Loupe lights are lights attached to dental loupes or other eyewear to illuminate an area of interest. Some loupe lights may use a fiber optic cable that transmits light from a light source.
Loupe lights are often bulky and heavy and uncomfortable to wear for prolonged periods of time. Loupe lights may restrict movement, or cause the loupe to move or become dislodged when the user turns or moves. Loupe lights may generate large amounts of heat and become very warm with prolonged use.
Other loupe lights use a self-contained light source and draw power from a remote power supply. These loupe lights are powered by a wire. Wire protection is designed to prevent the wire from being detached from the loupe light when the wire is pulled on, either through use or by accident. Wire protection may be afforded by a knot in the wire, or a crimp or screw securing the wire.
Filters are used with loupe lights for a variety of purposes, such as preventing the curing of light-cured materials. Filters may be attached and detached as necessary. Alternatively, filters may have an attachment that allow a user to manually move the filter between an in-use position and a non-use position. However, the user may not have a free hand, or the user may have soiled hands, making it difficult to move the filter or move the filter without soiling the filter.
What is needed is a filter that can be moved between an in-use position and non-use position without requiring the user to touch it.
A hands-free filter assembly is described. The hands-free filter assembly includes a filter, a filter attachment capable of being coupled to a loupe light, a filter swivel coupling the filter to the filter attachment, wherein the filter may be moved between an in-use position and a non-use position without manual manipulation, and a filter stop coupled to the filter attachment, the filter stop capable of maintaining the filter in the non-use position.
Lens 110 may be any suitable shape or configuration, and may be manufactured out of glass, plastic, or any other suitable material. In the embodiment shown, lens 110 is a biconvex singlet lens. Lens 110 may be coupled to body 120 by a press fit, threading, adhesive, or any other suitable method of coupling. In the embodiment shown, lens 110 is press fit to a front end of body 120.
End piece 130 may be any suitable shape or configuration, and may be manufactured out of metal, plastic, or any other suitable material. In the embodiment shown, end piece 130 is substantially cylindrical and is manufactured out of 6061 aluminum alloy. End piece 130 may be coupled to body 120 by press fit, threading, adhesive, or any other suitable method of coupling. In the embodiment shown, end piece 130 is threaded and configured to be coupled to the rear end of body 120, which is also threaded.
End piece 130 includes a hole 131 and an open channel 132 formed in end piece 130. Hole 131 is positioned within channel 132. In the embodiment shown, hole 131 is substantially circular and has a size substantially similar to that of wire 150. In the embodiment shown, channel 132 has a width substantially similar to that of wire 150. Channel 132 is also sufficiently deep to accommodate wire 150. Channel 132 is formed by channel walls 133. End piece 130 may have portions 134 removed to save weight.
Channel 132 may include other features which allow wire 150 to be held more securely in channel 132. For example, channel 132 may have ribs which extend partially into channel 132 and allows wire 150 to be held more securely in channel 132. As another example, channel 132 may have a surface treatment which allows wore 150 to be held more securely in channel 132.
Channel 132 may also have a cross-section which allows wire 150 to be held more securely in channel 132. Channel 132 may have cross-section that is wider at a top of channel 132 than at a bottom of channel 132. Channel 132 with this “wedge” cross-section allows wire 150 to be held more securely in channel 132 as wire 150 is pressed down into channel 132.
Channel walls 133 may be configured to be coupled to light source 140. In the embodiment shown, channel walls 133 include indentations 135 configured to assist in properly positioning or securing light source 140.
End piece 130 may have a mounting tab 139 which facilitates the coupling of compact loupe light 100 to a loupe. Mounting tab 139 may be used with different adapters in order to adapt compact loupe light 100 for use with different types of loupes.
Light source 140 may be any suitable source of light. In the embodiment shown, light source is an LED light mounted on a circuit board. Light source 140 may be a Cree XLamp 7090 XREWHT-L1-0000-X0D01 or a Cree XLamp 7090 XREWHT-L1-WH-R2-0-01.
Wire 150 may be of any suitable shape or configuration. In the embodiment shown, wire 150 is substantially cylindrical and includes two conductors and an insulating cover. Wire 150 may be coupled to light source 140 by soldering or any other suitable method of coupling. Wire 150 may be configured for connection to a power source.
Wire 150 passes through hole 131 and makes a bend before passing through at least portion of channel 132. The bend may be at least 75 degrees, but is preferably 90 degrees or greater.
Adhesive 160 at least partially fills channel 132. Adhesive 160 allows wire 150 to be held more securely in channel 132. Adhesive 160 fills channel 132 sufficiently to contact light source 140. Adhesive 160 allows light source 140 to be coupled more securely to end piece 130. Adhesive 160 may be Arctic Silver Arctic Alumina.
Adhesive 160 is electrically insulating. Electrical current from wire 150 will not conducted by adhesive 160. Adhesive 160 is also thermally conducting. Thus, waste heat from light source 140 is carried away by adhesive 160 and into end piece 130 and body 120. Adhesive 160, end piece 130, and body 120 thus act as a heat sink for light source 140.
Wire 150 is thus held in place by a combination of hole 131, channel 132, the bend created as wire passes through hole 131 and into channel 132, adhesive 160, and light source 140. This provides wire protection to wire 150 and strain relief to light source 140 in an effective and compact manner.
Hole 131 is positioned on a side of end piece 130. Wire 150 passes through hole 131 and at least a portion of channel 132, bends around a pin 136, and passes through another portion of channel 132.
Compact loupe light 100 can thus be made lightweight and compact. For example, compact loupe light 100 can be made to have a diameter of 0.65 inches or less, which is about the same as a dime, and a length of 0.76 inches or less. The compact loupe light 100 can be made to have a weight of 0.18 ounces or less, which is approximately the weight of a nickel.
Filter 210 is coupled to filter attachment 220 by filter swivel 230. Filter swivel 230 fits through filter hole 214 and is fixed to attachment hole 224. Filter swivel 230 may be a pin, bolt, or any other suitable coupling that prevents filter 210 from separating from filter attachment 220. Alternatively, filter swivel 230 may be fixed to filter 210, or fixed to neither filter attachment 220 nor filter 210. Filter swivel 230 allows filter 210 to rotate freely.
Filter stop 240 prevents the rotation of filter 210 past a certain point. Filter stop 240 may be formed as part of filter 210, as part of filter attachment 220, or coupled to either as a separate component. In one embodiment, filter stop 240 maintains filter 210 in the in-use position. In another embodiment, filter stop 240 maintains filter 210 in the non-use position. In the embodiment shown, filter stop 240 is a pin coupled to filter attachment 220.
In the embodiment shown, filter 210 hangs down from filter swivel 230 when in the in-use position. Filter 210 is thus maintained in the in-use position by gravity. To move filter 210 to the non-use position, the user “flicks” his head to rotate filter 210 about filter swivel 230. Filter 210 rotates freely and comes to rest against filter stop 240. Filter 210 is thus maintained in the non-use position by gravity and filter stop 240. To move filter 210 back to the in-use position, the user “flicks” his head again to rotate filter 210 about filter swivel 230.
While the invention has been described in terms of some specific examples and in some specific embodiments, it will be clear that this invention is not limited to these specific examples and embodiments and that many changes and modified embodiments will be obvious to those skilled in the art without departing from the true spirit and scope of the invention as defined in the appended claims.
This application is a continuation-in-part of pending patent application Ser. No. 12/229,365, entitled “COMPACT LOUPE LIGHT,” filed Aug. 22, 2008.
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Number | Date | Country | |
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Parent | 12229365 | Aug 2008 | US |
Child | 12696059 | US |