Methods and systems for no-glue pocketed spring unit construction. Rows of pocketed springs modules, comprising more than two pocketed springs surrounding a central hole, can be automatically loaded onto an assembler; pocketed spring-surrounded openings can be automatically aligned with welding phalanges; and probe/anvil welding pairs can be inserted into modules in different rows of modules, closed around polymer pocket fabric, and activated to weld rows of modules together without glue; without a user manually loading rows of modules onto the assembler.

Methods and systems for no-glue pocketed spring unit construction. Rows of pocketed springs modules, comprising more than two pocketed springs surrounding a central hole, can be automatically loaded onto an assembler; pocketed spring-surrounded openings can be automatically aligned with welding phalanges; and probe/anvil welding pairs can be inserted into modules in different rows of modules, closed around polymer pocket fabric, and activated to weld rows of modules together without glue; without a user manually loading rows of modules onto the assembler.

A pocketed spring unit comprising an array of springs 120 located in pockets 180 formed by discrete superposed webs 140 of pocketing material joined together by welds W between the springs, wherein the welds are located at alternately opposite ends of the pocketed springs.

FIG. 1 shows generally a pocketed spring unit at a first stage of manufacture. A row of coil springs 120 (only the end one of which is visible) is introduced by an inserter mechanism 130 into position between axially disposed webs 140a and 140b of pocketing material. The webs 140a and 140b are fed from supply reels (not shown via guide rollers 150. The springs 120 are partly compressed and are pushed between plates 160 towards the webs 140 by the inserter 130 in the direction of Arrow A1.

Once the springs are between the webs 140 a pair of ultrasonic welding tools 170a and 170b joins the webs together at weld locations W between the springs to form individual pockets 180 for the springs. One of the tools is a sonotrode/horn and the other is a base/anvil. Successive rows of springs are encapsulated by welds W that alternate between the axial ends of the springs, so that one is at an upper axial end and the next is at a lower axial end. The webs 140 may also be welded together along their edges (not shown)—i.e. at the ends of the rows—and between adjacent springs in the same row, to fully form the pockets.

A pocketed spring unit comprising an array of springs 120 located in pockets 180 formed by discrete superposed webs 140 of pocketing material joined together by welds W between the springs, wherein the welds are located at alternately opposite ends of the pocketed springs.

FIG. 1 shows generally a pocketed spring unit at a first stage of manufacture. A row of coil springs 120 (only the end one of which is visible) is introduced by an inserter mechanism 130 into position between axially disposed webs 140a and 140b of pocketing material. The webs 140a and 140b are fed from supply reels (not shown via guide rollers 150. The springs 120 are partly compressed and are pushed between plates 160 towards the webs 140 by the inserter 130 in the direction of Arrow A1.

Once the springs are between the webs 140 a pair of ultrasonic welding tools 170a and 170b joins the webs together at weld locations W between the springs to form individual pockets 180 for the springs. One of the tools is a sonotrode/horn and the other is a base/anvil. Successive rows of springs are encapsulated by welds W that alternate between the axial ends of the springs, so that one is at an upper axial end and the next is at a lower axial end. The webs 140 may also be welded together along their edges (not shown)—i.e. at the ends of the rows—and between adjacent springs in the same row, to fully form the pockets.

A spring feeding device configured to feed a spring (9) comprises a feeding member (60) delimiting a channel (68), a pusher (70) configured to push the spring (9) along the channel (68) delimited by the feeding member (60), and a drive mechanism con-figured to displace both the feeding member (60) and the pusher (70) such that the feeding member (60) and the pusher (70) move in opposite directions (91, 92).

A spring feeding device configured to feed a spring (9) comprises a feeding member (60) delimiting a channel (68), a pusher (70) configured to push the spring (9) along the channel (68) delimited by the feeding member (60), and a drive mechanism con-figured to displace both the feeding member (60) and the pusher (70) such that the feeding member (60) and the pusher (70) move in opposite directions (91, 92).

A pocketed spring assembly comprises a plurality of parallel strings of individually pocketed springs. A dimensionally stabilizing substrate is secured to at least some of the strings on one of the top and bottom surfaces of the strings. A scrim sheet is secured to at least some of the strings on an opposed surface of the strings to maintain the positions of the strings. The dimensionally stabilizing substrate is laterally rigid enough to maintain length and width dimensions of the coil spring assembly. However, the dimensionally stabilizing substrate is flexible enough to allow the pocketed spring assembly to be roll packed for shipping.

A pocketed spring assembly comprises a plurality of parallel strings of individually pocketed springs. A dimensionally stabilizing substrate is secured to at least some of the strings on one of the top and bottom surfaces of the strings. A scrim sheet is secured to at least some of the strings on an opposed surface of the strings to maintain the positions of the strings. The dimensionally stabilizing substrate is laterally rigid enough to maintain length and width dimensions of the coil spring assembly. However, the dimensionally stabilizing substrate is flexible enough to allow the pocketed spring assembly to be roll packed for shipping.

Methods and systems for no-glue pocketed spring unit construction. Rows of pocketed springs modules, comprising more than two pocketed springs surrounding a central hole, can be automatically loaded onto an assembler; pocketed spring-surrounded openings can be automatically aligned with welding phalanges; and probe/anvil welding pairs can be inserted into modules in different rows of modules, closed around polymer pocket fabric, and activated to weld rows of modules together without glue; without a user manually loading rows of modules onto the assembler.

Methods and systems for no-glue pocketed spring unit construction. Rows of pocketed springs modules, comprising more than two pocketed springs surrounding a central hole, can be automatically loaded onto an assembler; pocketed spring-surrounded openings can be automatically aligned with welding phalanges; and probe/anvil welding pairs can be inserted into modules in different rows of modules, closed around polymer pocket fabric, and activated to weld rows of modules together without glue; without a user manually loading rows of modules onto the assembler.