The present invention relates to a double pipe and, more specifically, to a double pipe for uniformly distributing a flow, which can distribute as uniformly as possible a flow which should be distributed toward branch pipes thereof. The present invention relates to a double pipe for uniformly distributing a flow, and can be applied to a seawater desalination device or a water purification device using a membrane and can be thus employed in the water treatment plant industry.

Provided is a retention and safety device for hoses including a connection end engageable to a fixed point of a system. The device may include: (1) a rope defining a main extension trajectory and including an engagement portion; (2) a coupling end secured to the rope and connectable to the fixed point; and (3) an engagement end connectable to the hose and including the engagement portion of the rope and a rope guide bushing slidingly constrained to the rope and enclosing at least two portions distant along the main extension trajectory and mutually juxtaposed to the rope. The engagement portion may be substantially continuous and define a complete turn making, by means of a fast knot, an engagement loop in use around the hose, so that the engagement portion can wind around the hose irreversibly clenching along the same if the device is placed in traction.

A water environment robotic system and method has a buoyancy configuration which can be selectively altered. The system includes an underwater robotic vehicle and a buoyancy module that is configured to be repeatedly, selectively buoyantly engaged and buoyantly disengaged with the underwater robotic vehicle. A tether is connected to the buoyancy module and a motor is operatively connected to the tether and is configured to extend and retract the tether and buoyancy module. The tether can be extended and retracted to extend and retract the buoyancy module. Extending and retracting the buoyancy module can buoyantly engage or buoyantly disengage the buoyancy module with the underwater robotic vehicle according to the arrangement of the system. By engaging and disengaging the buoyancy module, the buoyancy of the underwater robot can be selectively altered.

A system and methods for predicting structural failure of at least a portion of a wall of a fluid containment vessel. The wall has an innermost layer for contact with a fluid contained by the vessel and an outermost layer parallel with the innermost layer. The system includes strain-sensing means within a portion of the wall and surrounded by the at least one reinforcement layer including at least one conductor parallel to the innermost layer of the wall. Changes are sensed in an electrical property associated with the at least one conductor resulting from distortion of the wall of the vessel causing distortion of the at least one conductor.

A positioning mechanism for lowering a suction manifold from an operational position with respect to pump fluid end to a transit and service position includes a linkage base plate configured to be fixedly coupled with a vehicle trailer, a linkage arm pivotally coupled with the linkage base plate and the suction manifold, a primary damper pivotally coupled with the linkage base plate and the linkage arm, a secondary damper pivotally coupled with the linkage base plate and the suction manifold, and a mechanical stop removably coupled with the secondary damper and configured to maintain the secondary damper at a fixed length while the mechanical stop is coupled with the secondary damper. The positioning mechanism permits the suction manifold to fall under the force of gravity when the suction manifold is detached from the pump fluid end, the primary damper is configured to slow the fall of the suction manifold under the force of gravity, and removal of the mechanical stop from the secondary damper permits the secondary damper to shorten from the fixed length to a shorter length under the force of gravity.

A positioning mechanism for lowering a suction manifold from an operational position with respect to pump fluid end to a transit and service position includes a linkage base plate configured to be fixedly coupled with a vehicle trailer, a linkage arm pivotally coupled with the linkage base plate and the suction manifold, a primary damper pivotally coupled with the linkage base plate and the linkage arm, a secondary damper pivotally coupled with the linkage base plate and the suction manifold, and a mechanical stop removably coupled with the secondary damper and configured to maintain the secondary damper at a fixed length while the mechanical stop is coupled with the secondary damper. The positioning mechanism permits the suction manifold to fall under the force of gravity when the suction manifold is detached from the pump fluid end, the primary damper is configured to slow the fall of the suction manifold under the force of gravity, and removal of the mechanical stop from the secondary damper permits the secondary damper to shorten from the fixed length to a shorter length under the force of gravity.

A withdrawal system (1) for a container (2) and comprises an immersion pipe (4) mounted on and projecting into the container (2) as well as a withdrawal head (5) that is attachable to the immersion pipe (4) by means of a rotary connection. The withdrawal head (5) attached to the immersion pipe (4) is secured by means of a mechanical locking unit.

A withdrawal system (1) for a container (2) and comprises an immersion pipe (4) mounted on and projecting into the container (2) as well as a withdrawal head (5) that is attachable to the immersion pipe (4) by means of a rotary connection. The withdrawal head (5) attached to the immersion pipe (4) is secured by means of a mechanical locking unit.

A piping system includes a first and a second inner tube assembled end to end and a hot fluid detector. For each inner tube, a first peripheral tube into which the inner tube is introduced and fixed. For each first peripheral tube, a second peripheral tube into which the first peripheral tube is introduced and fixed. A sleeve has a first section which surrounds the ends of the second two peripheral tubes facing one another and a second section which extends between the two ends up to the walls of the first two peripheral tubes. A pipe crosses the sleeve and opening out, on the one hand, into the space between the inner tubes and the first peripheral tubes and, on the other hand, in the vicinity of the hot fluid detector. A piping system of this kind is therefore thermally insulated and allows detection in the event of a leak.

A fracturing fluid delivery system is provided. In one embodiment, the system includes a fracturing manifold and a fracturing tree. A fluid conduit is coupled between the fracturing manifold and the fracturing tree to enable receipt of fracturing fluid by the fracturing tree from the fracturing manifold through the fluid conduit. Further, the fluid conduit is an adjustable fluid conduit that provides a line-of-sight fluid connection from the fracturing manifold to the fracturing tree. Additional systems, devices, and methods are also disclosed.