A manifold includes a housing defining first and second inlets and outlets. With the housing, a valve retainer defines a first chamber in fluid communication with the first and second inlets. The valve retainer may engage a first valve assembly having a first actuator attached to a first valve member for regulating flow from the first outlet, and a second valve assembly having a second actuator attached to a second valve member for regulating flow from the second outlet port. A sensor assembly is configured to detect first and second operations of the first and second valve assemblies. A controller directs independent operations of the first and second actuators based on first and second flow rates derived from the first and second operations. The first and second valve members may be positioned within portions of respective first and second valve bodies in open fluid communication with the first chamber.

A hydraulic system for a hybrid module which is located between an engine and a transmission includes a parallel arrangement of a mechanical pump and an electric pump. Each pump is constructed and arranged to deliver oil to other portions of the hydraulic system depending on the operational mode. Three operational modes are described including an electric mode, a transition mode, and a cruise mode. Various monitoring and control features are incorporated into the hydraulic system.

An apparatus includes a high-pressure tank, a controller, a valve, controlled by the controller, and a heater.

The present disclosure provides a system and method for odorizing natural gas flowing through a distribution pipeline. The system includes a bypass line adjacent to a distribution pipeline, wherein bypass gas flows through the bypass line and an odorant tank connected to the bypass line, and into the distribution pipeline; a high-flow control valve and a low-flow control valve in the bypass line, wherein bypass gas flows through the odorant tank into the distribution pipeline when the high-flow control valve or the low-flow control valve is open; and a programmable logic controller connected to the high-flow and low flow control valve; wherein the programmable logic controller opens the high-flow or low-flow control valve for a predetermined dwell time proportional to an amount of bypass gas needed to odorize gas in the distribution pipeline each time that a preselected quantity of gas flows through the distribution pipeline.

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.

In accordance with the principals of the present invention, a computer-controlled valve array to meter fluids is provided. An intake manifold defines a fluid-inlet chamber. A fluid inlet is in fluid communication with the fluid-inlet chamber of the intake manifold, the fluid inlet adapted to receive a high-pressure source of fluid. A number of valves have an inlet and an outlet. In an embodiment, the valves comprise pintle valves. At least one valve inlet is in fluid communication with the fluid-inlet chamber. The valves are electronically controlled to allow fluid through in response to a trigger. An outtake manifold is in fluid communication with the valve outlets. Outlet ports are in fluid communication with the outtake chamber of the outlet manifold. The outlet ports are adapted to receive and fluid communicate with the output circuit.

There is provided an apparatus for supplying liquid, comprising a flow controller configured to measure a flow rate of a liquid and control the flow rate based on a measurement value; a first valve connected with the flow controller to control supply of a first liquid to the flow controller; a second valve connected with the flow controller to control supply of a second liquid to the flow controller; and a control device configured to control the first valve and the second valve, wherein the control device switches over the first valve and the second valve with providing a delay time between an open/closed switchover time of the first valve and an open/closed switchover time of the second valve.

A system for controlling sand discharge from a plurality of sand separators each of which has a dump line and an actuated valve apparatus in the dump line. There is a first controller which is operatively connected to the actuated valve assemblies and is configured to open one of the actuated valve assemblies in response to a parameter such as internal pressure in the sand separator. There is a second controller which is connected to the first controller and which is also connected to an actuated discharge valve in a common discharge line to which all of the dump lines are connected. On a command from the first controller to the second controller that a selected one of the actuated valve assemblies is opening, the second controller opens the discharge valve.

Disclosed is a flow control system for digital and mechanical redundant pressure compensation. On the basis of an original pressure compensation valve, two-position three-way electromagnetic valves are added to control the opening and closing of pressure compensation valves. Furthermore, pressure sensors and a controller are added, so that the system has a digital pressure compensation function. When the pressure sensor breaks down, the flow control system is switched to a mechanical compensation mode to achieve mechanical pressure compensation, the problem that system flow cannot be controlled when the sensor breaks down is solved, and the purpose of redundancy control is achieved. Moreover, the pressure compensation valve in the loop where the highest load is located can be controlled to be completely opened through the two-position three-way electromagnetic valve to reduce pressure loss of the valve port, and the pressure is not affected by load fluctuation.

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.