JP6336491B2 - Unbalanced hybrid cord and method of manufacturing such a cord with a cable coding machine - Google Patents

Description

  The present invention relates to the production of twisted hybrid cords.

  Various types of materials for applications such as tire reinforcements are often used in combination in the form of hybrid cords, for example, materials with higher and lower elastic moduli. When forming twisted cords, use different twist levels for the high and low elastic plies to construct the difference in modulus between the two materials or to obtain the desired cord response. Is common. Since cable coders do not form cords in the same way as ring twisters, they are not currently obtainable on cable coders. Even if a hybrid cord can be made on a cable coder, the behavior of the cord that can be obtained is limited to the behavior of balanced twisted cords, i.e. cords with the same length of high and low elastic plies. In that case, there is a unique response for any given twist level. If an unbalanced hybrid cord is needed, it is now made on a ring twister.

  Cable coders offer tremendous productivity benefits. Therefore, considering that unbalanced hybrids are more common than fully balanced twisted hybrids, it would be desirable to create both balanced and unbalanced hybrids on such equipment.

  The present invention relates to a hybrid cord including a plurality of plies, wherein at least two of the plies have a different ply length regardless of the number of twists of the plies, and at least one of the plies is 1 to 50% longer.

It is the figure on which the cable coder of the prior art was drawn. It is a front view of the cable coder of the present invention. It is a side view of the cable coder of the present invention. It is a graph which shows elongation at the time of load vs fracture.

  In the present specification, the hybrid cord means a cord composed of at least two plies in which at least one ply has a different elastic modulus from other plies. By way of example, one ply can be para-aramid and the other ply can be nylon. These plies may also have the same composition but different elastic moduli.

  In the present specification, the untwisted ply means the amount of twist that can be measured by the ply when the ply is taken out of the cord without returning the twist of the cord. In this specification, the ply length means the length of the ply when the ply is taken out from the cord without returning the twist of the cord.

  When two yarn plies are combined in the cable coding process, they pass through the adjusting device. The adjusting device may consist of two pulleys on the other side connected to two pulleys on one side by a solid shaft. The adjustment device helps to ensure that the plies enter the cord twister at the same speed. FIG. 1 shows a prior art adjustment device 10 generally including a pulley 11 connected by a shaft 12. These pulleys all have the same diameter. FIG. 2 shows an adjustment device 20 as a whole, which includes a pulley 14 a connected to a pulley 14 b by a shaft 15. The two pulleys 14a on one side are larger in diameter than the pulleys 14b on the two sides, so a ply moving through one side will enter the cord faster than a ply from the two sides. This is because the pulleys on both sides must be connected by a solid shaft and rotate at the same speed. The larger the outer circumference of a pulley on one side (relative to the pulley on the second side), creates a longer path that the ply wraps around, thus carrying more plies with each pulley rotation. FIG. 3 is a side view of FIG. 2 showing the path of the ply 13 around the pulley 14a having a larger diameter. The second component ply follows a similar path around the smaller diameter pulley 14b (not shown). Therefore, at least two of the plies have different ply lengths regardless of the number of twists of the plies. In one embodiment, the present invention uses a series of pulley sizes to create an unbalanced hybrid cord. By feeding the high elastic ply over the larger pulley and the low elastic ply over the smaller pulley, the high elastic ply is longer than the other ply in the cord structure. The pulley size ratio will determine the ply length ratio. If the high elastic ply pulley is 25% larger in diameter than the low elastic ply pulley, the high elastic ply will be about 25% longer than the low elastic ply.

  In addition to adapting the behavior of the ring twisted unbalanced hybrid cord to the cable coder productivity level, the quality of the cord can also be improved. When making a large difference in the number of twists between a high elastic ply and a low elastic ply on a ring twister, the highly twisted low elastic ply results in a huge amount of residual torque in the cord. If different sized pulleys are used to obtain length differences on the cable coder, such residual torque in the low elastic ply will be minimized or absent. This allows for more neutral cords and cords that are easier to control during manufacture.

  Hybrid cords may have no twist in the ply and the length of at least one ply may be 1-50% longer than the other plies, or 1-35% or 1-25% longer Can be made from several plies. The amount of length difference between the plies is selected to meet specific performance requirements. In some embodiments, the hybrid cord has a linear density of 500-5000 denier. In some other embodiments, the hybrid cord has a linear density of 1000-3500 denier. Hybrid cords are made from meta-aramid, para-aramid, polyazole, nylon, polyester, polyethylene naphthalate (PEN), rayon, polypropylene, ultra high molecular weight polyethylene (UHMW-PE), or a ply of polymer such as carbon It may be. A suitable polyazole is polyoxadiazole, for example available from OJSC Svetlogorsk Khimvolokno, Svetlogorsk, Belarus under the trade name Arselon ™. The hybrid cord may also be made from a metal ply.

  The hybrid cord may include only one ply of high modulus material and only one ply of low modulus material, such as at least one p-aramid ply and at least one nylon ply, The shortest ply is nylon. The hybrid cord may include at least one p-aramid ply and at least one m-aramid ply, the shorter length ply being m-aramid.

  In a preferred embodiment, the ply comprises a filamentary yarn that can be continuous, partially discontinuous, or discontinuous (such terms are well known in the textile industry). An example of a partially discontinuous yarn is a checkered yarn. An example of a discontinuous yarn is a spun yarn.

  In one embodiment of the invention, the p-aramid ply is 2-7% longer, preferably 3-6% longer, or more preferably 4-5% longer than the m-aramid ply. Hybrid cords of this structure forming woven or knitted fabrics are particularly suitable for use in parts that are subjected to burst pressure tests at low temperatures, eg, room temperature, and fatigue tests at high temperatures, eg, 175 ° C. An example of such a part is a turbocharger hose where the cords provide structural reinforcement to the elastomeric material. Similar applications may be found in other mechanical rubber goods applications such as conveyor belts and tires. In other embodiments, the p-aramid ply may be 3-5% longer than the polyoxadiazole ply, or the polyoxadiazole ply may be 1-10% longer than the m-aramid ply.

  These plies may have the same or different twist numbers. In some embodiments, these plies are untwisted.

  The pulley can be any cabling machine such as Oerlikon Saurer, Charlotte, North Carolina, or Verdol, Valence, France, or Aiddra Textile Engineers Ltd. , Surat, may be adapted to those available from India.

In one embodiment, the present invention is also directed to a method of providing a cord with a predetermined number of twists and constituent ply lengths, the method comprising:
(I) identifying a desired cord twist factor and constituent ply length;
(Ii) identifying the number of constituent plies and the composition of each ply;
(Iii) preparing a cabling machine;
(Iv) selecting an appropriately sized pulley of the regulator of the cabling machine such that the one side pulley is larger than the two side pulley to obtain the desired constituent ply length in the cord;
(V) setting a desired twist level of the hybrid cord in the cabling machine;
(Vi) supplying the plies to a cabling machine; and (vii) producing a cable cord having a desired twist factor and constituent ply length.

Another embodiment is a hybrid cord having a predetermined number of twists and a length of component ply by adjusting tension leads to force a length difference that achieves the objective outlined above to increase the size of the pulley On how to provide. This embodiment is
(I) identifying a desired cord twist factor and constituent ply length;
(Ii) identifying the number of constituent plies and the composition of each ply;
(Iii) preparing a cabling machine;
(Iv) setting a desired twist level of the hybrid cord in the cabling machine;
(V) setting a desired tension level of the constituent plies;
(Vi) supplying the plies to a cabling machine; and (vii) producing a cable cord having a desired twist factor and constituent ply length.

  In this embodiment, the cabling machine of FIG. 1 may be used in conjunction with a yarn tensioning device (not shown) located in front of each yarn feed pulley. Several types of tensioning devices are available on the market and are suitable for use.

  In both of the above methods, the constituent plies can have various twist combinations. For example, the plies can be untwisted, the constituent plies can have the same twist number, and at least two of the constituent plies can have different twist numbers.

  The following examples are given to illustrate the present invention and should not be construed as limiting in any way.

Sample Preparation The para-aramid yarn used was E. coli. I. Kevlar® K29 1100 dtex available from DuPont de Nemours and Company, Wilmington, Delaware.

  The nylon yarn used was PA66 1400 dtex available from Invista, Wilmington, Delaware.

  The cords were formed on an Oerlikon Allma CC3 cable coding machine, each cord containing one p-aramid yarn and one nylon yarn. All cords had a twist factor of 6.5. One cord had both yarns of equal length as both constituent yarns passed through a pulley of equal diameter. The other cords use a pulley with a diameter that is 5%, 10%, and 20% larger than the diameter of the pulley through which the nylon thread passes, respectively, by using a pulley that the p-aramid thread passes through. Also had 5%, 10%, and 20% longer p-aramid yarns. These cords were then tested for mechanical performance on an Instron® universal tester model 5500. This test method was ASTM D885-07. A graph of load versus elongation at break for each example is shown in FIG.

The curves in FIG. 4 demonstrate by way of example how the behavior of the hybrid cord can be modified with different pulley ratios without changing the twist level of the cord. In the case of the Kevlar® / nylon hybrid example, 100/100 indicates that the diameter of the pulley supplied with the Kevlar® yarn is the same as the diameter of the pulley supplied with the nylon yarn. Yes. Kevlar® / nylon hybrid 105/100 shows that the diameter of the pulley fed with Kevlar® yarn is 5% larger than the diameter of the pulley fed with nylon yarn, FIG. The same applies to the other curves. For certain tire applications, higher elongation and lower initial modulus are desirable, which can be achieved by using a larger pulley for the Kevlar® ply.
Next, a preferred embodiment of the present invention will be shown.
1. A hybrid cord comprising a plurality of plies, wherein at least two of the plies have a different ply length regardless of the number of twists of the ply, and at least one of the plies is 1 to A cord having a length that is 50% longer and wherein the ply comprises a yarn selected from the group consisting of continuous filaments, spun yarns, and checkered yarns.
2. The cord according to 1 above, wherein the constituent ply is a polymer or a metal.
3. The cord of claim 1, wherein at least one of the plies has a length that is 1 to 35% longer than the other plies.
4). The cord of claim 1, wherein at least one of the plies has a length that is 1 to 25% longer than the other plies.
5. The cord according to 2 above, wherein the polymer ply is selected from the group consisting of m-aramid, p-aramid, polyazole, nylon, polyester, polyethylene naphthalate, rayon, UHMW-PE, and carbon.
6). 6. The code according to 5 above, wherein the polyazole is polyoxadiazole.
7). 6. The cord of claim 5 comprising at least one p-aramid ply and at least one nylon ply.
8). 6. The cord of claim 5, comprising at least one p-aramid ply and at least one m-aramid ply.
9. The cord according to claim 7, wherein the shortest ply is nylon.
10. 9. The cord according to 8 above, wherein the shortest ply is m-aramid.
11. 9. The cord according to 8 above, wherein the p-aramid ply is 4 to 5% longer than the m-aramid ply.
12 A method for providing a hybrid cord with a predetermined number of twists and a length of a constituent ply,
(I) identifying a desired cord twist factor and the length of each constituent ply;
(Ii) identifying the number of constituent plies and the composition of each ply;
(Iii) preparing a cabling machine;
(Iv) setting a desired twist level of the hybrid cord in the cabling machine;
(V) setting a desired tension level of each constituent ply;
(Vi) supplying the ply to the cabling machine; and
(Vii) producing a cable cord having the desired twist factor and constituent ply length;
Including a method.
13. 13. The method of claim 12, wherein the constituent ply is untwisted.
14 The method of claim 12, wherein all of the constituent plies have the same number of twists.
15. The method of claim 12, wherein at least two of the constituent plies have different numbers of twists.
16. 13. A product made by the method of claim 12 wherein the component ply is untwisted.
17. A product made by the method of claim 12 wherein all of the constituent plies have the same number of twists.
18. 13. A product made by the method of claim 12 wherein at least two of the constituent plies have different twist numbers.
19. An elastomer-reinforced hose comprising the hybrid cord according to 1 above.

Claims (6)

A method for providing a hybrid cord with a predetermined number of twists and a length of a constituent ply,
(I) identifying a desired cord twist factor and the length of each constituent ply;
(Ii) identifying the number of constituent plies and the composition of each ply;
(Iii) preparing a cabling machine;
(Iv) selecting an appropriately sized pulley of the regulator of the cabling machine such that the one side pulley is larger than the two side pulley to obtain the desired constituent ply length in the cord;
( V ) setting a desired twist level of the hybrid cord in the cabling machine ;
( Vi) supplying the ply to the cabling machine; and (vii) producing a cable cord having the desired twist factor and constituent ply length.   The method of claim 1, wherein the constituent plies are untwisted.   The method of claim 1, wherein all of the constituent plies have the same number of twists.   The method of claim 1, wherein at least two of the constituent plies have different numbers of twists.   A method for providing a hybrid cord with a predetermined number of twists and a length of a constituent ply,
(I) identifying a desired cord twist factor and the length of each constituent ply;
(Ii) identifying the number of constituent plies and the composition of each ply;
(Iii) preparing a cabling machine;
(Iv) setting a desired twist level of the hybrid cord in the cabling machine;
(V) setting a desired tension level of each constituent ply;
(Vi) supplying the ply to the cabling machine; and
(Vii) producing a cable cord having the desired twist factor and constituent ply length;
Including
  The method wherein the constituent plies are untwisted.   A method for providing a hybrid cord with a predetermined number of twists and a length of a constituent ply,
(I) identifying a desired cord twist factor and the length of each constituent ply;
(Ii) identifying the number of constituent plies and the composition of each ply;
(Iii) preparing a cabling machine;
(Iv) setting a desired twist level of the hybrid cord in the cabling machine;
(V) setting a desired tension level of each constituent ply;
(Vi) supplying the ply to the cabling machine; and
(Vii) producing a cable cord having the desired twist factor and constituent ply length;
Including
  The method wherein at least two of the constituent plies have different numbers of twists.