In order to prevent unnatural behavior of a calculated flow rate, provided is a fluid control device in which a fluid control valve and upstream and downstream pressure sensors are provided on a flow path. The device includes a calculation unit configured to calculate a flow rate based on measured pressures; and an output unit configured to output the calculated flow rate, and exhibit a zero output function of outputting a zero value regardless of the calculated flow rate when the valve is in a closed state. The device is further configured to switch between execution and stop of the zero output function, and when the valve is in an open state and a difference between the measured pressures of the pressure sensors is larger than a threshold, stop the zero output function and cause the flow rate output unit to output the calculated flow rate.

An example method of filling epoxy in a fiber optic connector includes: applying the epoxy to a ferrule of a first connector at a first pressure for a first period of time; applying the epoxy to the first connector at a second pressure for a second period of time until the epoxy is sensed to exit a hole defined by the ferrule of the first connector; comparing the second period of time to a threshold; when the second period of time is greater than the threshold, increasing the first pressure, the first period of time, or the second pressure; and when the second period of time is less than the threshold, decreasing the first pressure, the first period of time, or the second pressure.

A fluid flow system may comprise an input line connected to a drilling system, one or more fluid flow lines connected to the input line, and an output line connected to the one or more fluid flow lines. The system may further include one or more valves disposed in each of the one or more fluid flow lines and one or more pressure sensors disposed in each of the one or more fluid flow lines. A method for controlling a fluid flow system may comprise moving a drilling fluid from a borehole into an input line of the fluid flow system, directing the drilling fluid through the input line into a fluid flow line, measuring a first pressure at a first pressure sensor in the fluid flow line, and measuring a second pressure at a second pressure sensor in the fluid flow line.

A system includes a flow sensor contained within a flow sensor housing, a base, and a seal. The base houses a controller that generates at least one operation modification signal, and the flow sensor is separable from and mountable onto the base. A bottom surface of the flow sensor housing includes the seal. The seal forms a liquid-tight engagement between the flow sensor housing and the base when the flow sensor is mounted onto the base.

A mattress assembly includes: multiple gas-filled chambers each having a top surface, the top surfaces of the chambers collectively composing a top surface of the mattress assembly; multiple composite sensors each associated with a corresponding chamber. Each composite sensor includes a pressure sensor to measure a pressure at a wall of the corresponding chamber and a temperature sensor to measure a temperature of the corresponding chamber. The assembly includes chamber regulators each in communication with a corresponding chamber, each regulator configured to pump gas at a first, higher temperature and gas at a second temperature to the corresponding chamber. The assembly includes a controller in communication with the composite sensors and chamber regulators, programmed to: receive, from composite sensor(s), state data including pressure and temperature information for the chamber corresponding to the composite sensor; determine, based upon the received state data, information about a patient's position relative to the corresponding chamber; and based on the patient's position, control the chamber regulator for the chamber to modify a pressure and/or a temperature of the chamber.

A system includes a flow sensor contained within a flow sensor housing, a base, and a seal. The base houses a controller that generates at least one operation modification signal, and the flow sensor is separable from and mountable onto the base. A bottom surface of the flow sensor housing includes the seal. The seal forms a liquid-tight engagement between the flow sensor housing and the base when the flow sensor is mounted onto the base.

The invention relates to an intelligent safety valve comprising a valve body having a first valve inlet, a valve outlet and a first sensor compartment, the first sensor compartment including a first sensor assembly, the first sensor compartment being arranged in the valve body, a first closing unit suitable for closing the intelligent safety valve, an actuator mechanically connected to the first closing unit in order to close the first closing unit, and a control unit which is connected to the actuator and is suitable for controlling the actuator, wherein the control unit is connected to the first sensor assembly in order to evaluate sets of measured values from the first sensor assembly, and wherein the first sensor assembly comprises at least one analysis sensor, for example a pH sensor, a conductivity sensor or an oxygen sensor.

An automated computer-vision system is used for timing the sand drainage in a sand management arrangement that handles flowback of sand and other solid materials in a slurry of flow from well(s) at wellsite(s). The automated system uses infrared imaging of flowback equipment to determine a level of solids (sand) in the equipment. Image processing of the temperature differences of the content in the equipment gives a demarcation of the sand and liquid separation in the equipment, which is used to determine how much sand is present. If the equipment is found to be full or above a predefined benchmark, the automated system operates a discharge skid to discharge the contents to a waste tank.

Techniques for correlating changing hydraulic pressure differentials with interval control valve (ICV) movements are contemplated. In some aspects, the disclosed technology includes include methods for applying, by a surface controller, a series of differential pressure values to a hydraulic-open line, receiving, from a position sensor, a corresponding valve position for each of the differential pressure values, and calculating a lag time, a move speed and a response delay for each of the first series of differential pressure values. In some aspects, the method can further include steps for generating an ICV positioning model based at least in part on the lag time, the move speed, and the response delay calculated for each of the first series of differential pressure values. Systems and computer-readable media are also provided.

A method for operating a filling system includes: determining a current valve curve of a first filling valve and a current valve curve of a second filling valve; comparing the current valve curve of the first filling valve with a reference valve curve of the first filling valve and comparing the current valve curve of the second filling valve with a reference valve curve of the second filling valve; adjusting a number of filling points at which the current valve curve differs from the associated reference valve curve; detecting and signaling a filling point error in the event of a deviation of the valve curve from the reference valve curve at one filling point; and detecting and signaling a process error in the case of deviation of the valve curve from the reference valve curve at both filling points.