A window manufacturing system includes a first wire, a second wire spaced apart from the first wire, a controller moving the first wire up and down and the second wire up and down, and a load carrier connected to the first wire and the second wire. Window substrates are disposed on the load carrier. The controller moves the first wire and the second wire in opposite directions to each other.

Disclosed is a mold for processing glass. The mold includes a concave mold having a cavity and a convex mold mating with the concave mold. When the molds are clamped, the convex mold protrudes into the cavity. The mold further includes a base, wherein the base is detachably fixed on a side of the convex mold distal from the cavity, and a material of the base is different from that of the concave or the convex mold fixed thereto. The mold according to the present disclosure may improve manufacture efficiency of three-dimensional glass substrates and has a prolonged life time.

Embodiments of a vehicle interior system and methods for forming the same are disclosed. A glass substrate is bent to a curved shape within a mold cavity, and a liquid polymer material is delivered to the mold and is in contact with the curved glass substrate. The liquid polymer is solidified to form a polymer frame that engages the bent glass substrate, and the engagement between the frame and the glass substrate holds the glass substrate in the bent shape. The temperature of the glass substrate during the bending process and formation of the frame are maintained below the glass transition temperature of the glass substrate.

Precision glass molds are described, which are formed by coating a mold made from high purity, fme grain sized graphite, with a coating including titanium. In various implementations, the titanium coating is overcoated with yttria (Y.sub.2O.sub.3) to provide a high precision glass mold of superior performance character. The resultant glass molds can be used to form glass articles having a highly smooth finish, for high precision applications such as consumer electronic device applications, medical instruments, and optical devices. The use of high purity, fme grain size graphite allows molds to be machined at low cost, thereby eliminating the need to fabricate a metal mold that must be coated with multiple layers including metal diffusion barrier layers to meet operational requirements for such precision applications.

Precision glass molds are described, which are formed by coating a mold made from high purity, fme grain sized graphite, with a coating including titanium. In various implementations, the titanium coating is overcoated with yttria (Y.sub.2O.sub.3) to provide a high precision glass mold of superior performance character. The resultant glass molds can be used to form glass articles having a highly smooth finish, for high precision applications such as consumer electronic device applications, medical instruments, and optical devices. The use of high purity, fme grain size graphite allows molds to be machined at low cost, thereby eliminating the need to fabricate a metal mold that must be coated with multiple layers including metal diffusion barrier layers to meet operational requirements for such precision applications.

A method includes the steps of: providing a mold substrate and a cover substrate that are bonded to each other, wherein a surface region of the mold substrate and/or of the cover substrate is structured so as to form an enclosed cavity between the cover substrate and the mold substrate; tempering the cover substrate and the mold substrate so as to decrease the viscosity of the glass material of the cover substrate, and providing an overpressure in the enclosed cavity compared to the surrounding atmosphere so as to cause, on the basis of the decreased viscosity of the glass material of the cover substrate and the overpressure in the enclosed cavity compared to the surrounding atmosphere, bulging of the glass material of the cover substrate starting from the enclosed cavity up to a stop area, spaced apart from the cover substrate, of a stop element so as to acquire a molded cover substrate with a cap element; and removing the stop element and the mold substrate from the molded cover substrate.

An amorphous alloy contains Ni and Nb and has a composition including at least one of: a composition containing Nb with a content in the range of 35.6 atomic % to 75.1 atomic %, Ir with a content in the range of 7.2 atomic % to 52.3 atomic %, and Ni with a content in the range of 4.0 atomic % to 48.5 atomic %; a composition containing Nb with a content in the range of 19.6 atomic % to 80.9 atomic %, Re with a content in the range of 7.4 atomic % to 59.2 atomic %, and Ni with a content in the range of 4.1 atomic % to 56.9 atomic %; and a composition containing Nb with a content in the range of 7.5 atomic % to 52.9 atomic %, W with a content in the range of 16.4 atomic % to 47.0 atomic %, and Ni with a content in the range of 22.0 atomic % to 53.3 atomic %.

An amorphous alloy contains Ni and Nb and has a composition including at least one of: a composition containing Nb with a content in the range of 35.6 atomic % to 75.1 atomic %, Ir with a content in the range of 7.2 atomic % to 52.3 atomic %, and Ni with a content in the range of 4.0 atomic % to 48.5 atomic %; a composition containing Nb with a content in the range of 19.6 atomic % to 80.9 atomic %, Re with a content in the range of 7.4 atomic % to 59.2 atomic %, and Ni with a content in the range of 4.1 atomic % to 56.9 atomic %; and a composition containing Nb with a content in the range of 7.5 atomic % to 52.9 atomic %, W with a content in the range of 16.4 atomic % to 47.0 atomic %, and Ni with a content in the range of 22.0 atomic % to 53.3 atomic %.

There is described interleavant particles for location between adjacent stacked glass sheets, the interleavant particles comprising an inorganic core with an outer coating, the outer coating comprising a biodegradable and/or water soluble polymer or film forming material, wherein the inorganic core is solid up to at least 100 C. has a compressive strength of at least 3 MPa and has a volumetric mass density less than 7.5 g/cm.sup.3 at 25 C.

There is described interleavant particles for location between adjacent stacked glass sheets, the interleavant particles comprising an inorganic core with an outer coating, the outer coating comprising a biodegradable and/or water soluble polymer or film forming material, wherein the inorganic core is solid up to at least 100 C. has a compressive strength of at least 3 MPa and has a volumetric mass density less than 7.5 g/cm.sup.3 at 25 C.