A surface treatment method for a casing is disclosed, the casing being formed by the outer surface and four sidewalls of the casing. The surface treatment method includes a heat transferring film formed on the casing by a vacuum heat transfer process or a paint-drying process and a surface pattern layer formed on a portion of a surface of the heat transferring film opposite to the outer surface by a digital inkjet printer applying three different types of UV-curable ink.

To provide a device for transferring a coated film in which a transfer unit can be protected well enough, a lid is not obstructive during the use of the device, and costs of production can be kept low. The device for transferring a coated film includes a hollow case having an opening formed therein. The case contains a sliding member 200 on which a first spool 300 for feeding a length of tape and a second spool 400 for taking up the tape are supported by their respective shafts, the sliding member 200 including a transfer unit 250 for transferring the tape. A control piece 220, which is a part of the sliding member 200, is exposed outside of the case through a guide slot formed in the case. The opening is opened and closed using a lid 500. When the control piece 220 is pushed ahead, the lid 500 is rotated and housed in the case. The transfer unit is moved to the outside of the case through the opening which is not covered with anything.

Methods, structures, devices and systems are disclosed for fabricating and implementing electrochemical biosensors and chemical sensors. In one aspect, a method of producing an epidermal biosensor includes forming an electrode pattern onto a coated surface of a paper-based substrate to form an electrochemical sensor, the electrode pattern including an electrically conductive material and an electrically insulative material configured in a particular design layout, and attaching an adhesive sheet on a surface of the electrochemical sensor having the electrode pattern, the adhesive sheet capable of adhering to skin or a wearable item, in which the electrochemical sensor, when attached to the skin or the wearable item, is operable to detect chemical analytes within an external environment.

The present invention provides a method for producing synthetic leather using a silicone rubber coating liquid; and synthetic leather produced by the method.

A method and apparatus for protecting a structure. A surface of the structure may be identified from a model of the structure. A perimeter of the surface of the structure may be identified from the model. The perimeter may be identified for the surface of the structure to be covered by a masking system during painting of the structure. A two-dimensional representation of the masking system may be generated for the structure based on the perimeter of the surface of the structure. Features for the masking system may be generated within the two-dimensional representation. Identifiers may be assigned to the features in the two-dimensional representation. Instructions for a forming tool may be generated based on the identifiers. The masking system may be formed from a sheet of masking material using the forming tool based on the instructions.

A method and apparatus for protecting a structure. A surface of the structure may be identified from a model of the structure. A perimeter of the surface of the structure may be identified from the model. The perimeter may be identified for the surface of the structure to be covered by a masking system during painting of the structure. A two-dimensional representation of the masking system may be generated for the structure based on the perimeter of the surface of the structure. Features for the masking system may be generated within the two-dimensional representation. Identifiers may be assigned to the features in the two-dimensional representation. Instructions for a forming tool may be generated based on the identifiers. The masking system may be formed from a sheet of masking material using the forming tool based on the instructions.

A system for protecting a surface of a substrate includes a protective film, which is configured to be applied and secured to the surface, as well as a backing on an adherent surface of the protective film and an application tape over an exterior surface of the protective film. Protruding features, such as tabs, adjacent to different peripheral edges of the protective film may enable removal of the backing and the application tape from the protective film, and may include features that indicate the order in which each protruding feature is to be grasped to peel its corresponding element away from the protective film.

A method for manufacturing a flexible display device by forming a flexible base substrate on a carrier substrate, the flexible base substrate having a display region and a non-display region, forming a display unit comprising a plurality of pixels at the display region, separating the flexible base substrate from the carrier substrate, forming an adhesive layer under the flexible base substrate, forming a flexible carrier film under the adhesive layer, forming a pressed region of the adhesive layer by partially pressing the adhesive layer, and mounting a driving circuit at a portion of the non-display region overlapping the pressed region.

An object of the present invention is to provide a laminated member for decoration that can be molded into a complicated shape and has a superior hardcoating property. The present invention relates to a laminated member for decoration having a protective film, a coating layer and a resin substrate, wherein the surface roughness Rz(a) of the adhesive layer of the protective film on the side where the coating layer is located and the surface roughness Rz(b) of the coating layer of an unheated sample formed by peeling the protective layer, the surface roughness being taken on the side opposite from the resin substrate, define Rz(b)/Rz(a)×100 having a prescribed relationship; the surface roughness Rz(b) and the surface roughness Rz(bh) of the coating layer of a heated sample prepared by heating the unheated sample under a prescribed condition, the surface roughness being taken on the side opposite from the resin substrate, satisfy at least one of Formulas (2) and (3) below:

0%≤Rz(bh)/Rz(b)×100<30%  (2), and

0≤Rz(bh)≤Rz(b)<0.5 μm  (3);

and the unreacted (meth)acryloyl groups of the coating layer of the heated sample irradiated with a prescribed amount of active energy rays have disappeared 10 to 100% as compared with the coating layer of the unheated sample.

An object of the present invention is to provide a laminated member for decoration that can be molded into a complicated shape and has a superior hardcoating property. The present invention relates to a laminated member for decoration having a protective film, a coating layer and a resin substrate, wherein the surface roughness Rz(a) of the adhesive layer of the protective film on the side where the coating layer is located and the surface roughness Rz(b) of the coating layer of an unheated sample formed by peeling the protective layer, the surface roughness being taken on the side opposite from the resin substrate, define Rz(b)/Rz(a)×100 having a prescribed relationship; the surface roughness Rz(b) and the surface roughness Rz(bh) of the coating layer of a heated sample prepared by heating the unheated sample under a prescribed condition, the surface roughness being taken on the side opposite from the resin substrate, satisfy at least one of Formulas (2) and (3) below:

0%≤Rz(bh)/Rz(b)×100<30%  (2), and

0≤Rz(bh)≤Rz(b)<0.5 μm  (3);

and the unreacted (meth)acryloyl groups of the coating layer of the heated sample irradiated with a prescribed amount of active energy rays have disappeared 10 to 100% as compared with the coating layer of the unheated sample.