The present disclosure relates to a method for controlling deformation of a flexible screen, configured to control the deformation of the flexible screen, the flexible screen including: a flexible screen body, a metal layer attached to a back surface of the flexible screen body, and a current controlled deformation layer coated on the metal layer; the flexible screen further including a power supply circuit, and a current regulation circuit through which the power supply circuit is coupled to the metal layer; and the method including: controlling intensity of current flowing in the metal layer to soften the current controlled deformation layer; making the flexible screen form a desired shape by means of bending or folding; and controlling intensity of current flowing through the metal layer to harden the current controlled deformation layer. In addition, a system for controlling deformation of a flexible screen is also provided. The above method and system for controlling deformation of a flexible screen can control the flexible screen to be deformed to have a desired shape.

An artificial muscle actuator that includes a housing, a dielectric fluid housed within the housing, and an electrode pair positioned in the housing. The electrode pair includes a first electrode and a second electrode. The first electrode and the second electrode each include a metal film. The first electrode includes an insulation bilayer disposed on the metal film of the first electrode in an orientation facing the second electrode. In addition, the insulation bilayer includes an acryl-based polymer layer disposed on the metal film and a biaxially oriented polypropylene (BOPP) layer disposed on the acryl-based polymer layer.

A system, including a magnetorheological (MR) fluid locking system, including a housing, a piston disposed in the housing, wherein the piston is configured to move axially within the housing, an MR fluid disposed in the housing, an MR fluid pump fluidly coupled to the housing, wherein the MR fluid pump is configured to pump the MR fluid into the housing, and an electromagnet configured to magnetize the MR fluid to control axial movement of the piston.

An actuator, such as a pressure actuator or a vacuum actuator, has a housing and a plunger that is guided through the housing. A diaphragm is connected to the housing and to the plunger and forms a gas-tight pressure chamber with the housing. A pressure medium connector is provided on the housing and communicates with the pressure chamber to pressurize the pressure chamber. A braking element is provided on the plunger and enables a braking force can be exerted on the plunger.

A system, including a flow control system, including a valve, a first cylinder including a piston coupled to the valve, wherein the piston moves axially within the first cylinder to transition the valve between open and closed positions, a magnetorheological (MR) fluid within the first cylinder configured to axially move the piston, and an MR fluid device configured to magnetize the MR fluid to control axial movement of the piston.

A device for use in compressing or expanding a working fluid, such as a gas, includes a container, a piston, working fluid, ferrofluid, and at least one magnetic component. The piston includes a piston face. The piston face and the container define an interior cavity having a volume that varies in response to movement of the piston relative to the container. The working fluid and the ferrofluid are contained in the interior cavity. The at least one magnetic component has a magnetic field that exerts magnetic forces on the ferrofluid that stabilize the ferrofluid in a subset of the interior cavity. This displaces the working fluid within the interior cavity.

An electro-hydraulic actuator includes a deformable shell defining an enclosed internal cavity and containing a liquid dielectric, first and second electrodes on first and second sides, respectively, of the enclosed internal cavity. An electrostatic force between the first and second electrodes upon application of a voltage to one of the electrodes draws the electrodes towards each other to displace the liquid dielectric within the enclosed internal cavity. The shell includes active and inactive areas such that the electrostatic forces between the first and second electrodes displaces the liquid dielectric within the enclosed internal cavity from the active area of the shell to the inactive area of the shell. The first and second electrodes, the deformable shell, and the liquid dielectric cooperate to form a self-healing capacitor, and the liquid dielectric is configured for automatically filling breaches in the liquid dielectric resulting from dielectric breakdown.

An ER fluid valve includes a housing and a plurality of parallel flow passages through the housing each defined by spaced electrodes at least one of which is controllable independently of other flow passages electrodes. A controller is configured to selectively establish electrical fields for all of the independently controllable electrodes to close all of the flow passages to ER fluid flowing through the housing. By removing the fields from all of the independently controllable electrodes, all the flow passages are open to the ER fluid flowing through the housing. By establishing fields for select independently controllable electrodes to close their associated flow passages and by leaving other flow passages open, restricted flow of the ER fluid through the housing is accomplished to vary the flow rate through the housing.

A device for use in compressing or expanding a working fluid, such as a gas, includes a container, a piston, working fluid, ferrofluid, and at least one magnetic component. The piston includes a piston face. The piston face and the container define an interior cavity having a volume that varies in response to movement of the piston relative to the container. The working fluid and the ferrofluid are contained in the interior cavity. The at least one magnetic component has a magnetic field that exerts magnetic forces on the ferrofluid that stabilize the ferrofluid in a subset of the interior cavity. This displaces the working fluid within the interior cavity.

A system, including a magnetorheological (MR) fluid locking system, including a housing, a piston disposed in the housing, wherein the piston is configured to move axially within the housing, an MR fluid disposed in the housing, an MR fluid pump fluidly coupled to the housing, wherein the MR fluid pump is configured to pump the MR fluid into the housing, and an electromagnet configured to magnetize the MR fluid to control axial movement of the piston.