A rare gas lamp device is disclosed. The rare gas lamp device includes: a lamp body provided in a shape of a cylinder to contain a rare gas and a fluorescent material for emitting light; a plurality of cap electrodes fixed to both ends of the lamp body; a plurality of band electrodes extending in a length direction from the plurality of cap electrodes and arranged opposite to each other with respect to a center axis of the lamp body, and positioned on a circumferential surface of the lamp body, wherein a light-emitting area of the lamp body is an exposed surface of the circumferential surface of the lamp body between the plurality of band electrodes; a spring holder coupled with each of the plurality of cap electrodes and configured to apply a voltage to the band electrodes through the plurality of cap electrodes, the spring holder including a first fixing part configured to support a first side of the cap electrode, a second fixing part configured to support a second side of the cap electrode, and an inserting opening formed between a first end of the first fixing part and a first end of the second fixing part such that the cap electrode is inserted in the inserting opening; and a stopper protruding from each of the plurality of cap electrodes, wherein, when each of the plural of cap electrodes is inserted through the inserting opening, the stopper is interfered by the first end of the first fixing part or the first end of the second fixing part to restrict the light-emitting area from rotating about the center axis of the lamp body.

A rare gas lamp device is disclosed. The rare gas lamp device includes: a lamp body provided in a shape of a cylinder to contain a rare gas and a fluorescent material for emitting light; a plurality of cap electrodes fixed to both ends of the lamp body; a plurality of band electrodes extending in a length direction from the plurality of cap electrodes and arranged opposite to each other with respect to a center axis of the lamp body, and positioned on a circumferential surface of the lamp body, wherein a light-emitting area of the lamp body is an exposed surface of the circumferential surface of the lamp body between the plurality of band electrodes; a spring holder coupled with each of the plurality of cap electrodes and configured to apply a voltage to the band electrodes through the plurality of cap electrodes, the spring holder including a first fixing part configured to support a first side of the cap electrode, a second fixing part configured to support a second side of the cap electrode, and an inserting opening formed between a first end of the first fixing part and a first end of the second fixing part such that the cap electrode is inserted in the inserting opening; and a stopper protruding from each of the plurality of cap electrodes, wherein, when each of the plural of cap electrodes is inserted through the inserting opening, the stopper is interfered by the first end of the first fixing part or the first end of the second fixing part to restrict the light-emitting area from rotating about the center axis of the lamp body.

An excimer bulb assembly, with an excimer bulb, at least one integral captured reflector, and an integral filter such that the excimer bulb only emits substantial UV radiation between 200 nm and 230 nm, using a filter that passes light from about 200 nm to 234 nm (+/−2 nm).

An excimer bulb assembly including an excimer bulb emitting a beam of UV light at a wavelength of 222 nm. The excimer bulb may include a filter that blocks any unwanted wavelengths of UV light. The assembly includes a focusing lens positioned a distance from the excimer bulb such that the emitted beam of UV light strikes the focusing lens at an angle. The distance between the excimer bulb and the focusing lens may be varied such that the angle changes when the distance is varied. A plurality of excimer bulbs emitting a beam of UV light at a wavelength of 222 nm in a pattern may be including in a fixture. The fixture may include a housing with the plurality of excimer bulbs are secured in the housing. At least one of the plurality of excimer bulbs may be adapted to independently swivel with respect to the housing so as to change the pattern of the emitted beam of UV light. Each of the plurality of excimer bulbs may be adapted to independently tilt with respect to the housing.

An excimer bulb fixture including an excimer bulb emitting a beam of UV light at a far UV C wavelength. The fixture includes a krypton/chloride bulb, a band pass filter and a diffusion layer or lens. The krypton/chloride bulb is adapted to project a beam of far UV C light through the filter and then through the diffusion layer or lens. The band pass filter is adapted to block substantial UV radiation wavelengths longer than 234 nm. The diffusion layer or lens is adapted to widen the beam of far UV C light. A method far widening a beam of far UV C light includes the steps of projecting a beam of far UV C light produced by a krypton/chloride bulb through a band pass filter; blocking substantially UV C radiation longer than 234 nm; projecting the filtered beam through a diffusion filter or lens; and, widening the filtered beam.

An excimer bulb assembly including a krypton/chlorine excimer bulb and a pass filter. The excimer bulb assembly does not emit substantial UV C radiation in wavelengths longer than deadly 240 nm through UV C wavelengths. The pass filter is adapted to block substantial UV C radiation in wavelengths in the range of 240 nm-280 nm. The assembly may include a captured reflector, a smart chip, and/or a heat sink. The bulb and its electrical connectors may form a cartridge. The assembly may include a housing and the cartridge may swivel in the housing.

An excimer lamp includes a discharge vessel in which a rare gas and a halogen are enclosed. The excimer lamp also includes at least one first electrode and at least one second electrode for generating a dielectric barrier discharge inside the discharge vessel. The discharge vessel has a discharge forming region and a non-discharge region such that discharging takes place in the discharge forming region and no discharging takes place in the non-discharge region. The discharge forming region is formed between the first electrode(s) and the second electrode(s). The non-discharge region communicates with the discharge forming region. The excimer lamp satisfies a following equation:

(Vb×Ph)/Sd≥4.50

where Vb [mm.sup.3] represents a space volume inside the discharge vessel, Sd [mm.sup.2] represents an inner surface area of the discharge vessel in the discharge forming region, and Ph [Torr] represents a halogen-atoms partial pressure enclosed in the discharge vessel.

An excimer lamp includes a discharge vessel in which a rare gas and a halogen are enclosed. The excimer lamp also includes at least one first electrode and at least one second electrode for generating a dielectric barrier discharge inside the discharge vessel. The discharge vessel has a discharge forming region and a non-discharge region such that discharging takes place in the discharge forming region and no discharging takes place in the non-discharge region. The discharge forming region is formed between the first electrode(s) and the second electrode(s). The non-discharge region communicates with the discharge forming region. The excimer lamp satisfies a following equation:

(Vb×Ph)/Sd≥4.50

where Vb [mm.sup.3] represents a space volume inside the discharge vessel, Sd [mm.sup.2] represents an inner surface area of the discharge vessel in the discharge forming region, and Ph [Torr] represents a halogen-atoms partial pressure enclosed in the discharge vessel.

In the excimer lamp according to the present invention, a flat discharge vessel having a substantially rectangular cross-sectional shape and comprising a pair of planar parts and a pair of side-surface parts has a pair of external electrodes disposed on the respective outer surfaces of the planar parts. The end parts of the external electrodes are provided with an auxiliary electrode extending to a region that is made smaller than the distance between the planar parts. A lead that supplies electricity to the external electrode is connected to the auxiliary electrode in the region that is made smaller than the distance between the planar parts.

In the excimer lamp according to the present invention, a flat discharge vessel having a substantially rectangular cross-sectional shape and comprising a pair of planar parts and a pair of side-surface parts has a pair of external electrodes disposed on the respective outer surfaces of the planar parts. The end parts of the external electrodes are provided with an auxiliary electrode extending to a region that is made smaller than the distance between the planar parts. A lead that supplies electricity to the external electrode is connected to the auxiliary electrode in the region that is made smaller than the distance between the planar parts.