There is provided a binder configured to bind a bound member by being struck out from a binding machine. The binder includes a substantially U-shaped base member that is plastically deformable, and a surface member that is provided on a surface of the base member. There is also provided a coupled binder including plural binders. Each of the binders is coupled to other of the binders on front and back surfaces thereof. The front and back surfaces of each of the binders are not provided with the surface member.

An apparatus to process a plurality of electrical wires as well as a method that uses the apparatus are indicated. The apparatus includes a feed device, a stationary holding device, a holding device that is non-stationary along a linear guiding direction, a non-stationary bundling device that is separate from the non-stationary holding device and a controller connected to a drive of the non-stationary bundling device. The stationary holding device and/or the non-stationary holding device are configured to twist the respectively held end of the wires; The controller controls the drive in such a way that a distance between a bundling segment of the non-stationary bundling device and the non-stationary holding device assumes a specified or a specifiable distance.

An apparatus to process a plurality of electrical wires as well as a method that uses the apparatus are indicated. The apparatus includes a feed device, a stationary holding device, a holding device that is non-stationary along a linear guiding direction, a non-stationary bundling device that is separate from the non-stationary holding device and a controller connected to a drive of the non-stationary bundling device. The stationary holding device and/or the non-stationary holding device are configured to twist the respectively held end of the wires; The controller controls the drive in such a way that a distance between a bundling segment of the non-stationary bundling device and the non-stationary holding device assumes a specified or a specifiable distance.

The invention discloses a gasket placement mechanism for a high speed wire rod baling machine and a related gasket structure. The baling machine comprises two pressing plates (2) reciprocating in the direction of compression, and filing-prevention disks (25) which are in a circular shape and have a certain thickness are fixed on two opposite compression surfaces of the pressing plates. Four diagonals of the pressing plates along with the filing-prevention disks are provided with four wire grooves (18) banding steel wires, and four diagonals of the pressing plates are respectively provided with conveying rollers (16) and gasket rolls (17). A numerical control motor drives the conveying rollers to rotate so as to drive the gasket rolls to be unfolded horizontally, and the unfolded gaskets (14) penetrate through a channel formed by the filing-prevention disks to reach the position of the wire grooves of the pressing plates. The gaskets are in a parallelogram shape or a long and narrow rectangle shape, and the adjacent gaskets are connected by means of the hypotenuses or long edges; sawtooth holes (14c) or line-like concave indentations are provided; conveying tooth holes (14a) are provided at the corresponding unfolded positions of the gasket rollers. The gasket placement mechanism achieves the mechanization and automation for gasket placement, specialized production of the gasket is facilitated, and operating efficiency is improved.

The invention discloses a gasket placement mechanism for a high speed wire rod baling machine and a related gasket structure. The baling machine comprises two pressing plates (2) reciprocating in the direction of compression, and filing-prevention disks (25) which are in a circular shape and have a certain thickness are fixed on two opposite compression surfaces of the pressing plates. Four diagonals of the pressing plates along with the filing-prevention disks are provided with four wire grooves (18) banding steel wires, and four diagonals of the pressing plates are respectively provided with conveying rollers (16) and gasket rolls (17). A numerical control motor drives the conveying rollers to rotate so as to drive the gasket rolls to be unfolded horizontally, and the unfolded gaskets (14) penetrate through a channel formed by the filing-prevention disks to reach the position of the wire grooves of the pressing plates. The gaskets are in a parallelogram shape or a long and narrow rectangle shape, and the adjacent gaskets are connected by means of the hypotenuses or long edges; sawtooth holes (14c) or line-like concave indentations are provided; conveying tooth holes (14a) are provided at the corresponding unfolded positions of the gasket rollers. The gasket placement mechanism achieves the mechanization and automation for gasket placement, specialized production of the gasket is facilitated, and operating efficiency is improved.

A cable bundle taping device adapted to wind a tape on a coiled cable bundle includes a support frame, a conveying device mounted on the support frame and adapted to convey the tape to a standby position, a first driving wheel rotatably mounted on the support frame and having a slot extending radially inward from an outer edge of the first driving wheel, and a tape binding mechanism arranged on a side of at least one sidewall of the first driving wheel near a bottom of the slot and opposite to the tape in the standby position. The coiled cable bundle is bonded to an end of the tape at the standby position and pushed to the bottom of the slot. The tape is wound on the coiled cable bundle by rotating the tape binding mechanism under driving of the first driving wheel.

A cable bundle taping device adapted to wind a tape on a coiled cable bundle includes a support frame, a conveying device mounted on the support frame and adapted to convey the tape to a standby position, a first driving wheel rotatably mounted on the support frame and having a slot extending radially inward from an outer edge of the first driving wheel, and a tape binding mechanism arranged on a side of at least one sidewall of the first driving wheel near a bottom of the slot and opposite to the tape in the standby position. The coiled cable bundle is bonded to an end of the tape at the standby position and pushed to the bottom of the slot. The tape is wound on the coiled cable bundle by rotating the tape binding mechanism under driving of the first driving wheel.

A system includes a tool for installing a cable material around a set of elongate members. The tool includes a housing; a cartridge detachably connected to the housing; and a jaw detachably connected to the housing. The cartridge has a length of cable material. The jaw is configured to extend around the set of elongate members to install the length of cable around the set of elongate members. A welding horn is detachably connected to the housing. At least one processor is configured to read a programmable chip. The programmable chip stores a set of parameters for at least one of the cartridge, the jaw, or the welding horn.

A system includes a tool for installing a cable material around a set of elongate members. The tool includes a housing; a cartridge detachably connected to the housing; and a jaw detachably connected to the housing. The cartridge has a length of cable material. The jaw is configured to extend around the set of elongate members to install the length of cable around the set of elongate members. A welding horn is detachably connected to the housing. At least one processor is configured to read a programmable chip. The programmable chip stores a set of parameters for at least one of the cartridge, the jaw, or the welding horn.

A pair of jaws for a twist tying machine enables a user to tie products with a small outer diameter. The pair of jaws includes a fixed jaw that has a generally cylindrical housing attached to the twist tying machine and extending to a flat distal edge. A fixed jaw channel is formed within the fixed jaw and configured to accommodate a product tie from the twist tying machine. A movable jaw is rotatably attached to the twist tying machine and extends to a movable jaw distal end. A movable jaw channel is formed within the movable jaw and configured to accommodate the product tie from the fixed jaw channel. Closing the movable jaw against the fixed jaw enables the product tie to travel through the movable jaw around a product, and through the fixed jaw creating a tie around the product.