The invention relates to a method for manufacturing a hoisting rope, comprising the steps of providing a plurality of elongated composite members, which composite members are made of composite material comprising reinforcing fibers in polymer matrix; and arranging the composite members to form an elongated row of parallel composite members, which row has a longitudingal direction, a thickness direction and a width direction, and in which row the composite members are positioned side by side such that they are parallel to each other, and spaced apart from each other in width direction of the row; and directing plasma treatment on the outer surface of the composite members; and embedding the composite members in fluid polymer material; and solidifying the polymer material wherein the composite members are embedded. The invention relates also to a hoisting rope obtained with the method and an elevator comprising the hoisting rope.

Provided are a resin composition for underlayer film formation with which a variation hardly occurs in the line width distribution after processing due to a small thickness of a residual film after mold pressing, a layered product, a method for forming a pattern, an imprint forming kit, and a process for producing a device.

Disclosed is a resin composition for underlayer film formation which is used to form an underlayer film by being applied onto a base material, including a first resin having a radical reactive group in the side chain, a second resin containing at least one selected from a fluorine atom and a silicon atom, and a solvent. The second resin is preferably a resin containing a fluorine atom. The radical reactive group of the first resin is preferably a (meth)acryloyl group.

Provided are a resin composition for underlayer film formation with which a variation hardly occurs in the line width distribution after processing due to a small thickness of a residual film after mold pressing, a layered product, a method for forming a pattern, an imprint forming kit, and a process for producing a device.

A resin composition for underlayer film formation includes a resin having a group represented by General Formula (A) and at least one group selected from a group represented by General Formula (B), an oxiranyl group and an oxetanyl group, a nonionic surfactant and a solvent. R.sup.a1 represents a hydrogen atom or a methyl group, R.sup.b1 and R.sup.b2 each independently represent a group selected from an unsubstituted linear or branched alkyl group having 1 to 20 carbon atoms and an unsubstituted cycloalkyl group having 3 to 20 carbon atoms, R.sup.b3 represents a group selected from an unsubstituted linear or branched alkyl group having 2 to 20 carbon atoms and an unsubstituted cycloalkyl group having 3 to 20 carbon atoms, and R.sup.b2 and R.sup.b3 may be bonded to each other to form a ring.

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A transdermal absorption sheet and a manufacturing method for the transdermal absorption sheet includes a laminating step of forming a multilayer film with a viscosity difference by forming, on a support, a lower layer containing a first transdermal absorption material and an upper layer containing a drug and a second transdermal absorption material and having a lower viscosity than the lower layer, a filling step of filling needle-like recessed portions corresponding to inverted needle-like protruding portions with a solution of the transdermal absorption material by pressing a mold in which the needle-like recessed portions are arranged in a two-dimensional array, against a surface of the multilayer film supported by the support to allow the multilayer film to flow, a solidifying step of solidifying the multilayer film with the mold pressed against the surface of the multilayer film, and a peeling-off step of peeling the solidified multilayer film from the mold.

A transdermal absorption sheet and a manufacturing method for the transdermal absorption sheet includes a laminating step of forming a multilayer film with a viscosity difference by forming, on a support, a lower layer containing a first transdermal absorption material and an upper layer containing a drug and a second transdermal absorption material and having a lower viscosity than the lower layer, a filling step of filling needle-like recessed portions corresponding to inverted needle-like protruding portions with a solution of the transdermal absorption material by pressing a mold in which the needle-like recessed portions are arranged in a two-dimensional array, against a surface of the multilayer film supported by the support to allow the multilayer film to flow, a solidifying step of solidifying the multilayer film with the mold pressed against the surface of the multilayer film, and a peeling-off step of peeling the solidified multilayer film from the mold.

An absorbent article having improved softness signals is disclosed. The article may include a topsheet or a backsheet including a nonwoven web. The web may have a basis weight of 30 gsm or less, may be formed of spunlaid fibers including polyolefin and up to 5 percent by weight TiO.sub.2, and may be impressed with a pattern of bond impressions to a bond area percentage of at least 10 percent forming a pattern of bonded regions and raised regions. The web may have opacity of 42 or greater; have an average height difference between bonded regions and raised regions of at least 280 m; be hydroengorged; and/or have a cross-direction tensile strength of 350 gf/cm. A nonwoven web manufactured to have a suitable combination of such features exhibits an enhanced appearance of softness, soft tactile feel and satisfactory mechanical attributes, while being relatively cost effective.

Feedstocks for additive manufacturing are provided. The feedstock may include a matrix material, and one or more capsules disposed in the matrix material, wherein the one or more capsules are configured to be removable from a surface portion when the matrix material is solidified to form one or more cavities in the surface portion. Methods of depositing the feedstocks and objects formed from the feedstocks are also provided.

An embroidery simulation system and method configured to create desired artwork on a readily attachable base member having the appearance of simulated embroidery is disclosed. The system and method are configured to enable an emblem to be created that resembles embroidery and is configured to enable the emblem to be attached to goods, that were traditionally embroidered, in a fraction of the time previously needed to embroider that same article. In addition, the emblem to be created by the system and method may be attached to goods that traditionally we unable to be embroidered, such as drinking mugs and other hard surfaced goods. The embroidery simulation system and method enhance the flexibility of a company by increasing the type and diversity of product to which an emblem can be affixed while also reducing inventory requirements for resellers of goods.

A method for manufacturing a masking film includes forming a molten polymer web that includes at least one polymer, spraying a fluid on one side of the molten polymer web to rapidly cool a random pattern of locations on the one side of the molten polymer web, and cooling the molten polymer web to form the masking film. The masking film includes a plurality of protrusions on one side thereof that correspond to the random pattern of locations on the one side of the molten polymer web contacted by the fluid.

Substrates comprising a functionalizable layer, a polymer layer comprising a plurality of micro-scale or nano-scale patterns, or combinations thereof, and a backing layer and the preparation thereof by using room temperature UV nano-embossing processes are disclosed. The substrates can be prepared by a roll-to-roll continuous process. The substrates can be used as flow cells, nanofluidic or microfluidic devices for biological molecules analysis.