lights  516  such as LED lights. There is also an inner reflector  514  positioned on an inner portion of housing  510 , which is configured to reflect the light created from lights  516 . 
       FIG. 43A  shows a side view of another embodiment which shows a series or a plurality of different light tubes  581  each comprising a translucent/transparent tube which can be made from any suitable material such as glass or plastic. This light tube can either be clear or frosted and contain therein a plurality of substantially conical shaped reflectors as well, such as those shown in wherein these spherical reflectors are configured to reflect light which is sent internally in the tube from each end. The spherical reflectors can be used along with conical shaped reflectors wherein these reflectors are coupled to the spherical shaped reflectors as shown previously. This embodiment is also shown in a side view in  FIG. 43B  and a perspective view in  FIG. 43C . 
       FIG. 44A  shows another embodiment which discloses a trapezoidal shaped design  590  having a plurality of end pieces  591  and a plurality of tubes  592  coupled to these end pieces. These end pieces  591  function as elbows wherein these end pieces are configured to send light in two directions. In addition  FIG. 44B  shows a side view which shows an end piece  591  as well as a tube  592  and another intermediate piece  593 , as well as another end piece  594 .  FIG. 44C  shows a side perspective view which shows an end piece  591  as well as a central tube  592 . The end piece can either be coupled to a light  595  or to a reflector  596 . 
       FIG. 45A  shows a side view of another embodiment  600  comprising a curved light comprising a straight section  601 , an end piece  602 , another end piece  603  and a central tie section  608 . There is also a curved section  609  which is in the form of a reflective bend for reflecting the light presented from ends  602  and  603 . Ends  602  and  603  are configured to house lights such as lights  362  such as those shown in  FIG. 23 . In addition  FIG. 45B  shows a perspective view of this type of light. Any other type of light, lens, reflector, and heat sink combination can be used as well such as that shown in  FIG. 26A . 
     Furthermore,  FIG. 46A  shows a side cross-sectional view of a substantially rectangular light device  610  comprising end pieces  602 , and  603  which include lights as described above. This light device also includes, central reflectors  610  and  611 , end lights  617  and  618 , as well as an end light section  613  which comprises a light  612  a light tube and a light reflector  619 . Light tube or section  613  is substantially shorter than light tubes  615  and  616 . Light reflector  619  comprises a substantially or partially spherical reflector which is mounted on a back wall and which is configured to reflect light. The perspective view of this light is shown in  FIG. 45  which shows light tube  616  as well. A perspective view is also shown in  FIG. 46B . 
     With this design, individual or multiple LED lights can be used in combination with a substantially or entirely spherical reflector  610 , and  611  to provide light throughout the tube. The tube can be coated with any light refracting or altering material to provide a tint to the light as well. Each of the tubes or covers shown above can also be coated with light altering material to alter the perceptible view of the light created either within the tube or from the tube. 
       FIG. 47A  shows a perspective view of another design  650  which includes a screw in light bulb type design which includes a series of lights  652  disposed inside of a housing  651 . There is a base stem  654  which is configured to screw into a light socket.  FIG. 47B  shows a cross-sectional view which shows light pipes  658  which feed into a cooling body  653  shown in  FIG. 47D .  FIG. 47D  is a cross-sectional view taken along the line A-A shown in  FIG. 47C . In  FIG. 47D  there is shown a cooling body  653  forming a portion of the housing wherein this view shows lenses  652   a  which are the same or substantially similar to lenses  320   b,  wherein each lens is associated with a light such as a LED light  655   a,    655   b,  and  655   c.  These lights  655   a,    655   b,  and  655   c  are mounted on a circuit board  656 , which is cooled by heat pipes  658 . These heat pipes are shaped differently but are otherwise essentially designed similar or the same as heat pipe  324  shown in  FIGS. 27A ,  28 B, and  28 E. This design creates a screw in LED based light which has sufficient cooling in the form of a heat sink body disposed in a region disposed offset from the position of the LED light. This design allows for greater cooling which allows for lights to be powered in a more intense manner creating a more efficient lighting system. 
       FIGS. 48A-48E  show different views of another embodiment of a dome shaped light  660 . In this view, this embodiment  660  includes a body section  661 ; a cylindrical shaped heat sink  662  coupled to the body section  661 . There is also a heat sink base  663  which is coupled to heat sink  662  (See  FIG. 48B ). As shown in  FIG. 48C  there are a plurality of fins  662   a,  and a plurality of heat pipes  662   b  extending or snaking through a body section of fins  662   a  or holes  662   c  in fins  662   a.  The fins  662   a  extend in a radial pattern along a backside face of this dome shaped housing  661 . There is also a coupler  664 , include a first hook section  664   a,  a second body section  664   b,  and a coupling block  664   c.  This coupler  664  is attached to dome housing  661  in any known manner, and inside of radially extending heat fins  662   a.  Heat sink body section  663  is coupled to a circuit board  665  which supports at least one or at least an array of lights and lenses  666 . These lights and lenses can be in the form of a light/lens design similar to that of light/lens design  320   a,  and  320   b  of  FIG. 27D . 
       FIG. 49A-49E  shows another embodiment. In this embodiment  670 , as shown in  FIG. 49B  there is at least one or a plurality of lights  677  and another set of at least one or a plurality of lights  675 . First set of lights  677  includes a lens  677   a,  and an associated LED  677   b  similar to the light/lens design  320   a  and  320   b  shown in  FIG. 27D . This design is coupled to a circuit board  677   c  which is coupled to a heat sink  673  which includes heat sink body  673   a  and light pipes  673   b.  This heat sink also extends to heat sink body  673   c.  Second set of at least one light/lights  675  is coupled to a circuit board/heat sink sandwich  676  which is similar or the same as shown with heat sink  673 /circuit board sandwich  673   c.  Heat sink body  673   c  is coupled to this second heat sink  673   b  as well. In this case, heat sink  673   b  bridges between heat sink sandwich  676  and  673 . Each of these heat sinks has venting holes which can be configured to receive heat pipes. There is also a translucent cover  678  shown in  FIGS. 48C ,  48 D and  48 E, as well as an elongated reflective surface  679  which has a first reflective section having a first end disposed adjacent to a LED light such as LED light  675 , and a second distal end. There is also a second reflective section which is coupled to the second end. The first reflective section  679   a  shape taken from the group comprising or consisting of, a substantially conical, sectional conical, frusto-conical, or rounded, or at least has a portion that is substantially conical, sectional conical, frusto-conical, or rounded. 
     The second reflective section  679   b  a shape taken from the group comprising or consisting of: rounded, spherical, semi-spherical, dome shaped, or a shape having at least one portion that is rounded, dome shaped or spherical shaped. 
       FIG. 50A  shows a perspective view of a light array such as that shown in  FIGS. 26A-26E . This view shows a first reflective pattern formed on this type of lens/reflector system, wherein there is shown emitted light band  700  which is emitted from a lens such as lens  320   b.  In addition there is another light band or light pattern  702  which is shown being emitted from lens  320   b  as well.  FIG. 50B  shows this light pattern in a cross sectional view taken along the line A-A shown in  FIG. 50C . 
       FIG. 51A-51C  shows another view of another light pattern formed from the design shown in  FIG. 50A . This light pattern shows an emitted light band  710  which is emitted from a lens such as lens  320   b.  Another light pattern, or light band is also shown  712  which is substantially similar to light band or pattern  710  and which crosses over this light pattern at a region adjacent to the second reflector section or portion such as second reflector portion  344  shown in  FIG. 26E . 
       FIG. 52A-52C  shows another view of another light pattern formed from the design shown in  FIG. 50A . This light pattern shows an emitted light pattern  720  which is reflected off of a first reflective portion or section such as portion or section  342  shown in  FIG. 29D , or reflective portion or section  352   a  shown in  FIG. 33A . Another section could be first section  210  shown in  FIG. 19 . 
       FIG. 53A-53C  shows another reflective band such as reflective band  730  which is emitted from a lens such as lens  320   b  and which is reflected off of a second reflective section such as reflective section  211 ,  368 ,  344 ,  344   a,    354   b,    396   b  etc. 
     Unless otherwise specified, the heat sink/light combinations along with the lens designs, and the reflector designs can be used interchangeably. 
     For example, the heat sink/light combinations can be used with any other different type of reflector combination specified above. For example, any one of the LED light/heat sink combination shown in  FIG. 1A ,  2 B,  3 C,  5 B,  5 C,  6 A,  6 B,  7 C,  8 A  9 A,  9 D,  10 A,  11 A,  12 A- 12 D,  13 A, 13 B,  14 A,  18 A,  19 ,  21 A- 21 D,  22 A- 22 E,  23 ,  24 A,  24 B,  25 A- 25 D,  26 A- 26 E,  27 A- 27 E,  28 A- 28 E;  32 A- 32 D;  34 A- 34 D;  35 ,  36 A- 36 B,  37 A- 37 D;  38 A- 38 D;  39 A- 39 E;  40 A- 40 E; 41 A- 41 B;  42 A- 42 E;  43 A- 43 C; 44 A- 44 C;  45 A- 45 B;  46 A- 46 B;  47 A- 47 E;  48 A- 48 E;  49 A- 49 E can be used with the other reflector or lens embodiments disclosed above. 
     In addition the different types of lenses can be used with any other different types of heat/sink combinations/reflector combinations specified above such as that shown in  FIG. 1A ,  5 B, 9 D,  12 C,  12 D;  13 B;  14 A;  FIG. 19 ;  FIG. 23 ;  24 A- 24 B;  26 A- 26 E;  27 A- 27 E;  28 A- 28 D;  30 A- 30 D;  37 A- 37 D;  47 A- 47 E;  48 A- 48 E;  49 A- 49 E can are interchangeable with the other heat sink/light designs, or reflector designs. 
     In addition the different types of reflectors such as the reflectors shown in  FIGS. 1C ,  2 B,  3 A;  6 B;  7 B;  8 B,  8 C;  9 A- 9 C;  9 D;  10 A;  11 A;  12 D;  13 B;  18 C;  19 ;  20 A- 20 D;  23 ;  29 A- 29 E;  31 B;  32 D;  33 A- 33 D;  35 ;  36 A;  38 A- 38 D;  39 A- 39 E;  40 A- 40 D;  41 A- 41 B;  43 A- 43 C;  44 A- 44 C;  45 A- 45 B;  46 A- 46 B;  47 A- 47 E;  48 A- 48 E;  49 A- 49 E; are interchangeable with the other heat sink/light designs, or lens designs disclosed above. 
     In all, the above designs are configured to reduce the number of LED lights required while providing a space saving cooling structure, which utilizes reflectors to create an omnidirectional, substantially omnidirectional or uniform, or substantially uniform pattern of light. One benefit, is to provide an efficient means or design to create a substantially even or even viewable light pattern, with no, or minimal dead reflective spots. 
     The use of the terms “a” and “an” and “the” and similar references in the context of describing the invention (especially in the context of the following claims) are to be construed to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. The terms “comprising,” “having,” “including,” and “containing” are to be construed as open-ended terms (i.e., meaning “including, but not limited to,”) unless otherwise noted. The term “connected” is to be construed as partly or wholly contained within, attached to, or joined together, even if there is something intervening. The recitation of ranges of values herein are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. 
     Any methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context. The use of any and all examples, or exemplary language (e.g., “such as”) provided herein, is intended merely to better illuminate embodiments of the invention and does not impose a limitation on the scope of the invention unless otherwise claimed. No language in the specification should be construed as indicating any non-claimed element as essential to the practice of the invention. 
     It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit and scope of the invention. There is no intention to limit the invention to the specific form or forms disclosed, but on the contrary, the intention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the invention, as defined in the appended claims. Thus, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. 
     Accordingly, while at least one embodiment of the present invention have been shown and described, it is to be understood that many changes and modifications may be made thereunto without departing from the spirit and scope of the invention as defined in the appended claims.