This is a National Stage application under 35 USC 371 of PCT/AU2004/000726, filed 23 Jun. 2003.
This invention relates to a method and apparatus for rectifying by reduction the diameter of round pipe or tubing with the secondary effects of straightening and rounding. More particularly, it relates to such methods and apparatus employing for the purpose a plurality of rollers.
For a variety of reasons, in the fabrication of pipe and tubing by rolling up a tubular form from a flat strip or skelp and seam welding the abutting edges, it is impossible to maintain precise control of the finished diameter. Particularly in larger diameters and where lighter gauge material is used, for example in diameters above 150 millimetres or where the wall thickness is less than 2% of diameter, pipe and tubing fabricated in this way may not be perfectly round. Some variation from straightness is also frequently experienced. It is well known that standards for some forms of pipe and tubing prescribe quite liberal tolerances.
Many applications exist in which pipe and tubing must meet precise specifications in relation to diameter, roundness and straightness and a variety of methods has therefore been developed to correct defects in these criteria. Where the diameter of pipe or tubing has to be increased, it is common to pass a cylindrical die of some suitable hard material and having an external diameter somewhat greater than the internal diameter of the pipe or tube through the lumen of the pipe or tube to stretch it. Where more than a minor correction is required, consecutive passes of dies of increasing diameter may be required, the internal surfaces of the pipe or tube lumen may require lubrication, scoring of the internal surfaces is common and some degree of wall thinning will occur. The process has the advantage of being operable on a continuous basis. In another method, the internal diameter of pipe or tubing is increased by subjecting the interior of short lengths to hydraulic pressure to expand it into an enclosing female die. Use of this method is normally confined to short lengths of pipe or tubing and has the disadvantages of slowness and the fact that it cannot be operated on a continuous basis. Both methods are well known in the art.
Where the diameter of pipe or tubing is required to be decreased, it is common to roll it down by passing the pipe or tubing through a plurality of concave rollers arranged such that their diameters extended meet at a common point and with their collective concavities more or less forming a complete circle slightly smaller than the final diameter of pipe or tubing required. Equally-spaced rollers are supported on shafts parallel to tangents to the surface of the pipe and tubing and are driven in rotation while the pipe or tubing to be resized is fed between them and is thereby cold worked to a smaller diameter. Unless the pipe or tubing is stretched at the time, some degree of wall thickening will occur.
One example of this method appears intended for use with only pipe or tubing of smaller diameters and the fact that the method includes a provision for final sizing to be performed by drawing the rolled pipe or tube through a female sizing die is indicative of the limited control of worked diameter available. During this method only relatively small decreases in diameter may be achieved in a single pass, normally of the order of 0.2 to 0.4 mm, that what is effectively a wiping action of the sides of the roller concavities may scuff or mar the external surfaces of pipe or tubing (an important factor in stainless steel products), and the fact that the method is relatively ineffective in large, relatively thin-walled pipe or tubing. The scuffing or marring of external surfaces is particularly pronounced in larger diameter pipe or tubing where the method is normally performed using only two rollers having deep concavities. Obviously, as suggested in the example cited, the diameter of pipe or tubing may be reduced by drawing it through a female sizing die. Where this method is employed, the pipe or tube may require lubrication, the external surface of the pipe or tubing is frequently scored by asperities in the die or picked up by the die and some wall thickening and elongation may occur. In another method, both internal and external dies are used in what is normally a second or third manufacturing operation.
Another example of diametral reduction by rolling, a short length of pipe or tubing is rotationally supported by clamps only at the ends and a plurality of cylindrical rollers is brought to bear against the outer surface of the length of pipe or tubing while it is rotated, thereby reducing its diameter and, if required, rendering it into tapered form. The method is applicable only to short lengths of pipe or tubing and obviously cannot be operated as a continuous process. Of relevance is a method in which thin-walled metallic tubing is formed from a solid blank in an Assel rolling mill. In this case, provision is made to vary the wall thickness of the formed tubing by adjusting the radial positions of a plurality of forming rollers. Adjustment is effected by increasing the skew of short shafts upon which the forming rollers are rotationally supported, thereby radially displacing the rollers inwardly or outwardly. The ends of the short shafts are rotationally supported in suitable bearings accommodated within the ball parts of ball and socket joints, which ball parts move in complementary sockets to permit skewing of the shafts. The rollers are short and are provided with shoulders which work on the blank from which the tubing is formed.
In many tube rolling methods, a mandrel is inserted into the lumen of a tube to be rolled and the tube worked by a plurality of rollers against the mandrel. Applications are also common in which laminated pipe or tubing is made by drawing one piece of pipe or tubing into the lumen of another. Where, for example, the inner pipe or tube is made from a polymer material, it is common to temporarily reduce its diameter by passing it between concave rollers or through a female sizing die in the manner described and, when positioned inside a pipe or tube of larger diameter, expanding it by the application of internal fluid pressure to make a tight fit within the outer pipe or tube. Additionally, to ensure a more secure capture of the inner pipe or tube, the outer pipe or tube may subsequently be reduced in diameter using one of the methods described. Where both the inner and outer pipes or tubes are of metal, the inner is captured simply by reducing the diameter of the outer.
The present invention provides a method and apparatus for reducing the diameter of pipe or tubing; that is precisely adjusted to produce an accurate finished diameter. The method and apparatus may be used with either continuous or discrete lengths of pipe or tubing. As a result of using the method and apparatus, a straightening effect is achieved without marring the external surface of the pipe or tubing. Using this invention provides a greater degree of reduction in diameter in a single pass than other systems resulting in properly rounded pipe or tubing properly round without the necessity to lubricate the pipe or tubing. The method and system are effective in treating a full range of diameters in both thin and thick-walled pipe or tubing.
In one aspect of the present invention, the diameter of pipe or tubing is reduced by passing it through a rotating apparatus comprising a supporting cylinder in which is provided a plurality of closely and equally-spaced, skewed, long, narrow, parallel cylindrical rollers of a rigid, hard material. The skewed rollers are brought to bear on the external surface of the pipe or tubing as it passes through the apparatus. The rollers comprise a first and second end and are supported in a cylindrical array with their ends on pitch circles of equal diameter and are rotationally supported in suitable bearings provided in first and second end flanges of the supporting cylinder. The first and second end flanges are provided with apertures to permit the ingress and egress of the pipe or tubing to be treated.
One or both or the end flanges are capable of rotational displacement within the ends of the supporting cylinder, thereby adjusting the degree of skew of the rollers which, although they are displaced relative to the longitudinal axis of the supporting cylinder, remain in planes parallel to the longitudinal axis. The bearings of the rollers are themselves supported in part-spherical bushings which are, in turn, accommodated within complementary cups formed in the end flanges such that the rollers may continue to be rotationally supported in the end flanges when in their skewed positions. The supporting cylinder is itself rotationally supported in one or more bearings which permit it to rotate about its longitudinal axis, driven by a suitable driving motor.
In operation, the degree of skew of the rollers is adjusted to bring narrow, centrally-located contact zones of the rollers to bear against the outer surface of the pipe or tubing with a desired force. As the pipe or tubing passes at a steady speed through the cylindrical array of rollers, the supporting cylinder is rotated by its driving motor, causing the contact zones of the rollers to describe continuous, parallel, overlapping, helical paths along the external surface of the pipe or tubing, locally applying a compressive force to the pipe or tubing in excess of the yield stress of its material and thereby causing the pipe or tubing to adopt a set at a smaller diameter. The passage of the contact zones of the rollers over the outer surface of the pipe or tubing causes the surface to be attractively burnished without marring, any out-of-roundness of the pipe or tubing is simultaneously corrected and, should the pipe or tubing require straightening, its restraint in correct alignment as it passes through the rollers will effect this.
The various aspects of the present invention will be more readily understood by reference to the following description of preferred embodiments given in relation to the accompanying drawings in which:
a, 1b and 1c are partial cross-sectional views of the supporting cylinder showing various positions of one of the cylindrical array of the rollers;
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In alternative embodiments, the pulley is replaced with a sprocket or gear (not shown) and the supporting cylinder is driven in a rotational sense by drive forces applied through one or more suitable chains or gears. As pipe or tubing to be treated 7 passes through the interior of the supporting cylinder and through the rotating cylindrical array of rollers (not shown), the contact zones of the rollers pass over the external surface of the pipe or tubing following continuous, parallel, overlapping, helical paths a typical one of which is indicated by arrow 24. It can be readily demonstrated that the power required to drive the rollers against the pipe or tubing is quite low and, even when the pipe or tubing is being heavily worked, is normally considerably less than the power required by conventional methods.
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In an alternative embodiment (not shown), the apparatus is made in multi-stage form with two or more of the units operated in tandem such that one of each or all units are employed to reduce the diameter of the pipe or tubing, correct its out-of-roundness or straighten it. The units are optionally operated with a common direction of rotation or with alternate units rotating in the opposite sense. It will be appreciated from further inspection of
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Sensing means in the form of opposed pairs of rollers attached to the inner ends of radially-arranged linear transducers are employed to measure the finished diameter of the pipe or tubing emerging from the apparatus, the rollers being urged into contact with the pipe or tubing by suitable springs. In a second embodiment, sensing means in the form of a laser micrometer are employed to measure the finished diameter of the pipe or tubing emerging from the apparatus. In a third embodiment, sensing means in the form of opposed pairs of proximity sensors, each the sensor measuring the gap between its reference surface and the external surface of the pipe or tubing are employed to measure the finished diameter of the pipe or tubing emerging from the apparatus.
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The rolling process performed by the apparatus provides accurate control of the external diameter of pipe or tubing; it requires no lubrication of the external surface of the pipe or tubing; it requires only low power for its operation; it leaves the external surface of the pipe or tubing burnished and easily polished; it is not limited by the diameter, length or wall thickness of the pipe or tubing; it may be operated with a greater lineal speed of the pipe or tubing than the output speed of a tube forming mill and the two may thus be operated in conjunction; it may be performed by multiple the rolling units operated in tandem; it exerts a rounding and straightening effect upon the pipe or tubing; it may be operated under automatic control; it may be employed with continuous lengths of the pipe or tubing or with discrete lengths; and it provides a greater reduction in external diameter of the pipe or tubing per pass than conventional rolling processes.
The present invention comprises a method for adjusting the dimension of a pipe or tube. In one embodiment of the method, the pipe or tube is passed in continuous advance through a plurality of cylindrical rollers arranged in a parallel-cylindrical array. The plurality of cylindrical rollers is contained within a supporting cylinder. The rollers are skewed to bring the rollers into forceful contact with the external surface of the tube. The parallel-cylindrical array of rollers is rotated at a controlled speed. The degree of skewing of the rollers is controlled as follows: by first sensing the linear speed of the tube, and then controlling the speed of rotation of the rollers in relation to the linear speed of the tube. The speed of rotation of the rollers can be manually controlled or automatically controlled.
During this method, sensors sense the straightness of the tube and improve the straightness by controlling the height of a means for supporting the apparatus. The height of a means for supporting the apparatus can be controlled manually or automatically. In one aspect of this invention, the tube is not supported internally by mandrels so that controlling the pressure on the tube is necessary to prevent collapse of the tube. In another aspect of the invention, the speed of rotation of the rollers is controlled in response to the linear speed of the tube and degree of skewing of the rollers. Again the linear speed can be controlled either manually or automatically.
The rolling process of this invention can be applied to continuous lengths of the tube or to discrete lengths of pipe or tube. The path of the rollers impacts the resulting diameter of the pipe or tube. The central contact zones of the rollers describe continuous, parallel, overlapping, helical paths along the external surface of the pipe or tube and a compressive force in excess of the yield stress of its material is applied to the external surface of the pipe or tube. It is the compressive force that ultimately causes the pipe or tube to set at a smaller diameter. In addition to effecting a smaller diameter within a pipe or tube, the passage of the central contact zones of the rollers over the outer surface of the pipe or tube also corrects any out-of-roundness of the pipe or tube and causes the external surface to be burnished.
One aspect of the method of the present invention comprises the use of sensing means to sense three properties of the invention, first, sensing the speed of rotation of the rollers, second, sensing the height of the supporting means, and third, sensing the degree of skewing of the rollers. Each of these properties determines the resulting diameter and finish of the pipe or tubing. In another aspect of this invention, the tube is passed through a plurality of parallel-cylindrical arrays of rollers arranged within a supporting cylinder wherein the arrays can be rotated in alternating directions. The steps of this method can be repeated so that each pass of the tube through the array further reduces the diameter of the tube. Advantageously, the method need not include the step of lubricating the tube. In one embodiment, the method is incorporated into a tube-forming mill to provide an immediate post-fabrication treatment of the tube.
Number | Date | Country | Kind |
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2003903206 | Jun 2003 | AU | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/AU2004/000726 | 6/1/2004 | WO | 00 | 12/22/2005 |
Publishing Document | Publishing Date | Country | Kind |
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WO2004/112978 | 12/29/2004 | WO | A |
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Number | Date | Country | |
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20060174669 A1 | Aug 2006 | US |