A package for a medical device includes a blister having a base and a plurality of walls extending from the base with the base and the walls defining a cavity for receiving the medical device. The blister includes a first thermoplastic polyurethane or a combination of the first thermoplastic polyurethane and polyethylene terephthalate glycol. The package also includes a lid disposed on the blister and at least partially covering the cavity. The lid has outer and inner surfaces and includes a high density polyethylene. The package further includes an insert disposed on and in direct contact with the inner surface of the lid and facing the cavity. The insert includes a second thermoplastic polyurethane for increasing puncture resistance of the lid from the medical device.

A mirror (31) that reflects solar light, a rear plate (35) that supports a rear surface of the mirror (31), and a support frame (36) that is disposed on a rear surface of the rear plate (35) are prepared. Next, the rear plate (35) and the support frame (36) are joined to each other. Moreover, an adhesive agent is disposed between the mirror (31) and the rear plate (35), the mirror (31), the rear plate (35), and the support frame (36) are elastically deformed so that a reflecting surface of the mirror (31) forms a target three-dimensional curved surface, using a lower mold (51) and an upper mold (52), and the elastically deformed state is maintained until the adhesive agent is cured.

A wipe includes a generally flat piece of material (10) made of paper, cloth or the like. The generally flat piece of material (10) is formed into a non-planar form having a three-dimensional shape, for example conical, for storage and dispensing.

An object of the invention is to provide a method for manufacturing an optical display panel. The method includes a feeding step including feeding an optical cell with a thickness of 0.2 mm to 1.0 mm by means of a feed roller unit arranged perpendicular to a direction in which the optical cell is fed; a bonding step including feeding a long carrier film from a continuous roll and bonding a sheet piece of the optical film to a lower surface of the optical cell with the pressure-sensitive adhesive interposed therebetween, wherein the lower surface is on a side in contact with the feed roller unit; and a rotation step including rotating the optical cell by 90 with respect to the direction in which the optical cell is fed which is bonded in the bonding step.

A curved reflective mirror includes a flat glass structure, an intermediate adhesive layer, and a flat glass mirror. The intermediate adhesive layer is positioned between the flat glass structure and the flat glass mirror. The flat glass structure, the intermediate adhesive layer, and the flat glass mirror are curved and deformed in a mechanical manner with the support of a mold. The curved and deformed flat glass structure, intermediate adhesive layer, and flat glass mirror are solidified and bonded together in a heating and/or ultraviolet (UV) light radiation and/or room temperature solidification manner to form a composite curved structure. Also provided is a method for manufacturing a curved reflective mirror. The curved reflective mirror can be widely applied in the fields of solar thermal collection and concentration and solar thermal power generation.