A filtered water supply extension system including an extension member and a flow control device, and a method for extending a filtered water supply of a primary appliance, for example, a refrigerator, to an external appliance, for example, a coffee maker, are provided. The extension member draws and directs an additional flow of filtered water from a water filter of the primary appliance to the external appliance, without interrupting a regular flow of filtered water from the water filter to one or more internal appliances, for example, an ice maker, a water dispenser, etc., of the primary appliance. The flow control device connects the extension member to the external appliance and controls the additional flow of filtered water to the external appliance. A microcontroller, in communication with a control panel, controls a valve assembly for directing a measured quantity of filtered water from the water filter to the external appliance.

A conveyor assembly for a medium, wherein the medium is conveyed from a source location to a destination via a conveyor line, where the conveyor line includes a conveyor section arranged between the source location and the destination and the conveyor section is equipped with two conveyor elements that are connected in parallel to each other and that are controlled by a respective flow controller, where the same flow target value and the same flow actual value are fed to both flow controllers, and the flow controllers ascertain a respective correcting variable for each conveyor element from said values, where a changeover device of the conveyor assembly prevents actuation of one conveyor element by one flow controller and releases the actuation of the other conveyor element by the other flow controller if the flow target value is above or below upper and lower changeover thresholds.

An apparatus for testing a fuel cap includes a gas manifold, a fuel cap connector, a base, and a removable cover. The gas manifold is configured to provide a bidirectional flow path through the fuel cap. The fuel cap connector is integrated with or coupled to the gas manifold, and the fuel cap connector is configured to connect the fuel cap to the gas manifold. The base is configured to support the gas manifold and provide at least a first gas input to the gas manifold and through the fuel cap via the bidirectional flow path. The removable cover is configured to be removably connected to the gas manifold and provide at least a second gas input to the gas manifold and through the fuel cap via the bidirectional flow path.

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.

Provided is a method for multi-supplying gas, the method comprising: installing a control valve and an flow meter on each of a plurality of branch lines branched from a main supply line, in which one or more gases are supplied, and supplying the gas; and providing the gas by adjusting flow of the gas by a controller connected to each of the control valve and the flow meter, wherein the controller has a first control manner, which controls each of the control valves based on a rate of flow measured by the flow meter to required portion flow for each branch line, and the first control manner adjusts an open rate of the control valve if the rate of the measured flow to the required portion flow is not within a predetermined range, and a unit of adjusting the control valve increases or decreases according to a difference between the measured flow and the required portion flow.

A hydraulic valve arrangement (1) is provided comprising comprising a supply port arrangement having a high pressure port (2) and a low pressure port (4), a working port arrangement having two working ports (6, 7), a first valve (13) arranged between said high pressure port (2) and said working port arrangement (6, 7), a second valve (14) arranged between said low pressure port (4) and said working port arrangement (6, 7), a controller (19) for controlling said first valve (13) and said second valve (14), said controller (19) having an input connection (20) for receiving a signal of an operator input device, and a regenerative flow path which can be established by means of at least one of said first valve (13) and said second valve (14). The function of such a hydraulic valve arrangement should be enhanced. To this end said controller (19) said controller interrupts said regenerative flow path when a feed pressure at said working port arrangement (6, 7) exceeds a predetermined pressure level.

In a method for operating a tank device of a motor vehicle, with the tank device having a tank and a tank ventilation device with at least one switching valve, an excitation current can be applied to the switching valve, and the switching valve opens only when the excitation current exceeds an excitation current threshold over a certain period of time. Provision is hereby made to apply an excitation current which is greater than the excitation current threshold, at least temporarily, in a first mode of operation to the switching valve for heating purposes, also when ventilation of the tank is not governed by a control unit of the tank device.

A method includes identifying time values for a length of time to carry out process fluid delivery within multiple processing chambers that concurrently process multiple substrates; translating each time value to a recipe parameter for execution of an operation of a processing recipe; and causing the operation to be performed using each recipe parameter as a control value to control valves of a fluid panel of the multiple processing chambers. For each processing chamber of the multiple processing chambers: causing the process fluid to flow to the processing chamber for a first period of time corresponding to a first time value; and causing the process fluid to flow to a divert foreline of the processing chamber for a second period of time, the second period of time being based on a timestep of the operation and the time value.

An air system for use in an air bed system can include a manifold and one or more valves. The manifold can define a an inlet, an outlet, and a vent fluidically connected to atmosphere. A method of operating an air bed system can include deflating an air chamber through the vent in a first valve configuration and through the vent and an exhaust port in a second valve configuration.

A fluid system includes a fluid control assembly in fluid communication with a fluid source in fluid communication with a fluid supply port and the fluid control assembly is in fluid communication with an actuator via an outlet port. A controller controls at least one supply valve and at least one exhaust valve. The at least one supply valve and exhaust valve are in a normally closed position until being actuated by the controller to an open position. The fluid control assembly includes a pressure sensor in communication with the outlet port. Whereby when pressure in the outlet port is less than a predetermined pressure, a controller opens the supply valve to communicate fluid to the actuator via the actuator line and when the pressure in the outlet port is greater than a predetermined pressure the controller opens the exhaust valve to vent the is outside a predetermined range.