An active interlocking fastener system is adapted to control an interlock in response to an external stimulus. The interlocking fastener system includes a first element including a plurality of first interlocking fasteners. The interlocking fastener system also includes a second element including a plurality of second interlocking fasteners configured to couple to the first plurality of interlocking fasteners. The plurality of first interlocking fasteners or the plurality of second interlocking fasteners includes a reactive material configured to vary a mechanical engagement between the plurality of first interlocking fasteners and the plurality of second interlocking fasteners as a function of the external stimulus.

A method for manufacturing a separable artificial muscle fastener includes: securing one or more muscle loops of an artificial muscle fiber to a substrate such that at least a portion of the one or more muscle loops extends out from the substrate; annealing the artificial muscle fiber to retain the one or more muscle loops; and cutting and removing a portion of the one or more muscle loops to transform the one or more muscle loops into one or more muscle hooks. When the one or more muscle hooks are engaged with one or more holders, actuating the one or more muscle hooks disengages the one or more muscle hooks from the one or more holders.

Locking mechanisms and electronic devices having locking mechanisms are described herein. In one example, a locking mechanism includes a latch configured to move between a locked position and an unlocked position, wherein a component of the electronic device is secured in the locked position and removable in the unlocked position. The locking mechanism further includes a memory wire in communication with the latch, wherein the memory wire is configured to contract in length to move the latch between the locked position and the unlocked position to release the component of the electronic device.

An active interlocking fastener system is adapted to control an interlock in response to an external stimulus. The interlocking fastener system includes a first element including a plurality of first interlocking fasteners. The interlocking fastener system also includes a second element including a plurality of second interlocking fasteners configured to couple to the first plurality of interlocking fasteners. The plurality of first interlocking fasteners or the plurality of second interlocking fasteners includes a reactive material configured to vary a mechanical engagement between the plurality of first interlocking fasteners and the plurality of second interlocking fasteners as a function of the external stimulus.

A method for manufacturing a separable artificial muscle fastener includes: securing one or more muscle loops of an artificial muscle fiber to a substrate such that at least a portion of the one or more muscle loops extends out from the substrate; annealing the artificial muscle fiber to retain the one or more muscle loops; and cutting and removing a portion of the one or more muscle loops to transform the one or more muscle loops into one or more muscle hooks. When the one or more muscle hooks are engaged with one or more holders, actuating the one or more muscle hooks disengages the one or more muscle hooks from the one or more holders.

Locking mechanisms and electronic devices having locking mechanisms are described herein. In one example, a locking mechanism includes a latch configured to move between a locked position and an unlocked position, wherein a component of the electronic device is secured in the locked position and removable in the unlocked position. The locking mechanism further includes a memory wire in communication with the latch, wherein the memory wire is configured to contract in length to move the latch between the locked position and the unlocked position to release the component of the electronic device.

A method of bonding or debonding objects includes providing a first object including a first substrate with moveable features thereon which provide an actuated and a non-actuated state having different protrusion from the first substrate or a different curvature. A second object has an array of loops thereon. The moveable features while in one of the actuated state and non-actuated state are positioned, sized and shaped to fit within the loops. The moveable features include or are mechanically coupled to a material which responds to application of an actuating condition including electrical current, temperature, or an electromagnetic field by changing between the actuated state and the non-actuated state. Electrical current, temperature, or an electromagnetic field is automatically applied or changed to trigger a state change between the actuated state and non-actuated state that results in a bonding event or a debonding event between the first object and the second object.