According to an aspect there is provided a base for an electric lamp which may be assembled in an efficient and convenient manner. The base comprises: a tubular enclosure (2) extending along an axial direction between a first and a second end portion of the enclosure, an insulator (4) attached to the first end portion of the enclosure such that a rotation of the insulator relative to the enclosure about the axial direction is prevented, the insulator having an inner portion (4b) facing towards an inner space of the enclosure, an outer portion (4a) facing away from said inner space and at least one channel for receiving an electrically conducting contact pin (5), the channel extending from the outer portion, through the insulator and leading into said inner space, and a housing (3) for accommodating electrical circuitry (11) for operating the electric lamp, wherein an end portion (5a) of the electrically conducting contact pin (5) has a lateral projection or recess being adapted to engage with an engagement portion (3 c) of the housing such that a separation between the insulator and the housing is prevented in at least said axial direction, and wherein the housing is attached to the inner portion of the insulator such that a rotation of the housing relative to the insulator about the axial direction is prevented, wherein a rotation of the housing relative to the enclosure is prevented.

A radiation source assembly comprises a source base, a UV transparent sleeve, and a UV lamp. The source base comprises a sealed electrical connection interface and an opposing sealed sleeve interface. The sealed electrical connection interface comprises a electrical contacts and the sealed sleeve interface comprise a radial sealing element, an outer collar, and a compression ring. The UV transparent sleeve is engaged with the sleeve interface such that the radial sealing element of the sealed sleeve interface is disposed between the UV transparent sleeve and the outer collar of the source base, and the compression ring is positioned over the UV transparent sleeve and engaged with the source base to compress the radial sealing element onto the UV transparent sleeve and the outer collar. The UV lamp is disposed within the UV transparent sleeve and electrically coupled to the electrical contacts of the electrical connection interface.

A radiation source assembly comprises a source base, a UV transparent sleeve, and a UV lamp. The source base comprises a sealed electrical connection interface and an opposing sealed sleeve interface. The sealed electrical connection interface comprises a electrical contacts and the sealed sleeve interface comprise a radial sealing element, an outer collar, and a compression ring. The UV transparent sleeve is engaged with the sleeve interface such that the radial sealing element of the sealed sleeve interface is disposed between the UV transparent sleeve and the outer collar of the source base, and the compression ring is positioned over the UV transparent sleeve and engaged with the source base to compress the radial sealing element onto the UV transparent sleeve and the outer collar. The UV lamp is disposed within the UV transparent sleeve and electrically coupled to the electrical contacts of the electrical connection interface.

There is disclosed a coupling for a radiation source assembly that comprises an elongate radiation source and an elongate radiation transparent protective sleeve for receiving the elongate radiation source. The coupling disengages in two stages when it is desired to remove the elongate radiation source for servicing (or any other purpose). The coupling is disengaged from a first position in which a seal is made between the sleeve bolt element and the lamp plug element. When this action takes place, the lamp plug element is still secure with respect to the sleeve bolt element but since there is no seal between the two, any fluid which has flooded the elongate radiation source (e.g., due to breakage or other damage to the protective sleeve) will emerge from the coupling warning the operator not to fully disengage the lamp plug element from the sleeve bolt element. If no such fluid is seen by operator, the operator may continue to disengage the lamp plug element from the sleeve bolt element to withdraw the elongate radiation source from the elongate radiation transparent protective sleeve.

There is disclosed a coupling for a radiation source assembly that comprises an elongate radiation source and an elongate radiation transparent protective sleeve for receiving the elongate radiation source. The coupling disengages in two stages when it is desired to remove the elongate radiation source for servicing (or any other purpose). The coupling is disengaged from a first position in which a seal is made between the sleeve bolt element and the lamp plug element. When this action takes place, the lamp plug element is still secure with respect to the sleeve bolt element but since there is no seal between the two, any fluid which has flooded the elongate radiation source (e.g., due to breakage or other damage to the protective sleeve) will emerge from the coupling warning the operator not to fully disengage the lamp plug element from the sleeve bolt element. If no such fluid is seen by operator, the operator may continue to disengage the lamp plug element from the sleeve bolt element to withdraw the elongate radiation source from the elongate radiation transparent protective sleeve.

A detector for an analytical device for analyzing a fluidic sample includes a housing, a lamp seat arranged in the housing and configured to receive a lamp for generating an electromagnetic radiation, and a movement mechanism to swivel the lamp seat with respect to the housing, and/or move the lamp seat between an operating orientation and a service orientation, so that the movement from the service orientation to the operating orientation results automatically in an electric contact and/or a mechanical positioning, in particular alignment, of the lamp.

A detector for an analytical device for analyzing a fluidic sample includes a housing, a lamp seat arranged in the housing and configured to receive a lamp for generating an electromagnetic radiation, and a movement mechanism to swivel the lamp seat with respect to the housing, and/or move the lamp seat between an operating orientation and a service orientation, so that the movement from the service orientation to the operating orientation results automatically in an electric contact and/or a mechanical positioning, in particular alignment, of the lamp.