The present disclosure relates to a method of providing a laminated vacuum insulated glass (VIG) unit (1), wherein the method comprises: providing a lamination assembly (10) comprising a vacuum insulated glass (VIG) unit (11) comprising at least two glass sheets (11a, 11b) separated by a plurality of support structures (12) distributed in a gap (13) between the glass sheets (11a, 11b), and a lamination layer (2) arranged between one of the glass sheets (11a, 11b) of the vacuum insulated glass (VIG) unit (11) and a further sheet (3). The further sheet (3) may be subjected to a first heating temperature (T1) by means of a first heating arrangement (9a), and the glass sheet (11a) of the vacuum insulated glass (VIG) unit (11) facing away from the further sheet (3) may be subjected to a second heating temperature (T2) by means of a second heating arrangement (9b), wherein the first heating temperature (T1) is higher than the second heating temperature (T2). The disclosure additionally relates to a system (100) for providing laminated vacuum insulated glass (VIG) units (1), and use of such a system.

Embodiments disclosed herein include multilayer films having at least an outer layer that includes 1) polyethylene elastomer and 2) ULDPE or VLDPE and that has a purge fraction greater than 20 percent as determined by Crystallization Elution Fractionation (CEF) test method. Embodiments disclosed herein also include related compositions to make such films and methods of making such films. The ULDPE or VLDPE can be made via Ziegler-Natta catalyst reaction techniques to provide the desired purge fraction.

Embodiments disclosed herein include multilayer films having at least an outer layer that includes 1) polyethylene elastomer and 2) ULDPE or VLDPE and that has a purge fraction greater than 20 percent as determined by Crystallization Elution Fractionation (CEF) test method. Embodiments disclosed herein also include related compositions to make such films and methods of making such films. The ULDPE or VLDPE can be made via Ziegler-Natta catalyst reaction techniques to provide the desired purge fraction.

Disclosed are a vacuum press method and apparatus. The vacuum press apparatus includes an upper pressing part provided with an upper diaphragm, a lower pressing part provided with a lower diaphragm, an airtightness-maintaining member mounted between the upper pressing part and the lower pressing part, a processing space formed by the upper and lower pressing parts, the airtightness-maintaining member, and the upper and lower diaphragms, a vacuum-pressing operation part communicating with the processing space, a heating part mounted in the upper pressing part, an ascending/descending heating operation space formed between the upper diaphragm and the heating part, an upper ascending/descending operation part communicating with the ascending/descending heating operation space, a cooling part mounted in the lower pressing part, an ascending/descending cooling operation space formed between the lower diaphragm and the cooling part, and a lower ascending/descending operation part communicating with the ascending/descending cooling operation space.

Disclosed are a vacuum press method and apparatus. The vacuum press apparatus includes an upper pressing part provided with an upper diaphragm, a lower pressing part provided with a lower diaphragm, an airtightness-maintaining member mounted between the upper pressing part and the lower pressing part, a processing space formed by the upper and lower pressing parts, the airtightness-maintaining member, and the upper and lower diaphragms, a vacuum-pressing operation part communicating with the processing space, a heating part mounted in the upper pressing part, an ascending/descending heating operation space formed between the upper diaphragm and the heating part, an upper ascending/descending operation part communicating with the ascending/descending heating operation space, a cooling part mounted in the lower pressing part, an ascending/descending cooling operation space formed between the lower diaphragm and the cooling part, and a lower ascending/descending operation part communicating with the ascending/descending cooling operation space.

An adhesive assembly can be used to join textile materials together creating a durable wash resistant. An emblem can be removed from a work shirt without leaving glue stains or residue. The shirt may be reused if emblems need to be removed or changed before the life of the garment expires. In various embodiments, a layer of mesh is incorporated into the heat activated glue on the back of the emblem. This mesh does not affect adherence to the garment. The emblem sticks just as well as without the mesh layer and with zero process changes to how the emblem is applied. The mesh allows for the complete removal of the adhesive from the garment when the patch is removed allowing the garment to be used even after the patch is removed.

An adhesive assembly can be used to join textile materials together creating a durable wash resistant. An emblem can be removed from a work shirt without leaving glue stains or residue. The shirt may be reused if emblems need to be removed or changed before the life of the garment expires. In various embodiments, a layer of mesh is incorporated into the heat activated glue on the back of the emblem. This mesh does not affect adherence to the garment. The emblem sticks just as well as without the mesh layer and with zero process changes to how the emblem is applied. The mesh allows for the complete removal of the adhesive from the garment when the patch is removed allowing the garment to be used even after the patch is removed.

The invention relates to a material comprising at least one laminate component containing polymeric fibers wherein the material has a loss tangent of less than 8×10.sup.−3 radians as measured at a frequency chosen from the group of frequencies consisting of 1.8 GHz; 3.9 GHz; 10 GHz; 39.5 GHz; and 72 GHz.

A thermoplastic bonded preform and method of manufacturing the preform are disclosed. The preform comprises a primary fiber comprising little or no sizing; a mechanical fiber; and a thermoplastic.

A process for in-line extrusion of polymeric coatings onto roofing shingles during manufacturing includes moving a web of shingle substrate material in a downstream direction and extruding a liquefied coating of polymeric material onto at least one surface of the moving web to form a thin film. The liquefied coating may be a molten polymeric material that forms a thin film on a back surface of the shingle material to prevent sticking and eliminate the need for a traditional back dusting with material such as powdered stone. The polymeric film further may be applied to the substrate material in lieu of a saturation coating of asphalt, thus reducing cost and weight while providing a comparable moisture barrier and a lighter more flexible shingle.