The present disclosure provides techniques for implementing and/or operating a system that includes an outer pipeline, an inner pipeline, and an outer pipeline sealing mechanism. The outer pipeline includes an outer pipe fitting to be secured to an end of an outer pipe segment. The inner pipeline includes an inner pipe fitting to be secured to another end of an inner pipe segment. The outer pipeline sealing mechanism includes a sealing plate to be secured to the outer pipe fitting; a sealing stem that extends out axially from the sealing plate, in which the sealing stem is to be secured to the inner pipe fitting to facilitate sealing an inner pipeline bore from an outer pipeline bore; and a seal ring to be compressed between the sealing plate and the outer pipe fitting to facilitate sealing the outer pipeline bore of the outer pipeline from external environmental conditions.

A dynamic support system includes a control system for controlling inflation and deflation of at least one actuator having an inlet connectable to the a control unit of the dynamic support system. The control unit may be in communication with a sensor and may control inflation and deflation of the at least one actuator in response to information provided by the sensor.

A dynamic support system includes a control system for controlling inflation and deflation of at least one actuator having an inlet connectable to the a control unit of the dynamic support system. The control unit may be in communication with a sensor and may control inflation and deflation of the at least one actuator in response to information provided by the sensor.

A tank system may be conventional and fixed, or mobile, such as a fracking fluid or other tank trailer. A drain port thereof is fitted with an adapter connecting a snorkel system to drain liquids from near the top of the liquid level in the tank. A snorkel head at the extreme distal end of a tube near the longitudinal center of the tank is suspended by a system of buoys. A flow field controller plate resists formation of vortices near the snorkel head, so it can operate as near the surface as possible, withdrawing the highest grade oil efficiently. At its exit, the proximal end of the tube drains oil through an inner conduit of an adapter at a penetration in the wall of the tank. The adapter forms an annulus around the inner conduit draining tank bottoms directly from the tank.

According to the present disclosure, a coupling plate is provided to form electrical, electronic, hydraulic and/or pneumatic connections. The coupling plate comprises an approximately flat base plate, at least two hydraulic connecting devices formed in the base plate, at least one electronic connecting device to provide an electronic connection between a control device of a vehicle and a control device of an accessory device, at least one electrical connecting device, a centring device with at least two coupling and/or counter coupling elements for the relative alignment of the connecting devices of the coupling plate and, if necessary, corresponding connections.

According to the present disclosure, a coupling plate is provided to form electrical, electronic, hydraulic and/or pneumatic connections. The coupling plate comprises an approximately flat base plate, at least two hydraulic connecting devices formed in the base plate, at least one electronic connecting device to provide an electronic connection between a control device of a vehicle and a control device of an accessory device, at least one electrical connecting device, a centring device with at least two coupling and/or counter coupling elements for the relative alignment of the connecting devices of the coupling plate and, if necessary, corresponding connections.

A flexible conduit for transporting fluids in a fluid system, such a fluid system on an aircraft, and methods of assembling the flexible conduit described. The flexible conduit can include a flexible inner hose for transporting a fluid. The flexible inner hose can be surrounded by a flexible outer wall which can contain any leakage of fluid from the flexible inner hose. The flexible inner hose and the flexible outer wall can be coupled on each end to ferrules. Swage rings can be swaged to secure the flexible inner hose and the flexible outer wall to the ferrules.

Apparatuses, devices, systems, and methods are described that provide fluid flow connectors. An example fluid flow connector includes a first connector body that defines a first inner bore and a first plurality of outer bores. The example connector further includes a second connector body that defines a second inner bore and a second plurality of outer bores. In an operational configuration in which the first connector body is attached to the second connector body, the first inner bore mates with the second inner bore to form a first fluid channel, and each of the first plurality of outer bores mate with a respective one of the second plurality of outer bores to form a second fluid channel. The example connector further includes a sealing mechanism that, in the operational configuration, seals the first fluid channel from the second fluid channel and seal the second fluid channel from an external environment of the fluid flow connector.

A connector assembly is configured to fluidly and removably connect a first set of microtubes to a second set of microtubes of a microfluidic device. The connector assembly provides multiple points of contact to the microtubes to provide a secure connection between the connector assembly and the microtubes. A single gasket provides a securely aligned connection between microtubes.

A connector assembly is configured to fluidly and removably connect a first set of microtubes to a second set of microtubes of a microfluidic device. The connector assembly provides multiple points of contact to the microtubes to provide a secure connection between the connector assembly and the microtubes. A single gasket provides a securely aligned connection between microtubes.