A mixer and method for mixing are provided. The mixer includes a housing having a fluid inlet, an additive inlet, and an outlet, with the housing defining a mixing chamber in fluid communication with the fluid inlet, the additive inlet, and the outlet. The mixer also includes an impeller disposed in the mixing chamber, wherein, when rotated, the impeller draws fluid through the fluid inlet. The mixer also includes a slinger disposed in the mixing chamber and configured to receive the fluid from the impeller and to receive an additive from the additive inlet. When rotated, the slinger slings the fluid and the additive radially outwards. The mixer further includes a stator disposed at least partially around the slinger, with the stator including vanes spaced circumferentially apart so as to define flowpaths therebetween.

A technique facilitates various types of cementing applications, such as a downhole cementing applications along a wellbore. The technique utilizes a mixer having a rigid body and a flexible skirt disposed along at least a portion of the interior of the rigid body. The mixer further comprises a cement blend inlet and a fluid inlet through which cement blend and fluid are introduced into the mixer to form a cement slurry. The flexible skirt is constructed to enable selective deformation, e.g. flexing, during formation of the cement slurry to reduce or prevent the formation of cement slurry caking within the mixer.

A blender has a mixing chamber for reception of materials to be blended. A mixing screw is mounted at a bottom of the mixing chamber for mixing materials within the mixing chamber and delivering mixed materials to an outlet feeding a processing line. Heaters are mounted within the mixing chamber for drying blend material in the mixing chamber.

An apparatus and method for mixing and milling dry ingredients with water to produce a homogenous beverage. The apparatus may include, for example, a water supply, a tubing system, a dry ingredient container, a splash-back prevention unit, and a mixer capable of emulsifying and homogenizing a slurry, which, in accordance with some embodiments, may include large ground course particles (such as nuts) and water. The apparatus may also include a pump configured to move the slurry and homogenized beverage through the tubing, and a motor, which, in accordance in some embodiments in accordance with the present disclosure, controls the mill.

A blender has a mixing chamber for reception of materials to be blended. A mixing screw is mounted at a bottom of the mixing chamber for mixing materials within the mixing chamber and delivering mixed materials to an outlet feeding a processing line. Heaters are mounted within the mixing chamber for drying blend material in the mixing chamber.

A mixer and method for mixing are provided. The mixer includes a housing including a fluid inlet, an additive inlet, and an outlet. The housing defines a mixing chamber in fluid communication with the fluid inlet, the additive inlet, and the outlet. The mixer also includes an impeller disposed in the mixing chamber. When rotated, the impeller pumps fluid through the fluid inlet. The mixer also includes a slinger disposed in the mixing chamber and configured to receive the fluid from the impeller and to receive an additive from the additive inlet. When rotated, the slinger slings the fluid and the additive radially outwards. The mixer further includes a flush line extending between the mixing chamber and the additive inlet. The flush line is receives, from the mixing chamber, a portion of the fluid pumped by the impeller and to deliver the portion of the fluid to the additive inlet.

A mixer and method for mixing are provided. The mixer includes a housing including a fluid inlet, an additive inlet, and an outlet. The housing defines a mixing chamber in fluid communication with the fluid inlet, the additive inlet, and the outlet. The mixer also includes an impeller disposed in the mixing chamber. When rotated, the impeller pumps fluid through the fluid inlet. The mixer also includes a slinger disposed in the mixing chamber and configured to receive the fluid from the impeller and to receive an additive from the additive inlet. When rotated, the slinger slings the fluid and the additive radially outwards. The mixer further includes a flush line extending between the mixing chamber and the additive inlet. The flush line is receives, from the mixing chamber, a portion of the fluid pumped by the impeller and to deliver the portion of the fluid to the additive inlet.

A technique facilitates various types of cementing applications, such as a downhole cementing applications along a wellbore. The technique utilizes a mixer having a rigid body and a flexible skirt disposed along at least a portion of the interior of the rigid body. The mixer further comprises a cement blend inlet and a fluid inlet through which cement blend and fluid are introduced into the mixer to form a cement slurry. The flexible skirt is constructed to enable selective deformation, e.g. flexing, during formation of the cement slurry to reduce or prevent the formation of cement slurry caking within the mixer.

A washing powder feeding device includes a frame, a water pipe, a powder feeding mechanism and a vortex tube body respectively assembled on the frame. The vortex tube body is defined with a first cylindrical cavity, an intermediate truncated cone cavity and a second cylindrical cavity from top to bottom, the first cylindrical cavity has a larger diameter than the second cylindrical cavity, a water inlet is formed on a side wall of the vortex tube body and communicated with and tangent to the first cylindrical cavity, the water pipe is communicated with the water inlet, and the powder feeding mechanism is configured to feed washing powder into the first cylindrical cavity. The device can effectively prevent the dissolved washing powder from adhering onto the pipeline to cause clogging of the pipeline, thereby ensuring the washing reliability.