A template made of plywood or similar material is inserted into a cover for a protective helmet so that the cover is stretched and once the template is inserted the assembled combination of the cover and the template resembles the shape of a disk. The disk-shaped assembly is placed on top of the bottom plate of a heat press. A layer with a decal or sticker is placed on top of the disk-shaped assembly. A heat press cover sheet is then placed on top of the disk-shaped assembly so that it also becomes into contact with the top plate of the heat press when the heat press is closed. The heat press may be set to a temperature of 350 degrees Fahrenheit and it can be set in a closed position for about 30 seconds in order to transfer sufficient heat so that the decal or sticker is applied or affixed to the cover surface.

Cards made in accordance with the invention include a specially treated thin decorative layer attached to a thick core layer of metal or ceramic material, where the thin decorative layer is designed to provide selected color(s) and/or selected texture(s) to a surface of the metal cards. Decorative layers for use in practicing the invention include: (a) an anodized metal layer; or (b) a layer of material derived from plant or animal matter (e.g., wood, leather); or (c) an assortment of aggregate binder material (e.g., cement, mortar, epoxies) mixed with laser reactive materials (e.g., finely divided carbon); or (d) a ceramic layer; and (e) a layer of crystal fabric material. The cards may be dual interface smart cards which can be read in a contactless manner and/or via contacts.

A method of manufacturing a footwear includes the steps of providing a leather base layer and providing a leather attachment layer. The leather base layer and the leather attachment layer are fixed against each other with an intermediate application of adhesive between them. The applied adhesive is activated. The leather base layer and the leather attachment layer are forced against each other under a pressure with the adhesive between them. The adhesive is cured and thereby the leather base layer and the leather attachment layer are bonded to each other. The bonded leather base layer and the leather attachment layer are integrated as part of the footwear.

A leather-based cover material for an inflatable sports ball that consists of a composite of a thin external layer, a filler, and an internal liner. The thin external layer is dimpled by using positive/negative embossing plates to create pebble projections on an exterior side and voids on the other or interior side. The interior side is coated with a filler material that fills the voids. The cover material is completed by attaching a liner layer to the cured filler material.

The described embodiments relate to a method for embedding one or more electrical components in a flexible substrate. The method includes receiving a substrate of a flexible material, wherein the substrate includes a cosmetic surface and an opposing surface. The method further includes applying a carrier form to the substrate to create a carrier assembly, wherein the carrier form includes one or more positive images representative a design to be transferred to the opposing surface of the substrate. The method further includes removing or cutting a portion of material from the opposing surface of the substrate to form a new opposing surface. Subsequently, the carrier form is removed from the substrate to reveal one or more embedding cavities extending into the substrate at the new opposing surface. In some embodiments, the embedding cavities can thereafter receive one or more electrical components.

Cards made in accordance with the invention include a specially treated thin decorative layer attached to a thick core layer of metal or ceramic material, where the thin decorative layer is designed to provide selected color(s) and/or selected texture(s) to a surface of the metal cards. Decorative layers for use in practicing the invention include: (a) an anodized metal layer; or (b) a layer of material derived from plant or animal matter (e.g., wood, leather); or (c) an assortment of aggregate binder material (e.g., cement, mortar, epoxies) mixed with laser reactive materials (e.g., finely divided carbon); or (d) a ceramic layer; and (e) a layer of crystal fabric material. The cards may be dual interface smart cards which can be read in a contactless manner and/or via contacts.

The present invention discloses a kind of production process for a fully covered leather sheath product, which comprises the following steps of: determining peripheral dimensions of leather such as the length and width according to the size of the product, and coating the leather with an adhesive; putting the shell of a product to be covered into the upper die of a mold, placing the trimmed leather into the lower die of the mold, and positioning it by a positioning post; heating the above-mentioned leather placed in the lower die of the mold; closing the upper die and the lower die immediately after the heating treatment is complete; opening the mold until the lamination is complete, taking out the product from the mold and fitting it with a fixture for the stretching folding treatment; heating the product along with the fixture to bond the leather with the interior of the product shell; and pressing it along with the fixture after heating; taking the pressed product out of the fixture and cutting excessive leather, attaching an inner lining material of the same dimensions after the excessive leather is cut, and pressing the inner lining material for bonding. The objective of the present invention is to provide a production process for the fully covered leather sheath product, which has high production efficiency and can improve the overall product design effect.

A laminar composite comprising a transparent or translucent cover layer, a base layer, and a layer of reptile shed sandwiched between the base layer and the cover layer. The base layer, cover layer and/or reptile shed are provided on one side with an adhesive, such as a heat-activatable adhesive, to bond the three layers together to form a flexible laminar composite.

Cards made in accordance with the invention include a specially treated thin decorative layer attached to a thick core layer of metal or ceramic material, where the thin decorative layer is designed to provide selected color(s) and/or selected texture(s) to a surface of the metal cards. Decorative layers for use in practicing the invention include: (a) an anodized metal layer; or (b) a layer of material derived from plant or animal matter (e.g., wood, leather); or (c) an assortment of aggregate binder material (e.g., cement, mortar, epoxies) mixed with laser reactive materials (e.g., finely divided carbon); or (d) a ceramic layer; and (e) a layer of crystal fabric material. The cards may be dual interface smart cards which can be read in a contactless manner and/or via contacts.

In the embodiments, sustainable wearable items are provided. In some embodiments, the sustainable wearable item can include an upper comprising an upper layer including an upper material selected from the group consisting of upcycled apple skin, sustainable satin, a combination of upcycled apple skin and tea bag recycled yarn, recycled polyamide yarn, and a combination of upcycled apple skin and recycled polyamide yarn, a lining including a material selected from the group consisting of upcycled apple skin and upcycled grape skin, and a first adhesive to bind the upper layer and the lining. In some embodiments, the sustainable wearable item can include a bottom comprising an insole including a material selected from the group consisting of upcycled apple skin and upcycled grape skin, an outsole including vegetable tanned leather, and a second adhesive to bind the insole and the outsole.