A bidirectional scoop assembly is shown that is mountable to a pipeline for taking samples from the pipeline. A wafer flange is mounted in said pipeline surrounding the fluid flow through the pipeline. A first tubular is extendable through a first side of the wafer flange to receive a sample from the pipeline. A second tubular is extendable through a second side of the wafer flange to receive a sample from the pipeline. The first tubular and second tubular are positioned adjacent each other whereby at least a portion of a first opening of the first tubular and at least a portion of a second opening of the second tubular are axially aligned or parallel to a flow axis of the pipeline.

In a pipe joint, a tapered male screw thread is provided at one end and a joint connection section which is connected to a joint section is provided at the other end. The tapered male screw thread has a length adapted so that, when the tapered male screw thread has been fastened to a tapered female screw thread formed in an end cap, the entire length is engaged with the tapered female screw thread, and the sealing effect is obtained by a seal member.

A swivel coupling assembly includes a first annular member having at least one annular barb, a shoulder and at least one annular groove containing a seal. There is a first bearing surface and a second bearing surface either side of the annular groove. The first and second bearing surfaces have a width equal to or greater than a width of the annular groove. There is a second annular member having an inner surface defining a bore configured to receive the first annular member. When joined, the shoulder of the first annular member frictionally engages the bore of the second annular, thereby allowing rotation. The seal engages with and seals the bore at a location between the ends of the second member. and spaced by a distance of at least the width of the first and second bearing surfaces from the shoulder and the second opening, respectively.

An oral irrigator handle including a housing and a first fitting, the first fitting including a first fitting inlet in fluid communication with a handle inlet in fluid communication with a fluid source and a first fitting outlet in fluid communication with the first fitting inlet. The handle includes a seal positioned around the first fitting and between the first fitting inlet and the first fitting outlet. A second fitting includes a second fitting inlet in fluid communication with the first fitting outlet and a second fitting outlet in fluid communication with the second fitting inlet. A bottom portion of the second fitting seats on a portion of the first fitting so that the seal engages an interior surface of the second fitting, a flow passage is coupled to the second fitting and in fluid communication with the second fitting outlet.

A retractable sample scoop is shown that is mountable to a pipeline for taking samples from the pipeline. A retractable mounting mechanism mounts to the pipeline wall. A tubular is extendable into the opening of pipeline and retractable from the pipeline. A first seal creates sealing around the tubular portion with respect to said pipeline while permitting insertion, retraction and rotation of said first tubular portion with respect to said pipeline. A second seal comprises a tubular without threads to pipe connector with threads.

A retractable sample scoop is shown that is mountable to a pipeline for taking samples from the pipeline. A retractable mounting mechanism mounts to the pipeline wall. A tubular is extendable into the opening of pipeline and retractable from the pipeline. A first seal creates sealing around the tubular portion with respect to said pipeline while permitting insertion, retraction and rotation of said first tubular portion with respect to said pipeline. A second seal comprises a tubular without threads to pipe connector with threads.

A bi-directional flow scoop system and/or tandem system is mountable to a pipeline operable for receiving and returning a fluid flow from the pipeline. A first tubular is mounted so that the first tubular extends into the pipeline. The scoop end comprises a bend leading to a first face with a first opening for communication with the fluid flow. A second tubular is mounted with a second opening for communication with the fluid flow. The bi-directional scoop is configurable to provide fluid flow in two directions when mounted to the pipeline. In one embodiment, the bi-directional flow scoop system and/or tandem system a flange is provided for separately mounting the first and second tubulars and in another embodiment the second tubular is mounted within the first tubular.

A bi-directional flow scoop system and/or tandem system is mountable to a pipeline operable for receiving and returning a fluid flow from the pipeline. A first tubular is mounted so that the first tubular extends into the pipeline. The scoop end comprises a bend leading to a first face with a first opening for communication with the fluid flow. A second tubular is mounted with a second opening for communication with the fluid flow. The bi-directional scoop is configurable to provide fluid flow in two directions when mounted to the pipeline. In one embodiment, the bi-directional flow scoop system and/or tandem system a flange is provided for separately mounting the first and second tubulars and in another embodiment the second tubular is mounted within the first tubular.

A banjo fitting is provided that may include an annular portion with an internal bore that extends along a first axis, and a hose attachment portion that extends radially from the annular portion, and has an internal fluid passageway extending along a second axis formed at an angle to the first axis. A seal rupturing structure may be positioned within the internal fluid passageway of the hose attachment portion.

Systems and designs are provided for a flexible connector to be used in fuel and hydraulic lines that can withstand a high level of internal and external stress. In one example, the connector consists of three separate components, an upper, a lower and a middle portion. Spherical bearings and compression springs are used o couple the three portions together. Spherical bearings provide the ability of the connector to rotate about an axis, while the compression springs hold together the system.