The invention relates to a method and guide system for the transport of containers or container components, in particular, preforms and/or closure caps, in industrial systems for container production and/or product filling, wherein the containers/container components are transported along at least one guide element. By generating an air cushion between the guide element and the containers/container components by flowing through a microporous layer formed on the guide element, even container components which are lightweight and/or do not slide well can be reliably slidingly transported along the guide elements, and containers can be reliably supplied to dividing worms or similar using dynamic pressure.

A conveying apparatus can comprise one or more support members defining an interior passage and a first plurality of apertures. A first cross-sectional area of the interior passage at a first end portion of a support area can be greater than a second cross-sectional area of the interior passage at a second end portion of the support area. A tube can extend within the interior passage and comprises a second plurality of apertures. Methods are also provided for conveying a ribbon with one or more support members.

A conveying apparatus can comprise one or more support members defining an interior passage and a first plurality of apertures. A first cross-sectional area of the interior passage at a first end portion of a support area can be greater than a second cross-sectional area of the interior passage at a second end portion of the support area. A tube can extend within the interior passage and comprises a second plurality of apertures. Methods are also provided for conveying a ribbon with one or more support members.

A flotation conveyance apparatus according to an embodiment includes a flotation unit for floating a substrate by ejecting a gas to a lower surface of the substrate. The flotation unit includes a plurality of ejecting ports provided on a surface facing the substrate and configured to eject the gas, and slits penetrating the flotation unit in a vertical direction. The flotation conveyance apparatus is configured in such a way that the gas staying between a surface of the flotation unit facing the substrate and the substrate is discharged to a lower surface side of the flotation unit through the slits.

A flotation conveyance apparatus according to an embodiment includes a flotation unit for floating a substrate by ejecting a gas to a lower surface of the substrate. The flotation unit includes a plurality of ejecting ports provided on a surface facing the substrate and configured to eject the gas, and slits penetrating the flotation unit in a vertical direction. The flotation conveyance apparatus is configured in such a way that the gas staying between a surface of the flotation unit facing the substrate and the substrate is discharged to a lower surface side of the flotation unit through the slits.

A noncontact support platform includes a plurality of pressure nozzles on an outer surface of a PV stage of the noncontact support platform. The pressure nozzles connected to a pressure source for creating an outflow of fluid through the pressure nozzles. A plurality of vacuum nozzles are interspersed with the pressure nozzles on the outer surface and are connected to a vacuum manifold via one or a plurality of hoses to create an inflow of the fluid through the vacuum nozzles. At least one flowmeter is configured to generate a signal that is indicative of a measured inflow via at least one hose of the hoses. A controller is configured to analyze the signal to determine whether the measured inflow is indicative of blockage of a vacuum nozzle and to generate a response when blockage is indicated.

A noncontact support platform includes a plurality of pressure nozzles on an outer surface of a PV stage of the noncontact support platform. The pressure nozzles connected to a pressure source for creating an outflow of fluid through the pressure nozzles. A plurality of vacuum nozzles are interspersed with the pressure nozzles on the outer surface and are connected to a vacuum manifold via one or a plurality of hoses to create an inflow of the fluid through the vacuum nozzles. At least one flowmeter is configured to generate a signal that is indicative of a measured inflow via at least one hose of the hoses. A controller is configured to analyze the signal to determine whether the measured inflow is indicative of blockage of a vacuum nozzle and to generate a response when blockage is indicated.

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.

Embodiments herein describe a pneumatic mandrel for a packaging system. In one embodiment, the mandrel includes a pneumatic nozzle proximate to a loading volume in which items are disposed before being packaged. The pneumatic nozzle can contain multiple ports for directing airflow in different directions. The directions at which the ports generate the airflow may be selected to move items that may be stuck or snagged into the loading volume. Stated differently, the mandrel may generate airflows in multiple directions for pushing items towards the loading volume.