A surge irrigation system includes a main inlet pipe configured to be coupled to a source of pressurized water. The main inlet pipe is coupled to a flow meter for the purpose of improving furrow irrigation. The system further includes two independent, valve-actuated and controlled pipe arm segments extending from the main inlet pipe. One of the pipe arm segments extends toward a first irrigation zone in a field, and the second pipe arm segment extends toward the second irrigation zone in the field. The system further includes water advance sensors for the purpose of improving a surge irrigation program for an improved autonomous and parameter-setting operation. Additionally the controller, sensor and interface use radio communication.

Systems, apparatus and methods for providing air and water to hot tub jets. The present teachings include jet assemblies, manifold assemblies, and related components, as well as methods of assembling hot tubs involving these components. In some cases, the present teachings describe the use of dual extrusion tubing to route air and water through adjacent, connected fluid conduits. In some cases, the present teachings describe a press-and-click method of connecting various components.

The disclosed subject matter includes embodiments of fluid couplings that prevent or discourage misconnection of fluid lines. In embodiments, a coupling device may be configured according to lookup table that defines compatible configurations of connectors. The configurations may be based on the presence and absence of interference members at standardized locations on the respective connectors. The interference members may include posts that mechanically interfere with other posts, but can be inserted into holes when two connectors have a compatible configuration.

A control valve connector has a valve body, a connecting member, at least two sealing rings and a positioning nut. The valve body has a first connecting opening and at least two second connecting openings, an outer edge of the second connecting opening provided with a threaded section. The first connecting opening is configured for coupling with the positioning nut, and the connecting member is a tubal body having a through aperture and a spherical end.

A self-contained breathing connector apparatus, includes a manifold having a manifold inlet, a first manifold outlet and a second manifold outlet, an inlet connector coupled to the manifold inlet, a first outlet connector coupled to the first manifold outlet, and a second outlet connector coupled to the second manifold outlet. The first outlet connector has a first valve and the second outlet connector has a second valve. The first manifold outlet includes a first valve housing for accommodating at least part of the first valve of the first outlet connector, and the second manifold outlet includes a second valve housing for accommodating at least part of the second valve of the second outlet connector.

An object of the invention is to prevent differences in the flow rate and the specific gravity of a gypsum slurry from being caused between slurry discharge ports, to divide a current of the slurry into streams without a factor of stagnation of the slurry provided at a branch part, and also, to ensure a sufficient distance between the discharge ports.

The slurry delivery conduit (10) has a rectilinear tube segment (14), a branch part (15) and branch tube segments (16). A tube-wall joint portion (20) of the branch tube segments configures a counter-flow splitting element (22) in a form of V-letter at the branch part. The slurry is introduced from a mixing area (51) into the rectilinear tube segment, which configures a straight rectilinear fluid passage. The rectilinear tube segment rectifies a flow of the slurry to be an axial or rectilinear current (S), and the axial or rectilinear current is split into branch streams (S1, S2) by the counter-flow splitting element.

A pulsation dampener system is provided. The pulsation dampener system includes a pump that pumps fluid through the pulsation dampener system. A pulsation dampener is located downstream from the pump and dampens pulsations within the fluid. A pressure sensor is located downstream from the pump and detects a pump pressure of the fluid at the pulsation dampener. A wye pipe located downstream of the pulsation dampener and the pressure sensor that diverts the fluid into two or more flow paths. From the wye, a first flow path increases pump pressure of the fluid and a second flow path allows the fluid to flow unrestricted. Piping receives the fluid from the first flow path and the second flow path and discharges the fluid further downstream.

A rigid valve block body and a method for determining fluid flow direction are disclosed. The valve block body includes a first fluid inlet and a further fluid inlet at opposed sides of a rigid valve block body. A first fluid outlet of the valve block body and a further fluid outlet of the valve block body are disposed in a spaced apart relationship. A first V-shaped fluid communication passageway comprises two passageway portions each extending within the valve block body from a first common root region proximate to the first fluid inlet. A further V-shaped fluid communication passageway comprises two further passageway portions each extending within the valve block body away from a further common root region proximate to the further fluid port. An end region of each passageway portion of the first V-shaped fluid communication passageway meets an end region of a respective passageway portion of the further V-shaped fluid communication passageway proximate to a respective fluid outlet.

The disclosure provides for a drain system for an appliance. The drain system can include a Y-hose having a flexible end coupled to a supply of water from tub, a recirculating end, and a drain end, a recirculating valve coupled with the recirculating end, a drain valve spaced from the recirculating valve and coupled with the drain end, and wherein the recirculating end and the drain end are connected via a continuous connecting wall.

A connection unit having a connector and at least one fluid line that is connected to the connector, wherein the connector has at least two connection ends and a connector section that connects the connection ends to one another. A fluid line end of a fluid line engages with at least one connection end of the connector. At least one compensation element is connected to the fluid line in the area of the fluid line end of the fluid line, the compensation element being supportable on at least one support stop via at least one spring element. Due to a pressure increase in the connector section, the compensation element is movable against the restoring force of the spring element in the direction of the support stop, with an increase in the internal volume of the connector section.