A pair of waveform disks for use in a disk-pack turbine used, for example, in systems and methods in at least one embodiment for separating fluids including liquids and gases into subcomponents by passing the fluid into an expansion chamber and then through at least a portion of a waveform pattern present between at least two disks. The disks having waveform patterns on at least one side.

A magnetic device for capturing metal wear particles in suspension in a lubrication fluid, the magnetic device being for inserting in a straight-line insertion direction of the magnetic device into a wall of a casing via a through orifice serving to put an inside volume of the casing containing the lubrication fluid into communication with an outside volume outside the casing, the magnetic device presenting a longitudinal axis X, the longitudinal axis X being for putting into coincidence with the direction for inserting the magnetic device into the casing, the magnetic device comprising a permanent magnet suitable for attracting the metal particles and a presence-detector member for detecting the metal particles attracted by the permanent magnet.

An air dust removal method, comprising the following steps: 1) using an ionization dust removal electric field to adsorb particulate matters in intake air; and 2) using the ionization dust removal electric field to charge an intake air electret element. The method can effectively remove dust in air, the dust removal ability is better, and the dust removal efficiency is higher.

Remotely-controllable internal devices for insertion into a biological lumen and similar spaces within biological organisms; and magnetic systems for remote control thereof. Embodiments include mechanisms for linear motion within a lumen, mechanisms for payload release of therapeutic, diagnostic, and examination materials, and anchoring mechanisms for affixing a device to the outer wall of a lumen for a variety of medical and biological purposes. Related embodiments provide additional features including gradual payload release and reversibly-anchoring mechanisms Different functionalities (motion, payload release, anchoring) are independently-controllable through embodiment configurations featuring differing magnetic force thresholds and orthogonally-oriented magnetic responses.

Provided herein are devices and methods for sample isolation comprising a planar member configured to rotate around a bearing, and a plurality of apertures positioned at an angle to the planar member. Exemplary embodiments relate generally to the field of sample isolation, and more particularly to sample isolation using centrifugal and magnetic forces.

Device for capturing and removing magnetic material from a flow of material, wherein the device includes a plurality of magnet rod assemblies for capturing magnetic material in a flow of material passing the magnet rod assemblies and where the magnet rod assemblies are removably arranged to an installation plate assembly of the device, where each magnet rod assembly includes a magnet rod comprising at least two magnet segments encapsulated in a non-magnetic material, wherein the magnet rod assemblies comprise a combined attachment and wiper assembly adapted for being received and accommodated in a slot in the installation plate assembly and detachable attachment to a locking groove in the extensions of the slot.

There is provided a fluid treatment separator and a method of treating fluid such as tailings from tailings ponds resulting from oil sands production. A fluid treatment separator may be used for treatment of a mixture containing at least oil and water. The separator includes a mixing chamber, an inlet and at least one outlet. The mixing chamber defines a flow path between the inlet and the at least one outlet. The inlet includes a nozzle arranged to introduce turbulence to the mixture along the flow path. At least one magnet is arranged to apply a magnetic field to the mixture along the flow path.

A system for separating particles or cells by magnetic ratcheting has a vector of spaced apart magnetic bars on a substrate. The system can be used to separate and concentrate magnetic objects based on iron oxide content. For cells, different phenotypes may be separated based on surface expression of proteins or molecules that are bound to magnetic beads. A magnetic field generator generates a cycling magnetic field that acts to separate magnetic particles or cells from non-magnetic particles or cells in a solution.

Microfluidic devices are described that include a microfluidic channel, a first array of one or more magnets above the microfluidic channel, each magnet in the first array having a magnetic pole orientation opposite to a magnetic pole orientation of an adjacent magnet in the first array, and a second array of one or more magnets beneath the microfluidic channel, each magnet in the second array having a magnetic pole orientation opposite to a magnetic pole orientation of an adjacent magnet in the second array. The first array is aligned with respect to the second array such that magnetic fields emitted by the first array and second array generate a magnetic flux gradient profile extending through the channel. An absolute value of the profile includes a first maximum and a second maximum that bound a local minimum. The local minimum is located within the microfluidic channel or less than 5 mm away from a wall of the microfluidic channel. Methods of using the new devices are also described.

A discontinuous wall magnet having an opening or channel is provided. A bead separation magnet having a discontinuous or segmented wall is also provided. The segmented wall causes bead formation to form in a segmented or gapped ring to allow for easier manual pipetting. Also provided are systems and kits having the inventive magnets. Methods of purifying a macromolecule using the inventive magnets are also provided.