A spool wire storage device includes a cabinet body, a door for providing access to an interior of the cabinet body, and a plurality of U-shaped spooled wire storage trays mounted within the cabinet body. The U-shaped spooled wire storage trays include a U-shaped bottom shelf, and a U-shaped sidewall extending upward from the U-shaped bottom shelf. The U-shaped bottom shelf and the U-shaped sidewall form an open front portion of the storage tray extending between terminal ends of the U-shaped sidewall. The U-shaped bottom shelf declines from the open front portion rearward. A spool of wire is located in each of the plurality of U-shaped spooled wire storage trays. A base is located beneath the cabinet body. The base forms a first fork channel and a second fork channel configured to receive forklift forks.

A high thread/yarn count woven textile fabric (800) is provided. The high thread/yarn count woven textile fabric (800) includes a plurality of warps (810), and a plurality of wefts (820). The high thread/yarn count woven textile fabric (800) having 250 to 3000 picks per inch in the weft (820) which can be extended up to 6000. Further, at least two recycled separable multi-filament parallel yarn picks are woven in groups together in the weft (820). It is provided that the recycled separable multi-filament parallel picks are separable and distinguishable from other picks very clearly. Furthermore, a denier of the recycled separable multi-filament yarn is range from 5 to 50. Usually, the thread/yarn count of woven textile fabric (800) is in between 400 to 3000 which can go up to 6000.

Disclosed is a method for manufacturing a cable-type secondary battery, which includes successively supplying a first electrode member, a separator ribbon and a second electrode member around a rod-shaped winding core, wherein a width of the first electrode member and a width of the second electrode member are respectively smaller than a winding circumference, and a width of the separator ribbon is greater than the winding circumference.

Cable retainers may include a panel having a pair of loop locks. The loop locks may engage each other to form a loop. The cable retainer may include a first and a second retention loop. Each retention loop may have a finger with a slot formed at a fold line of the finger. Each retention loop may also have a flap with a tab formed at a fold line of the flap. The finger and the flap of the first retention loop may be located directly across the panel from one another. The finger of the second retention loop may be located at a first end of the panel while the flap of the second retention loop may be located at a second end of the panel. The tabs and slots of each retention loop may interlock to form a rectangular cable passage. The cable retainer may be formed entirely of paper and may be formed without adhesive.

Cable retainers may include a panel having a pair of loop locks. The loop locks may engage each other to form a loop. The cable retainer may include a first and a second retention loop. Each retention loop may have a finger with a slot formed at a fold line of the finger. Each retention loop may also have a flap with a tab formed at a fold line of the flap. The finger and the flap of the first retention loop may be located directly across the panel from one another. The finger of the second retention loop may be located at a first end of the panel while the flap of the second retention loop may be located at a second end of the panel. The tabs and slots of each retention loop may interlock to form a rectangular cable passage. The cable retainer may be formed entirely of paper and may be formed without adhesive.

Cable retainers for cables are disclosed. The cable retainers may include a panel having a pair of loop locks. The loop locks may engage each other to form a loop. The cable retainer may include a first and a second retention loop. Each retention loop may have a finger with a slot formed at a fold line of the finger. Each retention loop may also have a flap with a tab formed at a fold line of the flap. The finger and the flap of the first retention loop may be located directly across the panel from one another. The finger of the second retention loop may be located at a first end of the panel while the flap of the second retention loop may be located at a second end of the panel. The tabs and slots of each retention loop may interlock to form a rectangular cable passage. The cable may also include a reinforcement structure disposed in a retention loop. The reinforcement structure may be stepped reinforcement structure. The cable retainer may be formed entirely of paper and may be formed without and adhesive.

A multilayer structured spun yarn (20) includes core component fibers (21) and sheath component fibers (24). The core component fibers (21) are a multifilament yarn. The sheath component fibers (24) include inner layer fibers (22) and outer layer fibers (23). The inner layer fibers (22) are untwisted and entirely bundled by the outer layer fibers (23) wound therearound in one direction. The sheath component fibers (24) are a blend of short fibers A with an average fiber length of 10 to 25 mm and short fibers B with an average fiber length of longer than 25 mm and 51 mm or shorter. The multifilament yarn of the core component fibers serves as a connecting yarn. The blending proportion of the short fibers A is preferably 0.1 to 20 mass % with respect to 100 mass % of the multilayer structured spun yarn (20). Accordingly, the present invention provides a multilayer structured spun yarn whose yarn properties and properties when the yarn is formed into a fabric are made comparable to those of conventional products by optimizing the yarn structure even when fibers with a short fiber length are contained, a method for producing the same, a fabric, and clothing.

A multilayer structured spun yarn (20) includes core component fibers (21) and sheath component fibers (24). The core component fibers (21) are a multifilament yarn. The sheath component fibers (24) include inner layer fibers (22) and outer layer fibers (23). The inner layer fibers (22) are untwisted and entirely bundled by the outer layer fibers (23) wound therearound in one direction. The sheath component fibers (24) are a blend of short fibers A with an average fiber length of 10 to 25 mm and short fibers B with an average fiber length of longer than 25 mm and 51 mm or shorter. The multifilament yarn of the core component fibers serves as a connecting yarn. The blending proportion of the short fibers A is preferably 0.1 to 20 mass % with respect to 100 mass % of the multilayer structured spun yarn (20). Accordingly, the present invention provides a multilayer structured spun yarn whose yarn properties and properties when the yarn is formed into a fabric are made comparable to those of conventional products by optimizing the yarn structure even when fibers with a short fiber length are contained, a method for producing the same, a fabric, and clothing.

A spool for use in a wire braiding machine, for example, which has a bi-tapered design including a central cylindrical section and a pair of tapered (e.g., frusto-conical or parabolic) flanges having surfaces that slope inwardly toward the cylindrical section. In this manner, the spool provides a progressively widening wire fill area, as measured along a direction parallel to the rotational axis of the bobbin, as the wound wire advances progressively radially outwardly from the cylindrical section. This widening wire fill area aids in preventing the formation, propagation and buildup of wire winding defects, such that the wire is more likely to unspool or pay-out from the spool without losing tension, snagging or breaking.

A spool for use in a wire braiding machine, for example, which has a bi-tapered design including a central cylindrical section and a pair of tapered (e.g., frusto-conical or parabolic) flanges having surfaces that slope inwardly toward the cylindrical section. In this manner, the spool provides a progressively widening wire fill area, as measured along a direction parallel to the rotational axis of the bobbin, as the wound wire advances progressively radially outwardly from the cylindrical section. This widening wire fill area aids in preventing the formation, propagation and buildup of wire winding defects, such that the wire is more likely to unspool or pay-out from the spool without losing tension, snagging or breaking.