In one embodiment, a mixing device includes a sleeve that forms an inner space configured to receive a sample container, a housing associated with the sleeve, a mixing element contained within the housing that is configured to mix liquid contained within the sample container, and an activation element configured to activate the mixing element when the activation element is triggered.

A waste absorbing media composition for use in an agitating waste non-contact toilet apparatus comprises an absorbent material, a liquid, and an indicator detectable by a sensor of the agitating waste non-contact toilet apparatus.

The present invention relates to a process for mixing a flocculant composition with mineral suspensions, especially waste mineral slurries, using an acoustic mixer. Preferably the flocculant composition is a polymeric flocculant composition preferably comprising a poly(ethylene oxide) homopolymer or copolymer. The process of the present invention is particularly suitable for the treatment of tailings and other waste material resulting from mineral processing, in particular, processing of oil sands tailings.

The present application is directed towards systems for adding components to materials being fluidized in a vibratory mixer by use of atomizers or sprayers. A mechanical system can fluidizes, mix, coat, dry, combine, or segregate materials. The system may comprise a vibratory mixer, mixing vessel containing a first material and a sprayer to introduce a second material. The vibratory mixer may generate a fluidized bed of a first material and the sprayer, coupled to the mixing vessel, may introduce a second material onto the fluidized bed to mix the materials in a uniform and even fashion.

A toilet apparatus has a waste material receiving bowl with an opening to receive an absorbent media and indicator and a sensor to detect a presence of the indicator in the material receiving bowl when the indicator is present in the material receiving bowl and transmit a signal indicating the indicator is present in the material receiving bowl. A control circuit receives the signal from the sensor, processes the signal to determine the indicator is present in the material receiving bowl, and causes one or more actions to be taken by the toilet apparatus based on determining the indicator is present in the material receiving bowl.

The present technology provides a technology that liquid in round-bottom vessels is efficiently agitated. There is provided a vessel rack at least including a holder having a plurality of through-holes into which round-bottom vessels each having a closed-bottom tube shape are inserted, and a support having a plurality of supporting holes that are arranged facing to the through-holes and support bottoms of the round-bottom vessels, the bottoms of the supporting holes each having a bulge such that liquid in the round-bottom vessels forms a vortex at a time of agitation of the liquid. Also, there is provided an agitator of agitating liquid in round-bottom vessels at least including the vessel rack, a mounting unit that mounts the vessel rack, and a rocking unit that rocks the mounting unit, and the like.

The present application is directed towards systems for adding components to materials being fluidized in a vibratory mixer by use of atomizers or sprayers. A mechanical system can fluidizes, mix, coat, dry, combine, or segregate materials. The system may comprise a vibratory mixer, mixing vessel containing a first material and a sprayer to introduce a second material. The vibratory mixer may generate a fluidized bed of a first material and the sprayer, coupled to the mixing vessel, may introduce a second material onto the fluidized bed to mix the materials in a uniform and even fashion.

The present invention provides a dye blending device. The dye containers of the device are connected with external dye supplying devices via a pipeline to obtain specific dyes; the motor thereof are connected with the dye containers via the pipeline to apply a pressure on the dye containers; quantitative pumps and electronic control valves are disposed between a collection zone and the dye containers to configure the transportation operation of the dye; a controller of the device receives a dye blending instruction, instructs the motor to apply a pressure to a specified dye container, enables a quantitative pump and an electronic control valve corresponding to the specified dye container to output a specified dosage of dye to the collection zone, and instructs a vibrator disposed in the collection zone to generate vibration to blend the mixture dye outputted to the collection zone, thus achieving the objective of automatically blending dyes.

A system includes a processing station and a lubricant supply system in fluid communication with the processing station. The processing station is operable to process at least one of a tire and a wheel prior to joining the tire and the wheel to form a tire-wheel assembly. The processing station includes at least one of a tire lubricating sub-station or a wheel lubricating sub-station. The lubricant supply system includes a storage container configured to store a lubricant and a whipping device received by the lubricant container and operable to whip or blend the lubricant from a semi-solid state to a whipped state. The lubricant supply system also includes a pump operable to pump the lubricant in the whipped state out of the storage container.

Layering of initially mixed granular dissimilar material components deposited by surface flow is realized by varying the relative angle of the flowing layer periodically with respect to the bulk of the pile formed. Layer thickness and extent can be controlled by varying the timing and extent of the surface variations. Variation in surface flow rates may be realized by varying the feed rate from an inlet to a collection base at a fixed feed location, varying the feed location relative to the collection base, tilting the collection base that is supporting the material, and reducing the pile repose angle using vibration or fluid flow through the base.