Abstract: The present disclosure describes methods and systems, including computer-implemented methods, computer program products, and computer systems, for determining carbon environmental impact for oil and gas pipeline leakages. One computer-implemented method includes: determining, by one or more hardware processors, an amount of Equivalent Carbon Dioxide (ECO2) associated with a pipeline leak in a hydrocarbon reservoir; determining, by one or more hardware processors, a probability of failure of the pipeline leak in the hydrocarbon reservoir; determining, by one or more hardware processors, an environmental consequence factor of the pipeline leak in the hydrocarbon reservoir; determining, by one or more hardware processors, a severity factor of the pipeline leak in the hydrocarbon reservoir based on at least one of the amount of ECO2, the probability of failure, or the environmental consequence factor; and outputting, by one or more hardware processors, the severity factor in a user interface.

Abstract: A method for testing salt formation includes heating, by a first heater of an apparatus, an anion solution arranged in a first vessel of the apparatus to a first predetermined temperature and heating, by a second heater of the apparatus, a cation solution arranged in a second vessel of the apparatus to a second predetermined temperature. The method also includes conveying, by a fluid pump of the apparatus, a volume of the anion solution from the first vessel to the second vessel and simultaneously rotating a stirrer arranged in the second vessel to form a mixed solution. The method includes conveying the mixed solution from the second vessel of the apparatus to a sampler of the apparatus.

Abstract: A method includes providing a cuvette containing a fluid sample having a first substance and emitting light from a light source through the cuvette containing the fluid sample for a duration of time. The cuvette is made of a material that at least partially dissolves in the presence of the first substance. Over the duration of time, the cuvette at least partially dissolves and an intensity of light that passes through the cuvette and the fluid sample changes at a rate. The method also includes receiving, by a light detector, the light that passed through the cuvette, measuring a change in intensity of the received light over the duration of time, and determining that the rate of change in intensity of the light over the duration of time is greater than a threshold rate of change.

Abstract: An apparatus includes a plate and a microheater. The plate defines a sample reservoir, component reservoirs, an outlet, a microfluidic channel, and branches. The sample reservoir is configured to hold a specified sample volume of a hydrocarbon sample. Each component reservoir is configured to hold a respective specified component volume of a different one of the hydrocarbons. The microfluidic channel extends from the sample reservoir to the outlet. Each branch connects a different one of the component reservoirs to the microfluidic channel. The microheater is an electrical resistor that is configured to provide heat to the hydrocarbon sample held in the sample reservoir. The hydrocarbon sample fractionates into the hydrocarbons, which are distributed across the component reservoirs, as the hydrocarbon sample flows from the sample reservoir to the outlet in response to receiving the heat from the microheater.

Abstract: An apparatus includes a plate and a micro-protrusion baffle. The plate defines a microfluidic channel that is configured to flow a sample of lubrication oil. The microfluidic channel has an inlet for receiving the sample of lubrication oil. The microfluidic channel has an outlet for discharging the sample of lubrication oil. The plate defines walls of the microfluidic channel. The walls extend from the inlet to the outlet. The micro-protrusion baffle is located within the microfluidic channel between the inlet and the outlet. The micro-protrusion baffle extends from any of the walls. The micro-protrusion baffle includes a cyclic olefin copolymer. Dissolution of at least a portion of the micro-protrusion baffle in response to the sample of lubrication oil flowing through the microfluidic channel indicates a presence of hydrocarbon fuel in the sample of lubrication oil.

Abstract: An Internet of things (IoT) based system for deploying volatile corrosion inhibitor (VCI) in order to mitigate soil-side corrosion of an aboveground storage tank is provided. The system includes: a VCI tank for storing the VCI; corrosion detection sensors on a soil side of the storage tank for detecting the soil-side corrosion, generating corresponding detection signals, and transmitting the detection signals over the Internet; a control circuit including control logic for receiving the detection signals, generating a flow control signal, and transmitting the flow control signal over the Internet; and a flow control valve (FCV) for receiving the flow control signal and controlling a flow of the VCI from the VCI tank to the soil side of the storage tank in response to the flow control signal in order to mitigate the soil-side corrosion of the storage tank.

Abstract: A system includes a microfluidic device having a substrate, a reservoir defined in the substrate a microfluidic channel formed in the substrate, a microheater, and a detector. The reservoir is configured to store a fluid sample to be tested for the presence or absence of a compound. The microfluidic channel extends from the reservoir and includes a first portion fluidically connected to the reservoir, a second portion, and a detection portion fluidically connected between the first and second portions. The microheater is arranged adjacent to the reservoir and is configured to heat the fluid sample to a temperature at which the fluid sample releases a byproduct in response to being heated. The detector is arranged in the detector portion and is configured to indicate a presence or absence of the compound in the byproduct released from the heated sample.

Abstract: This application discloses integrated probes and probe systems, which can be attached to the robotic arms of a remotely operated vehicle to perform both cathodic protection (CP) voltage measurements and ultrasonic testing (UT) thickness measurements at an underwater surface. In some embodiments, the integrated probe system couples an inner and outer gimbal together such that one or more electrically conductive legs pass from the outer gimbal through the inner gimbal. These legs are arranged about an ultrasonic sensor which extends from the front surface of the inner gimbal. When the integrated probe contacts the underwater surface, both the ultrasonic sensor and at least one leg contact the surface, thereby providing substantially simultaneous CP and UT measurements.

Abstract: This application discloses integrated probes and probe systems, which can be attached to the robotic arms of a remotely operated vehicle to perform both cathodic protection (CP) voltage measurements and ultrasonic testing (UT) thickness measurements at an underwater surface. In some embodiments, the integrated probe system couples an inner and outer gimbal together such that one or more electrically conductive legs pass from the outer gimbal through the inner gimbal. These legs are arranged about an ultrasonic sensor which extends from the front surface of the inner gimbal. When the integrated probe contacts the underwater surface, both the ultrasonic sensor and at least one leg contact the surface, thereby providing substantially simultaneous CP and UT measurements.

Abstract: This application discloses integrated probes and probe systems, which can be attached to the robotic arms of a remotely operated vehicle to perform both cathodic protection (CP) voltage measurements and ultrasonic testing (UT) thickness measurements at an underwater surface. In some embodiments, the integrated probe system couples an inner and outer gimbal together such that one or more electrically conductive legs pass from the outer gimbal through the inner gimbal. These legs are arranged about an ultrasonic sensor which extends from the front surface of the inner gimbal. When the integrated probe contacts the underwater surface, both the ultrasonic sensor and at least one leg contact the surface, thereby providing substantially simultaneous CP and UT measurements.

Abstract: This application discloses integrated probes and probe systems, which can be attached to the robotic arms of a remotely operated vehicle to perform both cathodic protection (CP) voltage measurements and ultrasonic testing (UT) thickness measurements at an underwater surface. In some embodiments, the integrated probe system couples an inner and outer gimbal together such that one or more electrically conductive legs pass from the outer gimbal through the inner gimbal. These legs are arranged about an ultrasonic sensor which extends from the front surface of the inner gimbal. When the integrated probe contacts the underwater surface, both the ultrasonic sensor and at least one leg contact the surface, thereby providing substantially simultaneous CP and UT measurements.