A fluid supply system and method is provided that includes a fluid pump, a pressure sensor, a pressure relief valve (PRV), and a fluid monitoring device. The fluid pump receives fluid from a first conduit and discharges fluid into a second conduit. The pressure sensor produces sensed fluid pressure signals. The PRV is in signal communication with the pressure sensor. The fluid monitoring device includes a control orifice in fluid communication with second and third conduits. The second conduit has a first inner diameter, the third conduit has a second inner diameter, and the control orifice has an orifice inner diameter, and the orifice inner diameter is less than the first and second inner diameters. The pressure sensor senses fluid pressure in the third conduit at a position in close proximity to the control orifice. The fluid monitoring device may be in a lead or a lag domain configuration.

An apparatus for the production of air gases by the cryogenic separation of air can include a cold box having a heat exchanger, and a system of columns; a pressure monitoring device; and a controller. The cold box can be configured to receive a purified and compressed air stream under conditions effective for cryogenically separating the air stream to form an air gas product. The apparatus may also include means for transferring the air gas product from the cold box to an air gas pipeline. The pressure monitoring device is configured to monitor the pipeline pressure, and the controller is configured to determine whether to operate in a power savings mode or a variable liquid production mode. By operating the apparatus in a dynamic fashion, a power savings and/or additional high value cryogenic liquids can be realized in instances in which the pipeline pressure deviates from its highest value.

Methods, apparatus, and articles of manufacture to multi-purpose an acoustic emission sensor are disclosed. An example apparatus includes a collection engine to obtain a measurement from an acoustic emissions sensor coupled to a fluid flow control assembly, and obtain a state of the fluid flow control assembly. The example apparatus further includes a selector to adjust a gain of a pre-amplifier based on the state to adjust the measurement, and a condition identifier to identify a condition of the fluid flow control assembly based on the adjusted measurement.

Methods, apparatus, and articles of manufacture to multi-purpose an acoustic emission sensor are disclosed. An example apparatus includes a collection engine to obtain a measurement from an acoustic emissions sensor coupled to a fluid flow control assembly, and obtain a state of the fluid flow control assembly. The example apparatus further includes a selector to adjust a gain of a pre-amplifier based on the state to adjust the measurement, and a condition identifier to identify a condition of the fluid flow control assembly based on the adjusted measurement.

A method of fabricating an elastomeric structure, comprising: forming a first elastomeric layer on top of a first micromachined mold, the first micromachined mold having a first raised protrusion which forms a first recess extending along a bottom surface of the first elastomeric layer; forming a second elastomeric layer on top of a second micromachined mold, the second micromachined mold having a second raised protrusion which forms a second recess extending along a bottom surface of the second elastomeric layer; bonding the bottom surface of the second elastomeric layer onto a top surface of the first elastomeric layer such that a control channel forms in the second recess between the first and second elastomeric layers; and positioning the first elastomeric layer on top of a planar substrate such that a flow channel forms in the first recess between the first elastomeric layer and the planar substrate.

A method of fabricating an elastomeric structure, comprising: forming a first elastomeric layer on top of a first micromachined mold, the first micromachined mold having a first raised protrusion which forms a first recess extending along a bottom surface of the first elastomeric layer; forming a second elastomeric layer on top of a second micromachined mold, the second micromachined mold having a second raised protrusion which forms a second recess extending along a bottom surface of the second elastomeric layer; bonding the bottom surface of the second elastomeric layer onto a top surface of the first elastomeric layer such that a control channel forms in the second recess between the first and second elastomeric layers; and positioning the first elastomeric layer on top of a planar substrate such that a flow channel forms in the first recess between the first elastomeric layer and the planar substrate.

An apparatus employing pressure transients for transporting fluids from a first reservoir to a second reservoir, includes at least one partly enclosed space and a body. The body is movable relative to the interior of the space. The apparatus also includes at least one first conduit and at least one second conduit in fluid communication with the opening via a third conduit, and connected to the first and second reservoir, respectively. An opening in the enclosed space allows a fluid to flow alternately in the direction into and out of the space and which opening is connected to a third conduit. At least one solid object is arranged to fall onto and collide with the body so as to generate pressure transients in the space to produce a flow of fluid in the direction from the space towards the second reservoir, and to produce a flow of fluid in the direction from the first reservoir towards the space.

Systems, methods and apparatuses are provided for the reduction of hydrodynamic frictional drag. These systems, methods and apparatuses can include a vessel surface having an external layer and a plurality of dimples, wherein the external layer comprises a hydrophilic material, and wherein each of the dimples includes an inner surface having a superhydrophobic coating. The dimples can be configured to maintain an air-water interface as one or more fluids flow over the vessel surface. In some embodiments, a pressure reservoir can be coupled with the dimples, and can include an acoustic speaker to vibrate the air-water interface.

A magnetic-hydrodynamic force fluid logic controller is provide that includes a solid or flexible or flexible substrate, a fluid chamber disposed above the substrate, where the chamber includes a fluid under test that includes an active magnet, where the active magnet is disposed to control a magnetic north pole of the droplet and a magnetic south pole of the droplet, a two-dimensional distribution of magnetic elements a surface the solid or flexible substrate, where the magnetic elements comprise a magnetization in a magnetic north pole and magnetization in a magnetic south pole, where the magnetic elements are activated by an external magnetic field of the active magnet, where the droplets have a droplet magnetization, where the droplet magnetization is configured for droplet self-interaction by the magnetic elements and the active magnet, where the self-interaction comprises splitting, merging, propagation, logic, storage, memory and all possible combinations of logical circuit operations.

An apparatus for the production of air gases by the cryogenic separation of air can include a cold box having a heat exchanger, and a system of columns; a pressure monitoring device; and a controller. The cold box can be configured to receive a purified and compressed air stream under conditions effective for cryogenically separating the air stream to form an air gas product. The apparatus may also include means for transferring the air gas product from the cold box to an air gas pipeline. The pressure monitoring device is configured to monitor the pipeline pressure, and the controller is configured to determine whether to operate in a power savings mode or a variable liquid production mode. By operating the apparatus in a dynamic fashion, a power savings and/or additional high value cryogenic liquids can be realized in instances in which the pipeline pressure deviates from its highest value.