KR20060048118A - Knitting Tool Bars - Google Patents

Abstract

The present invention relates to a knitting tool bar of a knitting machine comprising a body made of fiber reinforced composites and a method of making the same. The body has two or more open shapes arranged to form a wall surrounding the hollow space extending in the longitudinal direction. The Summary is not intended to limit the scope of the invention or to limit the detailed description.

Description

Knitting tool bar {Knitting tool bar}

1 is a diagram showing a knitting portion of a warp knitting machine;

2 is a diagram showing a press mold making an open shape;

3 is a view showing the shape of the guide bar;

4 is a view showing a guide bar having two shapes;

5A is a view of a needle bar;

FIG. 5B is a view showing an enlarged portion of FIG. 5A; FIG.

6A is a perspective view of a needle bar;

FIG. 6B is an enlarged view of a portion of the needle bar of FIG. 6A.

<Brief description of symbols for the main parts of the drawings>

1: guide bar 2: sinker bar

3: slider bar 4: needle bar

10: shape 11: shape

12: hollow space 20: auxiliary fixing element

63: Additional Shape 67: Groove

This application claims priority to European Patent Application No. 04 012 519.7, filed May 27, 2004, pursuant to US Pat. No. 119, which is incorporated herein in its entirety.

The present invention relates to a knitting tool bar of a knitting machine with a body made of fiber-reinforced composite, wherein the body has a wall enclosing a hollow space extending in the longitudinal direction.

Knitting machines have several bars that carry knitting tools. For clarity, a "knitting tool" includes all elements related to the knitting process, such as needles, guide needles, comb plates, pile sinkers, knock-over sinkers, and the like.

The bar extends to a fairly long length, especially beyond the entire length of the knitting machine. In each case it has a length of almost 6 meters. Even at shorter lengths there is a need for the stability of the bar's machine. In particular, the bar should have any stiffness and should not vibrate. However, it is desirable to keep the weight of the bar as small as possible, because each cycle of the knitting machine must be accelerated. For acceleration, the smaller the weight, the less the force and the higher the speed of the knitting machine.

The bars of a knitting machine generally consist of light metals such as magnesium or aluminum. Although these materials are relatively lightweight, the bars made of these materials still have significant mass. Thus, in DE 38 40 531 C1 it is proposed to produce the bars with reinforcing compounds. At its end the bar has a hollow shape with a hollow space entirely restricted by a closed circumferential wall. Two attachment features are formed on the outside of the hollow shape, which attachment features are used for the clamping attachment of the threaded guide holder or holding arm.

In the embodiment of the bar, while a significantly smaller weight and a significantly higher mechanical load capacity can be achieved, the load capacity is still limited.

In DE 41 11 108 C2, it is proposed to form a bar with reinforcing composites, the hollow shape consisting of a composite band raised flatly around each other for each mat knitted or woven into reinforcing fibers. The cast body is disposed in the hollow space so that the cast body is permanently placed in the hollow space and mounts a threaded specimen which is a female member for the attachment element.

However, this embodiment has disadvantages such as an increase in mass due to the cast body. However, the female threaded specimen is precisely positioned before it. Repositioning backwards is virtually no longer possible.

The present invention provides a bar having a low weight and high mechanical durability.

The present invention therefore provides a bar of the above-mentioned type in which the body is assembled from at least two open forms.

The open form is accessible from all sides. Thus, the body is first manufactured by assembling the shapes. The hollow space is first formed. This means that prior to assembly, the shape is freely accessible from all sides, including its side, so that multiple step measurements can be used before the shape is assembled. Thus, this can avoid such things as the necessity of arranging the threaded portion of the arm member through preventive measures in a position that will not be needed at all later. Any excess material region on the body needs to withstand if the body is provided directly in a hollow shape, for example through a drawing process.

At least one profile is preferably molded into the casting. It can be appreciated that the "strength" of the bar increases at a predetermined rate within any limit of the force on which the shape is molded. If the body is assembled from the shape, all shapes can be produced in a high strength manner that is produced in a press. In the press, the required pressure is controlled and applied as necessary. The body has a closed hollow shape, which can only be achieved by introducing a core. Even if the body is lengthened, it is quite difficult to remove the core again. An alternative is to leave the core in the body (DE 41 11 108 C2). In this case, however, the weight increases.

The shapes preferably have at least one connecting surface on which they lie flat against each other. A fairly large contact surface can be provided through the connecting surface, whereby the connecting portion is formed between two or more shapes with adequate reliability.

The shapes are preferably attached to each other. Significantly high bearing forces result in low final strength of adhesion, since such adhesion is formed in large areas above the connection surface.

At least one shape is provided in the hollow space with the auxiliary fixing attachment. The auxiliary fixing attachment may be attached to the shape before the shapes are joined to each other. Such auxiliary fixing elements need not be taken into account in the manufacture of the shape. Instead, if it is still freely accessible, it can later be confined to a hollow space and replaced within the shape attached to it.

The auxiliary fixing element is preferably arranged in an area where the two shapes overlap each other. This embodiment has several advantages, for example, the strength of the body is particularly strong in areas where the two shapes are placed on top of the other, and the auxiliary fastening element cannot be used to attach to the attachment, eg For example, a thread guide holder or the like cannot be used to attach to a bar, but can be used simultaneously to form and reinforce the connection between two shapes.

The secondary fastening element is preferably fixed with an adhesive. This adjustment is more convenient than everything else that makes the bar. If the auxiliary fixing element is attached to the inside of the shape, it can maintain its position at the time of installation. An auxiliary fastening element, for example a nut, provides a thread in which the screw bolt is later screwed on. Of course, in this case the hole needs to be made through the shape or shapes.

The shape has grooves outwardly running in the opposite direction in the longitudinal direction between which wave-shape flanges are arranged. The groove is used to support the needle, for example to support a knitting needle. These flanges support the needles in the longitudinal direction with respect to each other and form a space between adjacent needles. The strength is increased because the flanges run in a wave form. The shape consists of a reinforced composite, for example a carbon fiber-reinforced composite, which basically has one "hill" and at least part of the fiber is of a shape that is not grooved. May be guided in part. The flange can be increased to the extent that it is resistant to damage.

The general longitudinal groove running in the longitudinal direction is preferably arranged in an additional shape disposed on one side of the shape disposed outside the hollow space. The longitudinal grooves are used, ie to support the projections of the knitted needles in which the knitted needles are fixed in the longitudinal direction with respect to the knitted needle bar. The fragility of the body is avoided because no longitudinal groove is made in the shape surrounding the hollow space. The bar is in a particularly stable state and nevertheless performs the function of supporting needles such as knitting needles.

It is preferable that at least one shape consists of a resin penetration process material. The resin permeation processing material is, for example, a semi-finished product in which fibers such as carbon fibers and a composite are mixed in a predetermined ratio. Thus, the fibers are already present in the composite in some way. The composite forms a matrix reinforced by fibers. The resin penetrating workpiece is used in the form of a mat that can be inserted into a press. It is possible to distribute the fibers of the composite matrix better by the resin penetrating workpiece than by adding the composite in the press working. Often after heat-pressing, the resin penetrating workpiece hardens and eventually forms a final shape. Unnecessary projections of the resin penetrating workpiece may be perforated during or after press working, and may be cut or cut in a separate processing operation.

It is preferable that the said resin penetration process material is UD (unidirectional) resin penetration process material as an example. In the UD resin impregnated workpiece, the fiber runs completely in one direction. The shape made of the resin permeation processing material increases the tensile strength in that direction. Thus, there is a significant possibility of affecting the strength of the bar through the choice of fiber direction.

The shape consists of at least two resin penetrating workpieces placed on top of each other, and the fiber direction is at an angle. The angle may for example be 90 degrees. In this case, the tensile strength and the pressing strength increase in all directions.

The at least one resin penetrating workpiece preferably has a fiber direction running in the longitudinal direction, and the at least one resin penetrating workpiece preferably has a fiber direction running in the direction crossing in the longitudinal direction. This embodiment is advantageous for the entire bar with a guide. In one cycle, these bars move back and forth in the direction intersecting the longitudinal direction and the longitudinal direction. The fibers of the resin penetrating workpiece provide sufficient strength in both directions. Through the alignment for the purpose of the resin penetration processing material, the numerical stability of the bar is maintained in all fiber directions, for example, no dimensional change with temperature occurs in the longitudinal direction or in the direction crossing the longitudinal direction.

On at least one outer surface of the shape, the resin penetrating workpiece is arranged in the fiber direction running crosswise in the longitudinal direction. This is particularly useful in the grooves described above at the connection to the knitted needle bar, since the flanges laid in between have at least a layer on the surface of which the fibers and the fibers are laid down along the direction of the flanges. The strength of the flange is significantly increased.

It is preferable that the main body has a higher fiber component than the resin penetration processing material. This is achieved by applying a pressing force which causes part of the composite to be pressed out of the press in the course of producing at least one shape. This is facilitated by packing the prepared resin penetration processing material for press working into pieces of fabric fibers. Thus, the composite is guided to the surface more quickly and beyond the surface to the edge of the resin penetrating workpiece. If the resin penetrating workpiece has a fiber content of, for example, 60% through high pressing force, the body is provided with a fiber content of about 70%.

At least one shape preferably has a curved portion. The curved portion has greater strength than the flat portion. The curved portion may be manufactured through a press process.

It is also useful when at least one shape has offset reinforcing strips spaced from the hollow space. Such reinforcing strips can easily be accommodated so that the space is used in a knitting machine. The reinforcing strip can be used to assist in positioning the bar in a knitting machine. Such reinforcing strips can be easily molded at the time of molding in a press.

In a preferred embodiment, the shapes have a shape that can be placed on each other in only one alignment. The shapes are then self-centered to fit, ie the shapes are joined together in one alignment. For example, this shape can be achieved by having protrusions or bends in which the shapes are joined to one another.

The present invention relates to a knitting tool bar of a knitting machine comprising a body composed of a fiber-reinforced composite. The body has two or more opening shapes arranged to form a wall surrounding the hollow space extending in the longitudinal direction.

According to the invention, at least one shape is formed from a cast.

According to a feature of the invention, the shape has at least one connecting surface arranged to be structured and laid flat to each other.

According to another feature of the invention, the shapes may be attached to each other.

The knitted tool bar has an auxiliary fastening element connected to at least one shape. The auxiliary fastening element can be arranged in a hollow space. Furthermore, the auxiliary fastening element is arranged in an area where the two shapes overlap each other. The auxiliary fixing element can also be glued and connected.

According to another feature of the invention, the additional shape has a groove on its outer side which runs crosswise in the longitudinal direction between which the corrugated flanges are arranged. The additional shape is disposed on the side of one of at least two shapes outside of the hollow space, the additional shape having a longitudinal longitudinally oriented common longitudinal groove connected to the groove.

In addition, at least one of the two or more shapes consists of the resin penetration processing material. The resin penetration processing material may be a unidirectional resin penetration processing material. In addition, the at least one shape may be formed of at least two shapes placed on top of each other. The at least two resin penetration processing materials are arranged such that at least two resin penetration processing materials have a predetermined angle. The at least one resin penetrating workpiece may have a fiber direction running in the longitudinal direction, and the at least one resin penetrating workpiece may have a fiber direction running in a direction crossing the longitudinal direction. Further, the at least one resin penetrating workpiece has a fiber direction running in a direction crossing the longitudinal direction and is arranged on at least an outer surface of the shape. The main body has a higher fiber ratio than the resin penetration processing material.

According to the invention, at least one shape has a bend.

According to another feature of the invention, at least one of the two or more shapes may have an offset reinforcing strip spaced from the hollow space.

Two or more shapes are machined so that two or more shapes can be connected to each other by one alignment.

The present invention relates to a method for manufacturing a knitting tool bar of a knitting machine, the step of forming at least two open shapes, defining at least two shapes defining the open space extending in the longitudinal direction and forming a body Arranging. The body consists of a fiber reinforced composite.

According to the invention, the manufacturing method includes the step of forming an additional shape consisting of a groove extending to cross in the longitudinal direction and a plurality of corrugated flanges separated by the longitudinal groove. The manufacturing method includes disposing an additional shape on one side of at least two shapes outside of the hollow space. The method includes inserting a knitted needle into a groove located between the corrugated flanges and inserting a portion of the knitted needle into a longitudinal groove.

According to the invention, the body may form a guide bar.

According to another feature of the invention, the body forms a sinker bar.

According to another feature of the invention, the body forms a slider bar.

According to another feature of the invention, the body forms a needle bar.

Other features and advantages of the invention will be described with reference to the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be described in more detail below with reference to a number of drawings through non-limiting embodiments of the invention, wherein like reference numerals indicate similar parts.

The information shown herein is an example for schematically illustrating an embodiment of the present invention and provides the most usefully understood as the main idea and concept of the present invention. In this regard, no attempt is made to show the detailed structure of the invention in more detail than is necessary to fundamentally understand the invention, and it is apparent to those skilled in the art through drawings and descriptions how some aspects of the invention actually apply.

1 shows several knitting tools of a knitting machine called so-called guide bars 1a-1d, sinker bars 2, slide bars 3 and needle bars 4. The guide bars 1a-1d support the guide 5 attached to the guide bars 1a-1d via a holder 6, also called a thread guide holder. The sinker bar 2 supports the sinker 7. The slider bar 3 supports the slider 8 and the needle bar 4 supports the knitted needle 9.

Guide bar 1a represents a body consisting of two shapes 10, 11. The two shapes 10, 11 enclose a hollow space 12 extending perpendicular to the plane of the drawing. The direction perpendicular to the plane of the figure is mentioned below in the longitudinal direction, since it corresponds to the longitudinal direction of the knitting machine, in which a knitting area is shown.

2 shows a press mold 13 producing a shape 11. The press characterizes the top 14 and bottom 15 shown in FIG. 2 slightly offset relative to one another to show the shape 11.

The shape 11 is formed of at least two, preferably three, UD resin penetrating workpieces, and the fibers run in a direction crossing the longitudinal direction or the longitudinal direction. In order to make the shape 11, UD resin penetrating workpieces of suitable size and placed on top of each other are placed in the press mold 13. In order to process the shape 11, the upper portion 14 and the lower portion 15 move toward each other with a predetermined force. If necessary, heat may be applied. After the resin penetration processing material is cured, the shape 11 is molded into a desired shape. The extra corner areas 16 and 17 can be removed by cutting or stamping.

The shape (the same applies to all shapes) is an open shape, ie both sides of the shape 11 are entirely accessible.

3 shows the shape 11 with perforated holes 18, 19 and the auxiliary fastening element 20. The auxiliary fastening element 20 is bonded to a flange 21 having a connecting surface 22 on which its shape 11 can be connected to the shape 10 by gluing. The auxiliary fastening element 20 for each hole 19 and threaded hole 23 in which the screw bolt is subsequently screwed to attach the guide bar 1a to the guide lever (or other carrier) is not shown in detail. .

In a similar manner, the thread insert 24 is inserted into the hole 18 where the bolt 26 into which the thread is inserted is fixed to attach the holder 6 of the guide 5 to the guide bar 1a.

The other shape 10 is in principle constructed identically to the shape 11. At its upper end, it has a flange 26 with an opening 27. The flange represents, for example, an offset reinforcing strip 28 at an angle of 90 degrees to the flange 26. The reinforcing strip 28 is located at a distance from the hollow space 12. This gives the guide bar 1a a fairly large longitudinal stiffness in the longitudinal direction but does not interfere because it is adjacent to the bolt which is guided through the threaded hole 23 in the mounting step.

The guide bar 1d is folded into 180 degrees to form the guide bar 1d, even if the two shapes 10 'and 11' are identical, i.e. the same shape 10 'and 11' is used. . However, the same general guide bar is used for knitting machines.

The shape 11 shows an extension 29 which similarly constitutes the connection surface 30 at the side corresponding to the flange 21. The extension 29 in the mounted state (FIGS. 1-4) is placed in the corresponding extension 31 of the shape 11.

To complete the guide bar 1d, two shapes 10, 11 are produced in the press mold 13. The holes 18, 19 are similarly made by, for example, drilling or punching. The two shapes 10, 11 are then assembled and connected to each other at the connecting surfaces 22, 30. Such a connection is made, for example, by adhesion. Since adhesion occurs extensively throughout the entire bar length, adhesives with low final strength can be used and very high support strengths can be achieved. Additionally, the flanges 21, 26 or extensions 29, 31 lying on top of each other can be used to screw or knit the knitted elements to the bar. In screw fastening, the adhesive is not critical and may therefore be omitted if necessary.

The sinker bar 2 has two shapes 32, 33 which enclose a hollow space 34. The shapes 32, 33 are placed opposite one another in the sections 35, 36 or 37, 38 and are connected to each other. The bolt 39 is guided through the sections 35 and 36 so that the bolt is screwed to the nut 40 which is attached to the inside of the section 35 by, for example, adhesion. It does not support only the sinker bar 2 on 41, but the two ensure the connection between the shapes 32, 33.

In a similar manner to the guide bars 1a-1d, the thread insert 42 is guided through the sections 37, 38 where the thread insert bolt 43 is screwed into place. On the one hand, the bolt 43 supports the sinker 7 and on the other hand connects the two shapes 32, 33.

The section 36 here represents the reinforcing strip 44 offset substantially perpendicular to the section 36 and is thus spaced apart from the hollow space 34.

The sliding bar 3 consists of two shapes 45 and 46 which surround the hollow space 47. Here, the two shapes 45, 46 represent the reinforcing strips 48, 49, respectively, such that the two shapes 45, 46 are seated flat on each other in the reinforcing strips 48, 49. The reinforcing strip 48 is curved almost perpendicularly to the section 50 of the lower shape 46. The nut 51 is glued to the inside of the shape 46.

The shape 45 represents two semicircles 52, 53. The curved portion imparts increased rigidity in the longitudinal direction to the shape. The shape 46 also shows a bend 54, which is bent against each other. The two shapes 54 and 46 can be glued together.

On the other side of the connection surface embodied on the bends 53, 54, the two shapes 45, 46 form clamping arms 55, 56 between which the slider 8 with holder is clamped. Of course, the slider 8 is screwed.

5 and 6 specifically show needle bar 4. The needle bar first shows two shapes 57, 58 connected to each other in the curved reinforcement strips 59, 60. The nut 61 is attached to the inside of the shape 57. The nut can be accessed through the opening 62 so that the needle bar 4 can be attached to a carrier, although not specifically shown.

Another shape 63 is provided outside the shape 58, which is shown enlarged in FIG. 5B. The shape 63 forms a longitudinal groove 64 so that the protrusions 65 of each needle 9 are connected to fix the needle 9 in the direction of movement via the slider.

In total, the three shapes 57, 58, and 63 are composed of three layers as shown in FIG. 5B. The layer is represented by "-1", "-2", and "-3". Each layer is formed by a resin permeation workpiece, ie a semifinished product in which fibers, in particular carbon fibers, are embedded in a synthetic matrix. In this case, the resin penetration processing material is a UD resin penetration processing material (unidirectional resin penetration processing material), that is, a resin penetration processing material in which fibers are all aligned in one direction. In manufacture, some resin penetrating workpieces, in this case three resin penetrating workpieces, are placed on top of one another and pressed together in a mold similar to that shown in FIG. The resin penetrating workpiece having different directions of the fibers is placed on top of the cap. Each outer layer 58-1, 58-3, 63-1 is aligned so that the fibers lie side by side in the plane of the drawing and thus of the knitted needle 9 (in the non-cast state of the resin penetrating workpiece). Lay side by side in the direction. In contrast, the resin penetration processing materials 58-2 and 63-2 are aligned so that the fibers are laid in the longitudinal direction.

This also applies to the resin penetration processing materials of the layers 57-1 to 57-3 in a similar manner.

If the shapes 58 and 63 are processed in a corresponding press, the shape is shown in FIG. 6B so that the fibers of layer 63-3 lie in a plane parallel to the knitting needle 9 to form a waveform 66. do. After shaping the shape 63, the longitudinal grooves 64 sink so that the longitudinal grooves 64 pass through the two upper layers 63-1, 63-2, as well as the grooves 67 later. The knitting needles 9 are made to be arranged in the. The remaining flange 68 is formed from the fibers of the outer layer 63-3, which layer emerges from the "bottom" and sinks back to the "bottom" so that the outer layer of the corrugation 66 is secured at the ends of the fibers. It is formed by a continuous fiber structure that is not free. This substantially contributes to the stability of waveform 66. Similar considerations apply to the flange 68. The fiber is supported at the bottom on at least one side.

Knitting needle 9 is supported in groove 67 by holder 69. The holder 69 is fixed in position with the aid of the clamping portion 70 on the needle bar 4 such that the clamping portion 70 is attached to the needle bar 4 by means of a screw 71, the screw being two It is screwed into the threaded portion 72 which is guided through the two shapes 58 and 63. Otherwise, the shapes 57, 58, 63 are attached to another of the embodiments of the present invention.

In manufacturing the shapes 10, 11, 32, 33, 45, 46, 57, 58, 63, the UD resin penetrating workpiece is placed in each specially formed press mold, which press acts as necessary, If so, pressurize while raising the temperature. The pressing action is selected at such a high level that the composite of the synthetic matrix is extruded out of the mold. The shape is obtained by making the fiber portion larger than the fiber portion of the resin penetration processing material. The strength of the bar made later from this shape is increased. However, too much composite must be removed from the shape. The process of pressurizing with the composite is facilitated by packing the resin penetrating workpiece into the fabric fiber to disperse the composite outward.

Individual shapes can be processed after pressing. For example, the shapes can be cut to a suitable length. Portions protruding parallel to the longitudinal direction may be similarly cut or perforated. The shapes of the bars can be arranged relative to each other on the basis of the slider bar 3 via the bends 53, 54 and the reinforcing fiber strips 48, 49 as shown.

The foregoing examples are provided for illustrative purposes and do not limit the invention. The invention is described with reference to the examples, and the terminology used herein is for the purpose of illustration and description, not limitation. The claims may be modified without departing from the scope and spirit of the invention. Although the present invention has been described with reference to means, materials in particular embodiments, the invention is not intended, however, to be limited to the particular embodiments, but rather, the invention is to be understood as equivalent structures, methods within the scope of the appended claims. It can be extended functionally to, and use.

Claims (29)

A knitting tool bar of a knitting machine comprising a fiber reinforced composite and comprising a body having at least two open shapes disposed to form a wall enclosing a longitudinally extending hollow space. The method of claim 1, A knit tool bar, wherein at least one shape is formed as a cast part. The method of claim 1, The shape comprises a knitting tool bar, characterized in that it has one or more connecting surfaces arranged in contact with each other flat. The method of claim 1, Knitting tool bar, characterized in that the shape is attached to each other. The method of claim 1, A knitting tool bar, further comprising an auxiliary securing element coupled to one or more shapes. The method of claim 5, wherein And said auxiliary securing element is located inside said hollow space. The method of claim 5, wherein And said auxiliary securing element is arranged in an area where the two are superimposed on one another. The method of claim 5, wherein Knitting tool bar, characterized in that the secondary fixing element is glued and connected. The method of claim 1, A knitting tool bar, further comprising: an additional shape having grooves running outward in a direction intersecting the longitudinal direction between which the corrugated flanges are arranged. The method of claim 9, The additional shape is arranged on a side of one of two or more shapes outside of the hollow space, the additional shape having a common longitudinal groove oriented in the longitudinal direction that is connected to the groove. Tool bar. The method of claim 1, A letter tool bar, wherein at least one of the two or more shapes is formed from a resin impregnated workpiece. The method of claim 11, The resin penetration processing material is a knitting tool bar, characterized in that the unidirectional resin penetration processing material. The method of claim 12, And at least one of said shapes is formed from at least two resin penetrating workpieces placed on top of each other. The method of claim 13, And at least two resin penetrating workpieces are arranged such that the fiber directions of the two or more resin penetrating workpieces have a predetermined angle. The method of claim 14, At least one resin penetrating workpiece has a fiber direction running in the longitudinal direction, and the at least one resin penetrating workpiece has a fiber direction running in a direction crossing the longitudinal direction. The method of claim 15, And at least one resin penetrating workpiece having a fiber direction running in a direction crossing the longitudinal direction is disposed on at least an outer surface of the shape. The method of claim 11, And the main body has a higher fiber ratio than the resin penetrating workpiece. The method of claim 1, Knitting tool bar, characterized in that at least one shape has a bend. The method of claim 1, At least one of the at least two shapes has an offset reinforcing strip positioned spaced from said hollow space. The method of claim 1, At least two shapes are shaped such that the two or more shapes are connected to each other in one alignment. Forming at least two open shapes; Arranging two or more open shapes to define an open space extending in the longitudinal direction and to form a body, A method for manufacturing a knitting tool bar of a knitting machine, characterized in that the body consists of a fiber reinforced composite. The method of claim 21, Forming a further shape consisting of a groove extending in a direction crossing the longitudinal direction and a plurality of corrugated flanges separated by the longitudinal groove. The method of claim 22, A method of manufacturing a knitted tool bar, further comprising disposing an additional shape on one side of at least two shapes outside of the hollow space. The method of claim 23, A method of making a knitted tool bar, further comprising inserting a knitted needle into a groove positioned between the corrugated flanges. The method of claim 24, A method of making a knitting study bar, further comprising the step of inserting a portion of a knitting needle into a longitudinal groove. The method of claim 21, And the main body forms a guide bar. The method of claim 21, And the main body forms a sinker bar. The method of claim 21, And the main body forms a slider bar. 22. The method of claim 21 wherein the body forms a needle bar.

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