Abstract: A material composition with specific segment wavelength matching refractive index includes (a) resin or a composite thereof to serve as a bonding agent and (b) a medium material of metal oxides or complex metal oxides of specific particle size to serve as an additive for specific segment wavelength matching refractive index. The composition is formed by combining the bonding agent and additive. The composition material uses the wavelength of light emitting from a light-emitting diode (LED) die or excited from a fluorescent agent as the range of a segment to add nanometer particles of D=?/4n optic thickness as basis for formation of an effective medium layer and thus providing a matching refractive index for wavelength of the specific segment bandwidth. Corresponding to different refractive indexes nx of LED die materials, proper amounts of nanometer particles are selectively added to have the refractive index match the LED die.

Abstract: A light-emitting diode (LED) cutting method includes the following steps: positioning and retaining an LED die or an LED epitaxial substrate on a die retainer; introducing a liquid medium for preventing reflection of sound wave between a cutting tool and the die; activating a power source to drive a magnetostrictive material or piezoelectric ceramic material mounted on a machine to serve as a kinetic source by inducing volume expansion/compression that generates an up-and-down piston-like movement; and operating the cutting tool having super hard micro-particles of diamond, CBN, or SiC electroformed on the cutting tool to perform breaking cutting on an LED workpiece.

Abstract: A material composition with specific segment wavelength matching refractive index includes (a) resin or a composite thereof to serve as a bonding agent and (b) a medium material of metal oxides or complex metal oxides of specific particle size to serve as an additive for specific segment wavelength matching refractive index. The composition is formed by combining the bonding agent and additive. The composition material uses the wavelength of light emitting from a light-emitting diode (LED) die or excited from a fluorescent agent as the range of a segment to add nanometer particles of D=?/4n optic thickness as basis for formation of an effective medium layer and thus providing a matching refractive index for wavelength of the specific segment bandwidth. Corresponding to different refractive indexes nx of LED die materials, proper amounts of nanometer particles are selectively added to have the refractive index match the LED die.

Abstract: A method for manufacturing green-energy water, including: conducting water flow through a self-support visible-light photocatalytic reaction device, which decomposes the water into hydrogen ions and hydroxide ions; conducting the hydrogen ions and the hydroxide ions through an ion separation device, which separates the hydrogen ions and the hydroxide ions from each other; and conducting the separated hydroxide ions into an amount of water to form an amount of alkaline green-energy water and conducting the separated hydrogen ions into another amount of water to form an amount of acidulous green-energy water. The green-energy water manufactured in this way is environmentally friendly and can be used in cleaning purposes of photoelectric and semiconductor industries, processing of waste water, organic cultivation, organic agriculture, purification of water, sterilization of medical facility.

Abstract: A photon-alignment optical film includes a film substrate on which at least one layer of core/shell nanoparticles is coated. The core/shell nanoparticle layer includes a plastic substance, which is photo curable or heat curable, and a plurality of core/shell nanoparticles, which is uniformly distributed in the plastic substance. Light energy is used as a driving force to induce electrical potential of the same polarity on the surfaces of the core/shell nanoparticles to make the core/shell nanoparticles rearranged in the form of a matrix due to repulsion induced between like electrical polarity. Spacing between the particles, which is relatively constant, allows light to pass therethrough. The plastic substance is cured by light or heat to have the core/shell nanoparticles set in position to thereby form the optical film. Such an optical film features both diffusion and brightness enhancement.

Abstract: A photon-alignment optical film includes a film substrate on which at least one layer of core/shell nanoparticles is coated. The core/shell nanoparticle layer includes a plastic substance, which is photo curable or heat curable, and a plurality of core/shell nanoparticles, which is uniformly distributed in the plastic substance. Light energy is used as a driving force to induce electrical potential of the same polarity on the surfaces of the core/shell nanoparticles to make the core/shell nanoparticles rearranged in the form of a matrix due to repulsion induced between like electrical polarity. Spacing between the particles, which is relatively constant, allows light to pass therethrough. The plastic substance is cured by light or heat to have the core/shell nanoparticles set in position to thereby form the optical film. Such an optical film features both diffusion and brightness enhancement.

Abstract: A method for manufacturing green-energy water, including: conducting water flow through a self-support visible-light photocatalytic reaction device, which decomposes the water into hydrogen ions and hydroxide ions; conducting the hydrogen ions and the hydroxide ions through an ion separation device, which separates the hydrogen ions and the hydroxide ions from each other; and conducting the separated hydroxide ions into an amount of water to form an amount of alkaline green-energy water and conducting the separated hydrogen ions into another amount of water to form an amount of acidulous green-energy water. The green-energy water manufactured in this way is environmentally friendly and can be used in cleaning purposes of photoelectric and semiconductor industries, processing of waste water, organic cultivation, organic agriculture, purification of water, sterilization of medical facility.

Abstract: A light-emitting diode (LED) cutting method includes the following steps: (A) positioning and retaining an LED chip or an LED epitaxial substrate on a chip retainer; (B) introducing a liquid medium to serve as a sound wave reflection layer medium between a cutting tool and the chip; (C) activating a power source to drive a magnetostrictive or piezoelectric ceramic material mounted on a machine to serve as a power source by inducing volume expansion/compression that generates up-and-down piston-like movement; and (D) operating the cutting tool of a proper shape that has a surface on which super hard micro-particles of diamond, CBN, or SiC are electroformed to carry out up-and-down piston-like reciprocal motion on the material retained on the chip retainer to drive the super hard micro-particles on the surface of the cutting tool into a pre-cut workpiece to perform breaking cutting.

Abstract: The present invention relates to a method of producing high-density polyidimide (HPI) films and its production equipment. The production equipment comprises a raw material supplying means, a vacuum cavity, an energy supplier, a clad laminator, and a baked solidified polymer. The foregoing components constitutes the production equipment, using the monomer with the CONH bond or copolymer as raw materials to extract the unsaturated C?N bond by heat, electrons, light, radiation rays or ions as energy under low-pressure environment, so that the H in vacuum can extract the non-solidified HPI film from the electronic radical covalent polymers and via heat or light to rearrange the structure into a solidified HPI film. By means of the method according to the present invention, the original HPI that is not easily to produce as a film can be easily made in form of a film of HPI polymer on the clad laminator.

Abstract: The present invention relates to a method of producing high-density polyidimide (HPI) films and its production equipment. The production equipment comprises a raw material supplying means, a vacuum cavity, an energy supplier, a clad laminator, and a baked solidified polymer. The foregoing components constitutes the production equipment, using the monomer with the CONH bond or copolymer as raw materials to extract the unsaturated C═N bond by heat, electrons, light, radiation rays or ions as energy under low-pressure environment, so that the H in vacuum can extract the non-solidified HPI film from the electronic radical covalent polymers and via heat or light to rearrange the structure into a solidified HPI film. By means of the method according to the present invention, the original HPI that is not easily to produce as a film can be easily made in form of a film of HPI polymer on the clad laminator.

Abstract: The present invention relates to a method of producing high-density polyidimide (HPI) films and its production equipment. The production equipment comprises a raw material supplying means, a vacuum cavity, an energy supplier, a clad laminator, and a baked solidified polymer. The foregoing components constitutes the production equipment, using the monomer with the CONH bond or copolymer as raw materials to extract the unsaturated C═N bond by heat, electrons, light, radiation rays or ions as energy under low-pressure environment, so that the H in vacuum can extract the non-solidified HPI film from the electronic radical covalent polymers and via heat or light to rearrange the structure into a solidified HPI film. By means of the method according to the present invention, the original HPI that is not easily to produce as a film can be easily made in form of a film of HPI polymer on the clad laminator.

Abstract: The present invention relates to a method of producing high-density polyidimide (HPI) films and its production equipment. The production equipment comprises a raw material supplying means, a vacuum cavity, an energy supplier, a clad laminator, and a baked solidified polymer. The foregoing components constitutes the production equipment, using the monomer with the CONH bond or copolymer as raw materials to extract the unsaturated C═N bond by heat, electrons, light, radiation rays or ions as energy under low-pressure environment, so that the H in vacuum can extract the non-solidified HPI film from the electronic radical covalent polymers and via heat or light to rearrange the structure into a solidified HPI film. By means of the method according to the present invention, the original HPI that is not easily to produce as a film can be easily made in form of a film of HPI polymer on the clad laminator.

Abstract: A contamination-resistant thin film deposition method utilizing a reaction-type vacuum sputtering process in which an organic tetrafluoroethylene plastic and conductor substances are sputtered onto a substrate to deposit a thin film onto the substrate, with the thin film deriving its contamination-resistant capability from the anti-stick properties of the tetrafluoroethylene plastic and the anti-static properties of the conductor substances. The contamination-resistant thin film deposition method utilizes a configured tetrafluoroethylene plastic target structure that includes a negative substrate, a filiform electrode, an insulative support, a tetrafluoroethylene plastic sputtering substrate, a positive substrate, a tetrafluoroethylene plastic substrate rotating device, a magnetic field generator, and a gas input port.

Abstract: A miniature recycle-type heat exchanger to produce recycle-type heat exchangers from high extensibility, high plasticity aluminum or copper billets (ingots) utilizing a pressure forming press to extrude lightweight, thin, and small form factor recycle-type heat exchangers. The production method includes annealing copper and aluminum billet (ingot) material, conveying the material to a vibrator for placement in an ordered arrangement, and then conveying and fixing the material onto molds in a pressure forming press for the extrusion tasks required to fabricate the heat exchanger bodies. In the final stage after shaping and determination of the fluid input direction, the bodies are placed in a vacuum sputtering machine to undergo a rough textured heat conductive microparticulate deposition process to complete the production of miniature recycle-type heat exchangers that are of very compact dimensions and lightweight, but have a large heat exchange capacity and, furthermore, a high heat transfer rate.