A switch structure includes a light-emitting part configured to receive power from a vehicle and to radiate light, a moving block located so as to surround the light-emitting part, a light-transmissive part configured to allow light radiated from the light-emitting part to pass through an opening in the moving block, and a film-printing layer located on a top surface of the light-transmissive part and including a symbol.

A switch structure includes a light-emitting part configured to receive power from a vehicle and to radiate light, a moving block located so as to surround the light-emitting part, a light-transmissive part configured to allow light radiated from the light-emitting part to pass through an opening in the moving block, and a film-printing layer located on a top surface of the light-transmissive part and including a symbol.

A light with retractable sleeve comprises housing, a retractable sleeve disposed inside the housing, and a light body embedded in a front end of the retractable sleeve and protruding out of the housing; the retractable, sleeve comprising an inner sleeve, an outer sleeve disposed outside the inner sleeve, and a connector; the inner sleeve having a gear rack; the outer sleeve having thereon a button corresponding to the gear rack; the button being attached on the gear rack via a resilient element to prevent the outer sleeve from undesirably moving out of the inner sleeve along the axial direction; the outer sleeve and the inner sleeve can be extended with each other, so that the outer sleeve is extended out of the housing, thereby facilitating the light body installed thereon, the structure is simple and easy to use.

A light-emitting diode (LED) can have a light-emitting surface that can emit emitted light. A filter, disposed on the light-emitting surface, can be at least partially transmissive in a first area and at least partially reflective in a second area. The first area can direct at least some of the emitted light through the filter to form shaped light that extends over an area corresponding to a shape of a static light pattern. The second area can reflect at least some of the emitted light into the LED through the light-emitting surface. A lens can bring the shaped light to a focus that has the shape of the static light pattern. To increase a contrast of the focus, an absorber, disposed on the second area of the filter, can absorb emitted light that is transmitted through the second area of the filter.

A light-emitting diode (LED) can have a light-emitting surface that can emit emitted light. A filter, disposed on the light-emitting surface, can be at least partially transmissive in a first area and at least partially reflective in a second area. The first area can direct at least some of the emitted light through the filter to form shaped light that extends over an area corresponding to a shape of a static light pattern. The second area can reflect at least some of the emitted light into the LED through the light-emitting surface. A lens can bring the shaped light to a focus that has the shape of the static light pattern. To increase a contrast of the focus, an absorber, disposed on the second area of the filter, can absorb emitted light that is transmitted through the second area of the filter.

A book 10 including a bracket 30 for maintaining a light source 55 at a predetermined position such that, in use, the light source illuminates at least one article 16 included in the book and casts its shadow, and/or projects an image 50 after the light passes through it, onto an adjacent surface 40 for viewing thereof.

A book 10 including a bracket 30 for maintaining a light source 55 at a predetermined position such that, in use, the light source illuminates at least one article 16 included in the book and casts its shadow, and/or projects an image 50 after the light passes through it, onto an adjacent surface 40 for viewing thereof.

The present invention provides a laser spot light with improved radiating structure which includes a cylindrical shell, a mounting board fixed within the cylindrical shell, at least one laser head, an inner radiator made from heat-conductive metal and configured for supporting the at least one laser head and fixed on the mounting board, and an outer radiator made from heat-conductive metal and fixed to the side wall of the cylindrical shell with a part of the outer radiator passing across the cylindrical shell and touching with the inner radiator. Therefore an inner heat can be conducted to the outside of the cylindrical shell, and an operation temperature of the laser head can be maintained in a normal range.

The present invention provides a laser spot light with improved radiating structure which includes a cylindrical shell, a mounting board fixed within the cylindrical shell, at least one laser head, an inner radiator made from heat-conductive metal and configured for supporting the at least one laser head and fixed on the mounting board, and an outer radiator made from heat-conductive metal and fixed to the side wall of the cylindrical shell with a part of the outer radiator passing across the cylindrical shell and touching with the inner radiator. Therefore an inner heat can be conducted to the outside of the cylindrical shell, and an operation temperature of the laser head can be maintained in a normal range.

A precision approach path indicator (PAPI) employs an LED light source with first and second arrays of LEDs or other efficient light sources, disposed one above the other and emitting their respective color lights along an optic axis to a collimating lens of focal length f. First and (optional) second aperture plates positioned along the optic axis, each being a respective frame with a cut-out defining a horizontally elongated aperture for light passing along the optic axis. Intermediate aperture plate(s) can be positioned between the first and second aperture plates. The first frame is positioned between the light source and the collimating lens at the focal distance f from the lens. The optional second aperture plate is positioned at the collimating lens and covers top, bottom, and side edge portions of the lens. A planar blade extends from the light source to the first frame and has a distal edge extending across the aperture of the first aperture plate, substantially at the focus of the collimating lens, dividing the beam into white and red sectors. The intermediate aperture plate(s) can be adjusted for optimal separation. The PAPI can be considered to have an illumination portion formed of the light source(s), blade, and first frame; and an imaging portion formed of an enclosure and a lens positioned at its focal length distant from the front frame aperture and edge of the blade.