A system and method for assembling a plurality of components into an assembly is provided. The system includes an assembling robot and an adhesive dispensing robot. The assembling robot is configured to attach a first sub-assembly to a second sub-assembly. The first sub-assembly includes at least one of the plurality of components, and the second sub-assembly includes remaining ones of the plurality of components. The adhesive dispensing robot is configured to apply an adhesive between the first sub-assembly and the second sub-assembly, after the first sub-assembly is attached to the second sub-assembly, to bond the first sub-assembly to the second sub-assembly.

A system for assembling a plurality of components into an assembly is provided. The system includes an installation table, a first transfer robot, a second transfer robot, and an adhesive dispensing robot. The first transfer robot is configured to assemble some of the plurality of components into a first sub-assembly and transfer the first sub-assembly to the installation table. The second transfer robot is configured to assemble remaining ones of the plurality of components into a second sub-assembly, transfer the second sub-assembly to the installation table, and attach the second sub-assembly to the first sub-assembly. The adhesive dispensing robot is configured to apply an adhesive between the first sub-assembly and the second sub-assembly, after the second sub-assembly is attached to the first sub-assembly, to bond the second sub-assembly to the first sub-assembly.

Methods for welding motor vehicle body component subassemblies at a weld stations are disclosed. First and second pallets may be arranged for reciprocal movement between a load/unload station and the weld station and the pallets are alternately moved from a load/unload station to the weld station while the other pallet is moved from the weld station to a load/unload station. Each pallet may have a plurality of substations for receipt of component subassemblies and, while each pallet is at the load/unload station, the component subassembly at each substation is moved to the next successive substation and a further component is added to the moved component.

Embodiments of universal adapter system including a belt adapter for a belt, such as a tactical belt, configured to couple one or more pack adapters secured to a respective load bearing pack, such as a backpack. Other embodiments of the universal adapter systems may be described and claimed.

Provided is a method for manufacturing a gas sensor capable of securing airtightness without a chip in a sensor element. The method includes a step of obtaining an assembled body constituting the gas sensor, including steps of causing one end of the sensor element to abut to a positioning member for positioning the sensor element; applying a force F1 to the annularly-mounted members including a powder compact annularly mounted to the sensor element under a state that the sensor element is positioned and thereby compressing the powder compact so as to fix the sensor element inside of the tubular body, applying a force F2 larger than the force F1 to the annularly-mounted members under a state that the sensor element is not positioned and thereby further compressing the powder compact, so as to hermetically seal inside of the tubular body.

Provided is a method for manufacturing a gas sensor which suppresses a defective product caused by a defective posture of a sensor element therein. The method includes a step of obtaining an assembled body constituting the gas sensor, including steps of: causing one end of the sensor element to come to abut to a positioning member for positioning the sensor element; and applying a first force to the annularly-mounted members including a powder compact annularly mounted to the sensor element under a state that the sensor element is positioned and thereby compressing the powder compact so as to fix the sensor element inside of the tubular body, and the compression is performed while constraining the sensor element in a predetermined constraining region in the other end side of the sensor element.

A reconfigurable autonomous workstation includes a multi-faced superstructure including a horizontally-arranged frame section supported on a plurality of posts. The posts form a plurality of vertical faces arranged between adjacent pairs of the posts, the faces including first and second faces and a power distribution and position reference face. A controllable robotic arm suspends from the rectangular frame section, and a work table fixedly couples to the power distribution and position reference face. A plurality of conveyor tables are fixedly coupled to the work table including a first conveyor table through the first face and a second conveyor table through the second face. A vision system monitors the work table and each of the conveyor tables. A programmable controller monitors signal inputs from the vision system to identify and determine orientation of the component on the first conveyor table and control the robotic arm to execute an assembly task.

An automatic manufacturing station (3) and a manufacturing process for workpieces (2), in particular for vehicle body parts, has a manufacturing area (4) with a plurality of program-controlled manufacturing robots (9). The workpieces (2) are externally fed to the manufacturing station (3) on production load carriers (8). The manufacturing station (3) also has a plurality of work stations (10, 11, 12, 13). A station-bound transport device (15) transports the production load carriers (8) within the manufacturing station (3).

An automated assembly apparatus, system and method of use thereof, characterized by comprising an assembly robot having a plurality of hands, the plurality of hands being movable in an X-axis direction and a Y-axis direction by an X-axis moving unit and a Y-axis moving unit, and a plurality of workbenches which are provided with Z-axis moving unit and which are movable in a Z-axis direction by the Z-axis moving unit. A work area is independently provided for the plurality of workbenches, a width of a predetermined work area among the work areas is larger than clearance widths of the plurality of hands, widths of the work areas other than the predetermined work area are smaller than the clearance widths of at least some of the plurality of hands, and the hand which performs a job on the predetermined work area is disposed at a lowermost level in the Z-axis direction.

A system for producing multiple-pane insulating glazing units can include a conveyor and a plurality of laterally spaced-apart processing stations that are movable transversely relative to the longitudinally extending conveyor line. Each processing station may assemble glazing panes and a glazing spacer into a partially fabricated glazing unit, deliver insulative gas to a between-pane space between the glazing panes, and press the partially fabricated glazing unit together to seal the insulative gas in the between-pane space and form the multiple-pane insulating glazing unit. In some examples, each processing station moves to an alignment position with the conveyor to load glazing panes and a glazing spacer and then performs individual fabrication steps while offset from the conveyor. During this time, a different processing station can be aligned with the conveyor to unload a fabricated multiple-pane insulating glazing units and/or load unassembled glazing panes and a glazing spacer.