An article conveying system includes a tray that is disposed on a floor surface and on which an article to be conveyed is mounted, a robot provided with a force sensor that detects an external force, a frictional force reduction device provided in at least one of the floor surface or the tray, to adjust a frictional force between the floor surface and the tray, and a controller that controls the robot to apply a lateral load to the tray and thereby slide the tray on the floor surface, and controls the frictional force reduction device based on a magnitude of the external force in a direction of the lateral load that is detected by the force sensor when the lateral load is applied.

An article conveying system includes a tray that is disposed on a floor surface and on which an article to be conveyed is mounted, a robot provided with a force sensor that detects an external force, a frictional force reduction device provided in at least one of the floor surface or the tray, to adjust a frictional force between the floor surface and the tray, and a controller that controls the robot to apply a lateral load to the tray and thereby slide the tray on the floor surface, and controls the frictional force reduction device based on a magnitude of the external force in a direction of the lateral load that is detected by the force sensor when the lateral load is applied.

Methods and systems for determination of warpage in a workpiece supported by a non-contact support platform, including a surface with a plurality of pressure ports and a plurality of fluid evacuation ports on the surface, a supply system with a pressure supply connected to the plurality of pressure ports on the surface and configured to supply pressure at a substantially constant level and cause a fluid to flow out of the plurality of pressure ports, so as to support a workpiece by fluid-bearing formed under the workpiece, and at least one flowmeter, coupled to a controller and configured to measure the flowrate at the surface, wherein the workpiece is determined to be warped when the measured flowrate is outside a predefined flowrate range.

Methods and systems for determination of warpage in a workpiece supported by a non-contact support platform, including a surface with a plurality of pressure ports and a plurality of fluid evacuation ports on the surface, a supply system with a pressure supply connected to the plurality of pressure ports on the surface and configured to supply pressure at a substantially constant level and cause a fluid to flow out of the plurality of pressure ports, so as to support a workpiece by fluid-bearing formed under the workpiece, and at least one flowmeter, coupled to a controller and configured to measure the flowrate at the surface, wherein the workpiece is determined to be warped when the measured flowrate is outside a predefined flowrate range.

A glassware manufacturing system, waste handling system, and method are disclosed. The glassware manufacturing system, in accordance with one aspect of the disclosure, comprises an architectural installation having a forming floor and no basement beneath the forming floor; a glassware forming machine carried on the forming floor; a molten glass feeder configured to provide molten glass to the glassware forming machine; and a glassware manufacturing waste handling system including a sump pit in the forming floor, and a waste liquid trench substantially surrounding the glassware forming machine and flowing to the sump pit. Also, a cullet material handler and/or a molten waste glass sluice may be configured to receive molten glass and unused molten glass streams from the molten glass feeder and hot glassware rejects from the glassware forming machine.

A glassware manufacturing system, waste handling system, and method are disclosed. The glassware manufacturing system, in accordance with one aspect of the disclosure, comprises an architectural installation having a forming floor and no basement beneath the forming floor; a glassware forming machine carried on the forming floor; a molten glass feeder configured to provide molten glass to the glassware forming machine; and a glassware manufacturing waste handling system including a sump pit in the forming floor, and a waste liquid trench substantially surrounding the glassware forming machine and flowing to the sump pit. Also, a cullet material handler and/or a molten waste glass sluice may be configured to receive molten glass and unused molten glass streams from the molten glass feeder and hot glassware rejects from the glassware forming machine.

A flotation conveyance apparatus according to an embodiment conveys a substrate while floating the substrate by ejecting a gas to a lower surface of the substrate. The flotation conveyance apparatus includes an upper plate disposed on the substrate side including a plurality of ejecting ports for ejecting the gas and a lower plate disposed under the upper plate. Flow-paths for supplying the gas to the plurality of ejecting ports are provided on at least one of the upper plate and the lower plate.

A method and system for an automatic parts conveying system includes a parts feeder configured to receive parts from a receiving bin, a linear conveyor for conveying parts away from the parts feeder to an installation robot. The installation robot includes a robot arm controlled by a controller and a parts handling device coupled to a distal end of the robot arm. The automatic parts conveying system also includes one or more vibrating elements positioned along at least one of the linear conveyor, the parts feeder, and the receiving bin to impart vibratory motions to the at least one of the linear conveyor, the parts feeder, and the receiving bin for stimulating the parts into motion. The automatic parts conveying system also includes an air assist portion configured to provide pressurized fluid to the parts to facilitate moving parts through the automatic parts conveying system.

A method and system for an automatic parts conveying system includes a parts feeder configured to receive parts from a receiving bin, a linear conveyor for conveying parts away from the parts feeder to an installation robot. The installation robot includes a robot arm controlled by a controller and a parts handling device coupled to a distal end of the robot arm. The automatic parts conveying system also includes one or more vibrating elements positioned along at least one of the linear conveyor, the parts feeder, and the receiving bin to impart vibratory motions to the at least one of the linear conveyor, the parts feeder, and the receiving bin for stimulating the parts into motion. The automatic parts conveying system also includes an air assist portion configured to provide pressurized fluid to the parts to facilitate moving parts through the automatic parts conveying system.

A non-contact support platform with open-loop control, including: a surface, to support a workpiece by fluid-bearing of fluid flowing through a plurality of nozzles, a supply system, connected to the surface and configured to maintain the fluid-bearing by applying pressure to cause flow of the fluid out of a subset of the plurality of nozzles, and a controller, to control fluid flow in the supply system with an open-loop circuit to support the workpiece while it moves over the non-contact support platform, wherein the fluid flow is controlled based on at least parameter of a group of workpiece parameters consisting of a position of the workpiece, dimenions of the workpiece and a velocity of the workpiece while supported by the surface.