A system is provided for manufacturing a pipe bend, including: a securement structure including a securement device configured to secure a first end of a pipe and a pivot arm coupled to the securement device and configured to pivot about a pivot point to introduce a bend in the pipe; an induction ring configured to heat an annular band of a wall of the pipe; a first quenching ring configured to direct a first quenching fluid toward an outer surface of the heated annular band in the wall of the pipe; a second quenching ring configured to direct a second quenching fluid toward an inner surface of the heated annular band in the wall of the pipe; and a processor configured to control release of the first quenching fluid and the second quenching fluid such that the first quenching fluid reaches the outer surface and the second quenching fluid reaches the inner surface substantially concurrently.

A conduit bender having a unitary frame is mounted to a wheeled base which provides for transportation of the bender. A braking assembly provides for simplified locking of the wheels to secure the bender in a location. The bender is mounted to the base through a pivoting assembly which allows for bending of conduit in either a horizontal or vertical plane. A circuit is provided for controlling the bending operation. An auto-sensing portion of the circuit receives information regarding the characteristics of the conduit to be bent upon placement of the conduit in the bender. A feedback portion of the circuit is used to provide a precise bending operation.

A conduit bender having a unitary frame is mounted to a wheeled base which provides for transportation of the bender. A braking assembly provides for simplified locking of the wheels to secure the bender in a location. The bender is mounted to the base through a pivoting assembly which allows for bending of conduit in either a horizontal or vertical plane. A circuit is provided for controlling the bending operation. An auto-sensing portion of the circuit receives information regarding the characteristics of the conduit to be bent upon placement of the conduit in the bender. A feedback portion of the circuit is used to provide a precise bending operation.

A robotic tube bending machine is disclosed. The machine includes a tube feeding tray to load tubes. The pneumatic feed separator comprising two jaws to move in a reciprocating motion to separate each tube for sequential operation. The machine includes a robotic arm assembly in communication with a controller and includes a robotic arm and a pneumatic gripper and two gripper fingers to pick each tube from the tray by simultaneous movement of multiple axis of the robotic arm to reach a three-dimensional coordinate. The collision detection module to detect presence of the robotic arm across a non-intended area by measuring force of the robotic arm and deactivate the robotic arm upon detecting a condition of collision. The machine includes a bending die to clamp each tube and a pressure die to apply pressure on the bending die to bend each tube in intricate three dimensional shapes by rotating the tubes at predefined angles by maneuvering the robotic arm.

A method of bending a metallic article comprising at least the following steps is described: a) executing a relative movement between a bending head having at least one bending group and the metallic article, and b) bending the metallic article by means of an activation of the bending group. During step b), at least a first actuation device actuates the bending group according to a respective motion profile and during the step a), at least a second actuation device actuates a relative movement between the bending head and the metallic article according to a respective motion profile. The method also comprises a step of preparing, during which a respective initial motion profile of the first actuation device and/or of the second actuation device is modified for obtaining the respective motion profile in function of a first parameter and of a second parameter.

A bender and base assembly according to some embodiments of the disclosure is provided. The bender includes a frame having a pivot shaft extending therefrom, and a shoe shaft extending from the frame for receiving a shoe rotatably mounted thereon, the shoe shaft defining a shoe axis and a shoe plane perpendicular to the shoe axis. The base includes a pivot shaft receptacle, wherein the pivot shaft receptacle defines a pivot axis, wherein the pivot shaft of the bender is received by the pivot shaft receptacle of the base; wherein the pivot shaft rotates relative to the pivot shaft receptacle, to rotate the bender on the pivot axis between a horizontal bending position and a vertical bending position; and wherein the pivot axis intersects with the shoe plane. A lock is provided to lock the position of the bender relative to the base.

A bender and base assembly according to some embodiments of the disclosure is provided. The bender includes a frame having a pivot shaft extending therefrom, and a shoe shaft extending from the frame for receiving a shoe rotatably mounted thereon, the shoe shaft defining a shoe axis and a shoe plane perpendicular to the shoe axis. The base includes a pivot shaft receptacle, wherein the pivot shaft receptacle defines a pivot axis, wherein the pivot shaft of the bender is received by the pivot shaft receptacle of the base; wherein the pivot shaft rotates relative to the pivot shaft receptacle, to rotate the bender on the pivot axis between a horizontal bending position and a vertical bending position; and wherein the pivot axis intersects with the shoe plane. A lock is provided to lock the position of the bender relative to the base.

A computer controlled method for bending profiles for making insulating frames for double and triple glass pane glazings comprises at least the steps of: automatically feeding the profile to a profile machining section; immediately bringing the profile to a bending position, in which the profile is heated directly by hot air jets to a malleable condition at the bending position without moving the profile in its malleable condition.

A computer controlled method for bending profiles for making insulating frames for double and triple glass pane glazings comprises at least the steps of: automatically feeding the profile to a profile machining section; immediately bringing the profile to a bending position, in which the profile is heated directly by hot air jets to a malleable condition at the bending position without moving the profile in its malleable condition.

An automated bender and its method of operation according to some embodiments of the disclosure is provided. The automated bender includes a carousel which has all of the necessary components for bending a variety of conduit sizes provided thereon. The carousel can be rotated to a desired bending position to bend a particular type of conduit. A straight workpiece is fed into the automated bender and a bent workpiece, which may have multiple bends therein, is output from the automated bender. This bending process is performed without manual intervention. Software for achieving same is provided.