Abstract: An LED chip package structure with high-efficiency light emission by rough surfaces includes a substrate unit, a light-emitting unit, and a package colloid unit. The substrate unit has a substrate body, and a positive electrode trace and a negative electrode trace respectively formed on the substrate body. The light-emitting unit has a plurality of LED chips arranged on the substrate body. Each LED chip has a positive electrode side and a negative electrode side respectively and electrically connected with the positive electrode trace and the negative electrode trace of the substrate unit. The package colloid unit has a plurality of package colloids respectively covering the LED chips. Each package colloid has a cambered colloid surface and a light-emitting colloid surface respectively formed on its top surface and a lateral surface thereof.

Abstract: An LED package structure with a deposited-type phosphor layer includes a substrate unit, a light-emitting unit and a package unit. The substrate unit includes at least one circuit substrate. The light-emitting unit includes a plurality of LED chips disposed on and electrically connected to the at least one circuit substrate. The package unit includes at least one package resin body formed by a mold structure. The at least one package resin body is formed on the at least one circuit substrate to cover the LED chips, and the at least one package resin body includes a continuous phosphor layer formed therein and deposited on outer surfaces of the LED chips by centrifugal force. Hence, the instant disclosure provides the continuous phosphor layer with the deposited phosphor powders for covering the outer surfaces of the LED chips, thus the light-emitting efficiency of the LED package structure can be increased actually.

Abstract: A white light-emitting diode package structure for simplifying package process includes a substrate unit, a light-emitting unit, a phosphor unit and a conductive unit. The light-emitting unit is disposed on the substrate, and the light-emitting unit has a positive conductive layer and a negative conductive layer. The phosphor unit has a phosphor layer formed on the light-emitting unit and at least two openings for respectively exposing one partial surface of the positive electrode layer and one partial surface of the negative electrode layer. The conductive unit has at least two conductive wires respectively passing through the two openings in order to electrically connect the positive electrode layer with the substrate unit and electrically connect the negative electrode layer with the substrate unit.

Abstract: An LED package structure includes a conductive substrate unit, a first insulative unit, a second insulative unit, a light-emitting unit and a package unit. The conductive substrate unit includes at least two conductive bases and at least one gap is formed between the two conductive bases. The first insulative unit includes at least one first insulative layer filled in the gap to join the two conductive bases. The second insulative unit includes at least one second insulative layer disposed on the conductive substrate unit and a plurality of openings passing through the second insulative layer for exposing one part of the top surface of each conductive base. The light-emitting unit includes at least one light-emitting element passing one of the openings and electrically connected between the two conductive bases. The package unit includes a package resin body disposed on the second insulative unit to cover the light-emitting element.

Abstract: A conductive substrate structure includes a substrate unit, a conductive pad unit, and a conductive layer unit. The substrate unit has a top surface, a bottom surface, two opposite lateral surfaces, and a front surface. The conductive pad unit has at least two first conductive pads separated from each other and disposed on the top surface, and at least two second conductive pads separated from each other and disposed on the bottom surface. The conductive layer unit has at least two first conductive layers formed on the front surface and respectively electrically connected to two front sides of the two first conductive pads, and at least two second conductive layers respectively formed on the two opposite lateral surfaces and respectively electrically connected to two opposite lateral sides of the two second conductive pads. The two first conductive layers are respectively electrically connected with the two second conductive layers.

Abstract: A LED chip package structure with multifunctional integrated chips includes a substrate unit, a light-emitting unit, a chip unit, and a package colloid unit. The light-emitting unit has a plurality of LED chips electrically arranged on the substrate unit. The chip unit is electrically arranged on the substrate unit, and the chip unit is arranged between the light-emitting unit and a power source. The package colloid unit covers the LED chips. The package colloid unit is a strip fluorescent colloid corresponding to the LED chips.

Abstract: An illumination device with a fire-fighting function includes a transparent hollow casing, fire-fighting water, a light-emitting unit, and a light-guiding unit. The transparent hollow casing has a receiving space. The fire-fighting water is filled into the receiving space of the transparent hollow casing. The light-emitting unit has a plurality of light-emitting elements disposed beside one or more lateral sides of the transparent hollow casing. The light-guiding unit is disposed over the transparent hollow casing. Hence, when fire accident happens, the transparent hollow casing will melt and crack due to the developed over-heat, and the fire-fighting water is sprayed out from the receiving spaces in order to extinguish one part of flames. Therefore, the present invention can be used as a lighting device or can be used as a fire-fighting device when fire accident happens.

Abstract: A wafer level LED package structure includes a light-emitting unit, a reflecting unit, a first conductive unit and a second conductive unit. The light-emitting unit has a substrate body, a light-emitting body disposed on the substrate body, a positive and a negative conductive layers formed on the light-emitting body, and a light-emitting area formed in the light-emitting body. The reflecting unit has a reflecting layer formed between the positive and the negative conductive layers and on the substrate body for covering external sides of the light-emitting body. The first conductive unit has a first positive conductive layer formed on the positive conductive layer and a first negative conductive layer formed on the negative conductive layer. The second conductive unit has a second positive conductive structure formed on the first positive conductive layer and a second negative conductive structure formed on the first negative conductive layer.

Abstract: A lamp head assembly includes an outer head unit, an inner head unit, and an elastic pressing unit. The outer head unit includes at least two conductive pins. The inner head unit is disposed rotatably in the outer head unit. The elastic pressing unit is disposed movably in the outer head unit for selectively positioning the position of the inner head unit relative to the outer head unit or the position of the outer head unit relative to the inner head unit, wherein the elastic pressing unit includes a pressing element selectively exposed from the outer head unit.

Abstract: An LED chip package structure with different LED spacing includes a substrate unit, a light-emitting unit, and a package colloid unit. The light-emitting unit has a plurality of LED chips electrically arranged on the substrate unit, and the LEDs are separated from each other by totally different spacing or partially different spacing. For example, the spacings between each two LED chips are from rarefaction to condensation, from condensation to rarefaction, from center rarefaction to outer condensation, from center condensation to outer rarefaction, alternate rarefaction and condensation, or alternate condensation and rarefaction. The package colloid unit covers the LED chips.

Abstract: A method for fabricating a LED includes: providing a metal substrate; etching the metal substrate to form a first terminal, a second terminal, and a gap between the first terminal and the second terminal, wherein the first terminal has at least one first etching concave and the second terminal has at least one second etching concave; placing at least one LED chip in the at least one first etching concave, wherein the at least one LED chip has a first electrode and a second electrode; electrically connecting the first electrode with the first terminal, and electrically connecting the second electrode with the second terminal; and then covering the at least one LED chip with synthetic polymer, wherein the synthetic polymer is filled into the at least one first etching concave, the at least one second etching concave and the gap to connect the first terminal with the second terminal.

Abstract: An LED chip package structure with a high-efficiency heat-dissipating substrate includes a substrate unit, an adhesive body, a plurality of LED chips, package bodies and frame layers. The substrate unit has a positive substrate, a negative substrate, and a plurality of bridge substrates separated from each other and disposed between the positive and the negative substrate. The adhesive body is filled between the positive, the negative and the bridge substrates in order to connect and fix the positive substrate, the negative substrate and the bridge substrates together. The LED chips are disposed on the substrate unit and electrically connected between the positive substrate and the negative substrate. The package bodies are respectively covering the LED chips. The frame layers are respectively disposed around the packages bodies in order to form a plurality of light-projecting surfaces on the package bodies, and the light-projecting surfaces correspond to the LED chips.

Abstract: An LED package structure includes a substrate unit, a conductive unit, a heat-dissipating unit, a light-emitting unit and a package unit. The substrate unit includes an insulating substrate. The conductive unit includes two top conductive pads disposed on top surface of the insulating substrate, two bottom conductive pads disposed on bottom surface of the insulating substrate, and a plurality of penetrating conductive posts passing the insulating substrate. The two top conducive pads respectively electrically connect the two bottom conductive pads through the penetrating conductive posts. The heat-dissipating unit includes a top heat-dissipating block and a bottom heat-dissipating block respectively disposed on top and bottom surfaces of the insulating substrate. The light-emitting unit includes a light-emitting element on the top heat-dissipating block and electrically connected between the two top conductive pads.

Abstract: A detection system for detecting appearances of many electronic elements includes a rotary module, a feeding module and a detection module. The rotary module has a base structure and a hollow transparent rotary structure disposed on the base structure. The feeding module is disposed beside one side of the hollow transparent rotary structure in order to sequentially guide the electronic elements to the top surface of the hollow transparent rotary structure. The detection module has a plurality of detection units sequentially disposed around the hollow transparent rotary structure. Each detection unit is composed of an image-sensing element for sensing the electronic elements, an image-capturing element for capturing surface images of the electronic elements and a classifying element for classifying the electronic elements.

Abstract: A simple detachable illumination lamp tube includes a tube unit, a heat-dissipating unit, a light-emitting unit, a support unit and a lateral cover unit. The tube unit has a light-permitting hollow tube. The heat-dissipating unit has a heat-dissipating substrate received in the light-permitting hollow tube. The heat-dissipating substrate has two opposite lateral sides contacting the inner surface of the light-permitting hollow tube. The light-emitting unit has a plurality of strip light-emitting modules received in the light-permitting hollow tube. The strip light-emitting modules are disposed on the heat-dissipating substrate and electrically connected in sequence. The support unit has a plurality of support elements received in the light-permitting hollow tube and disposed between a bottom side of the heat-dissipating substrate and the inner surface of the light-permitting hollow tube. The lateral cover unit has two lateral covers installed on two ends of the light-permitting hollow tube.

Abstract: A method of manufacturing a LED chip package structure includes the steps of: providing a substrate unit including a strip substrate body; electrically connecting a plurality of LED chips to the strip substrate body; and placing a strip package colloid body on the strip substrate body to cover the LED chips, wherein the strip package colloid body has an exposed top surface and an exposed surrounding peripheral surface connected between the exposed top surface and the strip substrate body, and the strip package colloid body has at least one exposed lens portion projected upwardly from the exposed top surface thereof and corresponding to the LED chips. Hence, light beams generated by the LED chips pass through the strip package colloid body to form a strip light-emitting area on the strip package colloid body.

Abstract: A wafer level LED package structure for increasing light-emitting efficiency includes: a light-emitting unit, an insulating unit, two first conductive units and two second conductive units. The light-emitting unit has a light-emitting body, a positive conductive layer, a negative conductive layer, and a reflecting insulating layer formed between the positive conductive layer and the negative conductive layer. The light-emitting body has a bottom material layer and a top material layer. The insulating unit is formed around an outer area of a top surface of the bottom material layer and formed on a top surface of the reflecting insulating layer. One first conductive unit is formed on one part of the positive conductive layer and the insulating unit, and another first conductive unit is formed on one part of the negative conductive layer and the insulating unit. The two second conductive units are respectively formed on the two first conductive units.