203results about How to "Good heat shrinkability" patented technology

The invention provides a single-layer or multi-layer packaging film or sheet having at least one layer formed of a polyamide resin composition, wherein the layer formed of the polyamide resin composition is a layer (A) formed of a polyamide resin composition comprising a copolymer nylon (c) composed of an aliphatic nylon (co)polymer component (1) and an aromatic nylon (co)polymer component (2) in a proportion of at least 5 wt. %.

The invention discloses a ceramic coating diaphragm for a lithium battery and a preparation method of the ceramic coating diaphragm, and belongs to the technical field of batteries. The ceramic coating diaphragm comprises a ceramic coating and a substrate diaphragm, wherein the ceramic coating is prepared by uniformly coating the substrate diaphragm with water-based ceramic coating slurry; the ceramic coating slurry comprises components in percentage by weight as follows: 10%-30% of aluminum oxide, 0.5%-3% of a bonding agent, 0.2%-1.0% of an additive and 0.01%-0.1% of an auxiliary; and the aluminum oxide is nanometer aluminum oxide powder with the grain diameter ratio D1/D2 of 0.10-0.20. According to the technical scheme, the safety of the ceramic coating diaphragm is improved, the wetting ability of electrolyte is improved, and the cycle life of the battery can be prolonged when the ceramic coating diaphragm is applied to the lithium battery.

The invention discloses a preparation method of a heat shrinkable polyester film. The method comprises the following steps of: carrying out esterification and condensation polymerization reaction on multi-component dicarboxylic acid and multi-component dihydric alcohol in the presence of a catalyst, a stabilizing agent, an antistatic agent, a chain extender, an anti-caking agent or a modifying agent to prepare a multi-component polyester; carrying out melt extrusion, extension and pelleting on the multi-component polyester to prepare a multi-component polyester slice; and carrying out melted extrusion, die head casting, transverse far infrared drawing, cooling molding, rolling and cutting on the multi-component polyester slice to prepare the heat shrinkable polyester film. The heat shrinkable polyester film with high shrinkage percentage prepared by using the method is pretty high in strength and heat shrinkage performance, excellent in transparency, malleability, and toughness, good in glossiness, uniform in shrinkage, non-toxic, odorless, and easy to recycle, and a product of the film is suitable for labels for various containers and direct packaging of a food product, a beverage product, an electronic product, an electric product, a mechanical product, a hardware product and the like.

The invention relates to a preparation method for a ceramic coating separator material used to lithium ion batteries. The preparation method comprises steps of preparation of a ceramic slurry, separator pretreatment, precise coating, drying and the like. The prepared product has the characteristics that the ceramic coating is compact, uniformly and firm in adhesion and the separator is small in thermal shrinkage, and the prepared product has obvious effect on improving safety performance of the lithium ion battery and prolonging battery service life.

The invention discloses inorganic nanoparticle-modified aramid fiber paste and an aramid-coated lithium battery composite diagram. The inorganic nanoparticle-modified aramid fiber paste comprises aramid, inorganic nanoparticle, a coupling agent and a solvent. The aramid-coated lithium battery composite diagram comprises a battery diagram and an aramid coating layer, wherein the aramid coating layer is coated at a single side or dual sides of the battery diagram, and the aramid coating layer is formed by coating the inorganic nanoparticle with modified aramid paste. The high-temperature resistant performance of the lithium battery diagram is greatly improved, and the air permeability of the lithium battery diagram is improved.

The invention relates to a preparation method of a battery separator. The preparation method comprises: providing a polyolefin porous membrane; adhering an oxidizing agent to the surface of the polyolefin porous membrane; providing a liquid-phase medium containing an organic silicon oxide, wherein the organic silicon oxide contains a methacryloxy group or at least two alkoxy groups, and the alkoxy groups and the methacryloxy group are respectively connected with silicon atoms; heating the polyolefin porous membrane with the surface adsorbed the oxidizing agent in the liquid-phase medium to polymerize the organic silicon oxide and grafting the polymerized organic silicon oxide with the polyolefin porous membrane; and providing an acidic environment or an alkali environment, placing the grafted polyolefin porous membrane in the acidic environment or the alkali environment, to perform a condensation reaction on silicon and oxide groups to form a silicon-oxide cross-linked network structure which is grafted with the polyolefin porous membrane. The invention also relates to the battery separator.

The invention provides a lithium-ion battery separator, and a preparation method and application thereof. The lithium-ion battery separator comprises a separator substrate and an aqueous function layer composited on the surface of the separator substrate. The aqueous function layer is equipped with multiple micropores. The aqueous function layer has viscidity. When the separator provided by the embodiment of the invention is applied to a polymer lithium-ion battery, a partial lithium separation phenomenon will not occurs in a cycle process and deformation or a relatively high expansion phenomenon will not occur in a battery pole group, thereby facilitating stability of cycle life. Moreover, the heat contractility of the separator is improved. The separator and an electrode are adhered together well with the combination of effects such as the viscidity of the aqueous function layer. In a safety test process or when the battery is abused such as the fact that the battery is punctured, extruded, twisted and bended, or when the battery is used in a high temperature environment for a long time, the safety performance of the battery can be greatly improved.

The invention relates to a cable material, and in particular relates to a nano-modified low-shrinkage low-smoke halogen-free and flame-retardant polyolefin cable material and a preparation method thereof. The polyolefin cable material comprises the following components: EVA (Ethylene Vinyl-acetate Copolymer), MLLDPE (Linear Low-Density Polyethylene), an interfacial compatibilizer, aluminum hydroxide, nanometer strong micropowder, an antioxidant and a lubricant. The preparation method comprises the following steps of: evenly stirring the EVA and the MLLDPE as basic materials, the interfacial compatibilizer, the aluminum hydroxide, the nanometer strong micropowder, the antioxidant and the lubricant in a high-speed mixer; performing banburying in a banbury mixer at the temperature between 120 and 150 DEG C; extruding by using double screw rods; granulating by grinding and hot-cutting; conveying materials by using a cyclone separator; and screening by using a vibrating screen and packaging, thereby obtaining the finished nano-modified low-shrinkage low-smoke halogen-free and flame-retardant polyolefin cable material product. Compared with the common low-smoke halogen-free and flame-retardant polyolefin cable material, the polyolefin cable material provided by the invention has the effects that the thermal aging resistance is enhanced; the shrinkage performance of the product is improved greatly; and the problem that the low-smoke halogen-free polyolefin cable material is easy to shrink at the high temperature is solved.

An object of the present invention is to provide a tube which can be easily torn and has a large heat-shrinkability at a low temperature. The tube of the present invention is a heat-shrinkable tube having tearability, including a mixture of a fluorine resin and a different kind of resin from the fluorine resin, in which an amount of change in loss energy, ΔE loss, with change in temperature from 175° C. to 185° C. is a positive value.

Disclosed is a polyolefin microporous membrane having a bubble point of not more than 1 MPa, a tensile strength in the longitudinal direction of not less than 50 MPa, a tensile strength in the width direction of not less than 50 MPa, and a thermal shrinkage in the width direction at 130 DEG C of not more than 20%. This polyolefin microporous membrane is excellent in strength and low thermal shrinkage property, while having a large pore diameter.

The invention relates to a modified polyolefin membrane coated with a silicon dioxide layer and a preparation method thereof. The method comprises the following steps of: uniformly mixing ammonium hydroxide, water, ethyl alcohol and Tween 80; adding tetraethoxysilane; uniformly stirring; adding a polyolefin membrane; soaking for a period of time, and then taking out, cleaning and drying, thereby acquiring the product. According to the method provided by the invention, the technique is simple and convenient, the modified polyolefin membrane has no or less pollution to environment, the energy consumption is low, the application scope is wide and the performance is excellent when the prepared modified membrane is applied to a lithium sulfur battery.

The aim of the present invention is to obtain a heat-shrinkable film which is excellent in mechanical characteristics such as heat shrinkage characteristics, impact resistance, and transparency and in the finish of shrinkage and which is suitable for shrink packaging, shrink bundling, shrinkable labels, and so on. A film which is made from a mixed resin comprising as the main components either a polylactic acid resin (A) and a (meth)acrylic resin (B) or a polylactic acid resin (A) and a silicone/acrylic composite rubber (D) or has at least one layer made from the mixed resin and which exhibits a heat shrinkage percentage of 20% or above in the main shrinkage direction when dipped in water at 80 C for 10 seconds.

The production process of polypropylene film includes the following steps: mixing polypropylene resin and functional mother material in certain ratio, co-extruding in extruder to form initial tubular film; fast cooling of the initial tubuler film; preheating at 260-400 deg.c in a stove; transverse blowing to expand for 5.0-8.0 times at 300-510 deg.c in a stove; longitudinal stretching for 6.5-8.0 times at 135-150 deg.c; wind cooling, winding, cutting rewinding and re-cutting. Compared with available plain drawing process, the present invention has the advantages of small covered area, less investment and high heat shrinkage of the product.

The invention discloses a water-based metal ion secondary battery diaphragm, and a preparation method and application thereof, and belongs to the technical field of lithium battery diaphragms. The water-based metal ion secondary battery diaphragm comprises a porous base membrane; the surface of the porous base membrane is coated with a hydrophobic coating; the surface of the hydrophobic coating isgrafted with a hydrophilic coating; the hydrophilic coating is grafted on the surface of the hydrophobic coating through a laser radiation surface grafting method; the wavelength of a light beam forradiation is 9.1-10.6 [mu]m; and the radiation duration is 100-500 ns, preferably 100-200 ns. By adopting the technical scheme provided by the invention, the wettability and the liquid retention of the diaphragm can be effectively improved on the basis of keeping the original excellent physical properties, conductivity and cycle performance of the polymer diaphragm, so that the use requirements ofthe water-based metal ion secondary battery diaphragm are met.