A portable apparatus that can be temporarily attached to plumbing angle stop valves and the like, for the purposes of: (i) providing a controlled supply of water for repair and construction operations in a building; and (ii) testing for leaks in plumbing systems. This invention consists of the following components as depicted in FIGS. 1 through 4. Control unit consists of manifold interconnected with valve. Gauge is mounted into gauge port. Inlet pipe is attached to inlet port via matching threaded ends. Posterior end of inlet hose connects to inlet pipe via supply fitting. Anterior end or inlet hose can be attached onto a plumbing angle stop valve via supply fitting; said fitting has circumferential finger grips to facilitate attachment/removal without tools. Outlet port has outlet pipe mounted via matching threaded ends; said pipe can be fabricated in a straight or curved configuration. Quick-disconnect snap coupler can be installed between inlet pipe and inlet fitting as an alternate connection means. Quick-disconnect snap coupler can also be installed between outlet pipe and outlet fitting as an alternate connection means. To use the device, all components are interconnected as described and valve handle is rotated to the closed position. Supply fitting is attached to outlet of closed stop valve. Opening stop valve pressurizes manifold, allowing plumbing water pressure measurement via the gauge. Opening valve handle allows water to flow through device and exit end fitting. Garden hose or implements can be attached to end fitting to extend range of supplied water or employ task-specific tools.

Embodiments of system and methods for supplying fuel, enabling communications, and conveying electric power associated with operation of a hydraulic fracturing unit of a plurality of hydraulic fracturing units are disclosed and may include a fuel line connection assembly configured to be connected to the first hydraulic fracturing unit and to supply fuel from a fuel source to a gas turbine engine connected to the hydraulic fracturing unit. A system also may include a communications cable assembly configured to be connected to the hydraulic fracturing unit and to enable data communications between the hydraulic fracturing unit and a data center or another hydraulic fracturing unit. A system further may include a power cable assembly configured to be connected to the hydraulic fracturing unit and to convey electric power between the hydraulic fracturing unit and a remote electrical power source or the plurality of hydraulic fracturing units.

A system including a sensing device configured to (i) measure pressure of water in cold and hot water lines proximate to a fixture of a water system of a structure, and (ii) generate pressure measurement data representing the pressure of the water. The system also includes one or more processors. The system additionally includes one or more non-transitory computer readable media storing machine-executable instructions configured, when executed on the one or more processors, to perform detecting a non-cyclical pressure event corresponding to a water leak in the water system of the structure during a first time period based on an analysis of information comprising the pressure measurement data. Other embodiments are described.

The systems and methods described herein provide highly dynamic and interactive data analysis user interfaces which enable the data analyst to quickly and efficiently explore large volume data sources, such as computer code or intellectual system. A user interface can be implanted that includes a plurality of nodes associated with portions of a process. The nodes may include indications of logical relationships between nodes. Node identifiers may be associated with particular nodes and be usable to select particular nodes. Reliability scores associated with particular nodes can be included.

A detector unit for use in an aspirating detection system. The detector unit includes an aspirator for drawing air along at least one sampling pipe and into the detector unit; a sensor chamber for analysing a sample of the air drawn into the detector unit; a Venturi conduit through which the air is moved by the aspirator, the Venturi conduit including a first portion of the Venturi conduit and a second portion of the Venturi conduit, a cross-sectional area of the first portion being smaller than a cross-sectional area of the second portion; a pressure sensor configured to detect a differential pressure between the air in the first portion and the air in the second portion of the Venturi conduit; and a controller configured to determine a leak and/or a blockage in the aspirating detection system based on the detected differential pressure.

Methods, systems, and apparatuses are provided for detecting and determining conditions of and conditions within a fluid conduit.

A method for determining a state of a fluidic system can include measuring back pressures in the fluidic system at different times and determining a state of the fluidic system. The determination is based on at least the measured back pressures and on additional status information indicative of at least one status of the fluidic system at at least one of the different times.

Valves, internal combustion engines including such valves, and methods of on-board diagnostic leak detection for a crankcase ventilation system using such valves are disclosed. Each valve has a housing defining a first port and a second port in fluid communication with one another and defining a valve seat therebetween. A biasing member biases a poppet sealing member into a normally open position (defining unrestricted flow through the valve) and a commanded actuator is connected to the poppet sealing member. The poppet sealing member has an orifice therethrough defining a restricted flow path, and, upon command, the commanded actuator moves the poppet sealing member from the open position to a restricted flow position in which the poppet sealing member is seated against the valve seat for restricted flow thorough the orifice in the poppet sealing member.

A pump communicates with a waste fluid storage container and generates a negative pressure to draw waste fluids into the waste fluid storage container. A sensor measures a negative pressure. A driving unit performs driving control upon the pump. A computation unit detects, for example, the amount of air leak from the change in negative pressure. The driving unit performs driving control using an ON period Ton in which the pump operates and an OFF period Toff in which the pump stops. The computation unit detects the amount of air leak using the change in negative pressure in the OFF period Toff.

An inspection device includes an output unit, a storage unit, and an inspection unit. The output unit outputs a control signal for controlling a water supply valve to control supply and no supply of irrigation water from a water supply pipe in an open farm field, between an open state and a closed state. The storage unit stores water pressures of irrigation water as detected in a period from a state where the water supply valve becomes in the open state and irrigation water is supplied from the water supply pipe until an expected time elapses after the water supply valve becomes in the closed state and the water supply pipe is expected to be filled with irrigation water. The inspection unit calculates a time constant of water pressure based on the water pressures and inspects the water supply pipe based on the time constant.