An artificial muscle includes a housing including an electrode region and an expandable fluid region; an electrode pair positioned in the electrode region of the housing, the electrode pair comprising a first electrode positioned adjacent a first surface of the housing and a second electrode positioned adjacent a second surface of the housing, the first electrode and the second electrode each having a first end proximate the expandable fluid region and a second end opposite the expandable fluid region; a dielectric fluid housed within the housing; and a clamping device applying a force against the first electrode and the second electrode at the second end of the first electrode and the second electrode, wherein the electrode pair is actuatable between a non-actuated state and an actuated state such that actuation from the non-actuated state to the actuated state directs the dielectric fluid into the expandable fluid region.

A gripping device has at least one tendon associated with a gripping arm and guided in a freely slidable manner along a first and second arm portion thereof through a succession of guiding elements. The guiding elements associated with a first proximal arm portion of the arms are carried by an inner yielding panel so that when the inner yielding panel on the inner side of the first proximal arm portion engages against an item or component to be gripped, the guiding elements of the tendon carried by the inner yielding panel cause a tensioning of the tendon, which results in an articulation and/or inflection movement of a second distal arm portion with respect to the first proximal arm portion.

An artificial muscle including a housing, an electrode pair positioned in an electrode region of the housing, the electrode pair including a first electrode and a second electrode, the first electrode and the second electrode each including a pair of tab portions and a bridge portion, the pair of tab portions extending parallel to one another to define a gap portion between the pair of tab portions, the gap portion having a constant gap width extending along a tab length of the pair of tab portions, the bridge portion interconnecting the pair of tab portions, and a dielectric fluid housed within the housing, wherein the electrode pair is actuatable between a non-actuated state and an actuated state such that actuation from the non-actuated state to the actuated state directs the dielectric fluid into an expandable fluid region of the housing.

Various implementations include a modular soft robot including a base, an arm coupled to the base, and an actuator. The arm includes a first surface and a second surface opposite and spaced apart from the first surface. The first surface defines a plurality of channels, each channel comprising a proximal end at the first surface and a distal end spaced apart from the proximal end. Each channel has a longitudinal axis extending therethrough. The actuator is configured to deform the arm.

The subject invention pertains to a novel aerial manipulation system with a flying continuum robotic manipulator (AeCoM). A lightweight tendon-driven continuum robotic arm is coupled with an unmanned aerial vehicle. An attitude sensor (IMU) is used to assist in PCC (Piecewise Constant Curvature) configuration. A tension-based closed-loop control method is used to avoid tendon slacking in manipulating the shape of the continuum arm. The system can achieve improved relative payload capability and motion dexterity. Experimental results validate the performance of tendon-slacking avoidance and kinematics accuracy with different tip loading and tip positioning accuracy for aerial grasping.

Pneumatic soft actuators, and methods and machines capable of modifying their performance and mechanical characteristics. Such a pneumatic soft actuator can be used to connect mechanical components and include an inflatable pouch formed by an airtight, flexible, non-stretchable membrane. The inflatable pouch has oppositely-disposed ends adapted to couple to the mechanical components, and has two lateral edges in which symmetrical folds are formed and define end geometries at the ends of the inflatable pouch. Inflation and deflation of the inflatable pouch increases and decreases, respectively, a distance between the ends of the inflatable pouch to induce relative motion between the mechanical components coupled to the ends of the inflatable pouch.

An electrode pair is provided including a first electrode and a second electrode. Each of the first electrode and the second electrode have an outer surface, an inner surface, a first end, a second end, and a lead extending outwardly from the first end. The lead has a first width at the first end. The second end of at least one of the first electrode and the second electrode have a recess formed therein having a first terminus and a second terminus. A second width extends between the first terminus and the second terminus of the recess. The recess is defined by a saw-tooth pattern. When the first electrode is positioned on the second electrode, the recess of the at least one of the first electrode is adjacent the lead of the other electrode.

An artificial muscle includes an electrode pair including a first electrode and a second electrode. One or both of the first electrode and the second electrode includes a central opening. The first electrode and the second electrode each include two or more fan portions and two or more bridge portions. Each fan portion includes a first end having an inner length, a second end having an outer length, a first side edge extending from the second end, and a second side edge extending from the second end. The outer length is greater than the inner length. Each bridge portion interconnecting adjacent fan portions at the first end.

A robotic manipulator, comprising: a platform (302); a first pair of pneumatic artificial muscle (PAM) devices (112,114) coupled to the platform (302) at a first end of the first pair of PAM devices; a second pair of PAM devices (116, 118) coupled to the platform (302) at a first end of the second pair of PAM devices; a first pulley (342) coupling the first pair of PAM devices via a first belt (132) at a second end of the first pair of PAM devices; a second pulley (344) coupling the second pair of PAM devices via a second belt (134) at a second end of the second pair of PAM devices; a U-joint (160) positioned between the first and second pulleys, wherein the first pulley (342), the second pulley (344), and the U-joint (160) are rotatable along a pitch axis (P1), a yaw axis (Y1), and a roll axis (R1); and an actuated object (170) coupled to the U-joint (160), wherein motion of one of the first belt (132) of the first pair of PAM devices, the second belt (134) of the second pair of PAM devices, and both the first belt (132) and the second belt (134), cause motion of the actuated object (170) along one of the pitch axis (P1), the yaw axis (Y1), and the roll axis (R1).

An artificial muscle stack that includes a plurality of artificial muscle layers. Each artificial muscle layer includes one or more artificial muscles having a housing with an electrode region and an expandable fluid region, a dielectric fluid housed within the housing, and an electrode pair having a first and second electrode positioned in the electrode region. The first and second electrodes each include two or more tab portions and two or more bridge portions. The two or more bridge portions interconnects adjacent tab portions. At least one of the first and second electrode includes a central opening positioned between the tab portions and encircling the expandable fluid region. The plurality of artificial muscle layers are arranged such that the expandable fluid region of the artificial muscles of each artificial muscle layer overlaps at least one tab portion of one or more artificial muscles of an adjacent artificial muscle layer.