A method of forming a drag reducing polymer formulation. The method begins by forming a drag reducing polymer. A hydrocarbon additive is then incorporated with the drag reducing polymer to form a drag reducing polymer formulation. The drag reducing polymer formulation is then used as a drag reducer in hydrocarbon pipelines.

Conventional systems for monitoring pipe networks are generally not scalable, impractical in the field with uncontrolled environments or rely of static features of pipes that are vary depending on the pipes under consideration. The ideal sensor-ed monitoring systems are not economically viable. Systems and methods of the present disclosure provide an improved data-driven model to rank pipes in the order of burst probabilities, by including dynamic feature values of pipes such as pressure and flow that depends on network structure and operations. The present disclosure enables estimating approximate values for the dynamic features since they are hard to estimate accurately in the absence of a calibrated hydraulic model. The present disclosure also validates the estimated approximate dynamic feature values for the purpose of estimating bursts likelihood vis-a-vis accurate values of the dynamic metrics.

Various systems, methods, and devices are provided for focusing particles suspended within a moving fluid into one or more localized stream lines. The system can include a substrate and at least one channel provided on the substrate having an inlet and an outlet. The system can further include a fluid moving along the channel in a laminar flow having suspended particles and a pumping element driving the laminar flow of the fluid. The fluid, the channel, and the pumping element can be configured to cause inertial forces to act on the particles and to focus the particles into one or more stream lines.

Various systems, methods, and devices are provided for focusing particles suspended within a moving fluid into one or more localized stream lines. The system can include a substrate and at least one channel provided on the substrate having an inlet and an outlet. The system can further include a fluid moving along the channel in a laminar flow having suspended particles and a pumping element driving the laminar flow of the fluid. The fluid, the channel, and the pumping element can be configured to cause inertial forces to act on the particles and to focus the particles into one or more stream lines.

The LNG fuelling nozzles are plugged to the vehicles propelled by natural gas specifically in a coupling means of the fuel tanks. During the unplugging of said nozzles once the tank has been filled cause always inevitably a gas leak and in the event of a leak during the filling there is a leak near the user which, in addition to be hazardous, pollute the environment and economically harms the user.

For this reason the invention proposes a solution consisting of channeling the gas from these leaks to a supplementary tank and, from it to the supply tank, recovering all the leaks, for which a pipe is used as main elements of the device, which is coupled to the bayonet by means of a seal connector made of Teflon or similar material and, a check valve at the inlet of the supplementary tank, said seal can be incorporated either in the bayonet or in the receptacle.

A flow channel structure includes a member including a flow channel. The flow channel includes a first part, second parts, and connections. The first part extends in a first direction. The connections connect the first part and the second parts. The connections include a first bend and a second bend. The first bend arcuately extends with a first curvature and a central angle of greater than 90 degrees. The first bend has a first end connected to the second parts, and a second end. The second bend arcuately extends with a second curvature. The second bend has a third end connected to the second end. A tangent to the first end extends in a same direction as the second parts extend. A tangent to the second end is equal to a tangent to the third end.

A flow channel structure includes a member including a flow channel. The flow channel includes a first part, second parts, and connections. The first part extends in a first direction. The connections connect the first part and the second parts. The connections include a first bend and a second bend. The first bend arcuately extends with a first curvature and a central angle of greater than 90 degrees. The first bend has a first end connected to the second parts, and a second end. The second bend arcuately extends with a second curvature. The second bend has a third end connected to the second end. A tangent to the first end extends in a same direction as the second parts extend. A tangent to the second end is equal to a tangent to the third end.

Disclosed are gas cylinder assemblies for containing pressurized gas. The gas cylinder assembly has a polymeric liner and a low-permeability barrier layer. The polymeric liner a first end portion, a second end portion and a central body. The central body comprises an outer surface and an inner surface disposed between the first end and the second end. The gas cylinder assembly comprises a reinforcement structure wound over the central body. The gas cylinder assembly further comprises a metal foil interposed between the reinforcement structure and central body. The metal foil is configured to reduce permeation of contents of the polymeric liner.

A method of delivering transport fluid from an open port interface to an outlet via a transfer conduit includes delivering, to the open port interface, a transport liquid at a first flow rate. The open port interface is disposed in a pressure environment having a first pressure. A second pres-sure is applied at the outlet, wherein the second pressure is less than the first pressure. The pressure applied at the outlet generates a motive flow on the transport liquid, thereby drawing into the transfer conduit (a) the transport fluid, wherein the transport fluid is in contact with a wall of the transport conduit, and (b) a gas present in the pressure environment. The gas forms an air core within the drawn transport fluid. The air core extends substantially an entire length of the transfer conduit.

A water delivery device that includes a body having a cold water inlet, a hot water inlet, and an outlet; a mixing valve in the body, and a touchscreen user interface on a surface of the body. The mixing valve includes a housing having a mixing chamber that is fluidly connected to the outlet, a first flow control valve moveably disposed in the housing to control a cold water flow from the cold water inlet to the mixing chamber, and a second flow control valve moveably disposed in the housing to control a hot water flow from the hot water inlet to the mixing chamber. The touchscreen user interface allows a user to control a temperature and/or a flow rate of water from the outlet by controlling the first and second flow control valves.