Abstract: Systems and methods for using one or more pre-filled, portable containers, instead of pneumatic transfer, to move bulk material from a transportation unit to a blender receptacle of a blender are provided. A transportation unit may deliver one or more containers of bulk material to the well site, where the containers may be disposed in an elevated position around the blender receptacle. A gravity feed outlet may extend from one or more containers to route bulk material from the one or more containers directly into the blender receptacle. Since the transportation unit is able to unload the portable containers of bulk material without pneumatic transfer, the stackable containers may enable a cleaner and more efficient bulk material transfer at the site.

Abstract: Automatic flavoring and water dispensing systems are disclosed. The systems may be used to add flavorings to medications, and to reconstitute medications by adding water. The systems include multiple flavoring containers communicating with a valve assembly that controls the type and amount of each flavoring to be delivered during a dispensing operation. Water for reconstitution purposes may be provided through the flavoring valve assembly and/or through a separate valve. An input device such as a code scanner may be used to input data regarding the type of medication to be flavored into the system, and a flavoring formulary may be used to provide multiple flavoring options. The dispensing system allows for automatic dispensing of medication flavorings and/or reconstitution water from a single unit.

Abstract: An air/oxygen blender, optionally with an associated oxygen analyzer, is provided with an exhaust valve in fluid communication with one or more of a proportioning valve and a gas outlet which periodically opens to vent gas therefrom. The exhaust valve is preferably an electrically actuated valve, most preferably a solenoid valve, controlled by a control unit which periodically opens the exhaust valve. In another embodiment, an oxygen analyzer is provided with an exhaust valve in fluid communication with an oxygen sensing chamber. Preferably, the control unit controls the frequency of exhaust valve opening and the time period of exhaust valve opening. A method of prevention of contamination of a lower pressure source air or source oxygen connected to an air/oxygen blender is accomplished by periodically venting of gas from the exhaust valve.

Abstract: This dialysis device is configured so that residual liquid in a powder container 42 and a bypass path 51 can be drained. Accordingly, the dialysis device is provided with: a first liquid draining path 71 connecting a clean water supply path 31 to a stock solution supply path 44 on the upstream side of a liquid feed pump 33; a second liquid draining path 72 connecting the clean water supply path to a dialysate discharge path 32 on the downstream side of the liquid feed pump; and an opening path 77 allowing a branch path 43 to communicate with the outer space by opening an on-off valve 78. By opening the on-off valve of the opening path and actuating the liquid feed pump, a liquid in the powder container 42 and a liquid in the bypass path 51 can be discharged through the first liquid draining path and the second liquid draining path.

Abstract: A power system for an unmanned surface vehicle is disclosed. In one embodiment, the power system includes a fuel cell, a fuel storage, and an air management system. The fuel cell includes a fuel cell stack. The fuel cell stack includes a fuel inlet, an air inlet, and an exhaust outlet. The fuel storage includes at least one fuel-storage module fluidly connected to the fuel inlet of the fuel cell stack. The fuel-storage module is a source of energy for the fuel cell. The air management system is fluidly connected to the air inlet and the exhaust outlet of the fuel cell. An air snorkel is part of the air management system and provides air to operate the fuel cell while the unmanned surface vehicle is deployed on a surface of a body of water. The air snorkel includes an intake and an exhaust.

Abstract: Methods and devices for generating power using PEM fuel cell power systems comprising a rotary bed reactor for hydrogen generation are disclosed. Hydrogen is generated by the hydrolysis of fuels such as lithium aluminum hydride and mixtures thereof. Water required for hydrolysis may be captured from the fuel cell exhaust. Water is preferably fed to the reactor in the form of a mist generated by an atomizer. An exemplary 750 We-h, 400 We PEM fuel cell power system may be characterized by a specific energy of about 550 We-h/kg and a specific power of about 290 We/kg.

Abstract: A diluted solution production method of the present invention is a diluted solution production method of producing a diluted solution of a second liquid by adding the second liquid a first liquid, the method including feeding the first liquid to a first pipe; and controlling pressure in a tank that stores the second liquid to add, through the second pipe that connects the tank to the first pipe, the second liquid to the first liquid in the first pipe. Adding the second liquid includes measuring a flow rate of the first liquid or the diluted solution that flows through the first pipe; measuring a component concentration of the diluted solution; and controlling the pressure in the tank, based on the measured values of the flow rate and the component concentration, so as to adjust the component concentration of the diluted solution to a specified value.

Abstract: A solution making system and apparatus are described. The solution maker mixes a chemical or slurry with a solvent to a desired concentration. The concentration of the solution is monitored by one or more methods. Based upon this measurement, the concentration of the solution may be adjusted.

Abstract: An apparatus for entraining a powder in a process fluid is provided. The apparatus (2?) has a process passage (22) having a passage inlet (24) connectable to a source of process fluid, and a passage outlet (26). A nozzle (30) opens into the process passage (22) intermediate the passage inlet (24) and passage outlet (26). The nozzle (30) has a nozzle inlet (32), a nozzle outlet (36) and a nozzle throat (34) intermediate the nozzle inlet (32) and nozzle outlet (36), where the nozzle throat (34) has a cross sectional area which is less than that of the nozzle inlet (32) and nozzle outlet (36). At least one first port (42?) opens into the process passage (22) adjacent the nozzle outlet (36), and an entrainment fluid supply chamber (38) is in fluid communication with the nozzle 30. A first powder supply chamber (44?) is connected to the first port (42?) by a first powder supply passage (46), wherein the powder supply chamber (44?), powder supply passage (46) and first port (42?) are coaxial.

Abstract: A system for dispersing finely dispersed solids into high-viscosity products includes, in a container, a coaxial stirring system having stirring elements on two independently drivable, coaxially arranged shafts. A positive-displacement, close-wall-clearance stirring element on the one shaft and a plurality of stirring elements on a central shaft are arranged in such a manner that, in an upper mixing region of the container, a combination of the positive-displacement, close-wall-clearance stirring element and stirring elements for forming an ideally mixed zone is provided, and in a mixing region downstream of the upper mixing region of the container, stirring elements for developing a plug-flow zone are provided. A positive-displacement pump is provided in a region downstream of the plug flow zone as a discharge zone.

Abstract: A process for continuously mixing at least two fluid streams and splitting the stream of the mixture into at least two partial streams, comprising a) providing streams of the at least two fluids via separated conduits; b) combining the streams of the fluids and forming a homogeneous mixture; c) measuring the pressure in the conduit conveying the mixture of the fluids; d) splitting the stream of the mixture of the fluids into at least two partial streams and feeding each of the partial streams to a conduit equipped with a flow control device controlled by a controller; and e) adjusting the flow rates of the partial streams of the mixture of the fluids by feeding the pressure information measured in step c) as process variable to the controllers controlling the flow control devices, a process for feeding a mixture of at least two fluids via at least two feeding points, an apparatuses for carrying out such processes and a process for polymerizing olefins.

Abstract: The present invention relates to a system and process for a nutracuetical beverage compounding system and methods for the same. Provided is a customizable supplement beverage system and method for personalizing and operating the same to a particular user and optionally for operative tracking. Proposed additionally is an operative system for receiving and individually identifying a concentrate or supplement combinations, for mixing the same prior to a use, and for dispensing the same for use, and for tracking control factors relating to the same.

Abstract: A hydro-blender for mixing base fluids and particulates for use in pumping can include a transport device. The hydro-blender can also include a liquid tank connected with the transport device. An inlet manifold can be located within the liquid tank for receiving fluid from one or more fluid sources. The inlet manifold can be in fluid communication with one or more fluid sources. The hydro-blender can also include a mixing tub in communication with one or more hoppers via one or more augurs.

Abstract: Provided is a site vehicle for mixing and loading multiple kinds of explosives with different detonation velocities. The vehicle contains a double-helix conveying system, a plurality of storage bins (5-8) and multiple sets of pipelines. Emulsified bases, porous granular ammonium nitrate and physical density modifier are stored in the main material storage bins, an adjuvant storage bin is provided with a diesel tank (4, 31), a sensitizing solution tank (40) and a washing water tank (11), and the technical effect that multiple kinds of explosives with different detonation velocities are mixed and loaded can be realized by using the different combinations of the different raw materials of the storage bins and various output pipelines and some baffle plates.

Abstract: This gas mixing device includes a main gas flow path, an additive gas flow path, a mixing section, and a flow rate control unit. A pilot type pressure regulating unit configured to regulate pressure of a main gas based on a pressure in the additive gas flow path and a mass flow meter configured to detect the flow rate of the main gas flow path are provided on the main gas flow path. An additive gas flow rate regulator configured to regulate a flow rate of an additive gas is provided on the additive gas flow path. The flow rate control unit controls the flow rate of the additive gas using the additive gas flow rate regulator based on a flow rate of the main gas detected by the mass flow meter.

Abstract: A beverage preparation machine (1) includes: a base (10) having a fluid circuit for conditioning and delivering a fluid via a base outlet (11) and a base data interface (12,13); and a removable module (20) having a module inlet (21) and a module data interface (22,23) disconnectably connectable to the base outlet and the base data interface, respectively. The base (10) may have a base connector block (14) for mechanical connection to the module (20), the base outlet (11) and the base data interface (12,13) being borne by the base connector block (14). The module (20) can have a module connector block (24) for mechanical connection to the base (10), the module inlet (21) and the module data interface (22,23) being borne by the module connector block (14).

Abstract: A method and apparatus for obtaining a product chemistry from a product and a fluid is provided. A product is housed within a dispenser. A fluid is introduced through a manifold diffuse member having a plurality of ports. A cover is positioned adjacent the manifold diffuse member and includes a plurality of ports. The cover is able to be adjusted, for example, by rotating the cover, to align and un-align the manifold diffuse ports and the cover ports. This adjustment controls the flow characteristics of the fluid through the manifold diffuse member and cover to control the characteristics of the fluid in contact with the product. The adjustment of the cover to control the flow will provide a generally consistent concentration and erosion rate based upon known relationships between a characteristic of the fluid and the flow of the fluid in relation to the product.

Abstract: Novel systems and apparatuses for dispensing particulate media are disclosed. One such system may include a storage tank for storing media, a feed tube in communication with the tank, a mixing chamber in communication with the feed tube, a tank sensor to detect pressure within the storage tank, and a mixing chamber sensor to detect pressure within the mixing chamber, wherein the mixing chamber is preferably configured to receive media when the pressure within the storage tank is about equal to the pressure within the mixing chamber. A non-pressurizable vibrator is preferably mounted external to the feeder. The vibrator is configured to vibrate media received in the feed tube from the media tank substantially along the feed tube toward the mixing chamber. The media dispensing system may further comprise an accelerometer in communication the vibrator to provide feedback regarding vibration of the feed tube.

Abstract: Biomass feedstocks (e.g., plant biomass, animal biomass, and municipal waste biomass) are processed to produce useful products, such as fuels. For example, systems are described that can convert feedstock materials to a sugar solution, which can then be fermented to produce ethanol. Biomass feedstock is saccharified in a vessel by operation of a jet mixer, the vessel also containing a fluid medium and a saccharifying agent.

Abstract: A method and apparatus for treating a cellulosic feedstock, such as for subsequent ethanol production, are disclosed. The method comprises determining an initial moisture content of the cellulosic feedstock and adding an amount of moisture to the cellulosic feedstock to obtain a predetermined moisture content of the cellulosic feedstock, wherein the cellulosic feedstock may subsequently be subjected to hydrolysis. The apparatus comprises a moisture sensor that provides an initial moisture content reading of the cellulosic feedstock, and a weight sensor providing the weight of the cellulosic feedstock. A processor is configured to determine an amount of moisture to be added to the cellulosic feedstock based on the weight and the initial moisture content of the cellulosic feedstock to obtain treated cellulosic feedstock having a predetermined moisture content.

Abstract: A portable feed apparatus comprising a feed container, a mixing assembly that receives a feed from said feed container, at least one feed additive assembly in flowable connection with said mixing assembly, and a controller in communication with said mixing assembly.

Abstract: A method and system for diluting and dispersing chemicals that includes a plurality of concentrated liquid chemical containers, a plurality of control valves each in corresponding fluid relationship to the plurality of concentrated liquid chemical containers, at least one additional concentrated chemical container, a positive displacement pump in fluid relationship with the at least one additional concentrated liquid chemical container, at least one high pressure pump connected in fluid relationship to each of the plurality of control valves, at least one metering device located between at least one of the plurality of control valves, at least one liquid pressure adjustment valve connected in fluid relationship to the high pressure pump and a source of solvent or diluent, a hose connected in fluid relationship to the liquid pressure adjustment valve, and an applicator connected to the hose for dispersing a mixture of solvent, diluent and/or at least one concentrated chemical.

Abstract: This disclosure relates to making medical solutions. In certain aspects, a method is performed by a data processing apparatus. The method includes introducing liquid into a container that contains a dissolvable solid concentrate in a manner so that a layer of solution above the solid concentrate is maintained at a depth that allows the liquid introduced into the container to agitate the solution adjacent to the solid concentrate to cause mixing of the solid concentrate with the solution.

Abstract: Novel systems and methods for performing treatment (e.g., coloration) of keratinous fibers are disclosed. The methods and systems utilize one or more of a dispensing device which is configured to provide customized composition for treating keratinous fibers (e.g., a coloring composition), optionally formed from tablets; an optical reader, for obtaining sufficient characteristics of the keratinous fibers to make a realistic prediction of the outcome of a treatment (e.g., coloring treatment); a computational units for predicting an outcome of a treatment, optionally being interfaced with the dispensing device and for selecting a customized treatment; and tablet formulations which are useful in preparing customized composition for treating keratinous fibers. Further disclosed are rapidly disintegrating tablets for use in the preparation of compositions for treating keratinous fibers.

Abstract: An apparatus for controlling on site generation and mixing of a two or more part chemistry, such as a peroxide source and a catalyst. In particular, the invention discloses an apparatus and dispensing method for separating solid surfaces that undergo an uncontrolled, continuous reaction when contacted with water and allows for delivery of solid reactive chemistries at the same time in a standard spray from the bottom dispensing configuration while preventing continued reaction after the dosing is complete.

Abstract: The present invention relates to an automated solution dispenser for dispensing a solution having a defined list of characteristics. In particular, the automated solution dispenser according to the present invention is provided with one or more of the following modules: Central Mixing Chamber (CMC), Flush and Verification System (FVS), Liquid Handling System (LHS), Control System (CS), Pivot Pipe System (PPS), Solid Handling System (SHS) (which includes a Delivery mechanism and a Measuring mechanism), a Bottle Handling System (BHS), a Water Purification System (WPS) and Bottle Marking/Label (BM). The combination of one or more of these modules enables the automation of the creation of solution having the required characteristics.

Abstract: A method and apparatus for generating micro-bubbles and for mixing and/or blending fluids includes providing a pressurized elongate container, having at least one tube mounted in the container inlet. A pre-mixing chamber feeds into each tube. Each tube is cantilevered from the container inlet and has a fixed internal diameter. The tubes are replaceable so that the length of each tube in the container may be optimized to generate micro-bubbles. Tuning or optimizing of the micro-bubble generating system achieves a required pressure drop to form micro-bubbles of five microns or less, and may form nano-bubbles. An upstream pump pressurizes at least two fluids which feed into the pre-mixing chamber. Pressure from the container outlet may be controlled by a valve. The valve leads to a second container, which may be open to atmospheric pressure.

Abstract: A system for processing material has a power supply and a machine having a hopper for receiving and passing material to an auger. The auger has a shaft with an axis about which it rotates, a helical flighting mounted to the shaft, pins mounted to the helical flighting, and paddles mounted to the shaft. The radial outer edge of the helical flighting is crenelated with periodic notches that form rectangular blades on the helical flighting. The pins are rotationally and angularly aligned with leading edges of the rectangular blades. The system may include a vehicle, such as a trailer, having first and second compartments separated by a partition. The power supply is located in the first compartment and has a power supply member extending though the partition. The machine is located in the second compartment and coupled to the power supply member.

Abstract: A system for mixing fracturing gel includes a dry gel mixing chamber having a bladed impeller carried to rotate in the mixing chamber. The mixing chamber has a dry gel inlet and hydrating fluid inlet. A valve is fluidically coupled to the hydrating fluid inlet to automatically maintain a specified flow condition of hydrating fluid into the mixing chamber over multiple different values of the flow condition to the hydrating fluid inlet.

Abstract: What is disclosed is a plurality of prepaints which are used in any combination to produce base paints and/or colored paints of varying end-use application characteristics. Additionally, a mobile paint factory for producing a plurality of lines of paints from a plurality of prepaints en route to and/or at various locations is disclosed, which may include a vehicle having a paint production system, a spectrometer and a gloss meter. Furthermore, a method of producing a plurality of lines of user-selected paints from a plurality of prepaints en route to and/or at various locations is disclosed. The method may include: providing a mobile paint factory; prompting a user to select a value for a paint attribute on a slider; and automatically dispensing predetermined amounts of appropriate prepaints. The method may also comprise storing information about the reflectance of produced paints in a local data storage device.

Abstract: A seed treating device that has an input device that is detachably secured to a frame. Disposed within the frame is a mixing chamber that receives seed from the input and is in fluid communication with a pump. In this manner the pump is able to convey chemical treatments to the interior of the mixing chamber such that a blade assembly within the mixing chamber can mix the chemical treatment fluid with seeds therein in order to treat the seeds with the chemical treatment.

Abstract: A dispersing device (1) has a dispersing tool (3), which has a shaft tube (2), and a drive (4). A dispersing rotor is provided at the free shaft tube (2) end (5) remote from the drive (4), the dispersing rotor being connected to the drive (4) via a shaft which can be coupled to the drive (4) and which is arranged within the shaft tube (2). In order to monitor the temperature of the medium to be dispersed, a temperature sensor (7) with a corresponding electric input and output line (8) is provided on the shaft tube (2), which is stationary relative to the dispersing rotor and the rotatable shaft, the input and output lines (8) connecting the temperature sensor (7) to the drive (4) and/or analyzing electronics and/or a control or regulating device.

Abstract: A fluid mixing device is productive, maintainable and improved in operability and reliability even without high accuracy pressure control. A fluid mixing device includes a mixing tank, supply tanks, mixing tank flow channels, valves, and branch flow channels. The mixing tank mixes at least two liquids. Each supply tank is provided for each of the liquids and supplies each liquid to the mixing tank. Each mixing tank flow channel connects each supply tank to the mixing tank. Each valve is arranged in each of the mixing tank flow channels. Each branch flow channel is connected to each of the mixing tank flow channels and is connected from the one mixing tank flow channel to the valve in the other mixing tank flow channel. Further, when the valve has pressure applied thereto from the liquid passing through the branch flow channel, the valve closes the mixing tank flow channel.

Abstract: A process for continuously mixing at least two fluid streams and splitting the stream of the mixture into at least two partial streams, comprising a) providing streams of the at least two fluids via separated conduits; b) combining the streams of the fluids and forming a homogeneous mixture; c) measuring the pressure in the conduit conveying the mixture of the fluids; d) splitting the stream of the mixture of the fluids into at least two partial streams and feeding each of the partial streams to a conduit equipped with a flow control device controlled by a controller; and e) adjusting the flow rates of the partial streams of the mixture of the fluids by feeding the pressure information measured in step c) as process variable to the controllers controlling the flow control devices, a process for feeding a mixture of at least two fluids via at least two feeding points, an apparatuses for carrying out such processes and a process for polymerizing olefins.

Abstract: A rapid rate chemical solution generator system and a method of generating a chemical solution from the system to rapidly treat a body of water. The system and method are especially useful in emergency situations. The system includes a tank for mixing chemical material with water, a hopper for storage of the chemical material, a gate valve disposed between the tank and hopper, a mixer to agitate and blend the chemical material with the water and form the chemical solution and a pump to aid in drawing the chemical solution out of the tank and toward a desired application. The system is configured to provide long-term storage of the chemical material in the hopper, while keeping the chemical material available for rapid delivery to the tank when needed.

Abstract: A blender system is provided that maintains a chemical solution bath at desired concentrations. The blender system includes a blender unit configured to receive and blend at least two chemical compounds and deliver a solution including a mixture of compounds at selected concentrations to a tank that retains a selected volume of a chemical solution bath. The blender system further includes a controller configured to maintain at least one compound within a selected concentration range in the chemical solution bath. The controller controls at least one of operation of the blender unit to maintain the concentration of the compound within a selected concentration range within the solution delivered to the tank, and a change in flow rate of solution into and out of the tank when a concentration of the compound within the chemical solution bath falls outside of a target range.

Abstract: A chemical component mixing apparatus for use with a fluid source in creation of a concentrated solution mixture is described. The mixing apparatus includes at least one mixing station. The mixing station includes an injector assembly, where the injector assembly includes at least one venturi chamber having at least one suction port in fluid communication with the at least one venturi chamber. The apparatus also includes at least one super concentrate chemical component housed within a chemical container, where the chemical container is fluidly connected by a first tube to the at least one venturi chamber via the at least one suction port, a receiving container fluidly connected to the injector assembly via a second tube, and a fluid source inlet introducing a fluid into the at least one mixing station, where the pressure within the at least one mixing station is less than 150 psi.

Abstract: A means for mixing drinking water stored in large storage tanks, preventing stratification of the water, detects incipient stratification of water along thermoclines, and, responsive to thermocline detection, generates large mixing bubbles toward the bottom of the tank, causing mixing of layers of water in the tank through turbulence created as the bubbles rise through the tank.

Abstract: An automated solution maker is provided. The automated solution maker mixes a chemical with a solvent to a desired concentration. The concentration of the solution is monitored by measuring the conductivity of the solution. Based upon this measurement, the concentration of the solution may be adjusted.

Abstract: There is provided an apparatus and method for fluid mixing, which enable mixing efficiency to be enhanced and enable a lodging impurity to be easily removed. A liquid, powder, or the like is added from a pipe 2 to a liquid flowing in a pipe 1, and the resultant liquid then passes a plurality of half-open ball valves 3A to 3C, thereby being mixed. The ball valves 3A to 3C each have angular difference ? in the position around the axis thereof. Sufficient mixing can be performed without preparing a static mixer having a complicated structure. In addition, in the case where clogging due to an impurity occurs, the valve is opened with the result that the impurity can be released.

Abstract: A process for preparing a beverage comprises: providing a liquid carrier; supplying a flavouring ingredient to the liquid carrier; optionally heating the liquid carrier; and agitating the liquid carrier to promote dissolution and/or dispersion of the flavouring ingredient therein. The flavouring ingredient is supplied in the form of a self-sustaining body (2) to the liquid carrier, the self-sustaining body (2) having at least one surface (3) from which the flavouring ingredient is dissolved and/or dispersed into the liquid carrier. The liquid carrier is agitated in a controlled manner to circulate on this surface so as to achieve a controlled dissolution and/or dispersion of the flavouring ingredient into the liquid carrier.

Abstract: The present invention demonstrates a continuous process for dry conveying of powdered coal either a blend of carbonaceous material subject to partial oxidization whereby the conveying feed will be transferred via a suitable conveyer from an atmospheric silo to a or a number of extruder's LP Feeder Vessel and be fed over extruder's inlet chute in continuo to a or a number of extruder(s), in which the dry feed material will be densificated along the compression zone of that extruder up to high pressure and will be discharged over outlet chute into a downstream said First Pressurized Vessel, wherefrom the feeding precursor will be transported via a or a number of in series pressurized tubular-drag conveyor to the said Second Pressurized Vessel, which is equipped with one or more Reactor Feeding Unit(s), referred to Splitter(s), each one consisting of a Star Valve, Reactor-Feed-Line and a said Injection-Line for pneumatic conveying individually, whereby the feed carbonaceous material will be exposed to with injec

Abstract: A mixer (10) for mixing a combustible gas and a combustion supporting gas comprises a tubular mixing section (1) which extends between one end (1a) having a combustible gas supply port (2) and the other end (1b) having a mixed gas discharge port (3); and a combustion supporting gas supply tube (4) which is inserted into the tubular mixing section (1) between the one end (1a) and the other end (1b) of the tubular mixing section (1), is closed at its tip (4a), and has at least one combustion supporting gas supply port at its juxta-tip lateral part (4b). A central axis of the combustion supporting gas supply tube (4) at the juxta-tip lateral part (4b) is generally parallel to a longitudinal direction of the tubular mixing section (1).

Abstract: A method for continuously preparing a medium formulation mixes a diluent with a plurality of chemically incompatible concentrate solutions in such a manner that none of the ingredients of the concentrate solutions chemically react in an adverse manner. The method utilizes a static mixing chamber to add the concentrate solutions to the diluent stream sufficiently in advance of one another so that adverse chemical reactions do not occur. The method also adjusts a pH level of the diluent prior to adding any of the concentrate solutions to the diluent.

Abstract: A process and system mixes drinking water stored in large water tower type storage tanks, preventing stratification of the water, by generating large mixing bubbles in the tank's standpipe, causing mixing of layers of water in the tank through turbulence created as the bubbles rise through the tank. Embodiments of the present invention, adapted for use in storage tanks in which the standpipe serves as both water inlet and outlet, detect flow in the standpipe and provide mixing only when the standpipe is not serving as a water outlet.

Abstract: A processing liquid mixing apparatus and method capable of maintaining a mixing ratio of the processing liquid produced in a mixing tank constant, a substrate processing apparatus including the processing liquid mixing apparatus, and a storage medium storing a program for controlling the processing liquid mixing apparatus are disclosed. Discharge valves are first open and supply valves are close to discharge stock solutions to an outside through the discharge valves. After all flow rates of the stock solutions detected by LFC reach a predetermined flow rate, the discharge valves are close and the supply valves are open to supply the stock solutions to the second mixing tank through the supply valves.

Abstract: A method and apparatus for preparing and dispensing dental alginate compound comprising a disposable alginate mixing container containing a pre-measured amount of alginate compound powder, a water storage and dispensing means, and an alginate dispensing means. The alginate mixing container is comprised of an agitator utilizing mixing cords that are oriented at an angle to the plane of the arms of the agitator receiving the cords, and a plunger that is slidably engaged with the walls of the cylindrical mixing container. The angular relationship of the cords to the agitator arm pre-stresses the cords against the reactive forces generated by the impingement of the mixing cords and the alginate compound during mixing, and also provides a means to initiate the folding of the cords during the linear movement of the plunger as the alginate compound is dispensed from the mixing container into an impression tray.

Abstract: A method of continuously providing a pressurized slurry of a solid material and liquid carbon dioxide is disclosed. The method comprises mixing particles of the solid material and particles of solid carbon dioxide in a mixing container and feeding the mixture of the solid material and the solid carbon dioxide to a pump to form a slurry of the solid material and liquified carbon dioxide. Within the pump, the solid carbon dioxide sublimates, forming a gaseous carbon dioxide which subsequently liquefies due to an increase in pressure. The liquid carbon dioxide and the solid material then mix to form the slurry of the solid material and the liquid carbon dioxide. In some embodiments, the pressurized slurry may be used for pipeline transportation of the solid material. A system of producing a continuous pressurized slurry of solid material and liquid carbon dioxide is also disclosed. A method of producing hydrogen is also disclosed.

Abstract: In this disclosure, methods and systems for drug delivery utilizing high shear are disclosed. In an embodiment, a method comprises (1) subjecting a therapeutic fluid containing a drug to high shear; and (2) obtaining a processed therapeutic fluid, wherein the processed therapeutic fluid contains the drug in nano-size. In an embodiment, a method comprises (1) subjecting a drug carrier and a therapeutic fluid containing a drug to high shear; and (2) obtaining a processed therapeutic fluid, wherein the processed therapeutic fluid contains the drug carrier loaded with the drug. In an embodiment, a method comprises (1) applying high shear to a drug carrier and a therapeutic fluid containing a drug; (2) obtaining a processed therapeutic fluid, wherein the processed therapeutic fluid contains the drug-loaded carrier; and (3) modifying the drug-loaded carrier with a targeting moiety to obtain a modified drug-loaded carrier.

Abstract: The invention relates to a process and apparatus for the homogenization of feed stock. According to the invention, solid stock material is mixed in at least two successive homogenization steps (1), wherein each homogenization step comprises at least two adjacent tanks (2), and the stock material is fed into adjacent tanks of a first homogenization step (IA), at least two stock flows are conducted out form each tank of each homogenization step, and at least one stock flow is conducted from each homogenization step into at least one tank (2) of the following homogenization step.