A load assembly includes a supply mechanism structured to supply a plurality of container closures, and a conveyance assembly comprising a star wheel including a number of load pockets structured to receive the container closures and move the container closures from the supply mechanism to a processing assembly. The star wheel has an outer perimeter. Each of the load pockets is structured to receive a corresponding one of the container closures inboard of the outer perimeter of the star wheel.

Insulated packaging is provided including an inner substrate and an outer substrate attached to the inner substrate to form an air gap therebetween. An expandable material including expandable microspheres is provided with the expandable material disposed between the inner substrate and the outer substrate. An adhesive material different than the expandable material is disposed between the inner substrate and the outer substrate to attach the inner substrate to the outer substrate. A method for forming the insulated packaging is also provided.

A coating apparatus includes: a rotation holding unit configured to hold and rotate a substrate; a coating liquid supply unit configured to supply a coating liquid onto a surface of the substrate; and a control unit configured to control the rotation holding unit and the coating liquid supply unit. The control unit performs: controlling the coating liquid supply unit to supply the coating liquid onto an encircling line surrounding a rotational center of the substrate while controlling the rotation holding unit to rotate the substrate; followed by controlling the coating liquid supply unit to supply the coating liquid onto a central area; and followed by controlling the rotation holding unit to rotate the substrate at an angular velocity greater than that when the coating liquid is supplied onto the encircling line.

To prevent a height difference from being produced between a metal sheath and a paint layer formed on a vane surface of a vane body. A coating apparatus includes a jig adapted to support a guide vane equipped with a metal sheath for covering a leading edge portion; a nozzle adapted to spray paint onto a vane body; a robot adapted to move the nozzle; and a control unit adapted to control a spraying operation of the nozzle and robot. The jig includes a movable covering body adapted to separably cover the metal sheath and cover an exposed portion of adhesive between a lateral edge portion of the metal sheath and the vane surface of the vane body, and a covering body drive unit adapted to move the movable covering body between a state in which the movable covering body covers the metal sheath and a state in which the movable covering body is separated from the metal sheath while covering the metal sheath. The control unit performs control to make transition from a sheath cladding coating mode to a finish coating mode.

A can coating machine control system includes a coating control signal that functions as a go/no-go signal based on a plurality of monitored conditions such as can in position, vacuum pressure, gun in position, guard in position and speed condition. Local pressure regulation of the coating material in the spray gun is provided along with optional control of the material temperature. Local pressure regulation allows for optional spray weight control based on a wrap number derived from speed and gun spray durations. A CAN to CAN network buffer is provided as well for primary network isolation. A gun control circuit may be used to select specific gun drive signals and to adjust gun drive signals based on real-time feedback of the actual spray duration.

A station for treating objects may include: a booth including at least one entrance for an object and at least one exit for the object; a system configured to move the object between the at least one entrance and the at least one exit; at least one robot configured to treat the object in the booth; and/or a platform configured to support the object. The platform may be configured to rotate about a vertical axis so as to rotate the object inside the booth relative to the at least one robot. The at least one entrance may not be aligned with the at least one exit. The system may be configured to rotate with the platform so as to align with the at least one entrance in order to receive the object, and so as to align with the at least one exit in order to release the object.

A liquid feeding device that feeds a treatment liquid to a treating device and also recovers the treatment liquid for re-feeding, include feeding tanks having an exhaust passage and an overflow line, and can be switched to one of a feeding mode in which the treatment liquid is fed and a standby mode in which the feeding tank is on standby while accommodating the treatment liquid; a feeding mechanism that feeds the treatment liquid to the treating device from the feeding tank in the feeding mode among the plurality of feeding tanks; a recovery mechanism that recovers and returns the treatment liquid excessive in the treatment device to the feeding tank in the feeding mode; and an on-off mechanism provided in each of the plurality of feeding tanks to block the exhaust passage and the overflow line is provided.

A substrate processing apparatus includes: a circulation pipe which defines a circulation passage through which a chemical liquid within a chemical-liquid tank is circulated; a supply pipe which guides the chemical liquid from the circulation pipe to a chemical-liquid nozzle; a supply valve which is switched between an open state in which the chemical liquid flowing through the supply pipe toward the chemical-liquid nozzle is passed and a closed state in which the supply of the chemical liquid from the supply pipe to the chemical-liquid nozzle is stopped; a recovery pipe which guides the chemical liquid from a cup to the chemical-liquid tank; and a branch pipe which guides the chemical liquid within the circulation pipe to the recovery pipe.

The invention relates to a workpiece carrier device (1) comprising: a drive gear (3) for receiving workpiece arrangements (4), which is rotatable about a main axis (2), a number of drive bodies (6), which are arranged on the drive gear (3), are respectively rotatable about an axis of rotation (5) and each have a drive pinion (8) and a stationary internal input gear (9) with an inner toothing, which meshes with the drive pinions (8), wherein the axes of rotation (5) extend parallel to the main axis (2) and are arranged in an annular region of the drive gear (3) that runs concentrically in relation to the main axis (2), and so, when there is rotation of the drive gear (3) relative to the internal input gear (9), the drive bodies (6) rotate about their respective axes of rotation (5), wherein the internal input gear (9) and the drive bodies (6) with their drive pinions (8) are formed and arranged in relation to one another and a working clearance (S) is provided between the internal input gear (9) and the drive pinions (8) such that a driving effect is transferred to all of the drive pinions (8) equally during operation. The invention also relates to a coating arrangement 100 comprising such a workpiece carrier device (1).

A coating apparatus includes a process chamber, a rotation device, and a rotation holder. The rotation device is disposed in the process chamber. The rotation holder is connected to the rotation device. The rotation holder includes two extension elements, two retaining elements, and two pins. The two extension elements are disposed around a center axis and separated from each other, wherein each of the two extension elements has a side surface. Each of the two retaining elements has a bottom surface, one of the two retaining elements is connected to one of the side surfaces, and the other of the two retaining elements is connected to the other of the side surfaces. One of the two pins is connected to one of the bottom surfaces, and the other of the two pins is connected to the other of the bottom surfaces.