A method of manufacturing an optical component includes: providing a base comprising a first projection, wherein the first projection includes: an upper surface, and a plurality of lateral surfaces, wherein the plurality of lateral surfaces includes a first lateral surface including: a first light control region, a first non-light-control region that is continuous with the first light control region, and a second non-light-control region on an upper surface side of the first light control region, and wherein the first light control region is located between the first non-light-control region and the second non-light-control region; forming a lower surface of the optical component by processing a lower surface of the base such that the first non-light-control region in the base remains; and forming an upper surface of the optical component by processing an upper surface of the base to remove the second non-light-control region.

A reflector includes a first reflector section and a second reflector section. The first reflector section extends along a portion of a first ellipse. The second reflector section extends along a portion of a second ellipse, the second ellipse intersecting the first ellipse. The first reflector section and the second reflector section are joined at an intersecting point of the first ellipse and the second ellipse.

A method for 3D printing a 3D item (10), the method comprising providing a filament (320) of 3D printable material (201) and printing during a printing stage said 3D printable material (201) on a substrate (1550), to provide said 3D item (10), wherein the printing stage comprises (a) providing a layer (405) comprising particles (410) on the substrate (1550), wherein the particles (410) have a main axis (A1) having a main axis length (LI), and a minor axis (A2) having a minor axis length (L2), wherein the main axis length (LI) and the minor axis length (L2) have a first aspect ratio of at least 5, wherein in average the main axes (A1) of said particles (410) are configured parallel to a tangential plane (P) to the substrate (1550), wherein said particles (410) comprise light reflective material (411), and (b) printing said 3D printable material (201) on said layer (405) on the substrate (1550) to provide said 3D item (10) comprising said layer (405).

A reflector system to form a light module for an illuminating device of a vehicle. The reflector system has a base body and a reflector arranged on the base body. A light module comprises such a reflector system. The base body is made of a metal body and the reflector is made of a thermoplastic material, and the thermoplastic material forming the reflector is injection molded onto the metal body which forms the base body.

The present invention is directed to the production of shipping containers, computer server farm containers, and other forms of physical storage containers from a carbon nanotube-based fiber material with the potential application of other, non-carbon, nano-based materials containing various structures. Current materials used for shipping containers, computer server farm containers, and other forms of physical storage containers are heavier than the present invention and lack the ability to withstand high-intensity shock vibrations and other disturbances and are vulnerable to radiofrequency (RF) radiation. Instead of using metal, which is the currently preferred material used in the development of shipping containers, computer server farm containers, and other forms of physical storage containers, the present invention provides the use of a carbon nanotube-based material.

A lighting system with a laser light source for radiating light; a wavelength conversion element for receiving the radiated light from the light source and for re-emitting wavelength converted white light; and a reflector element for reflecting the light received from the wavelength conversion element is disclosed. The reflector element comprises a reflective surface and a micro-patterned surface comprising an array of micro-focal elements. Each micro-focal elements is configured to converge or diverge incident light from the wavelength conversion element.

Embodiments of the present disclosure relate to a retro-reflective raised pavement marker (100) and a method of manufacturing (200) thereof. The marker (100) comprises a marker body (1), at least one intermediate frame (6), and at least one retro-reflective lens (7) such that the marker body (1) completely houses the at least one intermediate frame (6) and the at least one retro-reflective lens (7). Further, the manufactured marker (100) is durable, effective and has better retention with the ground surface and better load distribution to the ground.

A method for manufacturing a light emitting device includes: preparing a baseplate having a plate surface on which a protrusion is disposed; forming a first resin frame having an opening on the plate surface, wherein the opening is located above the protrusion; forming a second resin in the opening; detaching the baseplate; bonding a light emitting element to a surface of the second resin surface that has been exposed as a result of detaching the baseplate; and forming a third resin that surrounds lateral faces of the light emitting element and that covers and contacts a portion of the first resin frame.

An optical element includes a base having a curved depression formed in a front surface thereof and a formed layer arranged on the base. The formed layer includes a main part in the depression as viewed from a depth direction of the depression and an overhang on the front surface of the base while connecting to the main part. An opposite surface of the main part to a surface thereof on a side of an inner surface of the depression is formed like a concave curve that is concave in a same direction as the inner surface of the depression. A predetermined surface of the main part that is opposed to the inner surface of the depression is provided with an optical function part.

A light emitting device includes a light emitting element having an upper face and lateral faces; a light transmissive member covering at least a portion of the upper face of the light emitting element and transmitting light emitted from the light emitting element; a first reflector covering at least a portion of lateral faces of the light transmissive member; and a second reflector covering the lateral faces of the light emitting element. The first reflector includes a first bottom face and a second bottom face. A plane in which the first bottom face of the first reflector extends is different than a plane in which a lower face of the light transmissive member extends. The second bottom face of the first reflector is located inward of the first bottom face of the first reflector, and is coplanar with the lower face of the light transmissive member. The first bottom face of the first reflector is covered by and in contact with the second reflector.