A reaction apparatus, comprising: a reaction kettle (1); a circulation loop, comprising a circulation pipeline (2) and a circulator pump (4) provided on the circulation pipeline (2), a discharging end of the circulator pump (4) being communicated with the top of the reaction kettle (1) by means of a circulation valve (3) and a charging end of the circulator pump (4) being communicated with the bottom of the reaction kettle (1) by means of a block valve (9); a feeding loop, comprising a feeding pipeline (7) and a bypass pipeline (5), the feeding pipeline (7) being provided between the block valve (9) and the circulator pump (4) and being communicated with the circulation pipeline (2), the bypass pipeline (5) being provided with a control valve (6), and one end of the bypass pipeline (5) being communicated with the discharging end of the circulator pump (3) and the other end thereof being communicated with the bottom of the reaction kettle (1); and a discharging loop, comprising a discharging pipeline (10) provided between the circulator pump (4) and the circulation valve (3) and communicated with the circulation pipeline (2), the discharging pipeline (10) being provided with a discharging valve (11).

A sample agitation system for an automated sampling device is described. In an example implementation, the sample agitation system includes a sample probe configured to contact a sample positioned within a sample vessel. Further, the sample agitation system includes an actuator coupled to the sample probe that is configured to stir the sample positioned within the sample vessel in one or more rotational directions. The directions may include, but are not limited to, clockwise motion, anti-clockwise motion, or the like. In some implementations, a sample probe support arm can be coupled to the sample probe and/or the actuator. The actuator can move the sample probe support arm in a translational, a rotational, and/or a vertical direction to rotate the sample probe and stir the sample.

A sample agitation system for an automated sampling device is described. In an example implementation, the sample agitation system includes a sample probe configured to contact a sample positioned within a sample vessel. Further, the sample agitation system includes an actuator coupled to the sample probe that is configured to stir the sample positioned within the sample vessel in one or more rotational directions. The directions may include, but are not limited to, clockwise motion, anti-clockwise motion, or the like. In some implementations, a sample probe support arm can be coupled to the sample probe and/or the actuator. The actuator can move the sample probe support arm in a translational, a rotational, and/or a vertical direction to rotate the sample probe and stir the sample.

A powdery-material feeding device is configured to feed a powdery material to a compression-molding machine configured to obtain a molded product by filling a die bore with the powdery material and to compress the powdery material with punches. The powdery-material feeding device includes a detector configured to detect a biologically-originated foreign matter mixedly contained in the powdery material to be fed to the compression-molding machine, and a controller configured to control to remove the powdery material mixedly containing the biologically-originated foreign matter detected by the detector to avoid feeding of the powdery material mixedly containing the biologically-originated foreign matter to the compression-molding machine, or to control to stop the feeding of the powdery material to the compression-molding machine.

Shown and described here is a process for preserving a dispersion in a metering apparatus, wherein the dispersion is stored in a container (1, 101, 201) which is part of the metering apparatus, wherein an oxidant is introduced into the container (1, 101, 201). Also described are a metering apparatus configured for this process and a use of an oxidant for preserving dispersions.

A stirrer assembly for, in use, stirring liquid in a receptacle with the receptacle lid in place, which includes a receptacle receiving portion which is locatable inside the receptacle, a first guide member which is mountable onto a floor of the receptacle for rotatably guiding the receptacle receiving portion, a second guide member which is defined centrally a receptacle lid and extending downward therefrom, for in use, rotatably guiding an upper region of receptacle receiving portion, a sealing member for releasably sealing the second guide member, and a drive member which is connectable to the upper region of the receptacle receiving portion, for in use, transmitting torque to the shaft upon rotation of the said drive member.

A kneading tool of a type prearranged for being mounted rotatable about an axis of rotation of a kneading machine includes: a central shaft defining a main axis; and plurality of arms transverse to said shaft, which are positioned in different orientations about the main axis and/or in different positions along said axis so as to be staggered and not overlying with respect to one another.

This invention provides a continuous liquid phase type wet exhaust gas treatment method for removing sulfur oxides from exhaust gas and collecting it as gypsum, which method is simple and humidifying liquid is uniformly sprayed into exhaust gas with it. The method is characterized in that humidifying liquid is injected downwardly in a region where exhaust gas flows vertically downwardly.

Disclosed in an embodiment of the present application is a mixing apparatus, mixing machine, and cooking utensil. A mixing apparatus that can be fitted to an electric motor assembly. The electric motor assembly is able to drive the mixing apparatus to rotate for mixing food ingredients. The mixing apparatus comprises a connection part, stirring rods extended from the connection part and stirring bars. The positions at which the stirring bars are fitted to the stirring rods can be adjusted based on the type and quantity of food ingredients to increase mixing uniformity.

A pot lid assembly comprises a pot lid, an electric motor assembly and a mixing apparatus. The electric motor assembly is fixed to the pot lid. The mixing apparatus includes a stirring rod and a plurality of stirring vanes. The electric motor assembly includes an electric motor. The electric motor includes a rotary shaft operatively connected with the stirring rod so that the electric motor can cause the stirring rod to rotate. The pot lid is configured to cover the pot body to form a closed cooking space. When the pot lid is removed from the pot body, the rotary shaft is disengaged from the stirring rod, and the mixing apparatus can stand in the cooking space of the pot body, with the stirring vanes serving as a support. The mixing apparatus remains in the cooking space of the pot body after the removal of the pot lid.