462results about How to "Fast bonding" patented technology

A transformable pressure sensitive adhesive composition comprised of from about 15 to about 80% by weight of a polymer having a softening point greater than 60° C.; from about 20 to about 85% by weight of a polymerizable resin having a softening point less than 30° C.; a latent initiator in an amount sufficient to cause a reaction between said polymer and said resin; and optionally, a crosslinking agent. The transformable pressure sensitive adhesive has particular applicability in connection with organic light emitting diode display devices, light emitting diode display devices, medical diagnostic testing devices, flexible or rigid LCD display devices, plasma display devices, and electrochromic devices.

A microwave-induced heating of CNT filled (or coated) polymer composites for enhancing inter-bead diffusive bonding of fused filament fabricated parts. The technique incorporates microwave absorbing nanomaterials (carbon nanotubes (CNTs)) onto the surface or throughout the volume of 3D printer polymer filament to increase the inter-bead bond strength following a post microwave irradiation treatment and/or in-situ focused microwave beam during printing. The overall strength of the final 3D printed part will be dramatically increased and the isotropic mechanical properties of fused filament part will approach or exceed conventionally manufactured counterparts.

The invention discloses a high-temperature-resistant hot melt adhesive membrane for aluminum honeycomb boards, and a preparation method thereof. The high-temperature-resistant hot melt adhesive membrane for aluminum honeycomb boards is made from, by weight percent, 30-50% of polyester elastomer with above 180 DEG C of melting point, 10-40% of polyolefin copolymer modified by maleic anhydride, 0-40% of polyolefin copolymer, 10-30% of tackifying resin, 0-15% of filler, and 1-3% of functional aid. The components add up to 100%. The high-temperature-resistant hot melt adhesive membrane for aluminum honeycomb boards has the advantages of high adhesion strength, instantaneous resistance to the temperature up to 170-190 DEG C, and long-term resistance to the temperature up to 130 DEG C.

A method and apparatus for making an anastomosis between a tubular duct and a vessel has an annulus having a longitudinal axis, a first set of fingers and a second set of fingers. The first set of fingers extend axially from the annulus in one direction and the second set of fingers extending axially from the annulus in another direction generally opposite the direction of the first set of fingers. The first and second sets of fingers are movable to penetrate the tubular duct and the vessel, respectively, as they move from a biased configuration to an unbiased configuration.

An improved fluoroplastic lined elastomeric tube that can maintain a stable flow rate while pumping aggressive chemicals in a peristaltic pump for an extended period of time and is fabricated in sizes ranging from 0.5 mm to 100 mm in inside diameter. The inner fluoroplastic liner comprises a composite of expanded polytetrafluoroethylene and a fluoroplastic polymer resulting in improved flex life over single component fluoroplastics. The inventive liner is bonded to either an unreinforced elastomer or a fiber reinforced elastomer for use in both low and high pressure peristaltic pump applications.

The invention discloses a biological adhesive which comprises a component a, and a component b, wherein the component a is a functional star polymer or/and a functional comb-like polymer, the functional star polymer is provided with one or more active groups, and the functional comb-like polymer is provided with one or more active groups; the component b is a functional polysaccharide which is provided with one or more active groups; and chemical reactions can be carried out between the active groups of the component a and the active groups of the component b so as to form novel chemical bonds. The invention further discloses a preparation method and application of the biological adhesive. The biological adhesive disclosed by the invention is a biocompatible adhesive (glue) formed by rapidly reacting the functional star polymer or/and comb-like polymer with lots of active groups and the functional polysaccharide. The adhesive based on the star polymer or/and comb-like polymer has a star or/and comb structure and has lots of active reactive groups, so that the gel forming reaction is fast, and the adhesive is reacted with tissues so as to realize an adhesive effect.

The invention discloses a double-component silicone structural sealant for heat mirror hollow glass and a preparation method of the sealant. The sealant comprises a component A and a component B, wherein the component A comprises hydroxyl-terminated polydimethylsiloxane, alkyl-terminated polydimethylsiloxane, hollow microsphere, ceramic microbead, metal hydroxide, metal oxide, activated calcium carbonate, inorganic pigment and a surfactant; the component B comprises alkyl-terminated polydimethylsiloxane, a coupling agent, a cross-linking agent, a catalyst, an inhibitor, a thickening agent, and silicon dioxide. The preparation method of the sealant comprises the following steps: 1) taking each ingredient in the component A to be mixed uniformly under the vacuum condition; 2) taking each ingredient in the component B to be mixed uniformly under the vacuum condition; 3) mixing the component A and the component B at room temperature according to the weight ratio of (8:1) to (20:1), and at last obtaining the sealant. The double-component silicone structural sealant is good in adhesiveness, high in curing speed, good in sealing performance, high in hardness and modulus, and excellent in thermal barrier effect, and suitable for sealing and bonding of heat mirror film, glass and metal materials etc.

A substrate bonding apparatus for bonding substrates together in a vacuum at high speeds, with a high degree of accuracy includes a first chamber C1, a second chamber C2, and a third chamber C3. Two substrates to be bonded together are loaded in the first chamber C1. The two substrates are bonded together in the second chamber C2. The two substrates bonded together are unloaded in the third chamber C3. The first and third chambers are variably controlled from an atmospheric pressure state to a medium vacuum state. The second chamber is variably controlled from the medium vacuum state to a high vacuum state.

A device for connecting two tubular vessels together in a side-by-side or tangential manner is disclosed. The device has an annulus and at least one series of fingers connected to and extending away from the annulus. In the preferred embodiment there are two sets of fingers connected to and extending away from the annulus in opposite directions. Each finger is preferably biased into an arcuate shape. In use, a deployment apparatus is used to constrain the fingers of the device to be in a relatively planar configuration. The deployment apparatus containing the device is placed between and in contact with the two tubular vessels so that one tubular vessel is above the device and one tubular vessel is below the device and so that the fingers of the device come into contact with the tissue of the vessels. As the fingers penetrate the vessels the constraint on the fingers is removed so that the fingers can assume their biased arcuate shape. In this way, the fingers penetrate and grasp the tissue of the vessels so that the device grasps the vessels and pulls the vessels toward each other.

A method of bonding a particle material to near theoretical density, includes placing a particle material in a die. In the first stage, a pulsed current of about 1 to 20,000 amps., is applied to the particle material for a predetermined time period, and substantially simultaneously therewith, a shear force of about 5-50 MPa is applied. In the second stage, an axial pressure of about less than 1 to 2,000 MPa is applied to the particle material for a predetermined time period, and substantially simultaneously therewith, a steady current of about 1 to 20,000 amps. is applied. The method can be used to bond metallic, ceramic, intermetallic and composite materials to near-net shape, directly from precursors or elemental particle material without the need for synthesizing the material. The method may also be applied to perform combustion synthesis of a reactive material, followed by consolidation or joining to near-net shaped articles or parts. The method may further be applied to repair a damaged or worn substrate or part, coat a particle onto a substrate, and grow single crystals of a particle material.

A technique to additively print onto a dissimilar material, especially ceramics and glasses (e.g., semiconductors, graphite, diamond, other metals) is disclosed herein. The technique enables manufacture of heat removal devices and other deposited structures, especially on heat sensitive substrates. It also enables novel composites through additive manufacturing. The process enables rapid bonding, orders-of-magnitude faster than conventional techniques.

The invention relates to the technical field of bra cup pad, and specifically relates to a vertical cotton breathable bra cup pad with a silica gel net and a preparation method thereof. The vertical cotton breathable bra cup pad comprises a vertical cotton outer layer and a vertical cotton inner layer; a vertical cotton interlayer is arranged between the vertical cotton outer layer and the vertical cotton inner layer; an adhesive layer is arranged between the vertical cotton interlayer and the vertical cotton inner layer; and a silica gel net layer is arranged between the vertical cotton outer layer and the vertical cotton interlayer. The vertical cotton breathable bra cup pad is prepared by a combined technology of hot pressing and cold pressing. The pad is made of vertical cotton, and is light, comfortable, and breathable. A silica gel layer is arranged between vertical cotton layers, the performance of the pad on resisting water washing is enhanced, the anti-collapse effect is good, three-dimensional effect of the cup pad is long-lasting and stable, and the deformation is difficult to happen.

The invention discloses a calcium-doped inorganic nanocomposite material for 3D printing. The calcium-doped inorganic nanocomposite material comprises the following components in percentage by weight: 73-80% of ceramic precursor powder, 5-10% of nano-powder reinforcing material, 2-5% of calcium powder, 2-5% of a surfactant, 2-5% of an organic solvent, 1-4% of an inorganic binder and 5-10% of a low-temperature curing agent, wherein the particle size of the nano-powder reinforcing material is 20-200nm. By adopting the surfactant to perform deaggregation treatment on nano-powder, the nano-powder has excellent dispersivity; by adding the nano-powder into the ceramic precursor powder, the density and strength of ceramic can be improved, and the toughness of a product can be further upgraded; by mutually coordinating and matching the inorganic mixed powder, the inorganic binder and the low-temperature curing agent, the fast binding can be realized at low temperature; and the inorganic nanocomposite material can be used as a molding raw material of a 3D printing fast molding machine, the fast molding on the 3D printing machine can be effectively realized, and the calcium-doped inorganic nanocomposite material can be applied to a variety of types of 3D printing machines.

The invention relates to a molded part for bonding to metal or plastic substrates for use as a fastening element. Said molded part comprises a hot melt adhesive, said hot melt adhesive being based on polyamide, polyolefins, polyesters, polyacrylates or polystyrene. The molded part according to the invention is characterized in that the hot melt adhesive has a softening point between 100° and 250° C., a tensile stress at yield of between 1 and 35 MPa and the molded part consists entirely of the hot melt adhesive. The invention also relates to a method for bonding molded parts from hot melt adhesives to substrates by way of inductive heating.

The invention is concerned with the mechanical equipment for making and forming the paper container, includes the stander: sets the paper feeding equipment, the delivery plate, the sidewall preheating arrangement, the sidewall forming equipment, the sidewall bonding equipment, the hemline preheating arrangement, the hemline forming equipment, the hemline bonding equipment, the bottom paper conveying appliance, the bottom paper feed apparatus, and the hemline reinforcing equipment on the stander; sets the motor and drive gear in the stander. The invention can avoid ultrasonic radiation, improve the bonding speed, in order to improve the working efficiency. The invention uses the pneumatic control and air conveying to improve the yield; the complete machines shorts the power stroke farthest, improves the stability and processing speed of the equipment.

The invention discloses a method for manufacturing an interior film-pasting woven bag, and relates to the technical field of woven bag manufacturing. The interior film-pasting woven bag comprises an outer plastic bag body formed by weaving polypropylene plastics. An ethylene-vinyl acetate film and a high-pressure low-density polyethylene film are sequentially arranged in the outer plastic bag body. The method includes the following operation steps: A, manufacturing plastic ribbon-like filaments; B, manufacturing the two films; C, manufacturing the outer plastic bag body with the double films; D, manufacturing an interior film-pasting woven bag reel by an interior film pasting combining machine through the outer plastic bag body, obtained in the step C, with the double films; and E, carrying out cutting and sewing on the interior film-pasting woven bag reel obtained in the step D, and completing manufacturing of the interior film-pasting woven bag. Compared with the prior art, the method can solve the problem that an inner bag body of an existing interior film-lining woven bag is prone to being damaged.

The invention relates to a medical antibacterial adhesive and a preparation method thereof, and belongs to the technical field of adhesives. The medical antibacterial adhesive comprises the following constituents in parts by weight: 16 to 20 parts of epoxy resin, 2 to 10 parts of crylic acid, 4 to 10 parts of editic acid, 12 to 18 parts of polyurethane, 2 to 5 parts of polyvinyl alcohol, 2 to 8 parts of methylol cellulose, 1 to 3 parts of citric acid, 3 to 9 parts of nanometer silicon micro powder, 10 to 14 parts of titanium dioxide, and 20 to 30 parts of glycol. The medical antibacterial adhesive has good bonding property, and can rapidly realize bonding even at low temperature; the medical antibacterial adhesive has excellent antibacterial property; the preparation method is simple, convenient to carry out, and suitable for large-scale promotion and application.

A transparent electrode for a gallium nitride-based compound semiconductor light-emitting device includes a p-type semiconductor layer (5), a contact metal layer (1) formed by ohmic contact on the p-type semiconductor layer, an current diffusion layer (12) formed on the contact metal layer and having a lower magnitude of resistivity on the plane of the transparent electrode than the contact metal, and a bonding pad (13) formed on the current diffusion layer. The transparent electrode is at an advantage in widening the surface of light emission in the p-type semiconductor layer, decreasing the operation voltage in the forward direction, and enabling the bonding pad to provide excellent adhesive strength.

The invention discloses a polymer represented by a formula I as well as a preparation method and application of the polymer. In the formula I, the molecular weight is 50000-120000; the ratio of x to y is 1:(0.25-0.75); n is 10-50; n1=2 or 3; R1 is any one selected from the group of C1-C4 alkyl and phenyl; and R2 is anyone selected from the group of groups represented by a formula II and a formula III. The preparation method comprises the step of reacting N-(3-amino alkyl) methacrylamide hydrochloride containing amino, dyhydroxyl substituted ortho aromatic aldehyde, phosphite ester and methylacrylic acid polyethylene glycol single methyl ether in an organic solvent in the presence of triethylamine, an initiator and a chain transfer agent. The macromolecular adhesive prepared by the invention is a water-based adhesive, which is mussel-mimetic and environmentally friendly; the macromolecular adhesive is applied to adhering among a plurality of substrates; adhesion can be realized under a variety of conditions; the macromolecular adhesive has good adhesive power; furthermore, the macromolecular adhesive is simple in preparation method, abundant in raw material source and low in cost; and therefore, the macromolecular adhesive is a potential excellent adhesive material.