A single-heating stage method for reclaiming or recovering metals like nickel and vanadium from a petroleum waste byproduct has three steps: melting the petroleum waste byproduct in a reducing atmosphere, generating agglomerated metal in the melted byproduct, and lifting the agglomerated metal to an exposed surface of the melted byproduct. The metal precipitates out of the molten byproduct, agglomerates into a separate portion, and rises to an exposed surface of the melted petroleum waste byproduct even though the metal may have greater density than the molten petroleum waste byproduct. The original petroleum waste byproduct stratifies into a byproduct remnant and the agglomerated metal disk. The agglomerated metal disk is separable from the byproduct remnant and may be additionally separated into constituent metals in those embodiments with multiple metals in the disk.

There is provided a particle classification system comprising: a classifier including: a vat defining an interior cavity, a feeder conduit upstream of the interior cavity, an overflow conduit in fluid communication between a top of the interior cavity and outside the vat, an underflow conduit downstream of the interior cavity and a controllable underflow valve fluidly connected to a bottom of the interior cavity, the underflow valve controlled to be either in an open configuration in which the interior cavity is in fluid communication with the underflow conduit or in a closed configuration in which the interior cavity is sealed from the underflow conduit; a feed preparation circuit upstream of the feeder conduit; a rejection circuit downstream of the overflow conduit, and a beneficiation circuit downstream of the underflow conduit. There is also provided a method of classifying fluid-borne particles comprising obtaining a feed containing high-density particles.

A separator device for removing particles from suspension in a liquid includes a housing having first and second chambers with apertures for ingress and egress of liquid into the first chamber. Means are provided for setting up a swirl of liquid within the first chamber. Apertures enable flow of liquid between the first chamber and the second chamber. Means are also provided for setting up a swirl of liquid within the second chamber. The swirl in the second chamber is in substantially the opposite direction to the swirl in the first chamber, and there is no substantial flow in the second chamber which is in the same direction as the swirl in the first chamber.

A separator comprises a housing and a separator chamber contained within the housing, an inlet and outlet to the separator chamber and a dividing member for substantially dividing the separator chamber into a first chamber and a second chamber. A flow path is provided between the first and second chambers for allowing flow to circulate between the first and second chambers, and guide means for creating opposing flow paths in the second chamber for slowing flow through the second chamber.

A connection assembly is disclosed for connecting a magnetic separator into a central heating system circuit, the magnetic separator including a housing, a separation chamber within the housing, and externally threaded inlet and outlet ports extending from the housing. The connection assembly comprises: a fitment adapted to be received within at least one of the ports of the separator, the fitment including a bore for carrying fluid from/to the central heating circuit to/from the separator; a threaded connector disposed around the bore for securing the fitment to the or each port, the threaded connector having a hand grip area for facilitating tightening of the connector by hand; and a removable force transfer element receivable between the fitment and the threaded connector for transferring force between the threaded connector and the fitment.

An apparatus, comprising a magnetically conductive conduit having a fluid entry port, a fluid impervious boundary wall and a fluid discharge port defining a fluid impervious flow path through the magnetically conductive conduit, at least one end of the conduit having a taper forming a planar surface extending from an outer to an inner surface; an electrical conductor comprising a length of an electrical conducting material having a first and second conductor lead, the electrical conductor coiled with at least one turn to form an uninterrupted coil of electrical conductor encircling a section of the outer surface of the magnetically conductive conduit; and an electrical power supply operably connected to at least one of the first and second conductor leads, wherein the at least one coiled electrical conductor is thereby energized to provide a magnetic field having lines of flux directed along a longitudinal axis of the magnetically conductive conduit.

A separator device 10 for removing particles from suspension in a fluid including a housing 12, having first and second apertures 96 for ingress and egress of fluid into and out of the housing 12; a first separator chamber 38 disposed at one end of the housing; a second separator chamber 40 disposed at the other end of the housing, and a central chamber disposed between the first and second separator chambers 38, 40, the first and second separator chambers 38, 40 being apertured for ingress and egress of fluid from the central chamber and each containing obstruction means to slow the flow of fluid within the chamber.

The present invention provides methods and compositions for separating cells from a sample containing erythrocytes. The method is for recovering desired cells from a sample containing the desired cells, erythrocytes and undesired cells comprising: a) contacting the sample with a composition, said composition comprising: i) an erythrocytes aggregation reagent ii) at least one antigen recognizing moiety coupled to a magnetic particle, wherein said particle with said at least one antigen recognizing moiety specifically binds to at least one antigen specific for one or more undesired cellular components; b) applying simultaneously i) gravity sedimentation for sedimentation of erythrocytes and ii) a magnetic field gradient to said sample for immobilizing said magnetic particle generating a pellet and a supernatant phase, and c) recovering the desired cells from the supernatant phase. Compositions for the use within the present method are also disclosed.

Apparatus for use in a treatment of fluid in a fluid circuit of a heating or cooling system. A vessel (102) defines an open upper end (104), a circulating fluid inlet port (104) in a side wall (105) thereof and a fluid outlet port (106) in a lower end (107) thereof, the lower end (107) providing an internal floor of the vessel (102) and the fluid outlet port (106) open to the internal floor of the vessel (102). The open upper end (103) of the vessel (102) is provided with a removable lid (108) that defines a dosing port (109) and an air vent port (110). A permanent magnet collector (112) for collecting magnetic particles on an external collection surface (113) thereof is removably locatable within the vessel (102). A method of treating fluid in a fluid circuit of a heating or cooling system.