An ultraviolet emitting device according to the present disclosure includes a lamp for mounting a discharge gas and an ultraviolet emission source therein, and a plurality of yarns formed by extending and aggregating carbon nanotubes in a first direction, and includes a first electrode at least partially exposed to the discharge gas within the lamp. Accordingly, electron emission efficiency of the first electrode is improved to achieve high efficiency, and durability is also improved to provide a long-life device.

An excimer lamp includes a housing portion having a sealed internal space, an internal electrode, and a discharge gas with which the internal space is filled. One end side of the internal electrode is electrically connected to a power supply member provided with a metal foil electrically connected to the internal electrode and is sealed together with the power supply member to one end side of the housing portion via a sealing portion. The other end side of the internal electrode protrudes into the internal space. A protrusion length, being a length of the internal electrode in the internal space and a length from one end of the internal space to the other end of the internal electrode, is equal to or less than a length from the other end of the internal electrode to the other end of the internal space in a direction along the axis.

This application discloses an ultraviolet lamp with minimized ozone generation, the ultraviolet lamp comprising an outer tube; an inner tube arranged across the interior of the outer tube; an outer electrode installed on the outside wall of the outer tube; and an inner electrode installed on the inner side of the tube; wherein the outer electrode is in surface contact with the outside wall of the outer tube; and the width of the contact surface between the outer electrode and the outer tube is equal to the width of the effective electric field generated between the outer electrode and the inner electrode. Thus, because there is no discharge area between the outer electrode and the outer tube, when the outer electrode is connected to a high voltage, there is no discharge in the air, and no ozone is generated.

An excimer lamp includes a plurality of arc tubes and an electrode pair. The electrode pair comprises a plurality of elongated electrode plates extending along a tube axis direction of the plurality of arc tubes. Each electrode plate comprises a polarity opposite that of an adjacent electrode plate (i.e., alternating polarities). The plurality of arc tubes and the plurality of electrode plates are disposed in an alternating side-by-side orientation such that an arc tube of the plurality of arc tubes is disposed between adjacent electrode plates of the plurality of electrode plates.

The invention relates to a low-pressure mercury vapour discharge lamp comprising a discharge vessel which encloses a discharge chamber in a gas-tight manner with said discharge chamber being provided with a filling of mercury and a filler gas, in particular a noble gas, wherein the discharge vessel has a first end section and a second end section , a first electrode arranged on the first end section and a second electrode arranged on the second end section for maintaining a discharge along a discharge path between the first electrode and the second electrode , and an amalgam deposit for regulating the mercury vapour pressure in the discharge chamber is arranged on the first end section outside the discharge path , wherein the position of the amalgam deposit is secured by means of an adhesion agent .

A sterilizing lamp includes a discharge tube, a ground electrode part, a high-voltage electrode part, a safety cover, and a light shield. The discharge tube is filled with discharge gas for generating excimer light. The ground electrode part and the high-voltage electrode part generate discharge in the discharge tube to excite the discharge gas. The safety cover is made of an electrically insulating organic material and covers the high-voltage electrode part. The light shield is made of an electrically insulating inorganic material and intervenes between the discharge tube and the safety cover to block the excimer light traveling from the discharge tube toward the safety cover.

Disclosed herein an excimer discharge lamp that is capable of mitigating a stress concentration occurring due to a fixing method of an outer electrode, and achieving a desired life of lamp in an ensured manner. The excimer discharge lamp comprises: an arc tube for enclosing a luminous gas inside and having a sealing portion formed contiguous to, via a reduced diameter portion, one end of a tube shaped luminous portion; and an outer electrode of a net-like shape arranged on an outer peripheral surface of the art tube. The one end of the outer electrode being fixed via an outer electrode fixing member provided on an outer surface of the sealing portion.

An excimer lamp includes a housing portion having a sealed internal space, an internal electrode, and a discharge gas with which the internal space is filled. One end side of the internal electrode is electrically connected to a power supply member provided with a metal foil electrically connected to the internal electrode and is sealed together with the power supply member to one end side of the housing portion via a sealing portion. The other end side of the internal electrode protrudes into the internal space. A protrusion length, being a length of the internal electrode in the internal space and a length from one end of the internal space to the other end of the internal electrode, is equal to or less than a length from the other end of the internal electrode to the other end of the internal space in a direction along the axis.

An excimer lamp includes a dielectric tube, an end cap, a conductive hollow tube, and an electrode grid. The dielectric tube has a closed end and an open end, and defines a cavity. The end cap sealingly covers the open end. The conductive hollow tube passes through the end cap and into the cavity of the dielectric tube, with a volume defined between an exterior surface of the conductive hollow tube and an interior surface of the dielectric tube. The volume is configured to hold a gas. The electrode grid is disposed on an exterior surface of the dielectric tube.

An excimer lamp includes a dielectric tube, an end cap, a conductive hollow tube, and an electrode grid. The dielectric tube has a closed end and an open end, and defines a cavity. The end cap sealingly covers the open end. The conductive hollow tube passes through the end cap and into the cavity of the dielectric tube, with a volume defined between an exterior surface of the conductive hollow tube and an interior surface of the dielectric tube. The volume is configured to hold a gas. The electrode grid is disposed on an exterior surface of the dielectric tube.