Abstract: An LED includes a base, a first lead and a second lead mounted to the base, a light emitting chip electrically connected to the first lead and the second lead, and an encapsulant sealing the chip. The first lead and the second lead each include a first beam and a second beam connected to each other. Each of the first beam and the second beam has two opposite ends protruding beyond two opposite lateral faces of the base, respectively, for electrically connecting with a circuit board.

Abstract: A method for packaging an LED, includes steps: providing a substrate; arranging an LED die on the substrate; forming a photoresist layer on the substrate to cover the LED die; arranging a mask directly on the photoresist layer; exposing the photoresist layer with the mask to a radiation source; removing the mask and the unexposed portion of the photoresist layer formerly sheltered by the mask, thereby leaving the exposed portion of the photoresist layer formerly unsheltered by the mask on the substrate, wherein the remained exposed portion of the photoresist layer surrounds the LED die; spraying fluorescent material toward the LED die surrounded by the remained exposed portion of the photoresist layer; removing the remained exposed portion of the photoresist layer; and finally encapsulating the LED die covered by the fluorescent material.

Abstract: A method for manufacturing light emitting diodes includes steps: providing a substrate having an upper conductive layer and a lower conductive layer formed on a top face and bottom face thereof; dividing each of the upper conductive layer and the lower conductive layer into first areas and second areas; defining cavities in the substrate through the first areas of the upper conductive layer to expose the lower conductive layer; forming conductive posts within the substrate; forming an overlaying layer to connect the first areas of the upper and lower conductive layers; mounting chips on the overlaying layer within the cavities and electrically connecting each chip with an adjacent first area and post; forming an encapsulant on the substrate to cover the chips; and cutting the substrate into individual packages.

Abstract: A method for manufacturing a light emitting diode is disclosed. Firstly, two leads each including a plateau are provided. A blocking layer is then formed on each plateau. A base is molded on the leads to embed the two leads therein, wherein the two blocking layer are exposed from the base. The blocking layers are removed from the plateaus so that the two plateaus are exposed. A light emitting chip is bonded on one plateau with a wire connecting the chip with the other plateau. Finally, an encapsulant is formed on the base to seal the chip and the wire.

Abstract: An LED includes a base, first and second electrodes embedded in the base, and an LED chip electrically connected with the first and second electrodes. The first electrode includes a first main body portion and three first branch portions. The second electrode includes a second main body and three second branch portions. The first and second branch portions are exposed at sidewalls of the base. One of the first branch portions and one of the second branch portions are exposed at two opposite lateral sides of the base respectively, and another one of the first branch portions and another one of the second branch portions are exposed at the same lateral side of the base. This disclosure also discloses a manufacture method for making the LED.

Abstract: A method for manufacturing LEDs is disclosed. A base is firstly provided. The base includes a plate, sidewalls formed on the plate and pairs of leads connected to the plate. The sidewalls enclose cavities above the plate. Light emitting chips are fixed in the cavities and electrically connected to the leads, respectively. Encapsulants are formed in the cavities to seal the light emitting chips. Each encapsulant has a convex top face protruding beyond top faces of the sidewalls. The convex top faces of the encapsulants are grinded to become flat. Finally, the base is cut to form individual LEDs.

Abstract: A method of packaging a light emitting diode comprising: providing a flexible substrate with a heat-conducting layer, an insulating layer covering on a surface of the heat-conducting layer and an electrically conductive layer positioned on the insulating layer; etching the conductive layer to form a gap in the conductive layer and expose a part of the insulating layer, the conductive layer being separated by the gap into a first electrode and a second electrode isolated from each other; stamping the flexible substrate with a mold at the position of the gap to form a recess in the flexible substrate; positioning a light emitting element on the conductive layer and electrically connecting the light emitting element to the conductive layer; and forming an encapsulation to cover the light emitting element.

Abstract: An LED package includes an insulated frame, a first metallic conductor and a second metallic conductor, a chip and an encapsulation. The insulated frame has a receiving groove defined therein. The two metallic conductors are both mounted on bottom of the insulated frame and separated from each other. The chip is placed in the receiving groove and electrically connected to the two metallic conductors. The encapsulation is located in the receiving groove. The first metallic conductor and the second metallic conductor each comprise a mounting portion exposed to the receiving groove and a reflecting portion extending from the mounting portion into the insulated frame. The first reflecting portion and the second reflecting portion cooperatively surround the receiving groove of the insulated frame.

Abstract: An LED (light emitting diode) module includes a circuit board and a plurality of LEDs mounted on the circuit board. The circuit board includes a support layer, an insulative layer and a conductive layer sequentially stacked on each other. The circuit board is embossed to form a plurality of pleats on top and bottom surfaces thereof, to thereby increase heat dissipation area of the circuit board.

Abstract: An LED includes a base, a pair of leads fixed on the base, a housing fixed on the leads, a chip mounted on one lead and an encapsulant sealing the chip. The housing defines a cavity in a central area thereof and a chamber adjacent to a circumferential periphery thereof. Top faces of the leads are exposed in the chamber. A blocking wall is formed in the chamber to contact the exposed top faces of the leads. A bonding force between the blocking wall and the leads is larger than that between the leads and the housing. A method for manufacturing the LED is also disclosed.

Abstract: An LED package includes a base, an LED chip, and an electrode layer. The base has thereon a first electrical connecting layer and a separated second electrical connecting layer. The LED chip is placed on the base and electrically connected with the first electrical connecting layer and the second electrical connecting layer by flip chip bonding. The electrode layer comprises a first electrode and a separated second electrode, and a receiving groove being defined between the first electrode and the second electrode. The base is received in the receiving groove of the electrode layer with the first electrical connecting layer being electrically connected to the first electrode, and the second electrical connecting layer being electrically connected to the second electrode.

Abstract: An LED (light emitting diode) includes a base, a pair of leads fixed on the base, a housing secured on the leads, a chip mounted on one lead and an encapsulant sealing the chip. The housing defines a cavity to receive the chip. The cavity includes an upper chamber and a lower chamber communicating with the upper chamber. The lower chamber is gradually expanded along a top-to-bottom direction of the LED, and the upper chamber is gradually expanded along a bottom-to-top direction of the LED. The encapsulant substantially fills the lower chamber and the upper chamber.

Abstract: A semiconductor light emitting device comprises a circuit, a reflector, an LED chip, an encapsulation layer and a luminescent conversion layer. The encapsulation layer comprises an annular projection formed outside the encapsulation layer. The circuit and the LED chip are covered by the encapsulation layer, wherein the annular projection of the encapsulation layer is inside the reflector; the encapsulation layer also fills in an interspace between two electrodes of the circuit. Therefore the semiconductor light emitting device is rigid and strongly resistant to water vapor and similar contaminants.

Abstract: An LED package structure includes a substrate, two electrodes engaged in the substrate, an LED chip, a reflective cup and an encapsulation. The substrate includes a first surface and a second surface opposite to the first surface. Each of the electrodes defines a groove. The grooves surrounding the LED chip. The LED chip is mounted on one of the electrodes and electrically connected to the two electrodes. The reflective cup is mounted on the substrate and surrounds the LED chip. The encapsulation covers the LED chip and extends in the grooves of the electrodes to prevent water/moisture from entering the LED chip.

Abstract: An LED package includes a substrate, an LED die, electrodes, a reflective cup, a barrier portion and an encapsulation. The substrate includes a first surface and a second surface opposite to the first surface. The electrodes are formed on the substrate and spaced from each other. The barrier portion is formed on the electrodes and covered by the reflective cup, wherein a bonding force between the barrier portion and the electrodes is larger than that between the reflective cup and the electrodes. The LED die is mounted on one of the electrodes, received in the reflective cup and electrically connected to the electrodes via wire bonding. The disclosure also provides a method for making an LED package.

Abstract: A method for manufacturing light emitting diodes includes steps: providing a substrate having an upper conductive layer and a lower conductive layer formed on a top face and bottom face thereof; dividing each of the upper conductive layer and the lower conductive layer into first areas and second areas; defining cavities in the substrate through the first areas of the upper conductive layer to expose the lower conductive layer; forming conductive posts within the substrate; forming an overlaying layer to connect the first areas of the upper and lower conductive layers; mounting chips on the overlaying layer within the cavities and electrically connecting each chip with an adjacent first area and post; forming an encapsulant on the substrate to cover the chips; and cutting the substrate into individual packages.

Abstract: An LED package includes an insulated frame, a first metallic conductor and a second metallic conductor, a chip and an encapsulation. The insulated frame has a receiving groove defined therein. The two metallic conductors are both mounted on bottom of the insulated frame and separated from each other. The chip is placed in the receiving groove and electrically connected to the two metallic conductors. The encapsulation is located in the receiving groove. The first metallic conductor and the second metallic conductor each comprise a mounting portion exposed to the receiving groove and a reflecting portion extending from the mounting portion into the insulated frame. The first reflecting portion and the second reflecting portion cooperatively surround the receiving groove of the insulated frame.

Abstract: A light emitting diode package comprises a light emitting diode chip, a first luminescent conversion layer and a separate second luminescent conversion layer on the first luminescent conversion layer. The first luminescent conversion layer has a first luminescent conversion element surrounding the light emitting diode chip. The second luminescent conversion layer has a second luminescent conversion element located above the light emitting diode chip. An excitation efficiency of the first luminescent conversion element is higher than that of the second luminescent conversion element.

Abstract: An LED package structure with a wide optical field comprises a substrate, an LED chip, and an encapsulation. The substrate has at least two electrodes and a carrier. The carrier has a carrier surface. The carrier surface is higher than a top surface of the substrate and higher than the electrodes. The LED chip is mounted on the carrier surface. The LED chip electrically connects with the electrodes via wires. The encapsulation covers the LED chip. The LED chip has a wide light emitting angle.

Abstract: The disclosure provides a manufacturing method for an LED package. A first luminescent conversion layer comprising one first luminescent conversion element is located on an LED chip, wherein the first luminescent conversion element is precipitated via centrifugation around the LED chip without sheltering the LED chip. Thereafter, a second luminescent conversion layer is located on the first luminescent conversion layer. The second luminescent layer has a second luminescent conversion element which has an excited efficiency lower that that of the first luminescent conversion element.