Bending head, especially for an automatic bending machine

Abstract

A bending head for an automatic bending machine includes a frame. A first rotationally driven bending roll is arranged in the frame. A bending arm is transversely arranged below the first bending roll and is coupled to a bi-directional drive, with an end of the bending arm rotatable about the longitudinal axis of the first bending roll. A rotatable second bending roll is mounted to an opposite end of the bending. A bending support is configured with the first and second bending rolls. The second bending roll is rotationally coupled to the first bending roll in a forced torque transmission manner for mutual counter-direction rotation of the first and second bending rolls. The bending rolls have axially symmetric reduced lateral circumferential sections. The bending roll controls an angle of mutual rotation of both of the first and second bending rolls.

Claims

1. A bending head for an automatic bending machine, comprising: a frame; a first bending roll arranged in the frame and rotatable about a longitudinal axis of the first bending roll, the first bending roll connected to a driving rotational source within the frame; a bending arm below the first bending roll with al longitudinal axis transverse to the longitudinal axis of the first bending roll, the first bending roll rotatably mounted on the bending arm; a bi-directional drive coupled to the bending arm to bi-directionally rotate an end of the bending arm about the longitudinal axis of the first bending roll; a second bending roll mounted to an opposite end of the bending arm, the second bending roll rotatable about a longitudinal axis that is parallel to the longitudinal axis of the first bending roll; a bending support comprising a body adjacent to the first and second bending rolls with an end pivotally mounted to the frame, wherein the body is tiltable to remove and insert bent material between the first and second bending rolls; the second bending roll rotationally coupled to the first bending such that driving rotation of the first bending roll produces counter-direction rotation of the second bending roll and the first bending roll thereby controls an angle of mutual rotation of both of the first and second bending rolls; each of the first and second bending rolls further comprising a cut-off circumferential section in a plan view, wherein the cut-off circumferential sections define reduced axially symmetric lateral circumferential sections that define a gap for insertion and removal of bent material from between the first and second bending rolls.

2. The bending head according to claim 1, wherein each of the first and second bending rolls is configured with a rotationally-fixed toothed wheel, wherein the toothed wheels are in engagement to rotationally couple the second bending roll and the rotationally-driven first bending roll.

3. The bending head according to claim 1, wherein the cut-off circumferential section of each of the first and second bending rolls is formed by a straight planar cut-off segment.

Description

DESCRIPTION OF DRAWINGS

(1) The invention is schematically represented in the drawings, where:

(2) FIG. 1 shows an overall view of a bending head;

(3) FIG. 2 shows a plan view of the bending head at the moment of the bending rolls being opened for inserting a bent tube and setting the head for bending to the left side;

(4) FIG. 3 shows a plan view of the bending head after closing the bending rolls for inserting a bent tube for bending to the left;

(5) FIG. 4 is a plan view of the bending head with an inserted bent tube and the bending rolls turned to the initial position for bending by 85 to the left;

(6) FIG. 5 is a plan view of the bending head after performing a bend by 85 to the left (FIG. 4) with the indicated mutual position of mutually corresponding lightweight sections of the circumference of both bending rolls;

(7) FIG. 6 is a plan view of the bending head at the moment of rearrangement of the bending rolls for a bend to the right and with opened bending rolls for inserting the bent tube;

(8) FIG. 7 is a plan view of the bending head from FIG. 6 for closing the bending rolls after inserting the bent tube for a bend to the right;

(9) FIG. 8 shows the turning of the bending rolls for bending to the right by 85 with a minimal straight section between the preceding and following bends; and

(10) FIG. 9 shows carrying out a bend by 85 to the right with a minimal straight section between the preceding and following bends and with the final mutual position of the bending rolls.

DETAILED DESCRIPTION

(11) Reference will now be made to embodiments of the invention, one or more examples of which are shown in the drawings. Each embodiment is provided by way of explanation of the invention, and not as a limitation of the invention. For example features illustrated or described as part of one embodiment can be combined with another embodiment to yield still another embodiment. It is intended that the present invention include these and other modifications and variations to the embodiments described herein.

(12) The invention will become apparent from the description of an embodiment of a bending head for an automatic bending machine provided with a gripping device and, where appropriate, also with a positioning device of the bent material 0. The individual components of the machine, including the bending head, are provided with drives and are connected to a control mechanism of the bending machine, so that bends can be formed at a desired location of the bent material 0, in a desired direction, and at a desired angle. In addition, the bending head according to the invention is designed for carrying out bends in both directions, i.e. both to the right and to the left, and, at the same time, it is designed for performing bends immediately one after another, or only with a minimal length of straight sections between the individual bends.

(13) Generally, the bending head is situated at the end of the machine and contains the first bending roll 1, which is mounted rotatably about its longitudinal axis in the frame of the bending head and is connected to a source of rotary motion. The first bending roll 1 is provided along its circumference with a shape groove as shown in FIG. 1 for the bent material 0, such as a tube, a pipe, a bar etc.

(14) Below the first bending roll 1 on the bending head is transversely arranged a bending arm 20, which is situated with its longitudinal axis perpendicularly to the longitudinal axis of the first bending roll 1. The bending arm 20 is mounted on the bending head with one of its ends rotatably mounted about the longitudinal axis of the first bending roll 1.

(15) The second bending roll 2 is mounted rotatably about its longitudinal axis at the other end of the bending arm 20, whereby the longitudinal axis of the second bending roll 2 is parallel to the longitudinal axis of the first bending roll 1 and, at the same time, is perpendicular to the longitudinal axis of the bending arm 20.

(16) As a result, both bending rolls 1, 2 are rotatably mounted on the bending arm 20 about their parallel longitudinal axes, whereby the second bending roll 2, due to being mounted on the bending arm 20, is able to revolve around the first bending roll 1. The bending arm 20 is coupled to a drive for its bidirectional rotary motion, e.g., with a rotary motor 8, which is the drive of bidirectional bending.

(17) As is apparent from the above description, the bending arm 20 is disposed transversely with its longitudinal axis to both rolls 1, 2 and is rotatable about the longitudinal axis of the first bending roll 1, whereby the second bending roll 2 moves together with the bending arm 20.

(18) The first bending roll 1 is, with the aid of forced torque transmission means, rotatably coupled to the second bending roll 2. Consequently, the second bending roll 2, during the rotation of the bending arm 20 about the longitudinal axis of the first bending roll 1, continuously rolls away with its lateral surface substantially over the lateral surface of the first bending roll 1 or, if the two rolls 1, 2 do not directly abut each other with their lateral surfaces, it rolls away in the vicinity of the lateral surface of the first bending roll 1.

(19) So as to facilitate insertion and removal of the bent material 0 into and from the bending shape groove in each of the bending rolls 1, 2 and, above all, so as to minimize or completely eliminate straight sections of the bent material 0 between the individual bends so that the bends would directly follow each other, both bending rolls 1, 2 are provided with mutually corresponding (i.e. mutually functionally coordinated) reduced lateral sections X of their circumference, the reduced section X having a shape of a cut-off circular segment in a plan view, as shown in FIGS. 2 to 7.

(20) Mutual coordination of the function of the reduced circumference sections X of each of the bending rolls 1, 2 is achieved by the above mentioned forced torque transmission means between the two bending rolls 2, which thus rotate jointly counter-directionally. The reduced sections X are always located mutually axially symmetrically to the axis situated in a common tangent line to both bending rolls 1, 2. By joint forced mutually counter-directional motion of the two bending rolls 1, 2, it is possible not only to restrain or prevent possible skidding of the bending rolls 1, 2, particularly of the second bending roll 2, over the surface of the bent material 0, such as tubes, pipes, and to prevent possible damage to the surface of the bent material 0, but mainly it is possible to achieve synchronization of the movement and position of the reduced circumference sections X of the two rolls 1, 2 in accordance with the principles of axial symmetry, as will be described in greater detail further on in the section dealing with the function of the bending head.

(21) In the illustrated embodiment, the forced torque transmission means of both rolls 1, 2 are formed by a pair of toothed wheels 4 that are in mutual engagement, wherein one toothed wheel 4 is mounted below the first bending roll 1 and the other toothed wheel is mounted below the second bending roll 2. Each of the toothed wheels 4 is secured against being turned relative to the bending roll 1, 2 below which it is arranged, e.g., it is pinned to this roll or otherwise suitably connected. For the purpose of synchronized rotation of both rolls 1, 2, which is used during setting the mutual mirror position of the reduced lateral circumference sections X of each of the rolls 1, 2 when need arises to carry out a bend by a defined angle and with a minimal length of straight sections between the and both when inserting and removing the bent material 0 into and from the bending shape groove in each of the bending rolls 1, 2, the first bending roll 1 is coupled to the drive of its rotary motion, e.g., to a rotary motor 7, so that the rotary motion of the first bending roll 1 is mirror transmitted into the rotary motion of the second bending roll 2. The drive of the first bending roll 1 is provided with monitoring the position of the shaft, thus enabling the turning of the first bending roll 1, and, consequently, also of the second bending roll 2, into the accurately required axially symmetrical mutual position of the lightweight sections X of the circumference of both rolls 1, 2.

(22) The pair of bending rolls 1, 2 is further aligned with a bending support 3 for bidirectional bending, which is used to absorb reaction forces occurring during the bending of the bent material 0 between the bending rolls 1, 2 and their mutual movement both to the left and to the right due to the second bending roll 2 being mounted on the transverse bending arm 20. In the illustrated example of embodiment, the bending support 3 is composed of a flat body, which is swingingly mounted in the frame of the bending head, e.g., it is mounted at one end of a pivot 30 that is rotatably mounted in the frame of the bending head. At its other end, the bending support 3 is coupled to the drive of its rotary motion, e.g., at its other end it is provided with a control lever 31, to which is connected a movable part of a linear drive 6, whose fixed part is mounted on the frame of the bending head.

(23) The bending head operates such that when it is necessary to perform a bend to the left, the bending arm 20 turns so that the second bending roll 2 is situated (in a plan view) on the right of the first bending roll 1, see FIGS. 2 to 4, whereupon both rolls 1, 2 turn with their lightweight sections X of the lateral circumference against each other (by turning the first bending roll 1 about its longitudinal axis, whereby this rotary motion is transmitted via the toothed wheels 4 to the second bending roll 2). Subsequently, the bent material 0 is inserted into the gap formed by the reduced sections X in the lateral walls of the rolls 1, 2 and both rolls 1, 2 reversibly turn about their longitudinal axes, by which means the sections X in the lateral walls of the rolls 1, 2 tilt away from each other into a position which does not hinder subsequent bending, and so the bent material 0 is closed between the bending rolls 1, 2 to perform the bending operation. When inserting and removing the bent material 0 into and from the rolls 1, 2, the bending support 3 is tilted down not to hamper the handling operations in the vicinity of the rolls 1, 2. The bending operation itself is carried out by turning the bending arm 20 to the left about the longitudinal axis of the first bending roll 1 to reach the desired angle, see FIG. 5, and then backwards. After the bending arm 20 returns back, both rolls 1, 2 again turn against each other about their longitudinal axes until the reduced circumferential sections X in the lateral walls of the rolls 1, 2 face each other, thereby releasing the bent material 0 for further handling and for setting up for another bend.

(24) When it is necessary to perform a bend to the right, the bending arm 20 turns in such a manner that the second bending roll 2 is situated (in a plan view) on the left side of the first bending roll 1, see FIGS. 6 and 7, whereupon both rolls 1, 2 turn with their reduced circumferential sections X facing each other (by turning the first bending roll 1 about its longitudinal axis) and this rotary motion is transmitted via the toothed wheels 4 to the second bending roll 2. Subsequently, the bent material 0 is inserted into the gap formed by the reduced circumferential sections X and both rolls 1, 2 turn reversibly about their longitudinal axes, by which means the reduced circumferential sections X tilt away from each other to a position that does not hamper the subsequent bending, and so the bent material 0 is closed between the bending rolls 1, 2 for bending. When inserting or removing the bent material 0 into and from the rolls 1, 2 the bending support 3 is tilted down to allow unrestricted handling operations in the vicinity of the rolls 1, 2. The bending operation itself is carried out by turning the bending arm 20 to the right about the longitudinal axis of the first bending roll 1 to reach the desired angle and then backwards. After the bending arm 20 returns back, both rolls 1, 2 again turn about their longitudinal axes until the reduced sections X in the lateral walls of the rolls 1, 2 face each other, thereby releasing the bent material 0 for further handling operations and for setting up for another bend.

(25) If a change in parameters of bending is required, e.g., a change in the bend radius, or when the bent material 0 has a different size or shape of the inter-section, the bending rolls 1, 2 are replaced, and, in case of need, also the toothed wheels 4 are replaced, the bending support 3 and, as the case may be, the individual parts of the bending head 3 are adjusted to achieve the desired final and initial positions, whereby the program according to which the bending head is controlled, also depending on other parts of the bending machine, is modified or a new program is used etc.

(26) During a bending operation with the requirement for a minimal or zero straight section between the individual bends, it is necessary to make sure that the circumference of none of the bending rolls 1, 2 intersects the position of the bent material 0 from the preceding bend, because otherwise it would not be possible to perform the bend. Therefore, prior to carrying out the subsequent bend with a small or no spacing from the preceding bend, it is necessary for both rolls 1, 2, to turn with their reduced sections X into such an initial position that after performing a bend to reach the desired angle (the rolls 1, 2 mutually roll away from each other during the bending operation), both rolls 1, 2 end up with their reduced sections X in a common line, as shown in FIG. 5, which illustrates the final mutual position of both rolls 1, 2 and the reduced sections X when turning by an angle of 85, whereby the initial mutual position of both rolls 1, 2, and the reduced sections X for this bend is shown in FIG. 4.

(27) Modifications and variations can be made to the embodiments illustrated or described herein without departing from the scope and spirit of the invention as set forth in the appended claims.