One or more techniques and/or systems are disclosed for a mixing assembly. The mixing assembly includes a rigid shaft; an end connection component coupled to a first end of the rigid shaft; and a start connection component coupled to a second end of the rigid shaft opposite to the first end of the rigid shaft. Further, a motor drive is coupled to the start connection component and configured to rotate the start connection component, the rigid shaft, and the end connection component. A collar is arranged between the start connection component and the motor drive. A connector is arranged between the collar and the start connection component. The connector includes threads configured to threadably attach to an opening in an intermediate bulk container for mixing a liquid housed therein.

A method for disposing of solid refinery waste is disclosed. The method includes removing solid waste constituents from inside a refinery tank using excavating machinery, delumping the solid waste constituents, and conveying the delumped solid waste constituents into a mobile tank. The method further includes transporting the delumped solid waste constituents in the mobile tank to a burning facility, adding at least one diluent, mixing, and pumping from the mobile tank a flowable mixture of refinery waste and the at least one diluent at the burning facility.

The present invention relates to a kind of pigment preparation, in particular to a modified layered silicate novel barrier and shielding pigment and its preparation method. It is a layer silicate with exchangeable anticorrosive ions as a template, using metal oxides or metal salts, inorganic acids to synthesize nano-spherical zinc phosphate, phosphate, molybdate, borate or tungstate, with rare earth cerium, strontium, lanthanum or praseodymium doped modification of the pigment. The invention uses silicate as a template to effectively control the agglomeration of nanoparticles during the liquid phase deposition process, avoiding the multiple cleaning and sewage treatment processes required by using surfactants and solvents. What is more valuable is lamellar silicic acid. The salt itself has certain anti-corrosion properties and is economical. At the same time, the physical barrier and exchangeable anti-corrosion ions of the lamellae further improve the anti-corrosion properties of the pigment, making the pigment highly active and shielding.

The present invention relates to a kind of pigment preparation, in particular to a modified layered silicate novel barrier and shielding pigment and its preparation method. It is a layer silicate with exchangeable anticorrosive ions as a template, using metal oxides or metal salts, inorganic acids to synthesize nano-spherical zinc phosphate, phosphate, molybdate, borate or tungstate, with rare earth cerium, strontium, lanthanum or praseodymium doped modification of the pigment. The invention uses silicate as a template to effectively control the agglomeration of nanoparticles during the liquid phase deposition process, avoiding the multiple cleaning and sewage treatment processes required by using surfactants and solvents. What is more valuable is lamellar silicic acid. The salt itself has certain anti-corrosion properties and is economical. At the same time, the physical barrier and exchangeable anti-corrosion ions of the lamellae further improve the anti-corrosion properties of the pigment, making the pigment highly active and shielding.

An apparatus has a container conveyor configured to transport a container to locations within the apparatus. The locations include a liquid station comprising a liquid source configured to dispense a liquid to the container, an additive station comprising an additive source configured to dispense an additive to the container, a distribution station accessible to a user and configured to receive the container, and a blending station separate from the liquid station, the additive station, and the distribution station. The blending station includes a blending mechanism configured to blend, in the container, the liquid and the additive to form a mixture. The blending station also has a cleaning chamber with a cleaning mechanism configured to clean remains of the mixture from the blending mechanism and the cleaning chamber.

A contrast agent mixer (100) for providing a foam type contrast agent is presented. The mixer (100) comprises a holding arrangement (109) for supporting a mixing container, a substantially homogeneous circular mixer blade (110) for mixing a contrast powder with a liquid in the mixing container (200), and a controller configured to control a rotational speed of the mixer blade (110) and a vertical distance (D) between the holding arrangement (109) and the mixer blade (110). A method, a system and a mixing container are also presented.

A contrast agent mixer (100) for providing a foam type contrast agent is presented. The mixer (100) comprises a holding arrangement (109) for supporting a mixing container, a substantially homogeneous circular mixer blade (110) for mixing a contrast powder with a liquid in the mixing container (200), and a controller configured to control a rotational speed of the mixer blade (110) and a vertical distance (D) between the holding arrangement (109) and the mixer blade (110). A method, a system and a mixing container are also presented.

The invention relates to a preparation process of a modified polyamide wax for coatings and a formed coating. The coating includes 0.5-5 parts by weight of modified polyamide wax; the preparation process of the modified polyamide wax for coating includes the following steps: S1, ratio of raw materials:raw materials include water-based polyamide wax, water-based polyurethane, polyoxyethylene monostearate, the first composite modifier, organic amine, organic solvent, the second composite modifier, deionized water; S2, prepare the first complex; S3, add organic amine, organic solvent and the second composite modifier is evenly mixed, and the temperature is raised to 100-120 C. until the water-based polyamide wax is completely dissolved to obtain the first intermediate modifier; S4, deionized water is heated up and slowly added to the first intermediate modifier in the process. The coating system prepared by the invention has good leveling, stability and sag resistance.

The invention relates to a preparation process of a modified polyamide wax for coatings and a formed coating. The coating includes 0.5-5 parts by weight of modified polyamide wax; the preparation process of the modified polyamide wax for coating includes the following steps: S1, ratio of raw materials:raw materials include water-based polyamide wax, water-based polyurethane, polyoxyethylene monostearate, the first composite modifier, organic amine, organic solvent, the second composite modifier, deionized water; S2, prepare the first complex; S3, add organic amine, organic solvent and the second composite modifier is evenly mixed, and the temperature is raised to 100-120 C. until the water-based polyamide wax is completely dissolved to obtain the first intermediate modifier; S4, deionized water is heated up and slowly added to the first intermediate modifier in the process. The coating system prepared by the invention has good leveling, stability and sag resistance.

The present disclosure relates to an application apparatus for mixing a plurality of components for producing a multicomponent mixture, in particular a polyurethane foam, and for introducing and/or applying the multicomponent mixture into and/or onto an object, in particular a lithium-ion battery, comprising: a mixing tube having a first closed end and a second end for discharging the multicomponent mixture from the mixing tube, wherein the mixing tube has a mixing space, a plurality of injection units arranged on the mixing tube, each configured to inject one of the plurality of components into the mixing space, a mixer arranged in the mixing space, configured to mix the injected components with one another, and a moving device configured to move the mixer between the first end and the second end. Furthermore, an application system comprising the application apparatus and a method for mixing a plurality of components for producing a multicomponent mixture and for introducing and/or applying the multicomponent mixture into and/or onto an object is disclosed.