NO123166B - - Google Patents

Description

method for producing this.

This invention relates to string or twine of synthetic monofilaments and a method for producing the same.

The term "twine" shall include cord, twine, strings and the like.

It is an object of this invention to provide synthetic monofilament string, and in particular string made from poly-olefins, which have improved bending and knotting properties compared to other synthetic strings which have been marketed up to now.

Another object is to provide string with uniform properties over the entire length and which is resistant to rot and ultraviolet radiation.

A further object is to provide a line with monofilaments extending substantially parallel to each other and comprising means for holding the monofilaments in their proper relationship to one another without affecting the flexibility of the line.

hot and without significantly increasing its price.

A further purpose is to provide a progress

method for the production of synthetic monofilament cords with high strength, flexibility and good tying properties.

Until now, lace and cord have been produced almost exclusively from natural fibres. Although these fibers have fulfilled the intended

purposes, they are quickly replaced by better synthetic fibres,

e.g. there has been a rapid increase in the use of polypropylene fibers for rope constructions. The natural fibers used to make lace, e.g. packing twine, was usually sisal or hemp (henequen) or a combination of these. Such fibers are cor-

tea and stiff and difficult to process with greater uniformity. For ordinary lines for agricultural purposes, it is common to find a strength variation in the lines of up to 40% over their entire length. Due to the wide variation in strength in natural fiber ropes or cords,

they are usually constructed thicker than necessary to compensate for weak points present in their construction. Due to the shortness of the natural fibers, laces or twine made from these must be twisted with a relatively short "lay"

to develop the strength of the fibers. Natural fibers will also break down quickly if they rot.

Several attempts have been made to construct laces

and stringing oriented polyolefin monofilaments by surrounding a large number of monofilaments with a continuous or discontinuous sheath of polyolefin. When the casing or mantle is constructed

made of polyethylene or a copolymer of ethylene, the friction coefficient of the mantle is low. In a simple knot, such as is tied using the mechanical tying device in a baler, the sheath of the line will act as a lubricant and allow the knot to slide and roll, thereby reducing the knot strength. In addition, the coefficient of friction between the sheath and the monofilaments is low and the monofilaments tend to slide inside the sheath and pull through the knot construction before they take up their proper tensile load.

The addition of inorganic fillers to a polyethylene sheath in sufficient quantity to substantially increase the coefficient of friction will also increase the stiffness of the sheath. The increased stiffness is undesirable in that a conventional mechanical tying device can then only partially close a simple knot before it is released. When tension is applied to the two main components of the line, such as when a bale of hay is released from the baler, the partially closed knot will not be attracted or closed sufficiently to prevent the cut-

ne knot ends from slipping through the knot, causing failure.

When the sheath is made of polypropylene or a copolymer thereof, the sheath will act as a fully or partially compact tube and exhibit undesirable stiffness. Again, the mechanically tightened knot will not close completely and the cut ends will tend to pull through causing the knot to fail.

Sheathed string, twine or cord also has one

undesirable property in that they resist axial twisting. When a line is "pulled" or "ejected" from the center portion of a line repack, this will result in one axial twist or twist for each package circumference of the line being pulled out. When it comes to mechanical hay balers, the aforementioned twist that is generated in the line will tend to remain in the machine's line chamber and will accumulate or accumulate there. When a sufficient amount of axial twist is collected in a short length of string which is not supported, the twist will tend to twist on itself so that a twist or kink is formed. The resulting twist gets in the way of the tensioning device and guides in the machine and causes the line to break.

A method is known from British patent 891 471

for the production of rope, whereby instead of twisting fibers to form yarn, twisting the yarn to form cords and twisting the cords into rope, yarn is used which each

consists of a number of continuous filaments that are tied very loosely together, are held parallel to each other and anchored with ribbons. In the case of this known product, the core of the rope consists of a bundle of parallel yarns bound together with ribbons which are twisted around the bundle in the form of a spiral and with the help of adhesive attached to the periphery thereof. Further layers of parallel yarns bound together with ribbons are placed on the core.

As mentioned, the present invention relates to a method

tea for the production of string, twine or the like, and this also includes yarn. As explained, the above-mentioned British patent relates to a method for producing rope using yarn with a twisted structure. The cord or yarn according to the present invention can be used as starting material for the rope which

manufactured according to the British patent document. Corded-electric-

However, the yarn product according to the present invention is based on individual monofilaments which are not themselves twisted.

According to the British patent document, ribbons are wound around

and glued to the yarn. These bands necessarily have a limited length

they and it is not possible to produce an unlimited length of rope in a continuous manner. This limitation does not exist in connection

see with the present invention.

Furthermore, there is no available adhesive which can produce a similar bond strength between the binding tape and monofilaments as is possible with a method according to the present invention. An essential feature of this consists in applying the binding tape while this is sufficiently hot to partially bond around the outer monofilaments and fuse with them.

More specifically, this invention thus primarily relates to a string, a twine or similar twisted product of the type comprising a bundle of oriented, synthetic monofilaments which extend in the longitudinal direction of the string and essentially parallel to each other, and a synthetic binding element in ribbon form. The new and distinctive features of the product according to the invention mainly consist in the fact that this tie is made from a material combined

equal to the monofilament material, extends around the monofilament leg

and has been applied while sufficiently warm to partially

wrap around and fuse with each of the outer monofilaments it contacts, which bond leaves behind

leaving some parts of the outer monofilaments uncovered and forming edges that extend largely in the circumferential direction of the line, which edges form wedges so that when the line is tied, the wedges will help prevent the knot from slipping"

A product in the form of string, twine or similar i

according to the present invention entails a number of advantages and special effects compared to previously known products for similar purposes. The fact that parts of the binder penetrate between the outer monofilaments prevents the binder from displacing

ves in relation to the outer filaments. Fusion of the band and the outer filaments helps to prevent relative movement between

loom these, and the inner surface of the tape has a relatively large contact area with each outer monofilament because it celsiusly joins around this, when the tape is applied in a hot state. The size of a

ordinary tie tape and the point of contact between the tape and each monofilament would otherwise be so small that there is no adhesive on the market that can provide the necessary bond between the synthetic materials used in such string or the like. This means that the indicated melting according to the invention is very important. In addition to this, it will be possible to extrude the binding tape immediately before it is wound around the monofilament bundle, so that it is not necessary to heat the tape material separately to cause it to fuse with the monofilament. This makes it possible to produce the entire line continuously, as both the monofilament line and the tie are extruded at the same time.

According to the invention, a method for the production of string, twine or the like as stated above is characterized by a continuous bundle of oriented, synthetic monofilaments which are kept mainly parallel to each other, being wrapped around a thin band or strip-shaped binding element of a synthetic material which is compatible with the monofilament material, in such a way that the binding element leaves parts of the monofilament exposed and forms circumferential, protruding wedge or gripping edges, and under such temperature conditions that the tape material adheres tightly to and partly around the outer monofilaments with which the tape comes into contact, and merge with these monofilaments.

Examples of the present invention are shown in the accompanying drawings where: fig. 1 is an illustration of a simple knot made using

of this lace,

fig. 2 is a perspective view, on a greatly enlarged scale, of a length of cord made according to one embodiment

of the invention,

fig. 3 is an enlarged cross-section along the line 3-3 in fig. 2.

Fig. 4 is a perspective view of a length of cord according to an alternative embodiment of the invention, and

fig. 5 is a cross-section along the line 5-5 in fig. 4.

Reference is now made to the drawings, where fig. 1 illustrates a simple lace knot 10 connecting two lengths of lace 11 and 12. These laces form main tension members which are brought together side by side and wound into a circular winding 15 which is arranged in the

substantially at right angles to the main parts 11 and 12.

Fig. 2 and 3 show one of the mentioned lace lengths, e.g. the cord 11, manufactured according to the invention. The cord is made up of a bundle of oriented synthetic monofilaments 20 which extend substantially parallel to each other in the cord's longitudinal direction. It is preferred that the monofilaments are substantially parallel to the line's longitudinal axis, but they may have some twist, and the words "substantially parallel" as used here and in the requirements shall include this twist. Synthetic binding element 22 extends around the monofilament strand 20 and is preferably fused to the monofilaments with which it comes into contact. The binding element 22 comes, e.g. in contact with and is fused to the outer monofilaments at 24, see fig. 3. As the tape is attached to the outer filaments while it is hot enough to fuse with them, said tape also closes around each monofilament with which it comes into contact, as clearly shown in fig. 3. In this example, the binding element 22 is a thin ribbon that is spirally wound around the filament bundle. It should be understood that several bands can be wound spirally around the filament tené. This spiral winding leaves gaps 26 between the windings where some of the monofilament is exposed or uncovered. In addition to this, the tie has side edges 28 and 29 which extend generally in the circumferential direction of the cord and tend to act as wedges. The binding element 22 cannot be displaced in the longitudinal direction of the cord, as it is fused with each outer filament over a relatively large contact surface and due to the parts of the binding element which extend inwards between the outer filaments, as shown in fig. 3..

When two of these lengths of string are fastened together with a knot 10, there will be a certain amount of resistance to slippage or untying of the knot caused by the monofilament, when they are formed of some materials that touch each other across gap 26 in the various windings of the string. In addition to this, the side edges 28 and 29 of the binding tape, which extend substantially in the circumferential direction of the monofilament bundle, will act to some extent as wedges and prevent the windings of the line, which extend substantially at right angles to the other particles of the line, from sliding along the latter. The fusion of the binding element 22 to the monofilaments with which it contacts holds all the monofilaments in their correct positions because the binding element is fused to the outer monofilaments which form a layer and surround the inner monofilaments. One

bundles of monofilaments lying side by side have great flexibility, and the spirally wound binding element 22 hardly gets in the way

for this one at all because the largest percentage of the monofilaments forming the bundle are free to move relative to each other when the line is bent" As the binding element is fused to the outer monofilaments, it cannot escape from these when the line is bent, subjected to harsh treatment, tied in a knot or cut into lengths.

The monofilaments 20 in this line are preferably made of polyolefin, such as e.g. polypropylene or linear high-density polyethylene. The binding tape 22 must be made of a material which is compatible with the monofilament material so that they both react in the same way to heat. The term "compatible with" is used to indicate material which will melt and bond with the synthetic monofilaments, and which has similar physical and chemical properties, i.e. in terms of flexibility and resistance to acid attack, rotting and the like. It is preferable to make the binding tape from the same material as the monofilaments. The binding element is wound around the monofilaments while it is sufficiently hot to melt to each of the latter monofilaments with which it comes into contact, such as at points 24 in fig. 3.

Fig. 4 and 5 show an alternative lace shape. This string is made of a bundle of monofilaments 34 extending substantially parallel to each other, and a compatible binding element around these filaments in a large number of annular bands 36, each of which has been applied while hot enough to partially join around and fuse with each of the outer monofilaments with which it comes into contact. The bands 36 are arranged at an axial distance along the string so that a gap 37 is formed between each band. Each band has side edges 39 and 40 which extend substantially in the circumferential direction of the cord and act as wedges.

The monofilaments 34 and the binding bands 36 can be made of the same material as the monofilaments and the binding band according to fig. 2 and 3. In addition, the string in fig. 4 and 5 in the same way as the previously described lace.

The method of producing synthetic string of the type discussed above may consist of surrounding a continuous bundle of oriented synthetic monofilaments which extend substantially parallel to each other in the longitudinal direction with a thin synthetic binding tape made of a material which is compatible with the monofilaments and which is sufficiently hot to partially wrap around and fuse weakly with each of the outer monofilaments it comes into contact with, see fig. 5, but not so much that it significantly reduces the bundle's tensile strength. As indicated above, it is preferred to use polyolefin for both the monofilaments and the binder, such as polypropylene or linear high-density polyethylene. Polypropylene is preferred because it is significantly less slippery than polyethylene. The binding element can be spirally wound around the monofilament bundle, or it can be used in the form of ring-shaped bands around the monofilaments at an axial distance from each other. The binder tape can be such that it will merge with the outer monofilaments at a small depth, while they partially join around said monofilaments. When using polypropylene the temperature should be in the range of about 177°C to about 310°C (350°F to 625°F), while with polyethylene the temperature should range from about 205°C to about 310°C (400°F to 625°F), to ensure the desired melt depth.

The binding tape should be quite thin so that it does not detract from the line's flexibility. The best results achieved have been with the spiral tape having a width of from about 0.015 to about 0.5 cm (0.006 to 0.200 inches) and a thickness of from about 0.01 to about 0.05 cm (0.004 to 0.020 inch). When individual annular bands are used, they may have a width of from about 0.015 to 1.25 cm (0.006 to 0.50 inches) and a thickness of from about 0.005 to about 0.05 cm (0.002 to 0.020 inches). a single spiral band should be from about 0.625 to about 5 cm (0.250 to 1.900 in), while for two spiral bands spaced equally apart, the lay per spiral be from about 1.25 to about 8.75 cm (0.500 to 3.500 inches). The annular bands may be spaced apart from about 0.5 to about 6.25 cm (0.200 to 2.50 inches). The melt depth of the spiral annular bands should be from about 0.00125 to about 0.0075 cm (0.0005 to 0.003 inches). However, it must be specified here that the gap between the windings of the winding band will help to maintain the flexibility of the line.

As indicated above, the tie elements will provide locking edges or wedges that prevent slippage when the line is tied into a knot. Because the monofilaments form an uneven surface in the bundle in the circumferential direction, this will help to prevent slipping, especially when polypropylene is used. The monofilaments are held in their proper coaxial arrangement without the need to place a complete jacket or continuous sheath around them. The gaps or spaces in the tie reduce the amount of material required without significantly affecting the line's strength, and further help to maintain the line's flexibility.

Suitable stabilizers or pigments can be added to the polyolefins that form the monofilaments and to the binding element to protect them from ultraviolet degradation.

The term "monofilament" as used in this description and in the following claims is intended to include monofilaments of any cross-section. The binder bands can also be of any cross-section, although open-use bands with a rectangular or oval cross-section are preferred.

Claims (3)

1. String, twine or similar twisted product, comprising a bundle of oriented, synthetic monofilaments (20,34) which extend in the longitudinal direction of the string and essentially parallel to each other, and a synthetic binding element (22,36) in ribbon form, characterized in that said bond is made of a material compatible with the monofilament material, extends around the monofilaments, and has been applied while sufficiently hot to partially wrap around and fuse with each of the outer monofilaments with which it contacts, ties leave some parts of the outer monofilaments uncovered and form edges (28,29,39,40) which extend largely in the circumferential direction of the line, which edges form wedges so that when the line is tied, the wedges will help prevent slippage of the knot. 2. String according to claim 1, characterized in that the tie (22) is wound in a spiral around the bundle of monofilaments (20), which spirals leave open spaces (26) between the individual windings. 3. String according to claim 1, characterized in that the binding element has the form of a plurality of ring-shaped bands (36) which extend around the bundle of monofilaments, and are placed at an axial distance from each other so that they have spaces (37)