Apparatus for a drill powered wire puller are disclosed. In an embodiment the drill powered wire puller includes a center plate, a cradle plate, a housing, a support, the support including a receiver, and a capstan. The center plate is coupled with the cradle plate at a proximal end. The cradle plate includes a U-shaped notch and two hooks or catches which are configured to couple the cradle plate with a powered rotary tool, such as a drill. The right side of the center plate is coupled with a housing, the left side of the center plate is coupled with a support. The left side of the support is coupled with a capstan. The support laterally offsets the receiver to align a longitudinal axis of the receiver with a radially curved portion of the capstan.

A tether includes a housing defining a cord aperture, a spool located within the housing and configured to rotate about a spool axis in either an extending direction or a rewinding direction, a cord wound around the spool and configured to pass through the cord aperture, a biasing member coupled to the spool, and a retractor lock. The biasing member biases the spool to rotate in the rewinding direction to retract the cord into the housing. The retractor lock is movable between a locked position and an unlocked position. The retractor lock prevents rotation of the spool when in the locked position and allows rotation of the spool in the unlocked position. The retractor lock is moves from the locked position to the unlocked position in response to a threshold cord force on the cord.

A tool-operated adjustment device includes a housing supporting a rotatable spool that is operably coupled to a tension line. The spool is configured to rotate about a first axis in a first direction to wind the tension line, and to rotate in a second direction opposite the first direction to unwind the tension line. The device includes a socket pivotally coupled to the housing and configured to rotate about a second axis. The socket is selectively coupled to the spool to drive rotation of the spool in the first direction. The socket is configured to removably connect and disconnect to a tool configured to rotate the socket about the second axis. The device includes a release mechanism that is configured to selectively release the spool such that the spool is free to rotate in either the first or second direction in response to manual forces applied to the release mechanism.

The present invention discloses a rotary self-lock catch. As a rope penetrates into the take-up cavity of the take-up reel and a tail end of the rope is limited at a boundary between a through hole and a hollowed cavity, when the rotary knob is rotated, the take-up reel can be driven to rotate together, so that the rope is wound in the take-up cavity by the take-up reel, and the rotary knob is allowed to rotate along one direction, so that an effect of tightening the rope can be realized.

A rotary wire-receiving rack comprises a winding structure, a shaft, a first handle, a lid, a locking slider, and a second handle. The winding structure includes two bars arranged longitudinally in parallel and two rods arranged horizontally in parallel for winding cables. Both ends of the two rods are linked to the bars respectively. The shaft is arranged parallel to and located between the rods. The shaft is pivoted on the bars. The first handle and the lid are respectively fixed at the two ends of the shaft. The lid has a locking hole, and the locking slider is slidably installed on the rod near the locking hole. The locking slider is formed with a locking pin that cooperates with the locking hole. The second handle is pivoted at the end of the bar which closing to the locking hole and having a recess for clamping a cable.

A strap winding, storage, and dispensing assembly for storing and dispensing a plurality of straps includes a spacing element engaged to and extending between a pair of plates. Each of a set of strap stowing units engaged to the pair of plates comprises a spindle having a winding element and a braking element operationally engaged thereto. The spindle can engage a respective end of a strap so that the strap is removably engaged to the spindle. The winding element is positioned to selectively rotate the spindle, in a first direction, to coil the strap therearound. The braking element is engaged to a respective one of the plates and is positioned to selectively engage the spindle, to prevent rotation thereof, to retain the strap therearound. The braking element also is positioned to selectively disengage the spindle so that the spindle can rotate in a second direction to uncoil the strap.

The present invention is a retractable pet leash with a variable brake system to control a pet. The variable braking system can be engaged or disengaged by the user via 3 methods. The first method is via a handle that is directly connected to the brake. The second method, also actuated by the user is a one touch brake system that uses the rotation of the reel to slowly apply the variable brake over several rotations of the reel. The third method allows the user to set the length of the leash cord and when the set length of the cord is met, engages the one touch brake system. The retractable pet leash provides a system to set the length of the leash cord being let out and ensures that the leash cord is kept taught between the user and the pet and notifies the user when the set length has been reached and applies variable braking in a steady and predictable manner to smoothly stop the pet.

A retractable reel system includes a reel, a gear assembly, a paddle wheel and a spring. The reel includes a concentric wheel shaft where the reel and wheel shaft rotate to wind and unwind a length of material from the reel. The gear assembly engages with an end of the wheel shaft to provide a gear reduction ratio between the wheel shaft and an output shaft of the gear assembly. The paddle wheel is connected to and concentric with the output shaft, and the paddle wheel includes a paddle that extends beyond an outer edge of the paddle wheel that rotates with the paddle wheel. The spring is arranged outside the outer edge of the paddle wheel. The spring is compressed by the paddle to store an energy when the reel is rotated to unwind the length of material from the reel. The stored energy is used to rotate the reel to wind the length of material around the reel.

A retractable reel system includes a reel, a gear assembly, a paddle wheel and a spring. The reel includes a concentric wheel shaft where the reel and wheel shaft rotate to wind and unwind a length of material from the reel. The gear assembly engages with an end of the wheel shaft to provide a gear reduction ratio between the wheel shaft and an output shaft of the gear assembly. The paddle wheel is connected to and concentric with the output shaft, and the paddle wheel includes a paddle that extends beyond an outer edge of the paddle wheel that rotates with the paddle wheel. The spring is arranged outside the outer edge of the paddle wheel. The spring is compressed by the paddle to store an energy when the reel is rotated to unwind the length of material from the reel. The stored energy is used to rotate the reel to wind the length of material around the reel.

A fish tape for use with a fish tape tool. The fish tape includes an inner core formed of a first material, and an outer sheath surrounding the inner core formed of a second material that has a lower coefficient of friction than the first material.