A fluid control device 10 comprises a valve device V2 including actuators 22 and 24 for opening and closing a flow path and adjusting a flow rate of a fluid flowing through the flow path, a pressure sensor PT provided upstream of the valve device V2, and a control circuit 12 connected to the valve device V2 and the pressure sensor PT, and the control circuit 12 controls an operation of the actuator based on a pressure measured by the pressure sensor PT and a reference pressure drop curve, while the upstream side of the fluid control device is closed and the valve device is opened using the actuators.

A flood control system for remotely and automatically controlling flooding and water storage on reservoirs. The flood control system generally includes a central computer that controls the water level by controlling or communicating with flow control gates positioned near a number of culverts, wherein each flow control gate typically includes: (a) a control unit communicatively coupled to the central computer, the control unit capable of sending local condition data to the central computer via a wireless connection and further capable of receiving control commands from the central computer; (b) an input/output interface capable of receiving signals or data regarding physical conditions proximate the flow control gate, the input/output interface coupled to the control unit; and (c) a water shutoff valve controllable by the control unit and positioned to selectively allow or block the flow of water through each culvert, wherein each control unit controls each water shutoff valve.

A fluid control device includes a main body block including a first flow passage, and a second flow passage, a first and second fluid control units installed on an installation surface of the main body block. The first and second flow passages include a first portion extending along a first direction and a second flow passage portion orthogonal to the first direction. The second portion is formed of a hole extending from a side surface of the main body block and a sealing member.

A zipper manifold for use in wellbore operations includes a trunk line having a first longitudinal axis, an inlet on a first axial end, an outlet on a second axial end, and a first gate valve positioned between the inlet and the outlet, a block tee fluidly connecting the trunk line to a secondary line, the secondary line having a second longitudinal axis parallel to the first longitudinal axis, a second gate valve positioned along the secondary line, and an outlet head at an end of the secondary line.

A system that controls the flow rates of a plurality of split channels provided parallel to each other to a certain flow split ratio includes: a flow split ratio calculation unit that, in order to be able to diagnose whether a system abnormality that affects the flow split ratio is occurring, calculates a ratio of output values of flow rate sensors obtained by allowing, while fluid control valves of different split channels are closed, fluids to flow in these split channels as an actual flow split ratio; a reference flow split ratio storage unit that stores a reference flow split ratio serving as a reference for the actual flow split ratio; and an abnormality diagnosis unit that compares the actual flow split ratio and the reference flow split ratio, and diagnoses a system abnormality.

Gas distribution apparatus to provide uniform flows of gases from a single source to multiple processing chambers are described. A regulator is positioned at an upstream end of a shared volume having a plurality of downstream ends. A flow controller is positioned at each downstream end of the shared volume, the flow controller comprising an orifice and a fast pulsing valve. Methods of using the gas distribution apparatus and calibrating the flow controllers are also described.

Provided herein are embodiments of a flood prevention system. The flood prevention system may include a water line, a sewer line, and at least one floating switch sensor. The water line and sewer line may be connected to a plumbing fixture. The floating switch sensor may be installed within the sewer line and be connected to a solenoid valve.

Disclosed is an NO supply device including a main gas circuit with NO/N.sub.2 flowrate controller controlled by piloting unit, and a backup circuit including a backup NO circuit and a backup O.sub.2 circuit. The piloting unit are configured in particular to control the NO/N.sub.2 flowrate controller in such a way as to regulate the flowrate of NO/N.sub.2 mixture in the main gas circuit and to direct the gaseous flow obtained in a downstream portion of the backup NO circuit connecting to the backup O.sub.2 circuit in order to form a common backup line including a backup outlet.

A cooling group for a laminar cooling device, including at least one cooling unit arranged above and below a strip to be cooled in order to supply the strip with a cooling liquid, including a central inlet via which cooling liquid is supplied, a distributing tube supplied with cooling liquid by the central inlet, and a number of supplying units supplied with cooling liquid from the distributing tube. Each supplying unit has a number of cooling nozzles via which cooling liquid is discharged onto the strip. In order to minimize the influence of the number of supplying units which are switched on or switched off, and thus have as little expenditure as possible, a volumetric flow rate regulating valve is arranged in or in front of the central inlet. The regulating valve is used to conduct a defined volume of cooling liquid through the central inlet per unit of time.

A fluid control device includes a body inside which is formed a flow path, a fluid control valve that is mounted on the body and controls a fluid flowing through the flow path, and a casing that is mounted on the body in such a way as to house the fluid control valve. A sloping surface that slopes towards the body is formed on a top surface of the casing, which is a surface facing towards an opposite side from the body.