A device to be installed in a pipeline, characterized by at least one static mixer and at least one pre-mixer arranged in a sleeve, wherein said at least one static mixer is characterized by: a body having a plurality of slots through the body, said slots having one or more sides that are angled with respect to an axis passing through a center of the body; a plurality of arms extending from an outer edge of the body towards a center of the body, wherein the plurality of slots comprising at least one concentric ring of slots.

In a fluid injection system for dispensing a solution, said fluid injection system comprises a feeder tank having a product to be dispensed therein, an inlet connection for diverting fluid from a flow line to a fluid nozzle means and an outlet connection for dispensing the solution into the flow line or onto a matter. The fluid nozzle means is in communication with the feeder tank and the inlet connection and the fluid injection system controls a flow rate of fluid at which the fluid nozzle means introduce the fluid into the feeder tank based upon characteristics comprising solubility of the product at a temperature of the fluid in the feeder tank, weight of the product to be dispensed or to be dissolved in the feeder tank, and dispensing time, and the fluid injection system controls a flow rate of the fluid nozzle means to satisfy equation: F=(W)/(T×S) wherein, F is the flow rate of the fluid nozzle means, W is weight of the product in the feeder tank, T is dispensing time and S is solubility of the product at the temperature of the fluid in the feeder tank.

A microfluidic device contains a first layer having a plurality of channels, a second layer having a plurality of droplet makers, and a third layer having a plurality of through-holes connecting the plurality of channels to the plurality of droplet makers. The channels have a height of at least 4 times greater than the height of the droplet makers. The microfluidic device has at least 500 droplet makers in an area less than 10 cm.sup.2. The channels are formed by direct laser-micromachining and the droplet makers are formed by soft lithography molding.

Methods of partition-based analysis. In an exemplary method, a device having a port fluidically connected to a chamber may be selected. A sample-containing fluid may be placed into the port. The sample-containing fluid may be moved from the port to the chamber. Partitions of the sample-containing fluid may be formed. A monolayer of the partitions in the chamber may be created. At least a portion of the monolayer may be imaged.

A continuous asphalt mixture production plant based on double-horizontal-shaft forced mixing includes a cold aggregate bin, a continuous aggregate conveying and metering system, a drying drum, an aggregate elevator, a double-horizontal-shaft continuous mixing host, a continuous asphalt metering and conveying system, a continuous powder conveying and metering system and a finished product bin. The double-horizontal-shaft continuous mixing host includes a first double-horizontal-shaft mixing cylinder and a second double-horizontal-shaft mixing cylinder connected in series. The first double-horizontal-shaft mixing cylinder is provided with an aggregate inlet, an asphalt inlet, a powder inlet and a first discharging port, and the second double-horizontal-shaft mixing cylinder is provided with a mixture inlet and a second discharging port. The aggregate inlet, the asphalt inlet and the powder inlet are respectively connected with an outlet of the aggregate elevator, the continuous asphalt metering and conveying system and the continuous powder conveying and metering system correspondingly.

Carbonation apparatus is provided for carbonating a mixed input flow of pressurized and refrigerated carbon dioxide and water. A first cartridge is disposed within the carbonation chamber, defining a porous micromesh net in fluid communication with the input flow and a central cavity in fluid communication with the carbonation chamber output port. The micromesh net is configured to break up chains of water molecules passing through the net, to enhance bonding between the water and carbon dioxide molecules within the cartridge. The net also responds to the flow of water and carbon dioxide molecules impacting and passing through the net by generating a passive polarizing field that has a polarizing influence on the water molecules to further enhance bonding. Beads may be provided within the cartridge for capturing and stabilizing carbon dioxide molecules to yet further enhance bonding between the water and the carbon dioxide molecules.

A micro-bubble acquisition apparatus is disclosed including a first body in which a water inlet channel, a water outlet channel, a vortex cavity communicating the water inlet channel with the water outlet channel, and an air inlet channel communicated with the vortex cavity are provided. The vortex cavity has an axis offset from an axis of the water inlet channel, the vortex cavity is provided with a water inlet communicated with the water inlet channel, and the water inlet is arranged at a side of the axis of the water inlet channel away from the axis of the vortex cavity.

A method for draining fermenting must from a fermentation tank comprises: a) breaking into chunks a cap that forms in the tank while must ferments in the tank, b) after breaking the cap, mixing the must to homogenize the must and reduce the size of the cap chunks to a size that can pass through a drain of the tank, and c) opening the drain in the fermentation tank to remove the must from the tank. Breaking the cap into chunks includes: a) injecting gas into the must to form a bubble in the must, b) moving the bubble through the must to generate a flow of must within the fermentation tank, and c) shearing a surface of the cap with the generated flow to break the cap into chunks Mixing the must to reduce the size of the cap chunks includes: a) injecting gas into the must to form a bubble in the must, and b) moving the bubble through the must to mix the must.

A continuous production device and method for a silane-modified sealing material are provided. The device includes a twin screw extruder set, a cooling unit, and a static mixing unit; where the twin screw extruder set includes at least two twin screw extruders in series, each of which is provided with at least two inlets and at least one vacuum port, the cooling unit is disposed between last two stages of the twin screw extruders, and an outlet of a last-stage twin screw extruder is connected to the static mixing unit. Through the arrangement of various units of the device and their positional relations, components can be mixed in sequence or added in stages, so as to adapt to the characteristics of each component; a heat stabilizer and a polymer are added together as raw materials, which can increase the temperature for dehydration and avoid thermal decomposition of the polymer, and they cooperate with a dehydrant to make water in the system easier to remove; and the device has high operation flexibility and can adapt to the requirement of variability of a formulation of the silane-modified sealing material.

Disclosed herein is a device and method for changing the conditions of a solution flowing in a serial path. In particular, disclosed herein is a device that includes a chemical reactor, a first system, and a second system that are each serial to one another. Each of the first system and the second system include a mixing chamber, a solvent reservoir, a solvent pump, and one or more detectors. Also disclosed herein is a method for changing the condition of a solution that includes flowing a liquid sample in a path, serially mixing the sample with at least two discrete solvents while it flows through the path, and detecting the condition of the sample after it is mixed with each solvent.