A spherical core spraying tool comprises a spraying spindle and connecting rods; the spraying spindle is circumferentially provided with a plurality of protruding rings, and is axially provided with a strip-shaped groove; the connecting rods are disposed in the groove; one end of the spraying spindle is a power input end, and the other end is provided with a locking sleeve; the groove runs through the protruding rings. By spot-welding steel balls in an inner hole of a spherical core and fitting the spherical core over the spraying spindle, the steel balls are stuck in the groove of the spraying spindle, and the both sides of the steel balls are tightened by means of the connecting rods in abutting-against fashion, so that a plurality of spherical cores is fixed together with the spraying spindle, and the plurality of spherical cores can be spray-coated simultaneously, thereby improving the efficiency.

Systems and methods are provided for securement of parts. One embodiment is a method for securing a part during fabrication. The method includes forming an interference fit between a pin and a wall defining a hole, supporting a weight of the part with the interference fit, and rotating the part around an axis of the part while the weight of the part is supported.

A system includes an injector including a robotic arm and a heated chamber. The injector includes a material feed and a heating element. The robotic arm is arranged to deposit the material feed onto a vehicle component in the heated chamber.

A method for applying material to a bicycle frame includes determining, via a controller, at least one physical dimension of the bicycle frame. The method also includes determining, via the controller, a distance setting between at least two material applicators. In addition, the method includes determining, via the controller, a pattern size of material sprayed onto the bicycle frame by each of the at least two material applicators. Further, the method includes adjusting, via the controller, a position setting of the at least two material applicators based at least in part on the distance setting and pattern size. Moreover, the method includes applying, via the controller, material onto the bicycle frame through the at least two material applicators.

A robotic lifting and orienting system for an overspray-free paint system includes: a base coupled to wheels; and an automated carrier coupled to the base. The automated carrier includes: a fixture assembly configured to hold an object to be painted; one or more manipulators configured to move the fixture assembly relative to a paint robot; a propulsion system connected to the wheels and configured to move the robotic lifting and orienting system; and a control module configured to control the one or more manipulators and the propulsion system to control positioning and orienting of the object relative to at least one of the paint robot and an overspray-free paint applicator of the paint robot.

A system and method include a frame member and an applicator. The frame member includes a hollow frame and a distribution component arranged in the interior of the frame. The distribution component includes a base component and a conduit on its exterior surface. The applicator delivers a fluid, which can include an anti-corrosion material, to the distribution component, which fluid is then delivered by the conduit throughout the interior of the frame and ejected through discharge openings of the conduit onto the interior surface of the frame to coat the frame with the fluid. The fluid may form an anti-corrosion coating on the interior surface of the frame.

Methods of manufacturing pre-fabricated insulated wall structures are described in this specification. The methods include (a) attaching a foam panel to a front frame surface of a substantially horizontally positioned frame; (b) placing the frame having the foam panel attached thereto on a track conveyor configured to convey the frame having the foam panel attached thereto in a substantially upright position; (c) conveying the frame having the foam panel attached thereto on the track conveyer in a substantially upright position to a spray foam application station; and (d) spray applying a spray foam composition into a cavity of the frame to form a substantially upright positioned wall structure having a foam layer deposited in the cavity in which the foam layer adheres to the foam panel. Also disclosed are track conveyors suitable for use in such methods.

Provided are a system and process for remanufacturing a waste cylinder assembly of an aircraft piston engine. The spraying apparatus includes a first power mechanism, a spray gun assembly and a second power mechanism. The first power mechanism drives the cylinder assembly to move in a horizontal direction and a vertical direction. The second power mechanism drives the spray gun assembly to rotate around a center of the blind hole and ensures that prepared coatings can be evenly distributed along an inner wall of the blind hole. A nozzle end of the spray gun extends into the blind hole, and the spray gun is adjustable relative to the center of the blind hole. A spraying distance is not fixed so as to change the spraying distance. Powder can be fully melted.

A coating apparatus includes a jig supporting a guide vane equipped with a metal sheath covering a leading edge portion; a nozzle spraying paint onto a vane body; a robot moving the nozzle; and a control unit controlling a spraying operation of the nozzle and robot. The jig includes a movable covering body adapted separably covering the metal sheath and covering 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 moving 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.

An apparatus suitable for cleaning vehicles, comprising: a base structure (1) for positioning the vehicle, a containment structure (2) of the vehicle associated with the base structure, and comprising at least two side walls (22) opposite to the side surfaces of the vehicle once the vehicle has been arranged on the base structure, and at least one plurality of washing nozzles (31) arranged in the base structure (1) and opposite to the bottom of the vehicle once the vehicle has been placed on the base structure.