A plain stepped splice lay-out scheme is presented that can be used for splicing strips to one another that comprise longitudinally arranged cords. The strips can take the form of a conveyor belt, transmission belt, timing belt, elevator belt, a rubber track or a reinforcing strip. The splice is opt
A plain stepped splice lay-out scheme is presented that can be used for splicing strips to one another that comprise longitudinally arranged cords. The strips can take the form of a conveyor belt, transmission belt, timing belt, elevator belt, a rubber track or a reinforcing strip. The splice is optimised for uniform bending stiffness and maximum strength retention. The cross section of the strip and the splice are substantially equal: there is no increase in thickness or width at the splice. The splice lay-out is characterised by the fact that the abutments (130)—those positions where cord ends (111, 121) meet—are positioned sufficiently far away from one another and by preference as far away from one another as possible. Preferred embodiments in terms of length common between cords of the different strips and local strength are given.
대표청구항▼
1. A splice connecting a first strip to a second strip, both strips comprising a number ‘M’ of parallel cords in a strip matrix, where, in a splice arrangement, each cord end of said first strip abuts to a cord end of said second strip at an abutment, and wherein at least one group of ‘N’ contiguous
1. A splice connecting a first strip to a second strip, both strips comprising a number ‘M’ of parallel cords in a strip matrix, where, in a splice arrangement, each cord end of said first strip abuts to a cord end of said second strip at an abutment, and wherein at least one group of ‘N’ contiguous cords is present with ‘N’ being equal to or larger than 12, wherein the distance taken along the splice between the first and last abutment of said at least one group is ‘Lgroup’ and said abutments within said group are regularly spaced apart over said length ‘Lgroup’ by a number of intervals, said interval being the smallest longitudinal distance between any pair of abutments within said group, wherein the taxi-distance between any pair of said abutments in said group is larger than four, said taxi-distance being the sum ‘i+j+1’ of the number of cords ‘i’ in between abutments of said pair plus ‘1’ and the number ‘j’ of intervals between abutments of said pair along the longitudinal direction of said splice. 2. The splice according to claim 1 wherein said interval is ‘Lgroup/(N−1)’. 3. The splice according to claim 1 wherein said taxi-distance between any pair of said abutments within said at least one group of ‘N’ contiguous cords is larger than a number ‘n’, ‘n’ being five or six or seven or any number up to ‘nmax’, ‘nmax’ being the largest number for which there is still at least one possible splice arrangement for a given value of ‘N’. 4. The splice according to claim 3 wherein, for a given ‘n’, the splice arrangement within said at least one group of ‘N’ contiguous cords with the largest common length is chosen, said common length being the sum of the intervals common between adjacent cords of said first and second strip within said at least one group of ‘N’ contiguous cords. 5. The splice according to claim 1 wherein just one abutment is present on the start of the first interval and just one abutment on each one of said interval ends within said at least one group of ‘N’ contiguous cords. 6. The splice according to claim 3 wherein said length ‘Lgroup’ is equal to or larger than ‘N/n’ times the critical length of said cord in said strip, said critical length being that length where the force needed to pull out a single, non-edge cord out of strip matrix material is equal to the breaking load of said cord. 7. The splice according to claim 1 wherein all ‘M’ cords in said splice arrangement are in said group of ‘N’ contiguous cords. 8. The splice according to claim 1 wherein a splice matrix or said strip matrix is a polymer material and said cords are steel cords. 9. The splice according to claim 8 wherein said polymer material is an elastomer or a rubber material. 10. The splice according to claim 8 wherein said polymer is a thermoplastic polymer. 11. The splice according to claim 10 wherein said splice matrix material comprises a mixture of a co-polymer and a base polymer, said co-polymer being a grafted co-polymer, a block co-polymer or a random co-polymer functionalised for enabling adhesion to said steel cords. 12. The splice according to claim 1 wherein said strips have a breaking load, said splice having a breaking load that is at least larger than half of said breaking load of said strips. 13. The splice according to claim 12 wherein said splice has a breaking load that is larger than 55% of the lower breaking load of any one of said first and second strip. 14. A strip comprising a splice according to claim 1. 15. The splice according to claim 2 wherein said taxi-distance between any pair of said abutments within said at least one group of ‘N’ contiguous cords is larger than a number ‘n’, ‘n’ being five or six or seven or any number up to ‘nmax’, ‘nmax’ being the largest number for which there is still at least one possible splice arrangement for a given value of ‘N’.
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이 특허에 인용된 특허 (6)
Worcester Winthrop S. (Akron OH), Belt and method of splicing the same.
Veronesi, William A.; Hawkes, Justin R.; Milton-Benoit, John M.; Wesson, John P.; El-Wardany, Tahany I.; Guo, Changsheng; Li, Wenlong, Joint configuration for a load bearing assembly.
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