The present invention relates to a method of manufacturing a light transmitting yttria member by using hot-press sintering. The present invention provides a method of manufacturing light transmitting yttria by performing hot-press sintering on a molded body made of raw material powder including yttria by using a hot-press sintering apparatus, in which the hot-press sintering is performed in a state in which a spacer is interposed between the molded body and a pressing surface of the molded body, and the spacer is made of heat-resistant metal which is substantially unreactive to the molded body at a sintering temperature. According to the present invention, it is possible to manufacture highly compacted light transmitting yttria having light transmittance of 80% by using a single hot-press sintering process.

A rolling apparatus includes a roller assembly and a power source. The roller assembly includes four rollers, where the four rollers (110a) are arranged side by side in pairs along a first direction and a second direction intersected with each other, and two rollers arranged side by side define a roll gap therebetween. The power source drives two rollers arranged diagonally to rotate in a same direction around their axes. Two roll gaps defined by one of the two rollers arranged diagonally and the two rollers arranged side by side therewith are used for rolling a first electrode plate twice, and two roll gaps defined by the other one of the two rollers arranged diagonally and the two rollers arranged side by side therewith are used for rolling a second electrode plate twice. In the rolling apparatus, the four rollers form strip moving routes.

A sealing device for a secondary battery includes a first pressing member on which a first sealing member covering a first surface of a secondary battery is disposed, a second pressing member on which a second sealing member covering a second surface of the secondary battery is disposed, and a gap adjusting member disposed on one or more of the first pressing member and the second pressing member and configured to adjust a distance between the first pressing member and the second pressing member.

In a forming process with a press having in a frame a ram closing through the force of a cylinder with a moveable piston against a press table in a straight-line movement, the piston initially acts upon at least one knuckle joint system during the closing of the press, and a hydraulic cushion of the ram concludes the closing process with extension of the knuckle joint system in movement direction of the piston and straight-line support thereof against the frame. In a press having in a frame a ram closing through the force of a cylinder with a moveable piston against a press table in a straight-line movement, the ram is connected so as to be fixed with respect to the frame via at least two identically constructed knuckle joint systems, and the ram has a hydraulic cushion.

Devices and methods for compressing thermal insulation material into blocks of insulation are disclosed which include a support surface for the compressed blocks of insulation, a compression device with a compression surface, and a feeding device for feeding thermal insulation material. By adapting the compression device for reciprocal movement between a first position, wherein the feeding device is allowed to feed thermal insulation material to a position on the support surface, and a second position, wherein, during movement from the first position to the second position of the compression device, thermal insulation material fed by the feeding device is compressed, highly compressed blocks of thermal insulation material are obtained that are suitable for use with known shredding devices.

A food baking apparatus includes a compressible die and a mechanical stop for controlling a die spacing of the compressible die. The mechanical stop includes a supporting system and a mounting element mounted onto the supporting system. The mounting element includes at least one protrusion having a particular amount of protrusion from the mounting element, which amount of protrusion may be adjustable for any single protrusion. By translation or rotation of the supporting system and/or the mounting element during operation of the apparatus, a protrusion is selected. The protrusions mechanically stop further compression of the dies during an operation of the food baking apparatus. Thus, the selection determines the die spacing applicable for the baking process, based on the amount of protrusion of the selected protrusion.

The invention relates to a device (100) for compressing thermal insulation material into blocks of insulation comprising: a support surface (110) for the compressed blocks (200) of insulation, a compression device (120) with a compression surface (120a), and a feeding device (130) for feeding thermal insulation material. By adapting the compression device (120) for reciprocal movement between a first position, wherein the feeding device (130) is allowed to feed thermal insulation material to a position on the support surface (110), and a second position, wherein, during movement from the first position to the second position of the compression device, thermal insulation material (200) fed by the feeding device (130) is compressed, highly compressed blocks of thermal insulation material is obtained that are suitable for use with known shredding devices. A corresponding method is also provided.

Method and Apparatus for fabricating a spacer frame for use in an insulating glass unit. One of a multiple number of possible spacer frame materials is chosen for the spacer frame. An elongated strip of the material is moved to a notching station where notches are formed at corner locations. The character of the notches is adjusted based on the selection of the metal strip material and more particularly to achieve bending of the material in an repeatable, straightforward manner. Downstream from the notching station the metal strip is bent into a channel shaped elongated frame member having side walls. Further downstream a leading strip of channel shaped material is severed or separated from succeeding material still passing through the notching and bending station.

A press machine includes a press frame, a crankshaft having a first eccentric portion, at least one crankshaft motor connected to the crankshaft, a ram, an upper tool section supported by the ram and a lower tool section fixedly attached to the press frame, a linkage type ram drive mechanism connected to the crankshaft and including at least one pivot support pin, and a ram adjustment mechanism including a pivot support member supporting the at least one pivot support pin. Wherein the at least one secondary ram drive link is pivotally connected at a first end to the at least one pivot support pin and at a second end to a first end of the at least one main ram drive link. The at least one main ram drive link is pivotally connected at a second end to the ram. The at least one ram drive connecting link is rotatably supported by the at least one first eccentric portion of the crankshaft at a first end and pivotally connected at a second end to the at least one main ram drive link at a point between the first and second ends of the at least one main ram drive link.

A press machine includes a press frame having first and second portions, a crankshaft, a crankshaft, a ram, a ram drive mechanism supported by the first portion of the press frame at a primary force application location, a ram guide linearly guiding the ram, and supported by the second portion of the press frame at a ram guide location; and a working tool including an upper tool section and a lower tool section configured for the processing of a workpiece. The upper tool section is fixedly attached to the ram and the lower tool section is fixedly attached to the press frame at a lower tool location. The primary force application location has a first working position during the processing of the workpiece, and a second resting position when the workpiece is not being processed. The ram guide location has a first working position during the processing of the workpiece, and a second resting position when the workpiece is not being processed. The difference between the working position and the resting position of the ram guide location is less than the difference between the working position and the resting position of the primary force application location.