A conveying apparatus suitable for sturdy articles, in particular flattened plastic bottles or the like, in a recycling plant, has an upwardly moving continuous conveyor that includes a horizontal conveyor and a vertical conveyor connected to the horizontal conveyor, both conveyors having a tubular housing in which a respective conveying screw is rotatably mounted. The inner wall of the tubular housing of the vertical conveyor and the associated conveying screw have a vertical driver bar disposed therebetween, projecting radially inward from the tubular housing and spaced from the conveying screw by a distance (a). The driver bar has cutting teeth on its longitudinal edge located at least facing the conveying screw. Preferably, the driver bar is fastened in an interchangeable manner on the vertical tubular housing and has cutting teeth on both longitudinal edges.

A machine tool for machining a workpiece clamped in the working space of the machine tool by means of a tool. The machine tool includes a machine bed, which has a chip collection region having at least one conveying channel open on the working space side for collecting chips that drop during the machining of the workpiece, and a conveying device for leading away chips that have dropped into the chip collection region in the at least one conveying channel. The conveying device has a stationary supporting shaft, which extends in the at least one conveying channel in the longitudinal direction of the conveying channel, wherein a spiral element is rotatably supported on the stationary supporting shaft, and wherein the conveying device also comprises a drive for driving the rotational motion of the spiral element about the stationary supporting shaft.

Auger conveyors most commonly employed in industries where the horizontal and/or vertical transfer of solids or semi-solid materials is required. Auger conveyors employ a rotating helical screw blade, commonly known as flighting, which rotates about on an inline axis within an inline conduit. Described herein is an auger conveyor which does not need to follow the traditional rule of rotating about on an inline axis. A flexible wire rope shaft is employed to rotate about on an infinite number of axes thereby facilitating an auger conveyor connected to the flexible wire rope shaft through buttons, to traverse a non-linear path.

A cantilevered screw assembly comprising a speed reducer to facilitate rotation of a screw. The speed reducer may be connected to a torque arm that is adapted to control or limit undesired movement (e.g., wobbling, orbital movement, etc.) of the screw during operation. In effect, one exemplary embodiment of a speed reducer may essentially float on a pivoting torque arm (and the shaft of the screw) such that the torque arm is adapted to limit undesired movement of the speed reducer and screw. As a result, an exemplary embodiment may eliminate the need for alternative drive systems or other means to control undesired movement of the screw. An exemplary embodiment may be particularly useful for light or infrequent duty or other small-scale applications to reduce the likelihood of a breakage of a screw or another portion of a cantilevered screw assembly (e.g., the bearing(s) or bearing assembly, the gears, etc.).

An auger system has oscillating auger supports. The auger moves through a pile of stored material to move material from one location to another. The auger support may be a hanger that shuttles along the central axis of the auger as the auger rotates. A bearing shaft has cam followers that contact an angled surface on the bearing to slide the bearing back and forth along said central axis when said auger rotates. An alternate support may be a support wheel that rotates about an angled shaft that causes the contact surface of the support wheel to move back and forth with respect to the central axis as the auger rotates. The angled shaft may adjust the amount of oscillation. The oscillating motion of the auger support in combination with synchronized cutters on the auger allows material to be removed from the path of the advancing auger support.

In a processing apparatus, a processing furnace includes a supply port configured to receive a processing target and a discharge port configured to discharge a residue. A temperature control region controls a temperature of an intermediate part between the supply port and the discharge port. A screw rotates to be able to convey the processing target supplied from the supply port toward the discharge port. A first decomposition region includes a first recovery port configured to recover a first fluid obtained by decomposing the processing target in a predetermined region in the intermediate part from the processing furnace. A second decomposition region includes a second recovery port configured to recover, from the processing furnace, a second fluid obtained by decomposing the processing target on the downstream side of the first decomposition region.

A transfer device (1) for the separated transfer of product carriers (2a-2e) with holders (21, 21a-21e) to an overhead conveyor is described, comprising a helical conveyor (11), which defines a conveying section (F) for the holders (21, 21a-21e) with a conveying portion (FF) and a transfer portion (FU), wherein the conveying section (F) in the conveying portion (FF) describes a linear path and in the transfer portion (FU) describes a transversely curved path superimposed on the linear path.

A screw conveyor assembly includes a first screw conveyor with a first housing and a first conveyor screw arranged therein, a second screw conveyor with a second housing and a second conveyor screw arranged therein, a transition housing to which the first housing and the second housing are connected forming a transition angle, and a runner disposed in the transition housing and arranged to conduct material being conveyed from the first conveyor screw to the second conveyor screw. The first conveyor screw is arranged upstream of the second conveyor screw. An additional conveyor element is disposed on a helix of the first conveyor screw, such that the helix is directly adjacent to the transition housing.

A plug screw feeder (1) comprises a plug screw (10) with a thread (12) and a plug screw housing (20) surrounding the plug screw. The plug screw housing comprises an inlet opening (24) in a side of the plug screw and in a vicinity of a first axial end (18) of the plug screw. The plug screw is arranged for feeding lignocellulosic biomass material (99) from the inlet opening to a second axial end (19) of the plug screw when being rotated. The thread, in at least a part of an inlet section (15) of the plug screw, presents a jagged peripheral rim (14A) with an inwards directed leading edge. The inlet section is defined as the section of the plug screw passing the inlet opening during rotation. A feeding arrangement and system for treatment of lignocellulosic biomass material comprising such a plug screw feeder is also disclosed.

A transport member includes: a shaft portion having a linear portion that is linearly disposed along a linear section of a transport path, and a curved portion that is curvedly disposed along a curved section of the transport path; and screw blades that are spirally formed on an outer circumferential surface of the linear portion and the curved portion, and that transport a powder material by rotation of the shaft portion in one of axial directions of the shaft portion, the screw blades having a small-diameter portion which has an outer diameter smaller in the curved portion than in the linear portion.