The present invention discloses a system for measuring the mechanical properties of sea floor sediments at full ocean depth. The system includes an overwater monitoring unit and an underwater measurement device, where the underwater measurement device includes an observation platform and a measuring mechanism; the observation platform includes a frame-type body and a floating body, a wing panel, a floating ball cabin, a leveling mechanism, a counterweight, and a release mechanism mounted on the frame-type body; the floating ball cabin seals a circuit system; the leveling mechanism adjusts the underwater measurement device horizontally on the sea floor when the frame-type body reaches the sea floor; the release mechanism discards the counterweight for recovery of the unit after the underwater measurement device completes the underwater operation; the measuring mechanism includes at least one of a cone penetration measuring mechanism, a spherical penetration measuring mechanism, and a vane shear measuring mechanism, or a sampling mechanism.

A real-time monitoring apparatus for seafloor deformation during hydrate exploitation, includes a main frame, a detecting device, and a sensing and wireless data transmitting device. The detecting device includes at least two detecting straight rods in different directions; the detecting straight rods are connected to the main frame through the movable sleeves; and at least two fixing supports are configured below each detecting straight rod, perpendicular to and uniformly distributed along the detecting straight rod. A movable lever is configured above each detecting straight rod, the movable lever is connected to the main frame through the lever-fixing rod, and a stretchable and compressible spring is configured at an upper end of the movable lever. The sensing and wireless data transmitting device includes at least two tension and compression force sensors in different directions, a gyroscope sensor, a wireless data transmitter, and a power source, all mounted in the main frame.

The present invention provides an experimental device for simulating invasion of shallow fluid into a wellbore, comprising: a casing pipe; a drilling-in device including a drill string extending into the casing pipe, and a drill bit located within the casing pipe and connected to the drill string; a driving device for driving rotation of the drill string, the driving device being disposed outside the casing pipe and connected to the drill string; a drilling fluid injection device for injecting drilling fluid into the drill string, the drilling fluid injection device being disposed outside the casing pipe and connected to the drill string; a shallow fluid injection device for injecting shallow fluids into the casing pipe, the shallow fluid injection device being disposed outside the casing pipe and communicating with the casing pipe; a pressure detection device for detecting a pressure within the casing pipe, the pressure detection device being connected to the casing pipe.

An apparatus and system for accessing a flow system (such as a subsea tree) in a subsea oil and gas production system, and method of use. The apparatus comprises a body defining a conduit therethrough and a first connector for connecting the body to the flow system. A second connector is configured for connecting the body to an intervention apparatus, such as an injection or sampling equipment. In use, the conduit provides an intervention path from the intervention apparatus to the flow system. Aspects of the invention relate to combined injection and sampling units, and have particular application to well scale squeeze operations.

The present invention discloses a system for measuring the mechanical properties of sea floor sediments at full ocean depth. The system includes an overwater monitoring unit and an underwater measurement device, where the underwater measurement device includes an observation platform and a measuring mechanism; the observation platform includes a frame-type body and a floating body, a wing panel, a floating ball cabin, a leveling mechanism, a counterweight, and a release mechanism mounted on the frame-type body; the floating ball cabin seals a circuit system; the leveling mechanism adjusts the underwater measurement device horizontally on the sea floor when the frame-type body reaches the sea floor; the release mechanism discards the counterweight for recovery of the unit after the underwater measurement device completes the underwater operation; the measuring mechanism includes at least one of a cone penetration measuring mechanism, a spherical penetration measuring mechanism, and a vane shear measuring mechanism, or a sampling mechanism.

A real-time monitoring apparatus for seafloor deformation during hydrate exploitation, includes a main frame, a detecting device, and a sensing and wireless data transmitting device. The detecting device includes at least two detecting straight rods in different directions; the detecting straight rods are connected to the main frame through the movable sleeves; and at least two fixing supports are configured below each detecting straight rod, perpendicular to and uniformly distributed along the detecting straight rod. A movable lever is configured above each detecting straight rod, the movable lever is connected to the main frame through the lever-fixing rod, and a stretchable and compressible spring is configured at an upper end of the movable lever. The sensing and wireless data transmitting device includes at least two tension and compression force sensors in different directions, a gyroscope sensor, a wireless data transmitter, and a power source, all mounted in the main frame.

An apparatus and system for accessing a flow system (such as a subsea tree) in a subsea oil and gas production system, and method of use. The apparatus comprises a body defining a conduit therethrough and a first connector for connecting the body to the flow system. A second connector is configured for connecting the body to an intervention apparatus, such as an injection or sampling equipment. In use, the conduit provides an intervention path from the intervention apparatus to the flow system. Aspects of the invention relate to combined injection and sampling units, and have particular application to well scale squeeze operations.

The present approach includes implementations for generating thermos-hydraulic data via a simulation and evaluating the thermo-hydraulic data pertaining to one or more parameters of a production system. The approach includes receiving operating parameters and receiving coefficients of polynomials for constructing a plurality of pump performance curves. The approach includes performing a selection step. The selection step includes selecting a pump from a plurality of pump types, and sizing the pump based in part on the thermo-hydraulic data, the operating parameters, and the coefficients of polynomials. The approach includes repeating the selection step until each pump of the plurality of pump types has been considered to generate a subset of pumps from the plurality of pump types. The approach includes performing an optimization step on the subset of pumps. The approach includes generating a visual display to identify the set of preferred pumps.

A laser measuring system for continuous measurement of a plurality of connected tubulars being inserted into or removed from a wellbore. The laser measuring system can have a laser housing with one or more laser surface velocimeters. The laser housing with a laser arm can be connected to a support member and can communicate via a network to a computer processor and data storage for measuring pipe joint length in real time. A pressurized gas port can pressurize the laser housing above ambient pressure to keep a laser beam clear of particulate and well fluids or ambient pressure can be used with a continuous airflow device. The laser beam is used to detect and calculate length and quantity of tubulars moving past the laser beam transmitting the information to the computer processor in real time.

The present invention provides an experimental device for simulating invasion of shallow fluid into a wellbore, comprising: a casing pipe; a drilling-in device including a drill string extending into the casing pipe, and a drill bit located within the casing pipe and connected to the drill string; a driving device for driving rotation of the drill string, the driving device being disposed outside the casing pipe and connected to the drill string; a drilling fluid injection device for injecting drilling fluid into the drill string, the drilling fluid injection device being disposed outside the casing pipe and connected to the drill string; a shallow fluid injection device for injecting shallow fluids into the casing pipe, the shallow fluid injection device being disposed outside the casing pipe and communicating with the casing pipe; a pressure detection device for detecting a pressure within the casing pipe, the pressure detection device being connected to the casing pipe.