A black image type hidden light system applied to a vehicle is composed of a control module coupled to a hidden lamp module in which an outer lens, an inner lens, and a light source are assembled in a lamp housing, and a black color surface of the outer lens covers an inner space of the lamp housing to block the exposure to the outside and transmits the light fully reflected to the inner lens to the outside, thereby forming a deposition image in black when not lit and a lamp image or a lighting image when lit, and in particular, optimizes a light transmittance with an amount of addition of a carbon black material mixed with a polycarbonate (PC) material, thereby substantially enabling the mass-production beyond the limitation of an AL deposition image.

Disclosed are a communication device and method for a vehicle, the device including a housing, an external lens structure covering an open front region of the housing, an internal lens structure mounted in the housing and covered by the external lens structure, a liquid crystal section mounted on the internal lens structure, configured to become transparent or opaque based on whether or not power is applied thereto, and a bezel disposed behind the liquid crystal section, such that the bezel becomes visible from an exterior of the communication device upon the liquid crystal section being controlled to be transparent.

A vehicular lighted exterior rearview mirror system includes a lighted exterior rearview mirror assembly and a light module disposed thereat. The light module includes at least three forward illuminating illumination sources that, with the lighted exterior rearview mirror assembly attached at the side of the vehicle, are arranged spaced apart at the lighted exterior rearview mirror assembly. With the lighted exterior rearview mirror assembly attached at the side of the equipped vehicle, the at least three forward illuminating illumination sources, when powered, emit light at least in a forward direction with respect to the vehicle. The light module includes a turn signal indicating illumination source and a light piping element. The light piping element guides light emitted by the turn signal indicating illumination source along the light piping element so as to emanate from the light module at an outboard portion of the mirror casing.

A vehicular lighted exterior rearview mirror system includes a lighted exterior rearview mirror assembly and a light module disposed thereat. The light module includes at least three forward illuminating illumination sources that, with the lighted exterior rearview mirror assembly attached at the side of the vehicle, are arranged spaced apart at the lighted exterior rearview mirror assembly. With the lighted exterior rearview mirror assembly attached at the side of the equipped vehicle, the at least three forward illuminating illumination sources, when powered, emit light at least in a forward direction with respect to the vehicle. The light module includes a turn signal indicating illumination source and a light piping element. The light piping element guides light emitted by the turn signal indicating illumination source along the light piping element so as to emanate from the light module at an outboard portion of the mirror casing.

The invention provides a vehicle lamp structure, which includes a first substrate, a first light-emitting element, a light guide and an optical member. The first light-emitting element is disposed on the first substrate. The light guide includes a light guide body and a light guide bump. The light guide body has an arc structure facing forward. The light guide body extends backward to form the light guide bump. The first light-emitting element is arranged below the light guide bump. The optical member is arranged in front of the light guide. The first light-emitting element upwardly emits a first light ray into the light guide bumps. After being reflected by the light guide bumps, the first light ray travels forward and emits from the arc structure. The first light ray is then received by and transmitted through the optical member.

The invention provides a vehicle lamp structure, which includes a first substrate, a first light-emitting element, a light guide and an optical member. The first light-emitting element is disposed on the first substrate. The light guide includes a light guide body and a light guide bump. The light guide body has an arc structure facing forward. The light guide body extends backward to form the light guide bump. The first light-emitting element is arranged below the light guide bump. The optical member is arranged in front of the light guide. The first light-emitting element upwardly emits a first light ray into the light guide bumps. After being reflected by the light guide bumps, the first light ray travels forward and emits from the arc structure. The first light ray is then received by and transmitted through the optical member.

A vehicular lamp fitting comprises: a decorative member; a first inner lens disposed on the front surface side of the decorative member; a light source disposed on the back surface side of the decorative member; a second inner lens disposed on the back surface side of the decorative member; the first inner lens includes a first light-entering surface, a first light-exiting surface, a first light guiding unit configured to guide light entering from the first light-entering surface, and a first reflection surface configured to reflect the light guided in the first light guiding unit to exit from the first light-exiting surface; the second inner lens includes a second light-entering surface arranged in a state facing the light source, a second light-exiting surface arranged in a state facing the first light-entering surface through a space, and a second light guiding unit.

A vehicular lamp fitting comprises: a decorative member; a first inner lens disposed on the front surface side of the decorative member; a light source disposed on the back surface side of the decorative member; a second inner lens disposed on the back surface side of the decorative member; the first inner lens includes a first light-entering surface, a first light-exiting surface, a first light guiding unit configured to guide light entering from the first light-entering surface, and a first reflection surface configured to reflect the light guided in the first light guiding unit to exit from the first light-exiting surface; the second inner lens includes a second light-entering surface arranged in a state facing the light source, a second light-exiting surface arranged in a state facing the first light-entering surface through a space, and a second light guiding unit.

Parallel light traveling in a direction perpendicular to an outgoing surface having a curved surface is emitted. A light guide member according to one or more embodiments may include: an incident surface where light from a light source enters; at least one reflective surface that reflects the light having entered from the incident surface; and an outgoing surface that is formed of a curved surface and emits the light reflected by the reflective surface. The reflective surface reflects the light having entered from the light source in a direction in which the incident angle of the light incident on the outgoing surface is constant.

A light emitting system includes a light pipe, a light source disposed at least partially within an interior of the light emitting system, and configured to emit light when receiving electrical power from an electrical power source, wherein the light source is arranged adjacent to and directed towards the light pipe, a lens substantially enclosing the interior of the light emitting system, the light pipe and the light source, the lens having an inner surface and an outer surface disposed opposite the inner surface, and a mask comprising a coating that is applied on the lens and laser etched to form a desired pattern, wherein light emitted from the light source passes through the light pipe and lens.