Disclosed is a bi-directional exhalation valve useful for many applications such as in CPAP devices. The exhalation valve includes a valve body having a center chamber, side chambers, and bidirectional ports coupled to the center chamber via passages and a mechanism that provides fluid ingress into the bi-directional valve in a first mode of operation or fluid egress from the bi-directional valve in a second mode of operation. Unidirectional ports are coupled to the plurality of bidirectional ports to provide providing fluid egress from the valve in the second mode of operation, and a unidirectional port provides fluid ingress into the bi-directional valve in the first mode of operation. A mechanism including a center paddle, side paddles, and a shaft are arranged in an elongated compartment of the valve body, such that the shaft is pivots and the central and side paddles open and close corresponding ones of the input and output ports.

A microfluidic valve comprises a first reservoir, a second reservoir, an inertial pump and a channel connecting the first reservoir to the second reservoir. The second reservoir is to receive fluid from the first reservoir through the channel under a pressure gradient. The inertial pump is within the channel proximate the second reservoir and distant the first reservoir.

The invention provides a system comprising a microfluidic device for providing a mechanical stimulation to a material, the microfluidic device comprising a hosting chamber, a pressure array, and an elastic membrane, wherein the hosting chamber is configured for hosting the material, wherein the membrane is arranged between the pressure array and the hosting chamber, wherein the pressure array comprises a plurality of pressure chambers configured to independently provide a pressure to the membrane, wherein the pressure array comprises two adjacent pressure chambers sharing a chamber separator, wherein the membrane is configurable at a plurality of distances from the chamber separator based on pressures provided to the membrane by the two adjacent pressure chambers.

A miniaturized hydraulic valve having a valve chamber arranged in a housing having an inlet and an outlet, wherein a wall includes a shifting member movable in the direction of the inlet and/or the outlet, and wherein a fluid-filled drive chamber is arranged on an opposite side of the wall, which is connected to a micropump in such a way that the shifting member can be actively deflected by fluid which can be pressurized by means of the micropump, so that its position can be changed relative to the inlet and/or outlet.

Example devices include a fluidic device, such as a fluidic valve, including a body formed from a rigid body material including a fluidic source, a fluidic drain, and a fluidic gate, each of which may have a fluid connection with a chamber, or a portion thereof. The device may further include a gate transmission element, located within the chamber, that is controllable between at least a first position and a second position using a gate pressure received through the fluidic drain. Adjustment of the position of the gate transmission element may allow control of fluid flow through the device. Other devices, methods, systems, and computer-readable media are also disclosed.

A cartridge for analyzing a biological sample, wherein the cartridge includes a fluid system having a plurality of channels and at least one valve, wherein the valve is covered on the outside by a cover, and wherein the valve is configured to be actuated by deforming a wall of the valve.

Microfluidic circuit elements, such as a microvalve, micropump or microvent, formed of a microcavity divided by a diaphragm web into a first subcavity bounded by a first internal wall and a second subcavity bounded by a second internal wall, where the diaphragm web is characterized as a thin film having a first state contacting the first internal wall and a second state contacting the second internal wall and exhibiting essentially no elasticity in moving between the first state and the second state, the thin film web having been stretched beyond its yield point before or during use are provided. The disclosed elements enable faster and more efficient cycling of the diaphragm in the microcavity and increases the diaphragm surface area. In a preferred embodiment, the microfluidic circuit element is pneumatically driven and controls the motion of fluids in a microassay device.

A cartridge for analyzing a biological sample, wherein the cartridge includes a fluid system having a plurality of channels and at least one valve, wherein the valve is covered on the outside by a cover, and wherein the valve is configured to be actuated by deforming a wall of the valve.

The disclosed apparatus may include a fluidic channel connecting an inlet port and an outlet port. The apparatus may further include a gate transmission element configured to limit fluid flow between the inlet port and the outlet port. Still further, the apparatus may include a primary gate terminal connected to a second fluidic inlet port, where pressure or force at the primary gate may at least partially control movement of the gate transmission element. The apparatus may also include a secondary gate terminal connected to the second fluidic inlet port. Pressure or force at the secondary gate may at least partially control movement of the gate transmission element. Various other associated methods, systems, and computer-readable media are also disclosed.

A valve system for driving fluid and a method for using the same are provided. The valve system includes a fluid unit far away from the rotation center, a fluid unit close to the rotation center, a fluid transferring unit and a gas path pipeline for communicating the fluid unit close to the rotation center with the fluid unit far away from the rotation center. A rotation radius of a fluid outlet of the fluid unit far away from the rotation center is greater than that of a fluid inlet of the fluid unit close to the rotation center. The fluid outlet of the fluid unit far away from the rotation center is located at an end thereof away from the rotation center, and the fluid inlet of the fluid unit close to the rotation center is located at an end thereof close to the rotation center.