Exemplary spatial genomics systems may include a flow cell and a fluid manifold. The flow cell may define an open interior, a fluid inlet to a first end of the open interior, and a fluid outlet to a second end of the open interior opposite the first end. The fluid manifold may include a body defining a plurality of fluid inlet lumens, a fluid outlet lumen, and a fluid waste lumen. Each of the plurality of fluid inlet lumens may be fluidly coupled with the fluid outlet lumen. The fluid outlet lumen may be fluidly coupled with the flow cell. The fluid manifold may include a plurality of fluid switches. Each of the plurality of fluid switches may be fluidly coupled with a respective one of the plurality of fluid inlet lumens. The fluid waste lumen may be fluidly coupled with the fluid outlet of the flow cell.

A fracturing manifold system includes a first manifold assembly in a side-by-side arrangement with a second manifold assembly. The first manifold assembly includes a plurality of first junctions, each having multiple inlet ports facing a first side of the fracturing manifold system. The second manifold assembly includes a plurality of second junction, each having multiple inlet ports facing a second side of the fracturing manifold assembly. Inlet ports on a single junction may be angled relative to each. The inlet ports may also be angled relative to a manifold flow path.

A coupling for an irrigation system may have a first member and a second member, each of which has threads that engage a threaded fitting of an adjacent component. The first member may have a shank and a flange that has a greater exterior dimension than the shank. The flange may have a first locking extension. The second member may have a bore that receives the shank such that the second member is slidable along the base member between a locked configuration in which rotation of the second member about the centerline induces rotation of the base member about the centerline, and an unlocked configuration, in which the second member is rotatable about the centerline independently of rotation of the base member. The second member may further have a first recess that receives the first locking extension in the locked configuration.

A fracturing system includes a plurality of junctions mounted on a chassis, such as a trailer chassis. Pressurized fluid is provided to the plurality of junctions via a plurality of conduits, e.g., from one or more pumps. The junctions and the conduits are independently mounted and independent vibration dampening systems damp vibrations at the individual mounts. Vibration of individual of the junctions may be damped by a first dampening system having first dampening properties and individual of the conduits may be damped by a second dampening system having second dampening properties different from the first dampening properties.

A fracturing system includes a plurality of junctions mounted on a chassis, such as a trailer chassis. Pressurized fluid is provided to the plurality of junctions via a plurality of conduits, e.g., from one or more pumps. The junctions and the conduits are independently mounted and independent vibration dampening systems damp vibrations at the individual mounts. Vibration of individual of the junctions may be damped by a first dampening system having first dampening properties and individual of the conduits may be damped by a second dampening system having second dampening properties different from the first dampening properties.

A fracturing manifold system including a first plurality of junctions mounted on a support structure and fluidly connected via conduit, individual ones of the first plurality of junctions configured to receive fracturing fluid from at least one fracturing pump and the first plurality of junctions including a first terminal junction. The fracturing manifold system further includes a fracturing head fluidly connected to the first plurality of junctions. The fracturing manifold system is configurable between a first configuration in which the fracturing head is mounted at a location proximate an end of the support structure and a second configuration in which an additional junction is mounted on the first support structure at the location, the additional junction is fluidly connected to the first plurality of junctions, a second plurality of junctions is fluidly connected to the additional junction, and the fracturing head is fluidly connected to the second plurality of junctions.

A fracturing manifold system including a first plurality of junctions mounted on a support structure and fluidly connected via conduit, individual ones of the first plurality of junctions configured to receive fracturing fluid from at least one fracturing pump and the first plurality of junctions including a first terminal junction. The fracturing manifold system further includes a fracturing head fluidly connected to the first plurality of junctions. The fracturing manifold system is configurable between a first configuration in which the fracturing head is mounted at a location proximate an end of the support structure and a second configuration in which an additional junction is mounted on the first support structure at the location, the additional junction is fluidly connected to the first plurality of junctions, a second plurality of junctions is fluidly connected to the additional junction, and the fracturing head is fluidly connected to the second plurality of junctions.

The present invention regards a manifold for use in a flow system, comprising a longitudinal main pipe section (1) with one inlet (13) connectable to a feed pipe (9) and at least two outlets (14) arranged in a row along the main pipe section (1), where a center axis (15) of the main pipe section (1) during normal use extends in a mainly horizontal direction. The outlets (14) are arranged in a lower half of the main pipe section (1) and connected to outlet pipe sections (22) arranged with a center axis (21) extending with an downward angle from the main pipe section (1). The invention also regards a method for distributing a mixed flow into several pipes and a method for cooling a multiphase fluid.

The present invention regards a manifold for use in a flow system, comprising a longitudinal main pipe section (1) with one inlet (13) connectable to a feed pipe (9) and at least two outlets (14) arranged in a row along the main pipe section (1), where a center axis (15) of the main pipe section (1) during normal use extends in a mainly horizontal direction. The outlets (14) are arranged in a lower half of the main pipe section (1) and connected to outlet pipe sections (22) arranged with a center axis (21) extending with an downward angle from the main pipe section (1). The invention also regards a method for distributing a mixed flow into several pipes and a method for cooling a multiphase fluid.

A piping structure (1A) comprises a first pipe (10) to which food (H) is supplied, a plurality of second pipes (20) provided downstream of the first pipe (10) and connected to the first pipe (10), and a plurality of third pipes (30) provided downstream of the second pipes (20), a number of the plurality of third pipes being connected to each of the second pipes (20).