A combined device for bending and cutting ribbon-shaped elements is described, comprising first guiding and supporting means (1, 101) adapted to allow positioning a ribbon-shaped element (T, T1), second guiding and supporting means (3, 103) adapted to prevent the rotation of the ribbon-shaped element (T, T1) with respect to an axis belonging to a plane on which the ribbon-shaped element (T, T1) rests, first translating means (41, 1041) and rotation means (4, 104) adapted to move a tool (5, 105) with respect to the second guiding and supporting means (3, 103); the second guiding and supporting means (3, 103) comprise a portion of bending profile (8, 108) adapted to bend the ribbon-shaped element (T, T1) and a portion of cutting profile (9, 109) adapted to cut the ribbon-shaped element (T, T1). A method is further described for bending and cutting ribbon-shaped elements performed through such device.

A control data creation device includes a specifying unit configured to change suction positions at which carrying-out arms suction a product P by moving the carrying-out arms on product data so as to specify an index for evaluating a suction state for each of the suction positions, and a layout setting unit configured to create control data in which the suction position is laid out to the product P based on each index specified for each of the suction positions.

A sealing apparatus (10, 10), comprising a sealing base plate (1, 1), pressing parts (2, 2), and a sealing turntable (3, 3), wherein a plurality of pressing parts are enclosed at one end to form a shrink hole (101, 101), and the sealing turntable drives the plurality of pressing parts to move synchronously so as to continuously shrink or expand the shrink hole. A sealing and cutting device, comprising the sealing apparatus (10, 10), a cutting apparatus (20, 20) and a conveying apparatus (70, 70), wherein the conveying apparatus is arranged at a first end of the sealing apparatus so as to convey a material (60) along a set direction, and the cutting apparatus is arranged at a second end of the sealing apparatus for use in cutting the material.

A machining system for cutting round material to length, in particular concrete steel. The machining system has a feeder assembly for feeding and positioning the round material, and a cutting device for cutting the round material to length. The feeder assembly is designed as a belt conveyor, wherein in a conveyor permanent magnets are arranged, which are positioned below a receiving surface for receiving round material, wherein the round material can be fixed to the receiving surface of the conveyor means by the permanent magnets.

A machining system for cutting round material to length, in particular concrete steel. The machining system has a feeder assembly for feeding and positioning the round material, and a cutting device for cutting the round material to length. The feeder assembly is designed as a belt conveyor, wherein in a conveyor permanent magnets are arranged, which are positioned below a receiving surface for receiving round material, wherein the round material can be fixed to the receiving surface of the conveyor means by the permanent magnets.

The present invention provides a blade cutting device capable of simplifying the work of cutting blade-shaped materials (31), and accurately forming blades. The blade cutting device includes a material accommodation section (32) comprising a plurality of accommodation chambers (R1 to R10) for accommodating the band-shaped materials (31) used to form blades, in such a manner as to be sorted by type; a band-shaped material machining section (33) comprising a feed unit for feeding a band-shaped material (31) pulled out from a predetermined accommodation chamber and a cutting unit (55) for cutting the band-shaped material (31) into a predetermined length for forming blades; and a control section for causing the material accommodation section (32) to move so as to locate the predetermined accommodation chamber of the material accommodation section (32) at a position facing the band-shaped material machining section (33). The predetermined accommodation chamber is located at the position facing the band-shaped material machining section (33), and the band-shaped material (31) pulled out from the predetermined accommodation chamber is cut into a predetermined length for forming blades. The work of selecting the band-shaped materials (31) can be simplified, and blades can be formed accurately.

A metal tab bending tool for securing an upright stud in place and relative to an elongated track of a wall assembly. The track includes an elongated flat web with first and second free-ended flanges extending in the same direction from opposed first and second side edges, respectively, of the web. Each flange of the web defines a plurality of spaced tabs extending toward the flat web from a free-end of each flange. The tool for connecting the stud in place and relative to the track includes a base. The tool also includes at least two pairs of bending arms each pivotally mounted to the base. Each pair of bending arms includes a first bending arm, adapted to be disposed to one side of the upright stud, and a second bending arm spaced apart from the first bending arm and adapted to be disposed to an opposite side of the stud. A mechanism is provided for moving at least one bending arm of each pair of bending arms from a first position and into engagement with a tab on each of the first and second free-ended flanges so as to bend opposed tabs on said first and second free-ended flanges engaged by the bending arms toward a center of the elongated track whereby inhibiting movement of said stud therepast. A method for securing a stud in place relative to a track is also disclosed.

A gripping device, in particular for loading/unloading apparatuses, includes: a main body; at least one first and a second articulated structure; at least one first and a second gripping head, respectively mounted on the first and second articulated; a first motorised member, mounted on the main body and active on the first articulated structure to modify the position of the first gripping head with respect to the main body; a second motorised member, mounted on the main body and active on the second articulated structure to modify the position of the second gripping head with respect to the main body. Each of the first the second articulated structures has: a first arm hinged to the main body; a second arm hinged to the main body; a rod, hinged to the first arm and to the second arm.

A strip material cutting device and a stacking apparatus are disclosed. The strip material cutting device includes a die-cutting module and a first temporary storage module, the die-cutting module is capable of moving in a reciprocating manner along a conveying line of a strip material, and the die-cutting module includes a first upper cutting die and a first lower cutting die capable of moving close to each other so as to cut the strip material. The first temporary storage module is located upstream of the die-cutting module. The first temporary storage module includes a first temporary storage roller that is capable of moving to temporarily store or release the strip material and is configured for enabling, during cutting, the die-cutting module and the strip material to be relatively stationary in a conveying direction of the strip material.

A dual pre-stacking system of steel plates for a single cutting line and a stacking method therefor. The dual pre-stacking system comprises: a cooling bed inspection stand, a crop shear with a cut-to-length function, a bilateral shear, 1#inkjet printer, a front pre-stacker, a cut-to-length shear, a length and thickness gauge, 2#inkjet printer, surface check/size inspection and fitting, and a rear pre-stacker arranged in order along the roller. The dual pre-stacking system and the stacking method therefor of the present invention solves the problem that the inkjet printing, size fitting and pre-stacking in the later zone of the cutting line are slow when producing steel plates with high magnification, simultaneously performs pre-stacking operation after bilateral cutting and surface check in one cutting line, achieves synchronous inkjet printing/imprinting, size fitting and pre-stacking of the steel plates at two sites along the cutting line.