Device for producing reinforcements, in particular reinforcement baskets for concrete pipes having a bell-shaped socket end, having an expansion device which has a single expansion slide, wherein the expansion slide is configured for modifying, in particular, during the production process of the reinforcement, a radial position of an assigned actuating element for a longitudinal wire of the reinforcement by way of a transmission mechanism of the expansion device. The device is characterized in that the expansion device has a mold slide, wherein an actuator drive is provided for moving the mold slide, and wherein the actuator drive for a linear movement of the mold slide in relation to the expansion slide is supported on the expansion slide.

A mobile manufacturing device and a method for producing three-dimensional lattice or mesh structures, wherein the mobile manufacturing device is a mobile device adapted to move along a three-dimensional structure to be produced, in particular while performing both translation and rotation movements in three-dimensional space, and wherein the mobile manufacturing device includes a means for detection of its position relative to the dimensional structure to be produced, so that the mobile manufacturing device is able to produce the three-dimensional structure as an autonomous robot.

A method of manufacturing a metal basket contains the steps of preparing materials, initial welding, bending, and finish welding. In a step of preparing materials, multiple first metal bars, multiple second metal bars, and at least two peripheral bars are provided. In a step of initial welding, the multiple first metal bars and the multiple second metal bars are stacked crisscross and are welded together to produce a grid frame which has a base and multiple surrounding grids, and the at least two peripheral bars are welded with the multiple surrounding grids respectively. In a step of bending, the grid frame and the multiple surrounding grids are bent, such that the multiple surrounding grids are bent upwardly and are perpendicular to the base. In a step of finish welding, the at least two peripheral bars are welded together.

A method of manufacturing a metal basket contains the steps of preparing materials, initial welding, bending, and finish welding. In a step of preparing materials, multiple first metal bars, multiple second metal bars, and at least two peripheral bars are provided. In a step of initial welding, the multiple first metal bars and the multiple second metal bars are stacked crisscross and are welded together to produce a grid frame which has a base and multiple surrounding grids, and the at least two peripheral bars are welded with the multiple surrounding grids respectively. In a step of bending, the grid frame and the multiple surrounding grids are bent, such that the multiple surrounding grids are bent upwardly and are perpendicular to the base. In a step of finish welding, the at least two peripheral bars are welded together.

The present invention relates to machines, systems and processes for feeding longitudinal wires (2) for mesh (6) production. Welding of longitudinal wires (2) with transverse wires (4) at welding unit (57) produces mesh (6). Longitudinal wires (2) are controllably rotated around their longitudinal axes to selected angles, and restrained until their welding with transverse wires (4), thus negating effects of residual curvature from roller straightener (36) and resulting in mesh (6) produced planar with distortion stresses effectively neutralized. A wire collector (79) releases a first longitudinal wire (2) for guided travel laterally to a receptacle (45). A rotator unit (71) simultaneously controllably rotates this wire, while the collector (79) simultaneously receives the length of the next longitudinal wire. Particular rotator units (71) facilitate such operation. In some versions an advancement roller assembly (120) proximate to the welding unit (57) may advance longitudinal wires (2) through the welding unit, freeing a longitudinal wires carrier (31) to return to the longitudinal storage (32) and to receive a next set of longitudinal wires.

The present invention relates to machines, systems and processes for feeding longitudinal wires (2) for mesh (6) production. Welding of longitudinal wires (2) with transverse wires (4) at welding unit (57) produces mesh (6). Longitudinal wires (2) are controllably rotated around their longitudinal axes to selected angles, and restrained until their welding with transverse wires (4), thus negating effects of residual curvature from roller straightener (36) and resulting in mesh (6) produced planar with distortion stresses effectively neutralized. A wire collector (79) releases a first longitudinal wire (2) for guided travel laterally to a receptacle (45). A rotator unit (71) simultaneously controllably rotates this wire, while the collector (79) simultaneously receives the length of the next longitudinal wire. Particular rotator units (71) facilitate such operation. In some versions an advancement roller assembly (120) proximate to the welding unit (57) may advance longitudinal wires (2) through the welding unit, freeing a longitudinal wires carrier (31) to return to the longitudinal storage (32) and to receive a next set of longitudinal wires.

The invention relates to a production plant (18) for manufacturing a three-dimensional reinforcement element for a reinforced concrete element, comprising a receiving table (19) for accommodating the reinforcement element and a manipulation device (21) for manipulating and joining individual parts of the reinforcement element. The manipulation device (21) comprises a first articulated arm robot (22) having a gripping mechanism (24) for positioning rebar mats and/or spacers of the reinforcement element and a second articulated arm robot (23) a welding unit (25) for welding the spacers to the rebar mats.

The invention relates to a production plant (18) for manufacturing a three-dimensional reinforcement element for a reinforced concrete element, comprising a receiving table (19) for accommodating the reinforcement element and a manipulation device (21) for manipulating and joining individual parts of the reinforcement element. The manipulation device (21) comprises a first articulated arm robot (22) having a gripping mechanism (24) for positioning rebar mats and/or spacers of the reinforcement element and a second articulated arm robot (23) a welding unit (25) for welding the spacers to the rebar mats.

The present disclosure relates to an automatic forming machine for plant growth supports, comprising a ring rolling system with a ring rolling unit, a mold system with a mold unit, and a welding system, which are all disposed on a machine frame, wherein the ring rolling unit can roll a metal wire and make the metal wire be formed into a ring with an opening in the mold unit; the mold system is for carrying the ring and making two free ends of the ring with an opening aligned or alternately overlap with each other; the welding system welds can weld the opening of the ring carried by the mold unit, causing the ring to become a closed ring. The present disclosure has a high automatic degree and can reduce the production time and labor cost.

A system for producing reinforcing cages for wind turbine tower segments, wherein a reinforcing cage has in each case substantially horizontally oriented ring segments and substantially vertically oriented stiffening elements. It is proposed that the system has a receiving area which is adapted so as to receive the preferably inner, substantially horizontally oriented ring segments of the reinforcing cage, a first handling robot for supplying and positioning the stiffening elements, and a second handling robot for connecting the ring elements to the stiffening elements.