A positive-electrode belt-shaped sheet is cut while the positive-electrode belt-shaped sheet and a negative-electrode belt-shaped sheet are continuously sent, a cut positive-electrode sheet laminated on the uncut negative-electrode belt-shaped sheet via a separator layer is sent and clamped, the uncut negative-electrode belt-shaped sheet is cut at a cutting gap between the positive-electrode sheets laminated thereon, so as to form a sheet unit including the positive-electrode sheet and the negative-electrode sheet, a lamination shape of the sheet unit is measured so as to determine good or bad of the lamination shape, the sheet unit is classified based on a good/bad determination result, and the sheet units determined as good products is collectively laminated and pressed so as to obtain a laminated electrode body. Here, the positive-electrode belt-shaped sheet is cut while the positive-electrode belt-shaped sheet is clamped.

A laminate including at least providing a first intermediate laminate provided with a carrier substrate including a support and a peelable metal layer formed on at least one surface of the carrier substrate, forming, in a section not serving as a product of the first intermediate laminate, a first hole reaching at least the support from the surface of the first intermediate laminate, to prepare a second intermediate laminate with the first hole, stacking and disposing on the surface where the first hole is formed, an insulating material and a metal foil in this order when viewed from the surface, and pressurizing the second intermediate laminate, the insulating material and the metal foil in the stacking direction with heating, to prepare a third intermediate laminate where the first hole is filled with the insulating material, and performing treatment with a chemical agent on the third intermediate laminate.

A lightweight construction element (1) comprises at least one lightweight panel (2) and a layer of insulating material (4) associated with the lightweight panel (2), wherein the at least one lightweight panel (2) comprises boards (6), which, on at least one of the main surfaces (8) thereof, have a group of grooves (9) running parallel and which boards (6) are arranged in at least one layer (5) and are connected to one another via adhesive bonds. The layer of insulating material (4) comprises wood chips (19), which are removed from starting boards during the manufacture of boards (6) for the lightweight panels (2). These lightweight construction elements have good load and thermal insulation properties. The material used originates from one source and achieves a large overall volume after processing.

A peeling apparatus including a support body supply unit, a support body hold unit, a transfer mechanism, and a first structure body. The first structure body has a convex surface. The support body supply unit has a function of unwinding a first support body and includes one of a pair of tension applying mechanisms. The support body hold unit includes the other of the pair of tension applying mechanisms. The pair of tension applying mechanisms applies tension to the first support body. The transfer mechanism has a function of transferring a process member. The first structure body has a function of bending back the first support body along the convex surface. The first structure body has a function of dividing the process member into a first member and a second member. An angle at which the first structure body bends back the first support body is an obtuse angle.

A method and an apparatus for manufacturing an optical display device by sequentially peeling a plurality of optical film sheets continuously supported on a long web of a carrier film and laminating the plurality of optical film sheets to a plurality of panel components are provided.

Snowboards are constructed by initial manufacture of a base sub-assembly including fewer than all layers of the snowboard, e.g., a base layer, edges, and a stabilizing layer. These layers are permanently bonded together into a unitary base sub-assembly. The running (bottom) surface is then finished to provide a desired surface consistency by eliminating undesired irregularities from the manufacturing process, e.g., using a conventional base grinding machine. Subsequently, the base sub-assembly and remaining snowboard layers (e.g., top sheet and a core sandwiched between reinforcing layers) are permanently bonded together into a unitary final snowboard assembly, which may then be worked to form a finished snowboard. Snowboards may be either flat or non-flat in both the longitudinal and transverse directions. Accordingly, the method may be used to produce snowboards having a desired sanded/ground base surface having a desired surface consistency, even for snowboards that are non-flat in the transverse direction.

A positive-electrode belt-shaped sheet is cut while the positive-electrode belt-shaped sheet and a negative-electrode belt-shaped sheet are continuously sent, a cut positive-electrode sheet laminated on the uncut negative-electrode belt-shaped sheet via a separator layer is sent and clamped, the uncut negative-electrode belt-shaped sheet is cut at a cutting gap between the positive-electrode sheets laminated thereon, so as to form a sheet unit including the positive-electrode sheet and the negative-electrode sheet, a lamination shape of the sheet unit is measured so as to determine good or bad of the lamination shape, the sheet unit is classified based on a good/bad determination result, and the sheet units determined as good products is collectively laminated and pressed so as to obtain a laminated electrode body. Here, the positive-electrode belt-shaped sheet is cut while the positive-electrode belt-shaped sheet is clamped.

The electronic component device production method includes a step A of preparing a layered body comprising electronic components immobilized on a support body, a step B of preparing an electronic component sealing sheet, a step C of disposing the electronic component sealing sheet over the electronic components under conditions where the probe tack force of the electronic component sealing sheet is 5 gf or lower according to a probe tack test, a step D of rising the temperature of the electronic component sealing sheet until the probe tack of the electronic component sealing sheet is 10 gf or greater according to the probe tack test to immobilize temporarily the electronic component sealing sheet onto the electronic components, and a step E of embedding the electronic components in the electronic component sealing sheet to form a sealed body comprising the electronic components embedded in the electronic component sealing sheet.

There is provided a composite structure, comprising a base member(s) made of metallic material, and a reinforcement member(s) made of fiber reinforced plastic including reinforcement fibers which are aligned in a uni-direction, wherein at least one slit is formed on the reinforcement member(s) so as to extend in an orientation direction of the reinforcement fibers.

A display apparatus, an attaching system and an attaching method. The display apparatus comprises a cover plate (2), a display panel (1) and a supporting plate (3). The cover plate (2) comprises a first flat surface portion (21), a second flat surface portion (22) and a first curved surface portion (23), wherein the first curved surface portion (23) is smoothly connected between the first flat surface portion (21) and the second flat surface portion (22); the second flat surface portion (22) is parallel to the first flat surface portion (21); the first curved surface portion (23) extends in a first direction; an orthographic projection of the first curved surface portion (23) on a first reference plane is arc-shaped; the first reference plane is perpendicular to an extension direction of the first curved surface portion (23); and an accommodating space is formed by means of the enclosure of the first flat surface portion (21), the second flat surface portion (22) and the first curved surface portion (23). The display panel (1) is arranged in the accommodating space. The supporting plate (3) comprises a first straight supporting portion (3a), a first cambered surface supporting portion (3b) and a second straight supporting portion (3c), which are sequentially connected; the modulus of the first cambered surface supporting portion (3b) is smaller than that of the first straight supporting portion (3a) and is also smaller than that of the second straight supporting portion (3c); the first straight supporting portion (3a) is attached to the side of the display panel (1) away from the first flat surface portion (21); the first cambered surface supporting portion (3b) is attached to the side of the display panel (1) away from the first curved surface portion (23); and the second straight supporting portion (3c) is attached to the side of the display panel (1) away from the second flat surface portion (22). The supporting plate (3) has enough strength to support the display panel (1), and the supporting plate (3) has enough flexibility so as not to be prone to warping and bulging when being bent, thereby preventing the display panel from warping and bulging.