Apparatus for manufacturing composite tubular articles

Abstract

A frame, a drive mechanism for rotating a mandrel, at least two spindles mounted to the frame, a tensioner, and a belt extending between the first and second spindles may be used to roll pre-preg strips or similar sheets of composite materials around the mandrel. The belt travels over the spindles, and the spindles guide the belt through changes in its direction of travel. The mandrel is mounted in the drive mechanism in contact with the belt, which changes its direction of travel around the mandrel. The lower surface of the belt bears against upper portions of the spindles, and the mandrel contacts the upper surface of the belt. As the drive mechanism rotates the mandrel, pre-preg sheets are fed between the mandrel and the belt and are thereby wrapped around the mandrel. The belt presses the pre-preg sheets against the mandrel. The wrapped mandrel may then be removed from the apparatus and cured in any suitable manner known in the art to produce a composite tubular article.

Description

DESCRIPTION OF A PREFERRED EMBODIMENT

As illustrated in FIG. 1, a first roller 10, a second roller 12 and a third 14 are generally parallel to one another. A belt 16 wraps around rollers 10-14. Resilient cords 18 connect the ends of belt 16 to one another. An electric drive motor 20 is connected to a drive shaft 22. A selectably releasably mounting 23 allows an operator to connect a mandrel 24 to drive shaft 22.

As illustrated in FIGS. 2-5, rollers 10-14 are rotatably mounted in a frame 26 and can be rotated freely with respect to frame 26. The ends of rollers 10 and 12 are received in bearing brackets 28 and 30, respectively. The ends of roller 14 are received in bearing brackets 32. Each of bearing brackets 32 is connected to a pneumatic cylinder 34.

A suitable controller (not shown) actuates pneumatic cylinders 34. An operator may control the actuation of cylinders 34 to either retract bearing brackets 32 and roller 14 or extend bearing brackets 32 and roller 14. Bearing brackets 32 slide in tracks 33 in response to actuation of cylinders 34. In the retracted position, roller 14 is closer to rollers 10 and 12 than in the extended position. Actuation of cylinders 34 is described below in further detail with respect to the method for using the apparatus to produce composite tubular articles. Each of bearing brackets 28 is connected to a pneumatic cylinder 36.

A suitable controller (not shown) actuates pneumatic cylinders 36. An operator may control the actuation of cylinders 36 to either retract bearing brackets 28 and roller 10 or extend bearing brackets 28 and roller 10. Bearing brackets 28 slide in tracks 37 in response to actuation of cylinders 36. In the extended position, roller 12 is closer to roller 10 than in the retracted position. In the extended position, the gap between rollers 10 and 12 is greater than the diameter of mandrel 24.

As illustrated in FIGS. 6-9, the above-described machine may be used for manufacturing a composite tubular article. Initially, an operator (not shown) actuates pneumatic cylinders 34 and 36 to retract rollers 14 and 12, respectively, thereby disposing rollers 10-14 in the relative positions shown in FIG. 6. When roller 14 is retracted, the slack in belt 16 can form a loop 38 that extends downwardly between rollers 10 and 12. Loop 38 is thus defined by the portions of belt 16 that extends over a line connecting the axes of rollers 10 and 12.

The operator then connects mandrel 24 to mounting 23 (FIGS. 1-3) and places mandrel 24 into loop 38. Mandrel 24 is preferably pre-heated before connecting it to mounting 23 to facilitate adhesion of pre-preg, as known in the art. In this position, it should be noted that the axis of mandrel 24 is vertically offset from the axis of rotation of motor 20. Drive shaft 22 has two universal joints 40 and 42 (FIGS. 2 and 3) that allow mandrel 24 to rotate in response to motor 20 while mandrel 24 is axially offset from the axis of rotation of motor 20 inside loop 38. Alternatively, a flexible drive shaft (not shown) would be suitable. In other embodiments, the motor may be mounted in vertically movable relation with respect to the frame and remain in axial alignment with mandrel 24 as mandrel 24 is moved vertically into or out of loop 38. In still other embodiments, motor 20 and mandrel 24 may remain in fixed vertical relation with respect to the frame, and rollers 10 and 12 may be mounted in vertically movable relation with respect to the frame. Any such arrangement that allows mandrel 24 to be easily inserted into and removed from loop 38 would be suitable.

The operator actuates pneumatic cylinder 36 to extend roller 12, thereby disposing rollers 10-14 in the relative positions shown in FIG. 7. In this position, the gap between rollers 10 and 12 is less than the diameter of mandrel 24. Mandrel 24 is thus retained in loop 38 beneath rollers 10 and 12. The operator then actuates pneumatic cylinder 34 to extend roller 14, thereby disposing rollers 10-14 in the relative positions shown in FIG. 8. Extending roller 14 substantially eliminates slack in belt 16. Resilient cords 18 further contribute to the tension in belt 16.

The operator then actuates motor 20 using a suitable controller (not shown). Mandrel 24 rotates in response to rotation of motor 20 via drive shaft 22. Belt 16 rotates in response to rotation of mandrel 24 because the tension in belt 16 promotes frictional engagement between mandrel 24 and belt 16. As mandrel 24 rotates, the operator feeds a pre-preg sheet 44 into the gap between rollers 10 and 12. Pre-preg sheet 44 is pinched between belt 16 and mandrel 24. Pre-preg sheet 44 will adhere to mandrel 24 and wrap tightly around 24. The operator may successively feed pre-preg sheets 44 to built up multiple-plies on mandrel 24. The controller that operates motor 20 preferably does not rotate motor 20 in a continuous manner, but rather rotates motor 20 a sufficient number of revolutions in response to each actuation by the operator to completely wrap a pre-preg sheet 44 around mandrel 24. When motor 20 has rotated this number of revolutions, thereby disposing belt 16 in the position shown in FIG. 8, the controller reverses the direction of motor 20 to return belt 16 to its initial position. Motor 20 is preferably not rotated continuously or for a greater number of revolutions because it is preferred that cords 18 do not pass between rollers 10 and 12. Nevertheless, in certain embodiments, belt 16 may travel a greater distance. Although in the embodiment described herein, the controller controls the number of revolutions of motor 20, the operator may control motor 20 manually in certain embodiments, energizing motor 20 for a period sufficient to wrap pre-preg sheet 44 around mandrel 24.

The operator actuates pneumatic cylinder 36 to retract roller 12, thereby disposing rollers 10-14 in the relative positions shown in FIG. 9. The tension in belt 16 raises the wrapped mandrel 24 to a position in which it is easily accessible to the operator. The operator may then remove the wrapped mandrel 24 from mounting 23. The wrapped mandrel 24 may be cured in any suitable manner known in the art, such as by placing it in an oven or autoclave. After curing, the resulting composite article may be removed from mandrel 24, as known in the art.

Although the machine of the present invention may be used for forming any type of tubular composite article, it is particularly suitable for forming tubular composite articles having multiple tapers or having contours or non-uniform tapers. Belt 16 conforms to such contours and presses prepreg sheet 24 firmly against mandrel 24 in a substantially uniform manner along the entire length of mandrel 24. To facilitate this uniform application of pressure, belt 16 may be made of any suitable pliable sheet-like material. The material is preferably sufficiently flexible, pliable or elastic to conform to the contours of the mandrel but also sufficiently rigid to travel in response to rotation of mandrel 24 without stretching excessively. Furthermore, the material is preferably sufficiently slippery to resist adherence of pre-preg but provides sufficient friction to rotate in response to rotation of mandrel 14. A material that has been used with suitable results is a woven matting known as "shade cloth," which is used for covering patios. This material has a fill comprising numerous closely-spaced, relatively thin, plastic fibers interwoven with a weft comprising a yarn having a lesser number of relatively thicker and stronger plastic fibers with the yarn strands spaced relatively further apart. Such shade cloth is sold under the brand name SARLON and is manufactured by Sadon Industries, Ltd. of New South Wales, Australia. Pre-preg does not readily adhere to the coarsely woven plastic. It is also believed that the lighter fill and heaver weft promotes uniform application of pressure against the mandrel. Belt 16 rotates in a non-uniform manner in response to rotation of a tapered mandrel; the taper causes certain portions of belt 16 to travel a different distance than other portions. Belt 16 will therefore be stretched diagonally. When the material described above is stretched diagonally, the weft fibers remain essentially parallel to one another and are displaced only axially with respect to one another. Essentially only the fill fibers are displaced diagonally, i.e., displaced from their perpendicular orientation with respect to the weft fibers. The heavier and thicker weft yarn strands, which thus contact the mandrel to a significantly greater extent than the fill fibers, remain in contact with essentially the same portion of the mandrel throughout the rolling step. In other words, a single weft strand does not significantly stretch diagonally across the mandrel but rather remains essentially parallel to the mandrel during the rolling step. The weft strands, which are spaced about one-eighth of an inch apart, are therefore extremely responsive to changes in mandrel diameter that occur over distances as small as one-eighth of an inch. Nevertheless, the belt conforms to changes in mandrel diameter regardless of the rate of taper because the fill fibers between the weft fibers also contact the mandrel to a certain extent. Indeed, it is believed that the weft fibers contact the mandrel to a greater extent when the belt is stretched diagonally, thereby automatically providing additional pressure in response to a change in taper.

In the embodiment described above, the tensioner that applies tension to belt 16 comprises resilient cords 18 as well as vertically movable roller 14. Nevertheless, in certain embodiments, the tensioner may comprise other movable mechanisms and/or stretchable resilient members. As illustrated in FIG. 10, a continuous belt 46 not having resilient cords may be used if the tensioner otherwise applies sufficient belt tension.

In the embodiment described above, the spindles between which loop 38 extends comprise rollers 10 and 12. Nevertheless, in certain embodiments, the spindles may comprise non-rotatable, low-friction elements or protrusions, over which belt 16 glides rather than rolls.

Obviously, other embodiments and modifications of the present invention will occur readily to those of ordinary skill in the art in view of these teachings. Therefore, this invention is to be limited only by the following claims, which include all such other embodiments and modifications when viewed in conjunction with the above specification and accompanying drawings.

Claims

1. An apparatus for wrapping material around a mandrel, said apparatus comprising:

a frame;

first and second spindles connected to said frame;

a belt in contact with a portion of each of said first and second spindles, said belt movable in a belt movement direction, said belt having two ends and including a resilient member connecting said ends; and

a drive mechanism having a rotatable driven portion with an axis of rotation extendable perpendicular to said belt movement direction, said mandrel mountable on said driven portion said belt and said resilient member movable in said belt movement direction as a result of actuation of said driven mechanism.

2. The apparatus claimed in claim 1, wherein said belt has an upper surface and a lower surface, portions of said lower surface of said belt are in contact with portions of each of said first and second spindles when a portion of said upper surface of said belt is in contact with said mandrel.

3. The apparatus claimed in claim 1, wherein said first and second spindles are rotatably mounted on said frame.

4. The apparatus claimed in claim 1, wherein a plurality of elastic cords connect said ends of said belt.

5. The apparatus claimed in claim 4, further comprising a third spindle, wherein said belt and elastic cords extend around said first, second and third spindles.

6. The apparatus claimed in claim 1, further comprising a third spindle movably mounted to said frame, wherein said third spindle is movable toward and away from said first and second spindles.

7. The apparatus claimed in claim 6, further comprising an actuator for selectably moving said third spindle toward and away from said first and second spindles.

8. The apparatus claimed in claim 7, wherein said actuator is pneumatically operated.

9. The apparatus claimed in claim 8, wherein a plurality of elastic cords connect said ends of said belt.

10. The apparatus claimed in claim 9, further comprising a third spindle, wherein said belt and elastic cords extend around said first, second and third spindles.

11. The apparatus claimed in claim 1, wherein at least one of said first and second spindles is movably mounted to said frame and movable toward and apart from the other of said spindles.

12. The apparatus claimed in claim 11, wherein said first and second spindles are rotatably mounted on said frame.

13. The apparatus claimed in claim 11, further comprising an actuator for selectably moving at least one of said first and second spindles toward and apart from the other of said spindles.

14. A continuous loop belt for use in a machine for wrapping material around a mandrel, the belt comprising:

a pliable sheet panel of coarse woven plastic fibers, the panel having sufficient pliability to conform to changes in mandrel diameter including multiple tapers or contours or non-uniform tapers in order to press pre-preg sheets against the tapered mandrel along its entire length, the panel having ends adapted to be connected together, a lower surface adapted to engage support spindles and an upper surface adapted to engage the mandrel, wherein said panel is formed at least partly of closely spaced, relatively thin, plastic fibers interwoven with a weft comprising a yarn having lesser number of relatively thicker stronger plastic fibers with the yarn strands spaced relatively farther apart; and

elastic tensioning means connecting the ends of said panel together to form a continuous loop for passing around the support spindles and partially around the mandrel and enabling the belt to stretch enabling portions of the belt to travel different distances to conform to a taper on the mandrel to form composite articles having multiple tapers or contours or non-uniform tapers.

15. A belt according to claim 14, wherein said panel upper surface is sufficiently slippery to resist adherence of pre-preg; and said panel upper surface providing sufficient friction to be driven by said mandrel.

16. A belt according to claim 14, wherein said elastic tensioning means comprises a plurality of elastic cords.

17. A method of making a belt for use in a machine for wrapping material around a mandrel, comprising:

providing a generally rectangular pliable sheet panel of coarse woven plastic fibers, the panel having sufficient pliability to conform to changes in mandrel diameter including multiple tapers or contours or non-uniform tapers in order to press pre-preg sheets against the tapered mandrel along its entire length, the panel having ends adapted to be connected together, a lower surface adapted to engage support spindles and an upper surface adapted to engage the mandrel; providing elastic tensioning means adapted to connect the ends of the panel together, wherein the step of providing a generally rectangular pliable sheet panel comprises providing the panel formed at least partly of a woven fabric of closely spaced, relatively thin, plastic fibers interwoven with a weft comprising a yarn having lesser number of relatively thicker stronger plastic fibers with the yarn strands spaced relatively farther apart; and

connecting the ends of the panel together by connecting the tensioning means to the ends of the panel thereby forming the belt into a continuous loop for mounting on the spindles, the elastic tensioning means enabling portions of the belt to travel different distances to conform to a taper on the mandrel to form composite articles having multiple tapers or contours or non-uniform tapers on the mandrel.

18. A method according to claim 17, wherein the step of providing elastic tensioning means comprises providing a plurality of elastic cords.

19. A method according to claim 17, wherein: said step of providing said panel includes providing said panel upper surface is sufficiently slippery to resist adherence of pre-preg; and said panel upper surface having sufficient friction to be driven by said mandrel.