CA1042739A

CA1042739A - Reinforcing cable for elastomeric articles and method and apparatus for its manufacture

Info

Publication number: CA1042739A
Application number: CA252,217A
Authority: CA
Inventors: Leendert Van Assendelft
Original assignee: Akzo NV
Current assignee: Akzo NV
Priority date: 1975-05-12
Filing date: 1976-05-11
Publication date: 1978-11-21
Also published as: FR2311138A1; ATA338576A; DE2619086A1; DE2619086C2; IE42594B1; YU39213B; US4022009A; FR2311138B1; BR7602912A; ES447638A1; GB1524094A; JPS525357A; LU74913A1; IE42594L; YU110776A; AT343014B; US4030248A; JPS5831438B2; IT1059752B

Abstract

ABSTRACT OF THE DISCLOSURE
A reinforcing cable for an elastomeric article comprises helically formed filaments, at least one single steel wrapping filament wound on at least two single steel core filaments, wherein the core filaments are of helical shape and are positioned beside and against each other so that they form a helix and each core filament is in line contact with at least one other of the core filaments, the line of contact being parallel to the direc-tion of the filament, and said at least one wrapping filament is in the form of a helix having the same hand and the same pitch as helix formed by the core filaments and is positioned on the inside of the helix formed by the core filaments.

Description

~04;~3~9 he invention relates to a reinforcing cord or cable (hereinafter referred to as a "cab]e") for elastomeric articles.
The invention also relates to a method of and apparatus for making a filament cable free from torsional strain while in an unloaded state from metal filaments.
A reinforcing cable for reinforcing articles of elastom-, eric material such as vehicle tyres, conveyor belts, hose and the like, is known from the United States Patent Specification t 3 273 978. The reinforcing element described therein comprises helically formed juxtaposed core filaments disposed in out-of-phase relationship and on which one or more wrapping filaments are wound.
As the juxtaposed core wires are disposed in out-of-phase relationship, they are only in point-to-point contact with each other and the cable therefore has a quite open structure.
The purpose of such an open structure is to provide sufficient spacing for penetration by the elastomeric material, as a result ~` of which the cable embeddedin the elastomer is given better longitudinal elasticity than conventional metal cables. With the cables described in the above-mentioned United States Patent `~ Specification the wrapping filaments exclusively serve to keep the randomly disposed core filaments together. Consequently, when the cable is loaded longitudinally, the wrapping filaments contribute considerably less to the strength of the cable than do the core filaments. Moreover, since the core filaments are spaced widely apart, the outside diameter of the cable is relatively large, so that the number of reinforcing filaments that can be accomodated in the space available in the article to be reinforced is relatively small, thus it is not possible to obtain an optimum reinforcing effect. For some applications the cables i have excessive elasticity and especially it has been found that , under low loads their modulus of elasticity is undesirably low.
.,. ~

;~ 104~:739 This drawback is encountered particularly if such cables are used for belts underneath the treads of automobile tyres.
In accordance with the present invention, there is provided a reinforcing cable for an elastomeric article comprising helically formed filaments, at least one single steel wrapping filament wound on at least two single steel core filaments, wherein the core filaments are of helical shape and are positioned beside and against each other so that they form a helix and each core filament is in line contact with at least one other of the core filaments, the line of contact being parallel to the direc-tion of the filament, and said at least one wrapping filament is in the form of a helix having the same hand and the same pitch as helix formed by the core filaments and is positioned on the inside of the helix formed by the core filaments.
In the cable of the invention, the wrapping filament or filaments fully contribute to the strength of the cable, which has a high modulus of elasticity. When the cable is embedded in an elastomeric material it produces a great stiffening and re-inforcing effect in the elastomeric material.
` In steel cords or cables that are commonly used for reinforcement the cord filaments are wound about each other.
The cable according to the invention differs from such cords in that the helical core filaments are not wound about one another but extend beside each other in such a way that each core filament is in contact with one or more other core filaments along the length thereof.
The cable according to the invention is of a simple construction and has been found to have a particularly favourable combination of static and dynamlc properties such as strength, ~ 30 longitudinal elasticity, tensile modulus, force distribution in ; the filaments, compression-fatigue resistance and processability.
The or each wrapping filament forms a helix whose pitch ., . . .. :,:
- :~

104;~739 is in the same as that of the core filaments and its disposition is such that in any cross-section of- the cable it lies against the inside of the helix formed by the core filaments, the angle of inclination of the wrapping filaments being of the same order of magnitude as that of the core filaments. As a result, each of the wrapping and core filaments contributes to the strength of the cable to a similar degree.
The cable of the invention may with particular advantage be applied in the reinforcing belts of automobile tyres. It is known to use steel cords, more particularly single stranded cords in the reinforcing belts of automobile tyres. The belt is generally built up of two closely spaced parallel cord plies, the cords of the one ply crossing those of the other ply. It has now been found that a belt reinforcedwith cables according to the invention has a considerably higher modulus than a belt reinforced with an equally large number of single stranded cords of equal length of lay and made up of filaments of equal diameter.
The higher modulus results in the tyre provided with such a belt displaying improved riding qualities, and more particularly improved cornering behaviour. A more rigid and, hence, less deformable belt improves the motor car's cornering ability and contributes to direct steering and consequently reduces tread wear.
It is also possible for the tyre belt to be made of fewer cables such that the modulus of the belt is equal to single strandedcables. The use of the cables according to the invention then has the advantage of leading to a lighter construc-tion, which will again be beneficial to riding comfort. The cables according to the invention moreover have a good resistance to corrosion and the spreading of corrosion. It has been found that during processing the elastomeric material readily penetrates between the adjoining core filaments of the cable and also into .

~()4'~7391 the space formed within the core filaments. This is not the case with single stranded cords, where the component filaments are in such firm contact with each other that the elastomer cannot penetrate into the central cavity within the component filaments, ; which will lead to the filaments under some circumstances being subject internally to corrosion, which is rapidly found to spread ` through the central cavity. This is attended with a considerable deterioration of the adhesion of rubber to cord and of the fatigue resistance of the cord. The cables according to the invention do not show this disadvantage.
The filaments, and in particular also the core filaments being covered with elastomeric material reduce their resistance to wear under bending loads. Moreover, the cable has good adhesion to the elastomeric material.
In a preferred embodiment of the invention, the cable comprises one wrapping filament which is displaced half a pitch length relative to the pitch of the core filaments. In such a ` cable the crest of lay of the wrapping filament is always midway between two successive crests of lay of the core filaments.
When the reinforcing cable comprises only one :
wrapping filament, preferably the cable comprises 3-8 core filaments and the core filament and the wrapping filaments each have the same diameter, which is in the range of 0.15 to 0.50 mm, and the lay length is 25 to 100 times the wire diameter.
A cable according to the invention may be made by successively imparting a permanent helical deformation to the core filaments, assembling the core filaments to form a bundle, winding the bundle of core filaments with one or more wrapping filaments which have previously been subject to a permanent helical deformation. The helical deformation of the one or more wrapping filaments may with advantage be such that it or they exert an elastic pressure on the core filaments.

104'Z739 'l`he or cach wrapping Eilarnent is in point-to-point - contact witl~ the core filaments. If the or each wrapping filament is very tightly wrapped on the core filaments, then ; at the points of contact the curvature of the wrapping filament may be somewhat sharper than that of the theoretical helix.
Such a reinforcing cable is within the scope of the invention.
A technique for imparting a permanent helical deforma-tion to metal filaments and assembling the filaments into a cable is known from U.S. Patent no. 3,641,555. This specifica-O tion describes the manufac-ture of steel filament cables from filaments, which run off from spools that are placed inside a rotor. While under tension the wires are separately guided - through bores in a disk connected to the rotor, said bores being provided with sharp edges at which the wires are so deflected that deformation forces beyond the elastic limit are set up.
The resulting helically shaped pre-formed filament are assembled . essentially in this form in a cable-forming sleeve. To reduce ~- its liveliness the cable is subjected to a false twist treat-ment before it is fed to a winding device. The radius of `O curvature of the helices formed in the filaments is dependent on the radius of curvature of the deflecting edge. As the radius of curvature of the deflecting edge becomes smaller, the radius of curvature of the filament will decrease provided that the ` filament is under sufficient tension. The radius of curvature of the filament will also decrease with increasing deflection angle. The deflection angle is the angle between the centre line of the bore and the running direction of the filaments to or from the bore.
d The apparatus known from the aforementioned patent specification comprises two disks provided with guide bores which -~ are arranged axially one behind the other and at some distance from one another with the one disk being somewhat rotated relative to the o~hcr. ~4 The radius of curvature of the helix is determined by the tensile force an~/or the relative rotation of the disks governin~ the deflection anc~le.
Tsle invention furtller provides a process of manufactur-ing the cable of tl-le invention, comprisiny running off a plurality of metal core filaments from a plurality of stationary delivery spools, assembling the core filaments to form a bundle of core filaments, guiding the bundle over a first deflecting edge havincJ a small radius of curvature and displacing the point of contact of the edge of the filament helically along the surface of the bundle thereby permanently deforming the filament to cause the filament to acquire a helical shape, and running off at least one metal wrapping filament from at least one spool, guiding said at least one further filament over at least one further deflecting edge and displacing the point of contact of the further deflecting edge along the surface of E
the filament to cause the filament to become permanently deformed t and acquire a helical shape having the same hand as that of the i:, S
bundle, and winding said at least one wrapping filament on the bundle so that helical shape of said at least one wrapping filament has the same pitch as the bundle. The filaments are preferably steel filaments.
Cables manufactured by the process of the invention are free from torsional strain whilst unloaded. The cable made by the process of the invention differs from the cables made by the method of the U.S. Patent no. 3,641,755 in that a number of filaments are not laid about one another but extend beside one another in such a way that each core filament is in contact with one or more other core filaments along the length thereof.
On the core filaments are wound one or more wrapping filaments in such a way that they lie against the inside 10~'~739 o~ the helix formcld by t~le core ~ilamcnts. The cable made by -the process of the invention has a favourable combination of mechanical properties ancl the production costs of the cable maybe considerably lower than that of a cable made by the method of ~.S. Patent no. 3,641,555. This lower production cost c is to be attributed to the fact that a large number of delivery spools are placed stationary outside a rotor and only spools for the wrapping filaments neecl be accomodated inside the rotor, whicll may consequently be of small dimensions so that it is possible to realize high production speeds and reduced operating costs.
~ccording to a preferred form of the process according to the invention, the bundle comprises two to five core filaments ' and one wrapping filament is so laid on the filaments of the .
bundle that it is displaced half a pitch length relative to the pitch of the bundle. This cable can be produced according to the present method at high speed especially because it may be produced using a rotor containing only one spool and such a rotor may be designed for high rotational speeds because of its small dimensions.
The present invention further provides apparatus for carrying out the process of the invention, the apparatus comprising a driven horizontal rotor having a spindle and including at least one eccentrically positioned filament guide opening, provided with at least one deflection edge having a small radius of curvature, at least one rotor spool freely and independently ~; suspended about the spindle and for supplying at least one wrappingfilament to said at least one eccentrically positioned filament guide opening to be deformed by said at least one deflection edge thereof, stationary delivery spools for supplying core fila- I ' 30 ments, a concentrically positioned guide opening arranged to receive t a bundle of the core filaments supplied from the stationary deli- `
very spools, at least one filament guide opening provided with at ; .

104273~

least one deflection edge and arranged to receive the bundle of core filaments from the concentrically positioned guide opening to be deformed by said at least one deflection edge thereof, and a cable-forming device arranged to receive the bundle of filaments and the wrapping filament from the respective guide openings to combine them to form a cable.
It is preferred that the drives of the rotor and the winding device are mutually adjustable so that with the same apparatus cables having different lay lengths can be formed.
For making cables with only one wrapping filament the apparatus is provided with one rotor spool and the deflecting - edge for the wrapping filament is positioned diametrically opposite the deflecting edge for the bundle. Such an arrangement enables the wrapping filament and the core filament to be assembled accurately at a point which is on the axis of the rotor spindle.
If several wrapping filaments are used, then their deflecting edges should be preferably close together and dia-metrically opposite the deflecting edge of the bundle. Such an arrangement causes the wrapping filaments to lie against one another so that a uniform build-up of the cable is obtained. It is preferred to use a common deflecting edge for the wrapping filaments.
It has been found that the cable can be more readily formed if the wrapping filament runs to a cable-forming sleeve at an angle larger than that at which bundle runs to the cable-forming sleeve. For accurate setting of position of the wrapping filament or filaments on the bundle it is important that the distance betwwen the deflecting edge for the bundle and the point of formation of the cable and the distance between the deflecting edge(s) for the wrapping filament(s) and said point of formation are continuously adjustable. When a cable -:
.

73'9 with one wrapping filament is made, the settiny of these distances makes it possible for the wrapping to be displaced ~' half a pitch length relative to the core filaments which form the bundle.
Example.
Test strips of reinforced rubber contain two cord plies. The cord plies are separated by a 1 mm thick layer of rubber and covered on either side with a 1.5 mm thick layer of rubber. The strips are cured in a mould measuring 100 by 12 cm for 30 minutes at 150C. After they have been cured, the strips are cut into test specimens 10 cm wide. In each ply the end count of the cords is 20 per inch (epi) and the cords in a ply are at an angle of 16 and 22, respectively to the longitudinal i direction of the strip.
Modulus measurement is carried out with an Instron dynamometer, using a gauge length of 72.6 cm and a speed of

2 cm/min. The strips contain steel cords A and B made up of filaments 0.25 mm in diameter. The cords A are cables according to the invention and consist of four filaments which form a bundle on which one wrapping filament is laid. The lay length is 10 mm.
The wrapping filament is displaced half a lay length relative - to the lay of the bundle filaments. The cords B are of the known construction of five filaments that are twisted together;
lay length 9.5 mm. The modulus values found are listed in the !.' table below:
Modulus expressed in kN at 1% elongation Strips with cords:
A B
Cord angle with longitudinal o~ 22 16 22 16 direction of the strip Modulus kNi 3.0 10.4 2.8 9.2 1~4;~'739 The invention is further described below with reference to the accompanying drawings in which:
Figure 1 is a view, partly in longitudinal section and partly an inside elevation of an apparatus according to the invention;
Figure 2 is a side elevation of a cable according to the invention and manufactured with the apparatus of Figure l; and Figure 3 shows the cable of Figure 2 in cross-section.
Referring to Figure 1, in a stand 1 there are mounted four superimposed delivery spools 2 from which four filaments

3 can be eachrun off through an adjustable filament tensioner 4 to a guiding eyelet 5. A delivery spool 6 is supported in a cradle 7. A spring-loaded band brake 8 serves to keep a filament 9 under sufficient tension as it runsoff the spool 6.
The cradle 7 is mounted on a rotor spindle 10 by means of roller bearings in such a way that the common centre of gravity of the cradle and the spool 6 is positioned sufficiently below the spindle 10 to prevent the cradle and the spool rotating with the spindle. A filament guiding eyelet 11 is located on the hollow spindle 10 at its end adjacent the spool 6. Fixedly secured to the hollow spindle 10 is a cup-shaped body 12 provided with two thread guiding edges 13 which are made of abrasion resistant material. In a lateral opening of the spindle 10 is a filament guiding pin 14. The spindle 10 is supported in a block 15 and provided with a pulley 16 arranged to be driven by a motor 17.
On the end of the spindle 10 remote from the spool 6 there is mounted a filament pre-forming unit 18. The cup-shaped body 12, the spindle 10 and the filament pre-forming unit 18 ~-~
together form a rotor. The filament pre-forming unit 18 is formed by a hollow cylindrical body 19 containing guiding eylets 20 and 21. On the body 19 there is fixedly secured a disk 22.
Also on the body 19 there is mounted a disk 23 which can be " -- 1 0 --, .. . , . , . :

:

3~
shifted and rotated relatlve to the disk 22 and can be fixed on the body 19. The disks 22 and 23 are provided with guiding eyelets 24 and 25 respectively. The edges of the eyelet 24 are slightly curved whereas one edge of the eyele-t 25 is strongly curved. A disk 27 provided with a hub is mounted rotatably and shiftably on the body 19 on which it can be secured by means of bolts (not shown). Against the disk 27 there is placed a disk 28 which can be rotated relative to the disk 27 and can be secured thereto with means not shown in the drawing. In the disk 27 there are provided filament passages 31 and 32. In the disks 27 and 28 there are guiding eyelets 29 and 30 respectively.
The edges of the eyelet 29 are slightly curved, whereas one edge of the eyelet 30 is strongly curved. All filament guiding members are formed of an abrasion resistant material.
The apparatus shown in Figure 1 comprises a cable-forming sleeve 33, roller pairs 34 and 35 driven at an adjustable speed, a false-twisting device 36, and a winding device 37.
~`' The pitch length of the bent filaments 3 and the filament 9 is determined by the speed of the spindle 10 and the speed at which ' 20 the filaments are pulled through the apparatus by means of the roller pair 34. The amplitudes of the helices of the filaments 3 and the filament 9 are determined by the deflection imparted to the filaments 3 on the edge of the guiding eyelet 25 and to the filament 9 on the edge of the guiding eyelet 30. By setting the filament tension and by varying the deflection angles by adjusting the disks 23 and 28 the desired amplitude is set.
Referring to Figures 2 and 3 four core filaments 38 form a helically shaped central bundle of the cable. It can be seen that the filaments 38 are positioned beside one another and are not wound about one another. An equally thick filament 39 is helically wound about the bundle and is displaced half a pitch length relative to the pitch of the bundle.

104'~739 The apparatus operates clS described below. The filaments 3 are bundled in the eyelet 5 and are guided past the spool 6 over the guide rings 13 and via the pin 14 to the centre of the shaft 10. The bundle is fed via the guiding eyelet 20 and the bore 26 through the eyelets 2~ and 25, which are somewhat displaced relative to one another, in such a way that the bundle of filaments 3 is sharply deflected over the edges of the guiding eyelet 25 resulting in a permanent helically shaped deformation of the filaments 3. The bundle runs through the passage 31 to the entrance of the forming sleeve 33.
The filament 9 from the delivery spool 6 passes through the guiding eyelet 11, and the bore of the shaft 10 to the eyelet 21 and from there via the passage 32 and through the guiding eyelets 29 and 30, which are also displaced relative to each other, in such a way that the filament 9 is helically deformed as a result of the large deflection over the edge of the guiding eyelet 30.
The collectively bent filament 3 are wrapped with the :
preformed filament 9 at the entrance of the forming sleeve to form the cable. The resulting cable passes via the roller pair 34, the false-twisting device 36 and the roller-pair 35 to the winding device 37.

.

Claims

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. A reinforcing cable for an elastomeric article comprising helically formed filaments, at least one single steel wrapping filament wound on at least two single steel core filaments, wherein the core filaments are of helical shape and are positioned beside and against each other so that they form a helix and each core filament is in line contact with at least one other of the core filaments, the line of contact being parallel to the direction of the filament, and said at least one wrapping filament is in the form of a helix having the same hand and the same pitch as helix formed by the core filaments and is positioned on the inside of the helix formed by the core filaments.

2. A reinforcing cable according to claim 1, provided with one wrapping filament, wherein the wrapping filament is shifted half a pitch length relative to the pitch of the core filaments.

3. A reinforcing cable according to claim 2, contain-ing 3-8 core filaments, and wherein the core filaments and said at least one wrapping filament have the same diameter, which is in the range of 0.15 to 0.50 mm, and the lay length is 25 to 100 times the wire diameter.

4. A process of manufacturing a filament cable according to claim 1, comprising running off a plurality of metal core filaments from a plurality of stationary delivery spools, assembling the core filaments to form a bundle of core filaments, guiding the bundle over a first deflecting edge having a small radius of curvature and displacing the point of contact of the edge of the filament helically along the surface of the bundle thereby permanently deforming the filament to cause the filament to acquire a helical shape, and running off at least one metal wrapping filament from at least one spool, guiding said at least one further filament over at least one further deflecting edge and displacing the point of contact of the further deflecting edge along the surface of the filament to cause the filament to become permanently deformed and acquire a helical shape having the same hand as that of the bundle, and winding said at least one wrapping filament on the bundle so that helical shape of said at least one wrapping filament has the same pitch as the bundle.

5. A process according to claim 4, wherein the fila-ments are steel filaments.

6. A process according to claim 4, wherein the bundle comprises two to five filaments and one wrapping filament is so laid on the filaments of the bundle that it is shifted half a pitch length.

7. A process according to claim 4, wherein that all filaments have the same diameter which is in the range of 0.15 to 0.50 mm and the pitch of the filaments is 25 to 100 times the filament diameter.