The invention discloses an immunoglobulin-binding magnetic bead, comprising a porous matrix and one or more magnetic particles embedded in said matrix, wherein said matrix comprises a porous polymer and at least 10 mg/ml Fc-binding proteinaceous ligands covalently coupled to said porous polymer.

Disclosed is a reverse flow multi-stage sedimentation rake-free thickening device relating to the field of slime water treatment. The device includes a feed assembly, a guide assembly, and a clean coal collection assembly. The guide assembly also includes a central tank body and coal slurry flows from the upper part of the central tank body to the inner side wall of the central tank body through the feed assembly and the medicament, and then flows to the middle of the central tank body through the guide assembly. After the reaction, the bubbles carry the fine coal slime and move up to the clean coal collection assembly. The clean coal collection assembly is located above the outlet of the guide assembly, and the clean coal collection assembly is sequentially provided with a central collection area, a defoaming area, and a diversion settlement area from the middle to the outside.

A magnetic filter 10 for a central heating system is disclosed, the filter 10 including a connection assembly 12, a canister 14, and a magnetic element 16, the connection assembly 12 including an inlet 24 and an outlet 26 for connection to a central heating circuit; the canister 14 having an interior separation chamber which is fluidly connected with the inlet 24 and outlet 26 for allowing fluid to flow into the inlet 24, through the separation chamber, and out of the outlet 26; and the magnetic element 16 being removably positionable on the outside of the canister 14, the canister 14 and the connection assembly 12 forming a sealed flow path comprising the inlet 24, the interior separation chamber and the outlet 26, and the connection assembly 12 further including a closable drain outlet 28b for draining fluid and magnetic particles from within the canister 14, internally of the magnetic element 16.

An intelligent magnetic microfluidic concentrator employs a technique of feeding ores circumferentially and allowing tailings to overflow centrally upward. The intelligent magnetic microfluidic concentrator comprises a sorting system consisting of an ore feeding chute, an overflow chute, an overflow tank, a sorting tank, and a magnetic system, the overflow tank is disposed at an upper portion of the sorting tank, the ore feeding chute is disposed at the top of the overflow tank, the ore feeding chute feeds an ore slurry to the upper portion of the sorting tank circumferentially along an inner wall of the sorting tank, and the tailings overflow out upward from the overflow tank disposed centrally and located at the upper half portion of the sorting tank. A magnetic microfluidic concentrator and a complete set of beneficiation equipment are also provided.

A water treatment apparatus using a lamella structure according to an embodiment of the present invention includes a first treatment tank which includes a plurality of inclined plates and is configured to pass water subject to treatment between the inclined plates adjacent to each other and a second treatment tank which is installed at a rear end of the first treatment tank to accommodate the water subject to treatment and into which bubbles are supplied, wherein the plurality of inclined plates include positive electrode plates and negative electrode plates that are alternately arranged, and the water subject to treatment passes between the positive electrode plate and the negative electrode plate.

An assembly and process for treating contaminated fluid. The assembly has a reactor including a tank with an internal weir, a low speed mechanical mixer, and means for delivering fluids to subsequent stages. A first stage has polymer make-up and coagulant feed units plus a dilution means which deliver modified contaminated fluid to a second stage with a low impact feed pump to preserve flocculant integrity. In a third stage, first sub-assemblies of self-cleaning magnetic shuttles capture at least some of the magnetic flocculant that escapes in the clarified effluent. In a fourth stage, second magnetic drum-type sub-assemblies separate magnetite particles from the flocculant, return the magnetite to the reactor, and send the non-magnetic solids to a fifth stagedewatering. This stage has a receptor for accommodating solids that are optionally treated with a coagulant and flocculant to produce solids to be transported to a landfill.

A microfluidic device may be provided. The microfluidic device comprises a processing surface having an aperture. The microfluidic device comprises a liquid ejection channel. The liquid ejection channel guides to the aperture. The microfluidic device comprises a first liquid injection channel guiding to the liquid ejection channel. The first liquid injection channel has a first end and a second end and is arranged to provide a fluid flow from the first end to the second end. At least a portion of the first liquid injection channel is closer to the processing surface than (both) the first and second ends to sediment particles.

A removal device for removing gas bubbles and/or dirt particles from a liquid in a liquid conduit system includes a main channel for a main flow, the main channel having an entry and an exit which are configured to be connected to the conduit system; a housing which defines an inner space; at least one supply channel extending from the main channel to the inner space; at least one return channel extending from the inner space back to the main channel; and a branch flow control member positioned in the main channel. The branch flow control member being movable between a first position to branch off at least a part of the incoming main flow into the inner space via the supply channel and a second position to branch off at least a part of the incoming main flow into the inner space via the supply channel.

Disclosed is a reverse flow multi-stage sedimentation rake-free thickening device relating to the field of slime water treatment. The device includes a feed assembly, a guide assembly, and a clean coal collection assembly. The guide assembly also includes a central tank body and coal slurry flows from the upper part of the central tank body to the inner side wall of the central tank body through the feed assembly and the medicament, and then flows to the middle of the central tank body through the guide assembly. After the reaction, the bubbles carry the fine coal slime and move up to the clean coal collection assembly. The clean coal collection assembly is located above the outlet of the guide assembly, and the clean coal collection assembly is sequentially provided with a central collection area, a defoaming area, and a diversion settlement area from the middle to the outside.

A magnetite level monitoring device for a magnetic filter in a central heating system, the magnetic filter including a separation chamber, an inlet to the chamber and an outlet from the chamber, and a magnetic element disposed within the chamber for attracting magnetic particles and removing the magnetic particles from the system water as it flows through the chamber, and the monitoring device including: a housing for placing adjacent to the outside of the separation chamber; a magnetometer mounted to the housing; a magnetic field guide mounted to the housing, the magnetic field guide being disposed between the magnetometer and the outside of the separation chamber, when the housing is mounted to the separation chamber; and output means adapted to issue a notification when the output from the magnetometer exceeds a predetermined threshold.