A mechanism for use in adjusting the position of components in a machine including an elongate shaft assembly, at least one projection shaft extending in a direction transverse to said elongate shaft assembly, and a support frame. The elongate shaft assembly includes at least one primary shaft segment, and at least one secondary shaft segment removably coupled to the primary shaft segment, the secondary shaft segment includes a first gear. The projection shaft extends in a direction transverse to the elongate shaft assembly and includes a second gear element disposed on its proximal end portion. The second gear element is coupled to the first gear element whereby rotation of the elongate shaft assembly translates into rotation of the projection shaft. The projection shaft is capable of being coupled to the components such that rotation of the projection shaft operates to adjust the position of the components.

An elastic junction device for the dynamic connection, in a rolling mill, between the motor side and the head of an adapter or between the adapter and one or more rolling rolls comprises a central body which can be connected to an end of said flange so that it can rotate integrally therewith. The device additionally comprises two skids through a connecting pin so that said block rotates integrally with said flange, said skids being mechanically couplable to said adapter to allow the rotation thereof upon the rotation of said flange and vice versa. The junction device comprises at least a first damper element and at least a second damper element housed in the block and which act on opposite parts of the connecting pin so as to absorb the axial tensions which are transmitted along the adapter as a result of the stresses caused by rolling.

An elastic junction device for the dynamic connection, in a rolling mill, between the motor side and the head of an adapter or between the adapter and one or more rolling rolls comprises a central body which can be connected to an end of said flange so that it can rotate integrally therewith. The device additionally comprises two skids through a connecting pin so that said block rotates integrally with said flange, said skids being mechanically couplable to said adapter to allow the rotation thereof upon the rotation of said flange and vice versa. The junction device comprises at least a first damper element and at least a second damper element housed in the block and which act on opposite parts of the connecting pin so as to absorb the axial tensions which are transmitted along the adapter as a result of the stresses caused by rolling.

A pilger rolling mill with a roll stand moves linearly back and forth along a movement direction and includes a crank mechanism having a rotatably supported crankshaft with a crank pin and push rod. A first end of the push rod is pivotably fastened to the crank pin and a second end is pivotably fastened to the roll stand, so that during operation of the pilger rolling mill a rotary movement of the crankshaft is converted into an oscillating movement of the roll stand along the movement direction. A compensation shaft is rotatably supported about an axis of rotation and includes a distribution of mass that is not rotationally symmetrical relative to its axis of rotation and a counter-mass. The crankshaft and the compensation shaft are connected to one another by a transmission so that a rotation of the crankshaft leads to a rotation of the compensation shaft.

A pilger rolling mill with a roll stand moves linearly back and forth along a movement direction and includes a crank mechanism having a rotatably supported crankshaft with a crank pin and push rod. A first end of the push rod is pivotably fastened to the crank pin and a second end is pivotably fastened to the roll stand, so that during operation of the pilger rolling mill a rotary movement of the crankshaft is converted into an oscillating movement of the roll stand along the movement direction. A compensation shaft is rotatably supported about an axis of rotation and includes a distribution of mass that is not rotationally symmetrical relative to its axis of rotation and a counter-mass. The crankshaft and the compensation shaft are connected to one another by a transmission so that a rotation of the crankshaft leads to a rotation of the compensation shaft.

A hand-powered jewellery rolling mill is disclosed. The mill comprises a support frame and a pair of opposed parallel cylindrical rollers rotatably mounted to the support frame. A drive shaft is connected to at least one of the rollers for rotation thereof. A manually rotatable handle is configured for providing a drive force to the drive shaft. The handle may be connected to the drive shaft through a high-ratio gear train. The rolling mill may further comprise an input shaft, rotatable by the manually rotatable handle. The input shaft may have a worm and a worm-to-gear coupling may transfer torque from the input shaft to the drive shaft.

A hand-powered jewellery rolling mill is disclosed. The mill comprises a support frame and a pair of opposed parallel cylindrical rollers rotatably mounted to the support frame. A drive shaft is connected to at least one of the rollers for rotation thereof. A manually rotatable handle is configured for providing a drive force to the drive shaft. The handle may be connected to the drive shaft through a high-ratio gear train. The rolling mill may further comprise an input shaft, rotatable by the manually rotatable handle. The input shaft may have a worm and a worm-to-gear coupling may transfer torque from the input shaft to the drive shaft.

A rolling mill assembly includes: a first cardan shaft including a first rolling mill-side joint and a first drive-side joint, a second working roller being connected to a second cardan shaft, which in turn is connected to a second drive device, the second cardan shaft including a second rolling mill-side joint and a second drive-side joint, the first rolling mill-side joint being located at a first distance to the first working roller, the second rolling mill-side joint being located at a second distance to the second working roller, the first distance and the second distance differing by 0.5 m to 4 m, the first cardan shaft further including a first device configured for length change between the first rolling mill-side joint and the first drive-side joint, the second cardan shaft further including a second device configured for length change between the second rolling mill-side joint and the second working roller.

A rolling mill assembly includes: a first cardan shaft including a first rolling mill-side joint and a first drive-side joint, a second working roller being connected to a second cardan shaft, which in turn is connected to a second drive device, the second cardan shaft including a second rolling mill-side joint and a second drive-side joint, the first rolling mill-side joint being located at a first distance to the first working roller, the second rolling mill-side joint being located at a second distance to the second working roller, the first distance and the second distance differing by 0.5 m to 4 m, the first cardan shaft further including a first device configured for length change between the first rolling mill-side joint and the first drive-side joint, the second cardan shaft further including a second device configured for length change between the second rolling mill-side joint and the second working roller.

The invention relates to a stand change carriage (10) for simultaneously receiving and transporting a plurality of stands of a rolling mill for rolling metal rods, wires or pipes, the stand change carriage (10) comprising a plurality of stand places (16), one of the stands being receivable individually in each of the stand places (16), the stand change carriage (10) comprising a plurality of steerable wheels (20), in order to transport the stands on rails or along a rail-less mill floor, and the stand change carriage comprising at least one hydraulic motor (21) which is operatively connected to at least one of the wheels (20) in order to drive it.