An impact test apparatus can be used to determine particle interfacial energies with varying relative air humidity. It was observed that capillary condensation increased the adhesive forces of hydrophilic materials. A systems humidity separation window was identified and the differences in interfacial energy for a hydrophilic surface and for a hydrophobic surface can be exploited in order to achieve the separation of particles. Separation and concentration of particles, particularly particles within a mineral ore body, can be obtained.

An apparatus (1) for thermal denitration of a uranyl nitrate hydrate to uranium trioxide UO3. The apparatus (1) comprises a burner (114) and a reaction chamber (110) configured to carry out thermal denitration of uranyl nitrate hydrate and to form uranium trioxide UO3 in the form of particles. The apparatus also comprises a separating chamber (120) suitable for separating UO3 particles from the gases resulting from the thermal denitration carried out in the reaction chamber (110), and at least one filter (130) configured for purifying the gases. The separating chamber (120) is a decanting chamber into which the reaction chamber (110) directly opens out. The filter (130) is capable of performing the separation at a temperature greater than or equal to 350° C. The invention also relates to use of such an apparatus, to a thermal denitration process and to UO3 particles obtained by such a process.

An impact test apparatus can be used to determine particle interfacial energies with varying relative air humidity. It was observed that capillary condensation increased the adhesive forces of hydrophilic materials. A systems humidity separation window was identified and the differences in interfacial energy for a hydrophilic surface and for a hydrophobic surface can be exploited in order to achieve the separation of particles. Separation and concentration of particles, particularly particles within a mineral ore body, can be obtained.

A flow-diverger feed inlet distributor and/or a vertical, partially perforated baffle for separating vapor and liquid in a horizontal vessel. The flow-diverger feed inlet distributor comprises multiple pairs of straight-vertical vanes positioned in the horizontal vessel adjacent a feed inlet opening at one head/end of the vessel. The partially perforated baffle is positioned in the vessel adjacent the feed inlet opening.

A flow-diverger feed inlet distributor and/or a vertical, partially perforated baffle for separating vapor and liquid in a horizontal vessel. The flow-diverger feed inlet distributor comprises multiple pairs of straight-vertical vanes positioned in the horizontal vessel adjacent a feed inlet opening at one head/end of the vessel. The partially perforated baffle is positioned in the vessel adjacent the feed inlet opening.

The present invention describes systems and methods for blocking, confining and settling suspended particulate matter less than 100 m, preferably less than or equal to 10 m, comprising irradiating with radio waves the medium in which said suspended particulate matter is present in order to destabilize it, causing blocking from one zone to another, confining and settling.

Methods for reducing particulates in the air are disclosed. In some embodiments, the method comprises spraying a composition having an effective amount of a zwitterionic polymer, a compressed gas propellant, and an aqueous carrier in to the air. The composition agglomerates particulates upon contacting particulates in the air thereby reducing particulates in the air.

The invention belongs to processes of converting carbonaceous raw materials to produce gaseous, solid, and liquid energy carriers and can be used in municipal, agriculture, wood processing industry, in the mining and petrochemical industries and other industries for thermochemical conversion of carbon-containing wastes from these industries to produce combustible gas, solid and liquid fuels, sorbents and other products. The process provides for the use of a vortex gasifier to produce hot generator gas, used as a heat carrier for the process of pyrolysis of raw material in the reactor, in which char and vapor gas are produced as a result of thermochemical reaction, a purification device to treat produced in the reactor vapor gas, and an apparatus for separation of vapor gas into different components. During the operation of the pyrolysis reactor, hot generator gas is fed into the upper part of the reactor and then proceeds to the bottom of the reactor through a gas duct inside the pyrolysis reactor until it reaches the distributor, through which it exits and travels up to the exit of the reactor, with simultaneous feed of raw material into the upper part of the reactor and movement of raw materials down the sloping mesh shelves. Effective thermochemical conversion of raw material is achieved in the countercurrent of raw material and heat carrier. The vapor gas formed in the pyrolysis reactor is supplied to the purification and separation units, while the char descends into the hopper from which it is released by a screw conveyor and/or sluice feeder to be sent to consumers or to the gasifier to obtain the heat carrier.

An apparatus (1) for thermal denitration of a uranyl nitrate hydrate to uranium trioxide UO3. The apparatus (1) comprises a burner (114) and a reaction chamber (110) configured to carry out thermal denitration of uranyl nitrate hydrate and to form uranium trioxide UO3 in the form of particles. The apparatus also comprises a separating chamber (120) suitable for separating UO3 particles from the gases resulting from the thermal denitration carried out in the reaction chamber (110), and at least one filter (130) configured for purifying the gases. The separating chamber (120) is a decanting chamber into which the reaction chamber (110) directly opens out. The filter (130) is capable of performing the separation at a temperature greater than or equal to 350 C. The invention also relates to use of such an apparatus, to a thermal denitration process and to UO3 particles obtained by such a process.

This disclosure teaches a composition and process which makes it possible to remove floating particulates or prevent the dissemination or particulates, by the misting of a solution that readily captures any particulate material in the air. More specifically, the present disclosure teaches the composition and use of aromatic compounds that are semi-volatile organic compounds (SVOCs) or slow evaporators in water-based carriers with surfactants as the misting/fogging agent for dust suppression. The particulate material is lowered to surfaces and removed by vacuuming, damp-wiping or using a dry cloth with a cationic charge (static cloth). This method can be achieved with neutral air pressure differentials in the work areas.