A system for recovering natural gas liquid from a source, comprising: a heat exchanger for cooling wellstream fluid directed therethrough; a first separator for receiving the fluid from the heat exchanger for separating liquid and gas; in a first configuration, the gas from the first separator being directed to a turbo-expander for reducing the temperature and pressure of the gas to form a cold fluid; the cold fluid being directed to a second separator for separating liquid and gas; gas from the second separator being directed to the heat exchanger where it flows therethrough for cooling the wellstream fluid; wherein if the turbo-expander is not operating, the first configuration may be a changed to a second configuration to bypass the turbo-expander and direct the gas from the second separator to a Joule-Thomson valve to form the cold fluid.

A flaring boom assembly for a flaring system of a rig is disclosed. The flaring boom assembly includes a tray device comprising an open top, a slanted bottom, and an outlet, and a telescoping mechanism mechanically coupled to the tray device and configured to adjust a relative position of the tray device with respect to a burning head of the flaring system based on a flaring intensity of the flaring system. The spills of the flaring system fall through the open top onto the slanted bottom and move along the slanted bottom toward the outlet based on a gravitational force.

An acoustic matching material for gas measurement including a matrix material having an acoustic impedance and an acoustic impedance reduction material, having an acoustic impedance lower than the acoustic impedance of the matrix material, the acoustic impedance reduction material being dispersed in the matrix material to create an acoustic impedance graduation through a thickness of the matching material.

A method may include obtaining first pressure data regarding a first pressure sensor upstream from a restricted orifice and second pressure data regarding a second pressure sensor downstream from the restricted orifice. The method may further include obtaining temperature data regarding a temperature sensor coupled to the restricted orifice. The method may further include obtaining various gas parameters regarding a predetermined gas flowing through the restricted orifice and various orifice parameters regarding the restricted orifice. The method may further include determining a first gas flow rate of the predetermined gas based on a gas flow model, the first pressure data, the second pressure data, the temperature data, the gas parameters, and the orifice parameters.

A system and method for flaring with a flare including a flare stack and a flare tip at a well site having a wellhead and a wellbore for production of crude oil or natural gas, or both, providing produced fluid including hydrocarbon from the wellhead to the flare stack, discharging the produced fluid from the flare tip through a nozzle discharge opening, combusting the hydrocarbon of the produced fluid as discharged from the flare tip, and a control system adjusting flow area of the nozzle discharge opening.

Systems and methods include a computer-implemented method for real-time flare network monitoring. Real-time flaring volume data is received from relief devices connected to a flare network. The real-time flaring volume data is analyzed in conjunction with heat and material balance information of the relief devices. A comprehensive molar balance is performed based on the analyzing, the balancing including losses/feed percentages for each component of the flare network including the relief devices throughout the flare network. Flaring data for the components is aggregated for each flare header. Real-time flare network monitoring information, including instantaneous component-wise flaring for each flare header in the flare network is provided for display to a user in a user interface.

A production stream is received from a well formed in a subterranean formation. The production stream includes a gaseous portion and a liquid portion. The liquid portion has a base sediment and water (BS&W) percentage. At least a portion of the gaseous portion of the production stream is combusted to produce a flaring byproduct stream. The flaring byproduct stream is flowed through a coiled tubing to the well. The BS&W percentage of the liquid portion of the production stream is measured. The flow of the flaring byproduct stream to the well is decreased in response to the BS&W percentage reaching a threshold BS&W percentage.

A transportable well capping system, kit, and methods are provided. The transportable well capping system can include a plurality of modular subsystems capable of fitting within a bed of a standard full-sized pickup truck. The modular subsystems can include a sealing mechanism subassembly including a plurality of different sized seals for securing to a range of diameters of well casings, a gas flow meter subassembly, a hydrogen sulfide scrubber subassembly, a compressor and storage subassembly capable of storing the scrubbed methane in a storage tank, and a methane destruction subassembly capable of igniting the scrubbed methane gas and converting it to carbon dioxide. The subassemblies are sized to be capable of fitting within the bed of a standard full-sized pickup truck and can be driven to a location of an abandoned well and fluidically interconnected in a manner to cap the abandoned well.

A system for monitoring flaring activities on a drill ship includes a plurality of devices in wireless communication with each other on the drill ship. Each of the devices includes a resistive temperature detector configured to determine a temperature within a sensing area of the resistive temperature detector, and a communication device operably connected to the resistive temperature detector, wherein the communication device is configured to receive the temperature data from the resistive temperature detector and send the temperature data to a remote system. The device may also include a global positioning system operably connected to the communication device, the global positioning system configured to identify a location of the drill ship in real-time and send the location data to the communication device, wherein the communication device is configured to send the location data to the remote system.

A system and a method for reduction or elimination of environmentally harmful or “greenhouse” gases in situations in which gaseous hydrocarbons are flared or vented from an oil and gas well are disclosed. The system configures to inject a chemically reactive, or dispersive, or reactive and dispersive atomized mist into a gas flow line leading to a flare stack. The mist reacts with the gas in the flow line to convert methane to hydrogen and carbon monoxide and to reduce other harmful gases, facilitating a clean-burning, compact flare of blue color due to the presence of primarily hydrogen, some carbon monoxide, and a small amount of residual methane. The hydrogen and carbon monoxide may be captured and stored before reaching the ignition point at the top of the flare stack.