The instant disclosure provides a thin film capacitor and a method of manufacturing the same. The method includes the following steps: placing a carrier substrate on a processing machine including at least one processing unit, and the at least one processing unit having a metal-layer forming module and an insulation-layer forming module that are arranged along a planar production line; forming a plurality of metal layers by the metal-layer forming module of the at least one processing unit, forming a plurality of insulation layers by the insulation-layer forming module of the at least one processing unit, and the metal layers and the insulation layers being alternately stacked on the carrier substrate to form a multilayer stacked structure; and then forming two terminal electrode structures to respectively enclose two opposite side end portions of the multilayer stacked structure.

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 a repeatable, straightforward manner. Better control over the notching process is also achieved by exhaust flow control of a double acting cylinder. A positioning spacer achieve very accurate side to side positioning of a die and anvil to precisely notch and deform the metal strip. 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.

Embodiments of the present invention relate to an apparatus and method for high speed automated installation or attachment of preformed handles onto portable containers such as buckets, boxes, cartons, or pails that are moving on a conveyor system through the apparatus. A frame structure supports the apparatus. A container conveyor conveys the portable containers into and out of the apparatus. A handle sheet conveyor conveys sheets of preformed handles from storage containers into a handle magazine. Individual handles are detached from the preformed handle sheets, after which the handles are attached onto the portable containers at a high rate of speed. A slidable handle separation and insertion mechanism includes a main slide for preforming the handles prior to insertion onto the portable containers. In some embodiments the main slide is angled at approximately a 45 degree angle from the horizontal.

A steering yoke cutting equipment with automatic transporting system which comprising a blanking press machine for cutting the yoke, a yoke input mechanism, intermediate transporting mechanism and a yoke output mechanism. The intermediate transporting mechanism which comprising a guide track, two sliding pieces slidably mounted the guide track, sliding piece cylinder, two sets of mechanical hands respectively fix mounted on the two sliding pieces; the yoke input mechanism and the yoke output mechanism are respectively arranged at two end of the intermediate transporting mechanism.

A machining system with a configuration in which working machines, including a machine tool, are configured to be disposed in a line, and in which multiple working machines perform operations on one work in order, is provided. The machining system includes: a base; and multiple working machine modules which are mounted on the base and are arranged in an arrangement direction, and has a configuration in which each of the multiple working machine modules is capable of being drawn out from the base along a track extending in an intersecting direction intersecting with the arrangement direction.

A steering yoke cutting equipment with automatic transporting system which comprising a blanking press machine for cutting the yoke, a yoke input mechanism, intermediate transporting mechanism and a yoke output mechanism. The intermediate transporting mechanism which comprising a guide track, two sliding pieces slidably mounted the guide track, sliding piece cylinder, two sets of mechanical hands respectively fix mounted on the two sliding pieces; the yoke input mechanism and the yoke output mechanism are respectively arranged at two end of the intermediate transporting mechanism.

A component mounting system and apparatus are provided that include a component mounting apparatus with a substrate holding device, a component supplying device, a head support portion, a mounting head and a forcing means. The mounting head is detachably attached to the head support portion. The mounting head of the system has a recording medium in which information relating to the mounting head is recorded. The system has an external storage portion that stores a plurality of batches of information relating to a plurality of mounting heads. The system further includes a recognizing portion that obtains and recognizes information from the external storage corresponding to the mounting head that is attached to the support portion.

The instant disclosure provides a thin film capacitor and a method of manufacturing the same. The method includes the following steps: placing a carrier substrate on a processing machine including at least one processing unit, and the at least one processing unit having a metal-layer forming module and an insulation-layer forming module that are arranged along a planar production line; forming a plurality of metal layers by the metal-layer forming module of the at least one processing unit, forming a plurality of insulation layers by the insulation-layer forming module of the at least one processing unit, and the metal layers and the insulation layers being alternately stacked on the carrier substrate to form a multilayer stacked structure; and then forming two terminal electrode structures to respectively enclose two opposite side end portions of the multilayer stacked structure.

Apparatus for machining hubs for vehicles, comprising a first machining group (11) having a first number (n1) of first stations, an inbound transfer station (11a), an outbound transfer station (11b), a loading station (117) and an unloading station (118); a second machining group (12) having a second number (n2) of second stations, an inbound transfer station (12a) and an outbound transfer station (12b); a first rotating table (13) having a number of first workpiece-holder sectors (131) equal to the first number (n1); where the first sectors (131) face the first stations; a second rotating table (14) having a number of second sectors (141) equal to said second number (n2); the second sectors (141) face the second stations; a first transfer group (15) for transferring workpieces between the first machining group (11) and the second machining group (12).

Embodiments of the present invention relate to an apparatus and method for high speed automated installation or attachment of preformed handles onto portable containers such as buckets, boxes, cartons, or pails that are moving on a conveyor system through the apparatus. A frame structure supports the apparatus. A container conveyor conveys the portable containers into and out of the apparatus. A handle sheet conveyor conveys sheets of preformed handles from storage containers into a handle magazine. Individual handles are detached from the preformed handle sheets, after which the handles are attached onto the portable containers at a high rate of speed. A slidable handle separation and insertion mechanism includes a main slide for preforming the handles prior to insertion onto the portable containers. In some embodiments the main slide is angled at approximately a 45 degree angle from the horizontal.