The present disclosure relates to an apparatus, system and method for a microchannel valve. The valve is configured to control or switch the flow of gasses or liquids. The valve includes a first substrate with a microchannel interrupted by a rotational element having a matching microchannel. The rotational element is attached to a second substrate in contact with the first. Actuation of the valve is achieved by rotating the second substrate relative to the first. The valve may be configured for capillary input and output, and/or for high pressure operation by means of capillary retention features. The valve may be disposed within a subassembly for maintaining contact, axial alignment, and relative rotational alignment between the first and second substrates. The present disclosure also provides a method for fabricating the valve. The present disclosure also provides ways to eliminate gaps between the two substrates.

A system including a flow control assembly. The system may include a flow regulating shunt system, for various purposes such as a use as a hydrocephalus shunt. The flow control assembly may be controlled according to selected parameters and methods. These include controlling microelectromechanical (MEMS) system to control a pressure in the flow control assembly.

A low-voltage microfluidic valve device and system for regulating the flow of fluid. One low-voltage microfluidic valve device for regulating the low of fluid includes a nano-textured dendritic metallic filament configured to grow and retract in response to a voltage. The low-voltage microfluidic valve device also includes a microfluidic channel configured to allow fluid flow, wherein the fluid flow is selectively interrupted by the growth of the nano-textured dendritic metallic filament. The low-voltage microfluidic valve device also includes a membrane positioned proximate to the fluid and configured to alter shape in response to the growth of the nano-textured dendritic metallic filament.

A fluid handling device includes a first channel, a second channel, and a valve disposed at a connection part between the first channel and the second channel. The valve include a partition wall disposed between the first channel and the second channel, and a diaphragm disposed so as to face the partition wall, a portion of the first channel, and a portion of the second channel. The diaphragm is configured in such a way that when no pressure is applied to the diaphragm, a gap, which serves as a third channel that allows the first channel and the second channel to communicate with each other, is formed between the diaphragm and the partition wall. In plan view, the length of the diaphragm in the extending direction of the third channel is longer than the length of the diaphragm in the direction orthogonal to the extending direction.

A pneumatic system for a medical fluid machine operating a medical fluid cassette, the pneumatic system including an interface for supplying positive pneumatic pressure and negative pneumatic pressure to the medical fluid cassette; a source of positive pneumatic pressure; a source of negative pneumatic pressure; and a pneumatic pump including a first head and a second head, wherein the first head is dedicated to supplying positive pneumatic pressure to the positive pneumatic pressure source and the second head is dedicated to supplying negative pneumatic pressure to the negative pneumatic pressure source.

Microvalve assemblies are disclosed that in some examples include a body including first and second ports and a body plate. The microvalve assemblies further include an actuator assembly including one or more exterior plates coupled to a stack. One of the one or more exterior plates contacts the body plate to form a seat and thereby restrict fluid flow from the first port to the second port, when the stack is not energized. Additionally, the actuator assembly is configured to, when the stack is energized, periodically generate a gap between the one of the one or more exterior plates and the body plate via near-field-acoustic-levitation (NFAL) to allow fluid flow through the first and second ports. Advantageously, the microvalves of this technology are relatively small and consume minimal power, thereby overcoming size and power limitations of existing valves, including pneumatic valve technologies.

In one aspect of the invention, the fluidic device includes a fluidic chip includes a body having a first surface and an opposite, second surface, one or more channels formed in the body in fluidic communications with input ports and output ports for transferring one or more fluids between the input ports and the output ports, and a fluidic chip registration means formed on the first surface for aligning the fluidic chip with a support structure; and an actuator configured to engage with the one or more channels at the second surface of the body for selectively and individually transferring the one or more fluids through the one or more channels from at least one of the input ports to at least one of the output ports at desired flowrates.

The disclosed device may include a first layer of fluidic transducers and a second layer of fluidic transducers. Each transducer in the first layer may include a first electrode coupled to a first substrate of the first layer, a second electrode coupled to a second substrate of the first layer, and a fluid channel between the first and second electrodes of the first layer. Each transducer in the second layer may include a first electrode coupled to a first substrate of the second layer, a second electrode coupled to a second substrate of the second layer, and a fluid channel between the first and second electrodes of the second layer. The second layer of fluidic transducers may be positioned on the first layer of fluidic transducers. Various other methods, systems, and computer-readable media are also disclosed.

A planar micromechanical actuator suspended on opposing suspension zones including a neutral axis between the opposing suspension zones, first to fourth segments into which the planar micromechanical actuator is segmented between the opposing suspension zones, each including a first electrode and a second electrode which form a capacitor and are isolatedly affixed to each other at opposite ends of the respective segment along a direction between the opposing suspension zones so as to form a gap between the first and second electrode along a thickness direction, the gap being offset to the neutral axis along the thickness direction, and wherein the first to fourth segments are configured such that the planar micromechanical actuator deflects into the thickness direction by the first and fourth segment bending into the thickness direction and the second and third segments bending contrary to the thickness direction upon a voltage being applied to the first and second electrodes of the first to fourth segments.

The present disclosure relates to an actuator, an actuator assembly, a method of operating an actuator, a computer program and a system. In one aspect, an actuator may comprise a plurality of independently operable actuation elements and an operator having an operator surface. Each actuation element may have an actuation surface. The operator may be driveable to move the operator surface along a path to selectively engage with the respective actuation surface of each actuation element to actuate the actuation element.