Method for providing a web with unique lines of weakness

What is claimed is: 1. A method of producing a fibrous web comprising a fibrous structure comprising fibrous elements, the fibrous web having a machine direction, a cross direction, and a Z-direction, discrete portions of the fibrous web being displaced in the Z-direction to extend above a plane formed by said machine and cross directions to form a plurality of collectively elongate spaced apart and repeating lines of weakness, the method comprising the steps of: providing a rotatable ring roll having at least one circumferential groove extending about an outer surface thereof; providing a rotatable pattern roll having circumferential protrusions extending from an outer surface thereof, wherein each of the circumferential protrusions along an axis of rotation for the pattern roll are each individually circumferentially positioned about the outer surface of the pattern roll to produce a selected perforation design having a differential perforation strength in the cross direction; positioning the circumferential protrusions on the pattern roll in selected cooperative alignment with the circumferential groove in the ring roll; closely spacing the circumferential protrusions on the pattern roll from the circumferential groove by a distance selected to permit the circumferential protrusions on the pattern roll to overstrain by moving select fibrous elements of the fibrous elements of the fibrous web apart to weaken the discrete portions of the fibrous web without contacting the circumferential groove when the circumferential protrusions on the pattern roll are received in the circumferential groove; rotating the ring roll and the pattern roll while passing the web therebetween; and, deflecting a first portion of the fibrous web and the individual fibrous elements comprising the first portion of the fibrous web contacting said cooperatively aligned circumferential protrusions and said circumferential groove in said Z-direction such that at least one of the circumferential protrusions overstrain by moving said individual fibrous elements comprising the first portion of the fibrous web apart in said Z-direction to extend above the plane formed by the machine and cross directions of the web to a first perforation strength; deflecting a second portion of the fibrous web and the individual fibrous elements comprising the second portion of the fibrous web contacting said cooperatively aligned circumferential protrusions and said circumferential groove in said Z-direction such that at least one of the circumferential protrusions overstrain by moving said individual fibrous elements comprising the second portion of the fibrous web apart in said Z-direction to extend above the plane formed by the machine and cross directions of the web to a second perforation strength, the first perforation strength being different from the second perforation strength, the overstrained individual fibrous elements comprising the first portion of the fibrous web and the overstrained individual fibrous elements comprising the second portion of the fibrous web forming the spaced apart and repeating lines of weakness; and, whereby the selected perforation design comprising said deflected select individual fibrous elements in said Z-direction is formed in the web. 2. The method of claim 1 wherein each of the circumferential protrusions extending from the outer surface of the pattern roll move apart and deflect individual fibers in said Z-direction of the web by mating with the at least one circumferential groove extending about the outer surface of the ring roll. 3. The method of claim 2 including selecting the degree of deflection of individual fibers in said Z-direction of the web when the circumferential protrusions mate with the at least one circumferential groove to control a degree of weakening of the web in the selected perforation design. 4. The method of claim 2 including selecting at least the size of the circumferential protrusions to control a degree of weakening of the web when the circumferential protrusions move apart and deflect individual fibers in said Z-direction of the web to produce the selected perforation design. 5. The method of claim 2 including selecting at least the pitch of the circumferential protrusions to control a degree of weakening of the web when the circumferential protrusions move apart and deflect individual fibers in said Z-direction of the web to produce the selected perforation design. 6. The method of claim 2 including selecting at least the slope of the circumferential protrusions to control a degree of weakening of the web when the circumferential protrusions move apart and deflect individual fibers in said Z-direction of the web to produce the selected perforation design. 7. The method of claim 1 including penetrating the web to thereby form individual perforations extending generally in the cross direction of the web and to also form individual perforations extending generally in the machine direction of the web. 8. A method of producing a fibrous web comprising a fibrous structure comprising fibrous elements, the fibrous web having a machine direction, a cross direction, and a Z-direction, discrete portions of the fibrous web being displaced in the Z-direction to extend above a plane formed by the machine and cross directions to form a plurality of collectively elongate spaced apart and repeating lines of weakness, the method comprising the steps of: providing a ring roll having a plurality of circumferential grooves extending about an outer surface thereof; providing a pattern roll having a plurality of circumferential protrusions extending from an outer surface thereof, wherein each of the circumferential protrusions being individually circumferentially positioned about the outer surface of the pattern roll in relation to the other protrusions to produce a selected perforation design having a differential perforation strength in the cross direction; aligning each of the circumferential protrusions on the pattern roll with a corresponding one of the circumferential grooves in the ring roll; arranging each of the circumferential protrusions on the pattern roll to produce the selected perforation design; closely spacing the circumferential protrusions on the pattern roll from the circumferential groove by a distance selected to permit the circumferential protrusions on the pattern roll to overstrain by moving select fibrous elements of the fibrous elements of the fibrous web apart to weaken the discrete portions of the fibrous web without contacting the circumferential groove when the circumferential protrusions on the pattern roll are received in the circumferential groove; rotating the ring roll and the pattern roll while passing the web therebetween; and, deflecting a first portion of the fibrous web and the individual fibrous elements comprising the first portion of the fibrous web contacting said cooperatively aligned circumferential protrusions and said circumferential groove in said Z-direction such that at least one of the circumferential protrusions overstrain by moving said individual fibrous elements comprising the first portion of the fibrous web apart in said Z-direction to extend above the plane formed by the machine and cross directions of the web to a first perforation strength; deflecting a second portion of the fibrous web and the individual fibrous elements comprising the second portion of the fibrous web contacting said cooperatively aligned circumferential protrusions and said circumferential groove in said Z-direction such that at least one of the circumferential protrusions overstrain by moving said individual fibrous elements comprising the second portion of the fibrous web apart in said Z-direction to extend above