The present disclosure provides a novel light-emitting diode assembly comprising a housing and an LED package having sidewall electrodes. The housing comprises sidewalls with contacts that are in electrical connection with electrodes of the LED package. The electrodes of the LED package are substantially exposed along the sidewalls of a resin carrier layer of the LED package.

The invention relates to a light-emitting diode arrangement having the following: a preferably heat-conductive substrate (2); a printed circuit board (5) which is arranged on the substrate (2), a recess (9) being provided in the printed circuit board (5); and at least one light-emitting diode chip (3) which is arranged on the substrate (2) and in the recess (9), said recess (9) being at least partly filled with at least one matrix material which preferably has a color-converting material (8).

According to various examples, systems, methods, and devices for a light emitting device are described herein. As one example, a light emitting device includes a light emitting element and a capacitor. The capacitor is configured as a voltage buffer for the light emitting element and is further configured to dissipate heat from the light emitting element. According to another example, a carrier for a light emitting arrangement is described herein. According to this example, the carrier includes a capacitor configured to buffer a voltage of the light emitting arrangement. The carrier further includes a contacting structure configured for electrically contacting the light emitting arrangement and the capacitor. The capacitor and the contacting structure are arranged such that the capacitor is configured to dissipate heat from the light emitting arrangement.

Provided is an anisotropic conductive adhesive in which excellent optical characteristics and heat dissipation characteristics are obtainable. The anisotropic conductive adhesive contains conductive particles each comprising a metal layer having Ag as a primary constituent formed on an outermost surface of a resin particle, solder particles having a smaller average particle diameter than the conductive particles, reflective insulating particles having a smaller average particle diameter than the solder particles and a binder into which the conductive particles solder particles and reflective insulating particles are dispersed. The conductive particles and the reflective insulating particles efficiently reflect light, thereby improving light-extraction efficiency of an LED mounting body. Additionally, inter-terminal solder bonding of the solder particles during compression bonding increases contact area between opposing terminals, thereby enabling achievement of high heat dissipation characteristics.

According to one embodiment of the present invention, the light emitting device includes an LED element, a side wall which surrounds the LED element, a phosphor layer which is fixed to the side wall with an adhesive layer therebetween, and is positioned above the LED element, and a metal pad as a heat dissipating member. The side wall includes an insulating base which surrounds the LED element and a metal layer which is formed on a side surface at the LED element side of the base, and is in contact with the metal pad and the adhesive layer. The adhesive layer includes a resin layer that includes a resin containing particles which have higher thermal conductivity than the resin or a layer that includes solder.

Embodiments of the invention include a light emitting device (LED 10), a first wavelength converting material (13, in a matrix 14 to form a layer 12), and a second wavelength converting material (forming layer 16). The first wavelength converting material includes a nanostructured wavelength converting material. The nanostructured wavelength converting material includes particles having at least one dimension that is no more than 100 nm in length. The first wavelength converting material (13) is spaced apart from the light emitting device (10).

Embodiments provide an illumination apparatus including a light emitting module including a board, at least one light emitting device disposed in a first region of the board and drive devices disposed in a second region of the board, a heat dissipation member, and dummy pads disposed around the at least one light emitting device, the heat dissipation member including a base, a core, and heat dissipation fins connected to the side surface of the core and the lower surface of the base. The first region is one region of the upper surface of the board, located within a designated range from the center of the board, and the second region is another region of the upper surface of the board, spaced apart from the first region by a first distance and spaced apart from the edge of the upper surface of the board by a second distance.

A wavelength converting device includes a heat dissipating member, a wavelength converting member, and a connecting member. The wavelength converting member is disposed on the heat dissipating member and contains a fluorescent material and a holding body including aluminum oxide, magnesium oxide, zirconium oxide, lutetium oxide, titanium oxide, chromium oxide, tungsten oxide, divanadium pentoxide, molybdenum trioxide, sodium oxide, yttrium oxide, silicon dioxide, boron oxide, or diphosphorus pentoxide. The connecting member contains a metal material and connecting the heat dissipating member and the wavelength converting member. The wavelength converting member includes an upper surface, side surfaces, and a lower surface. The connecting member is thermally connected to the side surfaces and the lower surface of the wavelength converting member.

A method for producing an optoelectronic component includes creating a first layer of a polymer material. The method also includes applying crystals to a surface of the first layer. The method also includes creating a second layer of a polymer material on the surface of the first layer. The crystals can be between the first and second layers.

A light emitting device includes: a heat dissipative board; a wiring board which adheres and is fixed to the heat dissipative board and in which a through-hole is formed; a light-emitting element which is mounted on a front surface of the heat dissipative board which is exposed through the through-hole of the wiring board; a bonding wire which connects the light-emitting element and the wiring board; and a light-reflecting member which covers a surface of an inner peripheral wall of the through-hole excluding disposition places of the light-emitting element and the bonding wire.