A method for producing linerless non-top coated thermal printable material. The method includes preparing thermal printable material by receiving base printable material, wherein base printable material being 75% w/w to 85% w/w of linerless non-top coated thermal printable material; applying heat-resistant material on base printable material, wherein heat-resistant material being 12% w/w to 18% w/w of linerless non-top coated thermal printable material; applying heat-sensitive material on heat-resistant material to produce thermal printable material, wherein heat-sensitive material being 3% w/w to 7% w/w of linerless non-top coated thermal printable material; and subjecting thermal printable material to supercalendering operation, supercalendering operation comprising passing thermal printable material through at least two calender rolls at temperature ranging from 30 C. to 80 C. rolling at speed ranging from 150 m/min to 500 m/min at pressure ranging from 50 bar to 120 bar to obtain linerless non-top coated thermal printable material.

A laminating device, a processing method for the electrode plate assembly, and a thermally bonding device for electrode plates are provided. The laminating device includes a laminating platform, a first driving roller assembly, and a second driving roller assembly. A first spacing d1 is arranged between the first driving roller assembly and the second driving roller assembly. A length of each of the electrode plate units is L, d1 is less than L, or d1 is greater than L, and a ratio between d1 and Lis a non-integer.

A high-speed, cold laminating system includes a lamination unit for inline use connected with a paper feeder supplying at least 30 ppm. The lamination unit further includes a set of unheated motor-driven laminating pressure rollers along a laminating path, and a cutter between the rollers and an exit. A diverter gate passes the paper sheets to the laminating path or to the exit without passing along the laminating path. The system includes a controller to control the motor, the diverter gate, and functions of the lamination unit. The controller is programmed to control the motor to pause the pressure rollers with a leading sheet therein while a subsequent sheet moves toward the pressure rollers so a laminated spacing distance between a trailing edge of the leading sheet and a leading edge of the subsequent sheet to equal a prescribed spacing distance.

The presently disclosed subject matter generally relates to recyclable insulation material for shipping containers, groceries bags, etc., machines for making the recyclable insulation material, and methods for the making the recyclable insulation material. In one aspect, an insulation product may include a first layer and a first continuous paper sheet formed into a first plurality of flexible loops disposed on and attached to the first layer and defining a first plurality of air channels that extend in a direction that is substantially perpendicular with a machine direction of the insulation product. A take up factor of the first continuous paper sheet to the first layer may be greater than 1:1.

An examination of microwave oven-resistant sheets for heat-insulating foamed paper containers revealed that blisters occur in the containers in the course of microwave oven treatment. That is to say, the present invention addresses the problem of providing a sheet for heat-insulating foamed paper container such that no blisters occur during microwave oven treatment. The present inventors have found that the problem to be solved by the present invention can be solved by a method for producing a sheet for a heat-insulating foamed paper container, wherein an air gap of 150 mm or larger, a drawing speed of 65 m/minute or lower, and a polyethylene resin density of 923 to 930 kg/m.sup.3.

A high-speed cold laminating system including a cartridge having two rolls of pressure-sensitive laminating film. The goes into a receptacle of the laminating system. A steering module is upstream of the pressure rollers and a cutter is downstream of the pressure rollers. The steering module orients and positions sheets with respect to a directional path. The cutter severs a length of the laminating film containing a sheet from the remaining laminating film. A controller controls the conveyance of sheets and is programmed for bi-directional communication with an EEPROM of the cartridge. The EEPROM provides information to the controller regarding the laminating film, and the controller tracks film consumption within the system. The controller is programmed to periodically update the EEPROM of the laminating film cartridge with a current remaining film length during use within the laminating system based on the laminating film consumption tracked by the controller.

The presently disclosed subject matter generally relates to recyclable insulation material for shipping containers, groceries bags, etc., machines for making the recyclable insulation material, and methods for the making the recyclable insulation material. In one aspect, an insulation product may include a first layer and a first continuous paper sheet formed into a first plurality of flexible loops disposed on and attached to the first layer and defining a first plurality of air channels that extend in a direction that is substantially perpendicular with a machine direction of the insulation product. A take up factor of the first continuous paper sheet to the first layer may be greater than 1:1.

A sheet laminator includes a fuser pressure member, a heater, a drive device, and circuitry. The fuser pressure member thermally fixes a two-ply sheet and a sheet medium inserted between two sheets of the two-ply sheet. The heater heats the fuser pressure member. The driver rotates the fuser pressure member. In response to a pause of a rotation of the fuser pressure member, the circuitry turns off a power supply to the heater, and perform one of immediately stopping the fuser pressure member or rotating the fuser pressure member and stopping the fuser pressure member after the rotation of the fuser pressure member, based on a state of the fuser pressure member.

A lamination-forming system according to the present disclosure includes: a pair of carrier films for sandwiching an object to be laminated between the pair of carrier films from above and below and conveying the object to be laminated along a conveyance direction; a film unwinder for unwinding the carrier film; a laminator for pressing the object to be laminated to form a lamination-formed product, the laminator being disposed on a downstream side with respect to the film unwinder; and a cooling unit configured to cool the lamination-formed product, the cooling unit being disposed on a downstream side with respect to the laminator. The cooling unit includes an airflow generation unit configured to cause a cooling air to flow in a direction inclined at a predetermined angle with respect to a direction substantially perpendicular to the conveyance direction, toward a downstream side in the conveyance direction.

The present invention relates to a functional fabric manufacturing method and a functional fabric thereby, which relates to a method for manufacturing an upcycle functional fabric, comprising steps of: (a) preparing a separator sheet with a microporous structure discarded due to treatment as defective or overproduction in production processes for manufacturing secondary batteries, (b) interposing an adhesive sheet between the separator sheet and a fabric sheet to be added to the separator sheet, thereby supplying each sheet, (c) laminating the separator sheet and the fabric sheet so that they are bonded by melting of the adhesive sheet, wherein in the step (b), each sheet is supplied to maintain a constant tension, but the separator sheet, the adhesive sheet, and the fabric sheet are all supplied at the same speed, and in the step (c), a stacked structure, in which the separator sheet, the adhesive sheet, and the fabric sheet are stacked in this order, is pressurized in a predetermined temperature atmosphere, and laminated.