The present invention provides a system and method for producing high-purity vanadium pentoxide powder. Industrial grade vanadium pentoxide is converted to vanadium oxytrichloride by low temperature fluidizing chlorination, wherein chlorinating gas is preheated via heat exchange between fluidizing gas and chlorination flue gas, and an appropriate amount of air is added to enable a part of carbon powder to combust so as to achieve a balanced heat supply during the chlorination, thereby increasing the efficiency of chlorination and ensuring good selectivity in low temperature chlorination. The vanadium oxytrichloride is purified by rectification, and then subjected to fluidized gas phase hydrolyzation and fluidized calcination, thereby producing a high-purity vanadium pentoxide product and a by-product of hydrochloric acid solution. The system and method have advantages of favorable adaptability to raw material, no discharge of contaminated wastewater, low energy consumption in production, low operation cost, stable product quality, etc.

The present invention provides a system and method for purifying and preparing vanadium pentoxide powder. Industrial grade vanadium pentoxide is converted to vanadium oxytrichloride by low temperature fluidizing chlorination, wherein chlorinating gas is preheated via heat exchange between fluidizing gas and chlorination flue gas, and an appropriate amount of air is added to enable a part of carbon powder to combust so as to achieve a balanced heat supply during the chlorination, thereby increasing the efficiency of chlorination and ensuring good selectivity in low temperature chlorination. The vanadium oxytrichloride is purified by rectification, and then subjected to fluidized gas phase ammonification, thereby obtaining ammonium metavanadate, and further obtaining a high-purity vanadium pentoxide powder product through fluidized calcination. The system and method have advantages of favorable adaptability to a raw material, no discharge of contaminated wastewater, low energy consumption and chlorine consumption in production, stable product quality and so on.

The disclosure provides a bulk material unloading system and method. The system includes a bulk material container containing a bulk material and an unloading device. The unloading device is configured to engage the bulk material container and at least partially invert the bulk material container. The method includes engaging a bulk material container containing a bulk material with an unloading device and emptying the bulk material container. Emptying the bulk material into the hopper includes lifting the bulk material container using the unloading device and rotating the bulk material container using the unloading device.

In accordance with embodiments of the present disclosure, systems and methods for passively reducing or preventing dust formation in a particulate handling system are provided. In some embodiments, the handling system includes a silo for holding bulk material used to form a well fracturing treatment fluid. The silo may include a chute to deposit a portion of the bulk material from the silo into a blender and a cyclone mounted to the silo to separate dust from a pneumatic air flow and to release a substantially clean air into the atmosphere. In other embodiments, the handling system may include a horizontally oriented cyclone assembly mounted to a blender storage tank, cyclone assembly including a horizontally oriented cyclone separator to separate dust from a pneumatic airflow and a dust collection container to receive the dust and output the dust into the storage tank.

Techniques or processes for efficiently producing concrete using dynamic feedback are disclosed. A concrete plant can use a control system to manage concrete production based on the dynamic feedback. The dynamic feedback can control mixing of concrete ingredients so as to yield uniform particle distribution for the concrete ingredients. The dynamic feedback can also avoid overflow situations as well as yield improved loading of the resulting concrete into a concrete transport vehicle (e.g., concrete truck).

Mixing systems that include a mixer housing and one or more disk assemblies for mixing and processing materials is disclosed. The disks rotate to mix an additive into the material and to carry agglomerated solids toward a discharge of the mixing system. The disks may have a plurality of fingers or lobes which extend from a central portion of the disks.

An on-site heavy metal contaminated soil treatment apparatus, comprising a sampling system, a molding system, a heat processing system and a tail gas processing system disposed in sequence. The sampling system includes a bucket elevator and a planetary stirring device which are connected in sequence and are disposed on a mobile platform of the sampling system. The apparatus is easy to move and assemble, has a small floor area, and can be built on a target contaminated site, reducing transportation costs and the risk of secondary contamination. The entire process performed by the apparatus proceeds automatically, reducing labor costs. The planetary stirring sampling method and automatic brick blank extrusion molding process of the apparatus are applicable to various types of heavy metal contaminated soil providing high processing efficiency and good molding effect. Combined microwave heating and high-temperature steam heating provide rapid heating, small thermal inertia, and easy temperature control.

Preloading a plurality of feed types of a feed mix for livestock in a mixing plant. Feed types are conveyed towards a mixer. Bunkers selectively discharge one of the feed types on a loading conveyor. A controller controls a preloading weight of the feed types to be discharged onto the loading conveyor. Feed types are individually discharge onto dump spots of the loading conveyor at the bunkers and terminate when a predetermined total weight is reached or interrupt when a maximum preloading capacity is reached or feed reaches the end of the loading conveyor. Feed types may be individually discharged from the bunkers onto the dump spots and the main component loaded into the mixer by a loading vehicle, such that the weight of the main portion and the weight of the supplemental portion add up to a programmed total weight of the main component.

The present disclosure refers to a filling machine and to a method for filling a foodstuff which comprises at least two components to be mixed, particularly for sausage production. The foodstuff may be filled into a filling hopper of the filling machine and thoroughly mixed with a mixing cam. The mixing cam may be driven via its own drive at different speeds according to a specific speed profile while the foodstuff is conveyed out of the lower portion of the filling hopper via a conveying mechanism and is filled via a filling unit.

A volumetric mixer is provided including a holding section adapted to store one or more materials simultaneously, one or more conveyors disposed in the holding section, a mixing section, one or more heating units disposed in the mixing section, and a control unit. The conveyors are operable to convey materials from the holding section to the mixing section and the one or more conveyors are operable to be individually controlled by the control unit to deliver a pre-determined amount of each material from the holding section to the mixing section.