Abstract: A portable, high power arc lamp system for composite curing and tooth whitening applications utilizes battery cells to power a lamp, such as a short-arc xenon lamp. The use of battery power allows for a high power system without the need for costly components required if ac power were used. Battery power is acceptable for low duty cycle applications such as composite curing and tooth whitening. The batteries may be recharged using either standard 110 V or 220 V house current and a charging circuit is included to charge the batteries. An elliptical reflector is used to direct the light from the xenon lamp to a flexible light guide. The system of the present invention is particularly suited to the curing of dental composites and tooth whitening procedures. Significantly improved methods of curing and whitening may be realized through the use of a high power light source of the present invention.

Abstract: A laser system for use in performing dental procedures is provided. The system includes a handpiece which is capable of being connected to a source of laser light, such as a fiber optic cable. The fiber optic capable carries laser light into the handpiece. For most of the purposes contemplated herein, the argon laser light is preferred. The handpiece includes a collimating lens such that the laser light is collimated and a collimated laser output exits said handpiece. Collimated laser light is found to be useful in initiating the curing of dental resin restorative materials. Also placed within the handpiece is a mirror for controlling the direction of laser light output from said handpiece and for directing the collimated laser light toward a dental work area. Finally, multiple detachable attachments are provided which are capable of being mounted on the exterior or at the proximal end of said handpiece for optionally modifying said collimated laser light output.

Abstract: An apparatus and method for multiplexing a light beam such as a laser beam with one or more optical surfaces such as mirrors is taught. In one embodiment, the apparatus includes an electromagnet, an armature, and an optical device. The optical device is mounted on the armature. The armature and the electromagnet preferably form part of an electromagnetic relay, so that actuating the electromagnet creates an electromagnetic force which moves the armature from a rest position into a responsive position near the electromagnet, thereby moving the optical device into an active position wherein the optical device engages the light beam. In a presently preferred embodiment, the apparatus also includes a leaf spring which urges the armature, and hence the optical device, away from the electromagnet when the electromagnetic force is absent.

Abstract: A laser that is capable of producing light from a chosen group of frequencies not adequate or available using a single gas laser is provided. The laser is capable of producing selected and well defined light wavelengths. The laser is also capable of eliminating unwanted frequencies in order to prevent such frequencies from competing with (robbing power from) the desired wavelengths. The laser constitutes a multiple gas laser. A combination of argon and krypton is used. Argon is known to produce a good blue laser beam in the area of 488 nm. Mixed with the argon is krypton. Krypton also produces a blue output at 482 nm and 476 nm. In addition, krypton produces strong outputs in red, yellow, and green wavelengths (647 nm, 568 nm, and 529 nm respectively). Accordingly, access to each of these colors is provided by the argon-krypton in the mixture. Certain light frequencies are unnecessary and undesirable. Elimination of undesirable wavelengths is accomplished primarily through the optics used.

Abstract: The present invention automatically compensates for thermally induced changes in the index of refraction. This is accomplished by choosing materials from which to construct the rods such that the position of the optical elements are changed in an advantageous manner as temperatures change. For example, a pair of upper rods and a pair of lower rods are provided. The upper rods may be constructed of INVAR or other similar material with a very low coefficient of thermal expansion. The two lower rods, however, are constructed of a composite of materials having a chosen higher coefficient of thermal expansion. For example, rods may be provided which are approximately 50% to approximately 75% INVAR. The remainder of the rods are comprised of a material of a much higher coefficient of thermal expansion, such as stainless steel.the result of such a construction is that as the temperature of the device rises, the lower rods expand at a much faster rate than do the upper rods.