An electric permanent magnet chuck, comprising a casing (1), the casing being provided thereon with at least one open inner cavity; reversible magnetic material (2) is provided at a lower portion of the inner cavity, and a coil (3) is arranged in the inner cavity along an outer wall of the reversible magnetic material; a magnetic pole (4) is superposed and fixed in the inner cavity, an annular groove being provided at a lower surface of the magnetic pole, and permanent magnetic material (5) that matches the annular groove being disposed in the annular groove. The electric permanent magnet chuck has the advantages of a simple structure, low processing difficulty, good sealing performance, small magnetic loss and so on.

An improved machining system for use in a CNC mill for the production of thin, hardened metal implement such as bed knifes includes a laminate mounting substrate with holes for receiving a pair of locator pins therein, at least one of the locator pins configured to displace longitudinally relative to the mounting substrate but not laterally which allows the system to accommodate a wide variety of metal implements. The system also includes magnetic cladding to protect the metal implement from metal chips being attracted by a magnetic element positioned beneath the mounting substrate to the finished product, allowing for higher quality cutting heads in the mill and a more efficient production of finished implements. A method of forming such implements is also provided.

This work clamping device including a receiving member which has a first contacting surface which comes into contact with a first circumference position of an outer circumference surface of a columnar portion of a work and a second contacting surface which comes into contact with a second circumference position of the outer circumference surface of the columnar portion, an attraction member which is provided in the receiving member and which is made of a ferromagnetic material or a magnet, a pre-clamping positioning member which is attached to the columnar portion and which temporarily hold the columnar portion to the receiving member by being attracted to the attraction member by magnetic force, and a clamp mechanism which presses the columnar portion temporarily positioned by the pre-clamping positioning member toward the receiving member.

An apparatus for storing fasteners, typically screws, and guiding them during insertion into a surface employs a block of material having a lower face for bringing into proximity with surface and an upper face, parallel to the lower face. A set of screws are embedded in the block with their central axes parallel such that the screw heads are accessible to a driver from an upper face and screw tips are located within the block adjacent to a lower face. The screws are preferably deployed in side-by-side rows, advantageously in one or more rectangular or hexagonal grid. A driver acting on the head of one of screws is effective to drive the screw through block and into surface to reach a final inserted position.

A magnet chuck has a piston assembly including a tube shaped permanent magnet and a core yoke able to move on the interior of a cylinder tube. The permanent magnet is provided on the outer periphery of the core yoke, is magnetized in the radial direction, and a magnetic sensor is attached to the side surface of the cylinder tube.

The invention relates to a magnetic holding device (10), in particular a clamping device, comprising a holding surface (9) and at least one first permanent magnet (11), characterized in that the holding device (10) comprises at least one second permanent magnet (12) which is rotatably mounted relative to the at least one first permanent magnet (11) about a rotational axis (3), whereby the pole direction (2) of the second permanent magnet (12) is rotatable relative to the pole direction (1) of the first permanent magnet (11).

A rail processing device (1) comprising at least a first (3A) and a second work station (3B) provided on a common frame (30), and configured to alternately lock a rail (2) when the latter is being processed, each work station (3A, 3B) comprising at least a first magnetic anchorage plane (4) configured to cooperate with a web (2A) of the rail (2) when the latter is being processed in the respective station, and a transport system (50A, 50B) to move the rail (2) from the first work station (3A) to the second work station (3B) and vice versa.

Systems and methods for depositing a thin film layer onto a flexible ferromagnetic substrate include a porous block in a deposition zone and a plurality of magnets embedded within the porous block. The magnets provide a downward force on a flexible ferromagnetic substrate being transported over the porous block, e.g., in a reel-to-reel system. Pressurized gas is forced upward through the porous block, providing an upward force that balances the downward force and supports the substrate at a desired height above the porous block. The substrate is thus held flat during transport through the deposition zone, enabling uniform deposition of a thin film layer.

An apparatus, including an external component of a medical device configured to generate a magnetic flux that removably retains, via a resulting magnetic retention force, the external component to a recipient thereof, wherein the external component is configured to enable the adjustment of a path of the generated magnetic flux so as to vary the resulting magnetic retention force.

Magnetic sample holders for abrasive operations include an array of magnets embedded in a matrix material. Each magnet of the array is positioned between about 0 mm and about 4 mm from at least one adjacent magnet of the array. Exposed surfaces of the magnets of the array are coplanar with a planar working surface of the matrix material. Methods of forming a polycrystalline diamond compact element include magnetically securing an alloy sample to an array of magnets embedded in a matrix. Each of the magnets of the array is within about 4 mm of at least one adjacent magnet of the array. A portion of the alloy sample is abraded away, and the alloy sample is positioned proximate to diamond grains and a substrate. The alloy sample, diamond grains, and substrate are subjected to a high pressure/high temperature process to sinter the diamond grains.