An improved tooling, including: a base housing having an interior and tooling holes, the tooling holes being configured to receive alignment studs attached to a tooling fixture; a first clamping fixture and a second clamping fixture fit inside hollowed regions within the base housing; a shaft having a length and an axis along the length of the shaft, the shaft situated inside the base housing and the shaft having a first threaded region and a second threaded region to connect the first clamping fixture and the second clamping fixture, whereby rotation of the shaft causes the first clamping fixture and the second clamping fixture to move towards and away from each other along the axis of the shaft; each of the first clamping fixture and the second clamping fixture comprising one or more securing mechanisms configured to: engage and disengage the alignment studs based upon rotation of the shaft.

An improved tooling, including: a base housing having an interior and tooling holes, the tooling holes being configured to receive alignment studs attached to a tooling fixture; a first clamping fixture and a second clamping fixture fit inside hollowed regions within the base housing; a shaft having a length and an axis along the length of the shaft, the shaft situated inside the base housing and the shaft having a first threaded region and a second threaded region to connect the first clamping fixture and the second clamping fixture, whereby rotation of the shaft causes the first clamping fixture and the second clamping fixture to move towards and away from each other along the axis of the shaft; each of the first clamping fixture and the second clamping fixture comprising one or more securing mechanisms configured to: engage and disengage the alignment studs based upon rotation of the shaft.

A pretensionable locking system, a method for producing a locking system and a medical-technical instrument including a locking system. The locking system (2) includes a locking body (10) with an inner thread (12), and an inner locking body (20) with an outer thread (22). In a pretensioned position, the inner thread lies against the outer thread in a first longitudinal axial direction (80) and is pretensioned against the outer thread. In a locked position, the outer locking body is fixed on the inner locking body by screwing the inner thread onto the outer thread. The outer locking body has a resilient retaining element (14) that projects radially inward, and the inner locking body has a rigid bulge (24) that projects radially outward. In the pretensioned position, the retaining element lies against the bulge in a second longitudinal axial direction (85) that is opposite the first longitudinal axial direction.

A sliding table includes a sliding seat having a seat body made from a first material and disposed between two main rigid rails parallel with each other. The seat body has two opposite rail recesses opening toward the main rigid rails, and two inner cyclic track holes disposed between the rail recesses. Two seat body rigid rails made from a second material harder than the first material are fixed in the rail recesses to confront the main rigid rails. Two roller belt modules are arranged in two cyclic track members overmolded to the seat body. When the seat body moves along the main rigid rails, each roller belt module circulates along one of the cyclic track members.

A sliding table includes a sliding seat having a seat body made from a first material and disposed between two main rigid rails parallel with each other. The seat body has two opposite rail recesses opening toward the main rigid rails, and two inner cyclic track holes disposed between the rail recesses. Two seat body rigid rails made from a second material harder than the first material are fixed in the rail recesses to confront the main rigid rails. Two roller belt modules are arranged in two cyclic track members overmolded to the seat body. When the seat body moves along the main rigid rails, each roller belt module circulates along one of the cyclic track members.

A decoupling control method for linkage turntable in the technical field of associative motion control mechanisms. Steps of the technical solution are as follows: measure a length L of a hypotenuse of a triangular structure; convert A-axis coordinates input to the system into Z0-axis coordinates according to Z0=L*cos α and input them on Z0-axis; and in the case of a speed control method, convert the A-axis coordinates into a periodic displacement of Z0 according to ΔZ0=L*(cos α.sub.1−cos α.sub.2), and input the displacement to Z0-axis. The beneficial effect is that the horizontal displacement generated by the movement of the Z0-axis is directly integrated into the closed loop of the X-axis by means of measurement combination and the displacement directly calculated by grating scale has high precision and no delay, and it is possible to achieve a more effective control level on this mechanical structure. In addition, the optimized control algorithm makes the X-axis have the motion characteristics of RTCP in the process of A-axis rotation, thereby reducing the requirements for the dynamic performance of the X-axis motor.

A decoupling control method for linkage turntable in the technical field of associative motion control mechanisms. Steps of the technical solution are as follows: measure a length L of a hypotenuse of a triangular structure; convert A-axis coordinates input to the system into Z0-axis coordinates according to Z0=L*cos α and input them on Z0-axis; and in the case of a speed control method, convert the A-axis coordinates into a periodic displacement of Z0 according to ΔZ0=L*(cos α.sub.1−cos α.sub.2), and input the displacement to Z0-axis. The beneficial effect is that the horizontal displacement generated by the movement of the Z0-axis is directly integrated into the closed loop of the X-axis by means of measurement combination and the displacement directly calculated by grating scale has high precision and no delay, and it is possible to achieve a more effective control level on this mechanical structure. In addition, the optimized control algorithm makes the X-axis have the motion characteristics of RTCP in the process of A-axis rotation, thereby reducing the requirements for the dynamic performance of the X-axis motor.

Pantograph machine (1) equipped with cutting blades hot punches pre-shaped, and drills, for machining panels, in particular slabs and ICF panels, with foamed materials or extruded, comprising at least a first station (1) consisting of at-least a castle (1′), supported by a base (2) which houses a supporting surface (3), the castle (1′) comprising: at least one frame (5) carrying punches-cutting blades (6) connected operatively to a frame-carrier carriage (9) sliding on guides, and moved by means of a transmission; at least two slides (23) for milling, performed by a tool (24) mounted on an electro-spindle (25), place on a carriage (14); at least-one frame (15) carrying wires (16) operatively connected to a frame-carrier carriage (19) sliding on guides (10) and moved by means a transmission.

Pantograph machine (1) equipped with cutting blades hot punches pre-shaped, and drills, for machining panels, in particular slabs and ICF panels, with foamed materials or extruded, comprising at least a first station (1) consisting of at-least a castle (1′), supported by a base (2) which houses a supporting surface (3), the castle (1′) comprising: at least one frame (5) carrying punches-cutting blades (6) connected operatively to a frame-carrier carriage (9) sliding on guides, and moved by means of a transmission; at least two slides (23) for milling, performed by a tool (24) mounted on an electro-spindle (25), place on a carriage (14); at least-one frame (15) carrying wires (16) operatively connected to a frame-carrier carriage (19) sliding on guides (10) and moved by means a transmission.

A reconfigurable machining center includes a base structure extending in a first direction, a movable crossmember movable in the first direction and provided with a machining head, supporting elements on the base structure to enable movement of the movable crossmember along the first direction, a first leadscrew rack, integral with the base structure and having a first helical circular toothed sector, and extending along the entire base structure parallel to the first direction, and a first screw rotatably coupled to the movable crossmember and engaging a corresponding first leadscrew rack, and having a rotation axis parallel to the first direction. The longitudinal extension of the base structure in the first direction is an integer multiple of the pitch of tooth of the leadscrew racks, and the base structure includes coupling elements adapted to couple the base structure to a following and/or preceding adjacent base structure along the first direction.