CS245514B1 - Clamp dog - Google Patents

Description

It is an object of the invention to provide a driving heart for transferring torque from a spindle to a rotary workpiece clamped between the tips of a machine tool, such as a center lathe, center grinding machine and the like.

Hitherto, standardized constructions of driving shafts are known, consisting of a body provided with a central bore into which a clamping screw extends. The body passes smoothly into an elongated stem terminated by a straight or a straight shaft. a bent end cooperating with a pin or groove in a drive disc mounted on the machine spindle. The workpiece is fastened in the opening of the carrier body by a fastening screw. The disadvantages of this solution are, in particular, in the small range of clamping diameters and also the possibility of use only in the driving disc with pin, respectively. a groove according to the end of the stem of the carrier body.

It is also known to have a driving heart formed by a ring ring having at least three threaded holes for clamping screws around its circumference. The clamping screws terminated by hardened tips are pushed into the workpiece surface, and the drive is secured by a bolt immeasurably attached radially to the ring surface. The disadvantage of this solution is the high workmanship of the clamping carrier to the workpiece. Carrying heart function to the obiecte. The function of the entrainment heart is also dependent on the kind of cooperating entrainment disc.

Disadvantages of the present state are eliminated by the driving heart according to the invention, characterized in that the cylindrical disk is provided with a through hole formed by a large center bore and a small eccentric bore connected to each other by planes that pass through a small eccentric bore. drilling and eccentric drilling have a common axis. The cylindrical disk has threaded holes formed on its annular ring, one of which is radial and the other has an axis parallel to the center hole drilling axis, for replaceable cylindrical driving arms.

The advantages of the proposed solution are mainly in the possibility of clamping a large range of diameters. The spacers attached to the clamping screw allow the clamping of very small workpiece diameters. Interchangeable drive arms increase the versatility of use for various drive disc constructions. The simple shape and easy manufacturing have a positive impact on the economy of production and the use of the driving heart.

The driving heart of the invention is shown in the accompanying drawing, in which an alternative is depicted with the spacers used on the screw and the disc is provided with a radial driving cylindrical arm. A cylindrical disk 1 is provided with a through hole 10, which is formed by a large central bore 2, a small eccentric bore 3 and plane surfaces P1, P2. The planes Ρ, P2 pass through the eccentric bore 3 and are tangential to the central drilling 2 so as to form the abutment surfaces for the workpiece 11 pressed by the clamping screw 4 screwed into the cylindrical disc 1 and extending into the through hole 10. 3 either touch each other at one point, eventually intersect, or do not touch. The ratio of the diameter of the center drilling 2 to the diameter of the eccentric drilling 3 is in the range 5: 1 to 8: 1 and the support surfaces for the workpiece 11, which form planes Ρι, P2, form an angle in the range 90 ° to 130 °. Thread holes 5, 6 for the replaceable cylindrical carrier arms 7 are formed in the annular ring of the cylindrical disk 1. Thread holes 5, 6 are formed in the right-hand hole 5 and the left-hand hole B from the eccentric drilling 3, in the spaces between the planes that extend through the center drilling axis 2 and form an angle of 20 ° ^C to 501 with the axis 9 The cylindrical driving arm of the threaded drilling 5 is screwed into the radial threaded drilling 5. on the spindle (not shown). If a carrier heart 7 with a carrier arm 7 oriented parallel to the center hole 2 is required, the arm 7 is unscrewed from the threaded hole 5 and screwed into the threaded hole B. In operation, the workpiece 11 is pushed it has a common axis 9 with a central bore 2 and the eccentric bore 3 is pressed against the support surfaces defined by the planes Ρι, P2.

In the case of clamping a small diameter of the workpiece 11, which cannot be clamped by the functional stroke of the screw 4, a replaceable spacer 8 is required at the end of the clamping screw 8. The spacer 8 has a prismatic shape in flat for contact with the workpiece 11. clamping of different workpiece diameters 11.

After the carrier heart is clamped on the workpiece 11, the workpiece is fixed between the machine tool tips and the carrier arm 7 is supported on the carrier pin of the carrier disc (not shown or inserted into the slot of the carrier disc of the spindle).

The object of the invention is applicable in the field of machine tools, in particular in the machining of shaft-shaped workpieces clamped between the tips of a machine tool, for example a center lathe, a grinding machine and the like.

Claims (3)

A carrier heart comprising a cylindrical disc, a clamping screw and a driving arm, characterized in that the cylindrical disc (11) is provided with a through hole (10) formed by a central bore (2), an eccentric bore (3) and plane surfaces (Pi). P2J, which pass through the center of the eccentric drilling (3) and are tangential to the central drilling (2). 2. The driving heart according to claim 1, characterized in that the cylindrical disk (1) has threaded holes (5, 6) formed therein for replaceable cylindrical driving means. BACKGROUND OF THE INVENTION arms (7), one of which is radial with respect to central drilling (2) and the other parallel to it, and are located in the space to the right and left of the eccentric drilling (3), the centers of the threaded holes (5, 6) being the spaces between the planes that cross the center drilling axis (2) and form an angle of 20 ° to 50 with the axis 3. A carrier heart according to claim 1 or 2, characterized in that the ratio of the diameter of the central drilling (2) to the diameter of the eccentric drilling (3J is in the range of 5: 1 to 8: 1).