A veneer peeling apparatus includes a bearing frame (10) for rotatably supporting a round wood (20), a peeling blade (24) which can be placed against the periphery of the round wood, and at least one milling head (40) for scarfing at least one edge of the veneer, wherein the milling head (40) includes a groove milling cutter (44) for trimming the veneer.

The veneer lathe comprises rotatable spindles for engaging the ends of a block, a centering device for measuring dimensions of the block for determining optimal centering of the block, the centering device comprising centering spindles for engaging each end of the block, transfer arms moveable in the axial direction of the spindles for engaging the ends of the block and in a direction that is perpendicular to the axial direction for transferring the block from the centering device to a peeling position, a knife assembly comprising a knife and a nose bar, which is in the form of a rotatable roll, and a support device comprising a lower roll and an upper roll at a distance from the lower roll for supporting the block during peeling.

The veneer lathe comprises rotatable spindles for engaging the ends of a block, a centering device for measuring dimensions of the block for determining optimal centering of the block, the centering device comprising centering spindles for engaging each end of the block, transfer arms moveable in the axial direction of the spindles for engaging the ends of the block and in a direction that is perpendicular to the axial direction for transferring the block from the centering device to a peeling position, a knife assembly comprising a knife and a nose bar, which is in the form of a rotatable roll, and a support device comprising a lower roll and an upper roll at a distance from the lower roll for supporting the block during peeling.

Embodiments of an electric linear actuator may include a roller screw assembly, an electric motor coupled to the roller screw assembly, and a linear transducer operatively coupled with the roller screw assembly. The motor may be configured to drive the roller screw assembly to extend and retract another component, such as a rod. In some embodiments, the linear transducer may be configured to detect a position of the rod. The roller screw assembly may be coupled directly to the motor via a gear coupling, with the motor disposed generally in axial alignment with the roller screw assembly. Other embodiments disclosed herein include a veneer lathe carriage with electric linear actuators and corresponding apparatuses, methods, and systems.

Embodiments of an electric linear actuator may include a roller screw assembly, an electric motor coupled to the roller screw assembly, and a linear transducer operatively coupled with the roller screw assembly. The motor may be configured to drive the roller screw assembly to extend and retract another component, such as a rod. In some embodiments, the linear transducer may be configured to detect a position of the rod. The roller screw assembly may be coupled directly to the motor via a gear coupling, with the motor disposed generally in axial alignment with the roller screw assembly. Other embodiments disclosed herein include a veneer lathe carriage with electric linear actuators and corresponding apparatuses, methods, and systems.

The invention relates to a method for manufacturing a sheet from the pseudostem of the banana plant, including the steps of: cutting out a beam from a central portion of the pseudostem; cutting leaves from the beam; forming a sheet by assembling the leaves such that the latter overlap over a predetermined width; and pressing the resulting sheet.

The invention relates to a method for manufacturing a sheet from the pseudostem of the banana plant, including the steps of: cutting out a beam from a central portion of the pseudostem; cutting leaves from the beam; forming a sheet by assembling the leaves such that the latter overlap over a predetermined width; and pressing the resulting sheet.

Embodiments of an electric linear actuator may include a roller screw assembly, an electric motor coupled to the roller screw assembly, and a linear transducer operatively coupled with the roller screw assembly. The motor may be configured to drive the roller screw assembly to extend and retract another component, such as a rod. In some embodiments, the linear transducer may be configured to detect a position of the rod. The roller screw assembly may be coupled directly to the motor via a gear coupling, with the motor disposed generally in axial alignment with the roller screw assembly. Other embodiments disclosed herein include a veneer lathe carriage with electric linear actuators and corresponding apparatuses, methods, and systems.

Embodiments of an electric linear actuator may include a roller screw assembly, an electric motor coupled to the roller screw assembly, and a linear transducer operatively coupled with the roller screw assembly. The motor may be configured to drive the roller screw assembly to extend and retract another component, such as a rod. In some embodiments, the linear transducer may be configured to detect a position of the rod. The roller screw assembly may be coupled directly to the motor via a gear coupling, with the motor disposed generally in axial alignment with the roller screw assembly. Other embodiments disclosed herein include a veneer lathe carriage with electric linear actuators and corresponding apparatuses, methods, and systems.

Apparatus for peeling a log (5) comprising a cutting station (3), a loading station (2) and a device (4) for transferring logs (5) from the loading station (2) to the cutting station (3), the cutting station (3), the loading station (2) and the transfer device (4), in use, interacting with each other to position the log (5) in the cutting station (3). The loading station (2) comprises a device (10) for axially rotating the log (5) about a second rotation axis (11) and a radiographic examination device (19) configured to generate, in use, radiographic scans of the log (5). An electronic unit is connected both to the radiographic examination device (19), to receive digital-format data from it relating to each radiographic scan generated by it, and to the axial rotation device (10), and which is programmed to use said digital-format data to control the operation of the transfer device (4) and/or the cutting station (3).