For alignment of rotational shafts, two devices for attachment to circular faces of two shaft segments. Each of the two devices has a laser photoelectric device for ascertaining a dimension of displacement of the two shafts from a desired axis of rotation relative to each other. Each of the two devices having a base surface with two linear contact edges designed to engage with a circumferential surface of a shaft and to ensure alignment between the device and an axis of rotation of the shaft to within a tolerance compatible with alignment tolerances of the shaft. Each of the two linear contact edges includes at least two terminal end regions and a center region together defining a line contact at linear intersection of two surfaces meeting at a non-zero angle linear contact edges designed to affix and release from the shaft surface, and to ensure parallel alignment between the device and an axis of rotation of the shaft to a precision allowing measurements to within tolerances required by machinery driven by the shaft. The base surface of at least one of the devices has been modified from its commercially-delivered condition to provide raised rails designed to improve tactile feedback of to a user of the alignment between the base and an axis of rotation of the shaft, and has affixed thereto two rails designed to improve tactile feedback of to a user of the alignment between the base and an axis of rotation of the shaft. Each base has a magnet and a switch to vary magnetic flux for affixation and release from the shaft surface. Each device has brackets designed to securely and reproducibly position laser photoelectric devices relative to the base and axis of rotation of the shaft. The attaching includes a human placing at least one of the devices slightly askew relative to the axis of rotation of the shaft, and the human gently twisting the device to allow the liner contact edges to seat on the circumferential surface of the shaft, to provide tactile feedback to the human to confirm parallel alignment between the at least one device's laser photoelectronic device and the axis of rotation of the shaft.

A modular angular alignment clocking mechanism employs a hollow housing, a threaded interface ring, and a compression spring. The threaded interface ring is inserted into the housing and is followed by the compression spring. The housing is configured to thread onto one cylinder. Another cylinder is then threaded into the threaded interface ring and torqued to specification after clocking.

A modular angular alignment clocking mechanism employs a hollow housing, a threaded interface ring, and a compression spring. The threaded interface ring is inserted into the housing and is followed by the compression spring. The housing is configured to thread onto one cylinder. Another cylinder is then threaded into the threaded interface ring and torqued to specification after clocking.

A method for sensing misalignment of a rotating shaft includes rotating the shaft. A distance from a sensor on the shaft to a first rim of a first coupling mounted to an end of the shaft is sensed as the shaft rotates. A change in the distance from the first sensor to the first rim of the first coupling is determined based on the sensed distance. An angle of the first coupling based on the change in the distance from the first sensor to the first rim of the first coupling during one revolution of the shaft is determined based on the sensed change in the distance from the first sensor to the first rim. An angle of the shaft is determined based on the sensed distance from the first sensor to the first rim of the first coupling representing the sensed change in the distance from the first sensor to the first rim.

A method for sensing misalignment of a rotating shaft includes rotating the shaft. A distance from a sensor on the shaft to a first rim of a first coupling mounted to an end of the shaft is sensed as the shaft rotates. A change in the distance from the first sensor to the first rim of the first coupling is determined based on the sensed distance. An angle of the first coupling based on the change in the distance from the first sensor to the first rim of the first coupling during one revolution of the shaft is determined based on the sensed change in the distance from the first sensor to the first rim. An angle of the shaft is determined based on the sensed distance from the first sensor to the first rim of the first coupling representing the sensed change in the distance from the first sensor to the first rim.

Disclosed is a mounting point locator tool for positioning a bracket of a drawer slide assembly such that the drawer slide assembly is square with the face frame of a cabinet carcass. The locator tool comprises a base perpendicularly extending from a first end of a rod. A bracket holding fixture is connected to a second end of the rod. In one embodiment, the base, the rod, and the fixture are ridgidly connected. In an alternate embodiment, the base is comprised of a sleeve extending generally perpendicular from a planar plate and slidingly engaged with the rod. The sleeve includes a pair of sides connected at a right angle for alignment with the face frame. The fixture includes a pair of prongs having edges spaced a predetermined distance and a set of slots having a predetermined width for releasably securing the bracket.

A detection device includes: a body; a first set of at least three contact areas on the body to contact a corresponding set of at least three contact areas of a central processing unit (CPU) cover; and a second set of at least three contact areas on the body to contact a set of at least three contact areas on heatsink componentry. An incorrect assembly position of a heatsink is indicated when one or more points of contact with the heatsink componentry and the CPU cover is incorrect.

A detection device includes: a body; a first set of at least three contact areas on the body to contact a corresponding set of at least three contact areas of a central processing unit (CPU) cover; and a second set of at least three contact areas on the body to contact a set of at least three contact areas on heatsink componentry. An incorrect assembly position of a heatsink is indicated when one or more points of contact with the heatsink componentry and the CPU cover is incorrect.

An alignment apparatus for accurately aligning a replacement spindle with a pre-existing axle shaft to facilitate repairing a damaged axle assembly. The alignment apparatus may comprise an axle clamp assembly and a spindle clamp assembly. The axle clamp assembly may be mountable to an axle shaft. The axle clamp assembly may be self-centering and self-aligning. Similarly, the spindle clamp assembly may be mountable to a spindle. The spindle clamp assembly may be self-centering and self-aligning. The axle clamp assembly may be fixable to the spindle clamp assembly. By fixing the axle clamp assembly to the spindle clamp assembly, a desired alignment between the axle shaft and the spindle may be achieved.

An alignment apparatus for accurately aligning a replacement spindle with a pre-existing axle shaft to facilitate repairing a damaged axle assembly. The alignment apparatus may comprise an axle clamp assembly and a spindle clamp assembly. The axle clamp assembly may be mountable to an axle shaft. The axle clamp assembly may be self-centering and self-aligning. Similarly, the spindle clamp assembly may be mountable to a spindle. The spindle clamp assembly may be self-centering and self-aligning. The axle clamp assembly may be fixable to the spindle clamp assembly. By fixing the axle clamp assembly to the spindle clamp assembly, a desired alignment between the axle shaft and the spindle may be achieved.