A table saw accessory is provided that generally includes: an outfeed support having at least one surface for supporting material fed through the table saw beyond an end thereof; a telescopic section having a proximal end and a distal end, and configured to extend outward from the end of the table saw, where the outfeed support is coupled to the telescopic section at the end thereof; and a connection system for attaching the accessory to the table saw, where the connection system is coupled to the telescopic section at the proximal end thereof.

A table saw accessory is provided that generally includes: an outfeed support having at least one surface for supporting material fed through the table saw beyond an end thereof; a telescopic section having a proximal end and a distal end, and configured to extend outward from the end of the table saw, where the outfeed support is coupled to the telescopic section at the end thereof; and a connection system for attaching the accessory to the table saw, where the connection system is coupled to the telescopic section at the proximal end thereof.

A metrological apparatus (15) is disposed for adjustment of an attitude of a workpiece (16) having an arcuate upper surface (17) relative to a rotary axis (C) of the metrological apparatus (15). The workpiece (16) is brought into a first rotary position (c1). A plurality of measured points within a measuring plane on the upper surface (17) is recorded. The workpiece (16) is moved into a further rotary position (c2) about the rotary axis (C), and again measured points in the measuring plane (E) on the upper surface (17) of the workpiece (16) are recorded. Based on these recorded measured points, the actual attitude (Li) of the workpiece (16) deviation from a specified target attitude (Ls) are determined. Adjustment parameters are determined, and an adjustment assembly (24) of the metrological apparatus (15) is activated as a function of the calculated adjustment parameters to adjust the workpiece (16).

A rotary table according to the exemplary embodiment of the present disclosure includes a piston 70 having a first tapered portion 72, and a clamp 80 having a second tapered portion 82. When the first tapered portion 72 comes into close contact with the second tapered portion 82 by a movement of the piston 70, a pallet base 30 is fixed to a table base 10, and thus the pallet base 30 is rotated, thereby maintaining a preset posture.

The present invention provides a four-chain six-degree-of-freedom hybrid mechanism. The four-chain six-degree-of-freedom hybrid mechanism comprises a fixed platform, a sliding rail mounted on the fixed platform, two sliding blocks, a mobile platform and four linear actuator chains connecting the mobile platform with a first sliding block and a second sliding block. The mobile platform is square-shaped. In the four linear actuator chains, the first linear actuator chain and the third linear actuator chain have the same structure while the second linear actuator chain and the fourth linear actuator chain have the same structure. The mobile platform can achieve six degrees of freedom. The four linear actuator chains coordinate to drive so as to achieve two translational degrees of freedom and two rotational degrees of freedom; the first sliding block and the second sliding block coordinate to drive so as to achieve the other translational and rotational degrees of freedom.

The present invention provides a four-chain six-degree-of-freedom hybrid mechanism. The four-chain six-degree-of-freedom hybrid mechanism comprises a fixed platform, a sliding rail mounted on the fixed platform, two sliding blocks, a mobile platform and four linear actuator chains connecting the mobile platform with a first sliding block and a second sliding block. The mobile platform is square-shaped. In the four linear actuator chains, the first linear actuator chain and the third linear actuator chain have the same structure while the second linear actuator chain and the fourth linear actuator chain have the same structure. The mobile platform can achieve six degrees of freedom. The four linear actuator chains coordinate to drive so as to achieve two translational degrees of freedom and two rotational degrees of freedom; the first sliding block and the second sliding block coordinate to drive so as to achieve the other translational and rotational degrees of freedom.

A reversible flip-away work-stop for strut systems. The reversible flip-way work stop includes a first component allowing a work stop positioning plate to pivot in a semi-circular motion allowing the work stop positioning plate to be moved and immediately configured in a right-handed configuration or a left-handed configuration without manual disassembly and reassembly in a strut in a strut system. A second component allowing the work stop positioning plate to be micro-adjusted to measurements including thousands of an inch for precisely measuring a material to be cut. A third component includes a pre-determined length to exactly match an alignment of a front face of the work stop positioning plate allowing a measurement to be read on a measuring component in the strut on the strut system without obstruction. The third component also including a pre-determined width and shape matching a width and a shape of a measuring component in the strut on the strut system allowing easy movement of the reversible flip-away work stop within the strut in the strut system and providing the ability to add a custom measuring component to the strut system.

A reversible flip-away work-stop for strut systems. The reversible flip-way work stop includes a first component allowing a work stop positioning plate to pivot in a semi-circular motion allowing the work stop positioning plate to be moved and immediately configured in a right-handed configuration or a left-handed configuration without manual disassembly and reassembly in a strut in a strut system. A second component allowing the work stop positioning plate to be micro-adjusted to measurements including thousands of an inch for precisely measuring a material to be cut. A third component includes a pre-determined length to exactly match an alignment of a front face of the work stop positioning plate allowing a measurement to be read on a measuring component in the strut on the strut system without obstruction. The third component also including a pre-determined width and shape matching a width and a shape of a measuring component in the strut on the strut system allowing easy movement of the reversible flip-away work stop within the strut in the strut system and providing the ability to add a custom measuring component to the strut system.

A device for loading and unloading and for operating a machine vise (10) of a machine tool (02), the device having a positioning device (13) mounted so as to be displaceable along a longitudinal direction (L), a coupling unit (14) movable together with the positioning device (13) being disposed at one end of the positioning device (13) in the longitudinal direction (L) for the detachable mechanical coupling to a machine vise (10) of the machine tool (02) and for the operation, in particular opening and closing, of the machine vise (10) and a workpiece handling unit (15), in particular a multiaxial robot unit, being disposed on the positioning device (13) behind the coupling unit (14) in the longitudinal direction (L) so as to be movable together with the positioning device (13).

A device for loading and unloading and for operating a machine vise (10) of a machine tool (02), the device having a positioning device (13) mounted so as to be displaceable along a longitudinal direction (L), a coupling unit (14) movable together with the positioning device (13) being disposed at one end of the positioning device (13) in the longitudinal direction (L) for the detachable mechanical coupling to a machine vise (10) of the machine tool (02) and for the operation, in particular opening and closing, of the machine vise (10) and a workpiece handling unit (15), in particular a multiaxial robot unit, being disposed on the positioning device (13) behind the coupling unit (14) in the longitudinal direction (L) so as to be movable together with the positioning device (13).