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.

The invention relates to a method for induction bend forming a compression-resistant pipe (I) having a large wall thickness and a large diameter. According to said method, in an initial phase t1, an initial tangent (3) of the pipe (I) is heat-treated by pushing the initial tangent (3) through the inductor (20) without the intervention of the bending lock (31). At the end of the initial tangent (3) the advance of the pipe is stopped at a time t2, and the inductor (20) is moved along the pipe (I) counter to the advance direction while the bending lock (31) is closed on the pipe (I). In order to induce the bending process in a phase t3, the movement speed of the inductor (20) is reduced to zero and the latter is moved to its bending position. At the same time, the advance of the pipe (I) is started. In a phase t4, a pipe bend (4) is produced at a constant process advance speed of the pipe (I). In a phase t5, the advance speed of the pipe (I) is reduced and the inductor (20) is accelerated counter to the advance direction while the bending lock (31) is opened. In a phase t6, a final tangent (5) is heated by further advancing the inductor in the opposite direction.

Machine for bending at least one longitudinal cylindrical pipe, the bending machine having at least one heating module configured so as to heat a longitudinal cylindrical pipe and at least one deformation module configured so as to deform a longitudinal portion of a longitudinal cylindrical pipe in order to bend it, said heating module having a plurality of heating units, each heating unit can include a peripheral heating body defining an internal opening adapted to allow the passage of a longitudinal portion of a longitudinal cylindrical pipe to be heated.

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.

A hollow stabilizer has a tubular shape and is provided with a torsion section that is provided to a vehicle and that extends in the vehicle width direction; an arm section that extends in the front-back direction of the vehicle; and bent sections that connect the torsion section and the arm section. The hardness of the outer surface of the bent inner sides of the bent sections of the hollow stabilizer is 70% or more with respect to the hardness of the outer surface of the arm section.