A training disruptor device simulation system is described. The training disruptor device simulation system can include a training disruptor device and a simulator system. The training disruptor device can be configured to mimic a conducted electrical weapon and generate signals that can be detected and analyzed by the simulator system.

Implementations of conductive energy weapons (CEWs) may include a shock generating circuit configured to couple to a power source, two electrodes operatively coupled to the shock generating circuit, and a safety circuit operatively coupled to the shock generating circuit. The shock generating circuit may be configured to generate a first pulse train and deliver the first pulse train to a target, and may be configured to generate at least a second pulse train and deliver the at least second pulse train to a target. The safety circuit may be configured to prevent the CEW from applying pulse trains to the target after a predetermined number of pulse trains. The first pulse train may include two or more pulses having waveforms substantially identical with each other, each of the waveforms of the two or more pulses having both a positive voltage segment and a negative voltage segment.

A conducted electrical device (100) that includes a housing (120), an electrode (105) configured to be ejected from the housing (120), and a controller (205). The controller (205) is configured to receive a characteristic as a function of at least one selected from the group consisting of audio and video, corresponding to a target (110), and control the electrode (105) based on the characteristic.

A conducted electrical weapon (“CEW”) comprises one or more mechanisms for receiving, aligning, and maintaining a position of a magazine within a bay of the CEW. Bias spring and datums may be used to align the magazine to be coupled to the CEW, wherein bias springs are configured to apply pressure to push the magazine to interact with datums to align the magazine. A spring and ramp mechanism may be used to maintain a position of the magazine coupled to the bay of the CEW. Respective grades of a locking ramp and a release ramp are used to lock a spring in place when a magazine is coupled to the bay of the CEW.

A conducted electrical weapon may deploy a first electrode. Deploying the first electrode may include deploying fewer electrodes than a minimum number required by the conducted electrical weapon to provide the stimulus signal at a remote location. The first electrode may be deployed in response to a first activation signal of a plurality of activation signals. The conducted electrical weapon may deploy a second electrode in response to a second activation signal of the plurality of activation signals. A signal generator of the conducted electrical weapon may provide a stimulus signal between the first electrode and the second electrode.

A magazine for a conducted electrical weapon may include a bore configured to receive a cartridge. The bore may be sized and shaped to receive a cartridge having a specific cartridge type. A cartridge may comprise a cartridge identifier coupled to an outer surface of the cartridge. The cartridge identifier may include a physical property indicating a cartridge type of the cartridge. The cartridge identifier may allow the cartridge to be correctly received into the bore of the magazine.

A short-range conducted electrical weapon (“conducted electrical weapon”) may be configured to deploy electrodes having a minimum spacing when coupled to a target at short-range. The conducted electrical weapon may comprise a housing. The housing may comprise a target end opposite a grip end. The grip end may be configured to removably receive a cartridge. The cartridge may house two or more electrodes. The target end may comprise one or more activation buttons or terminals. In response to the activation buttons or terminals being activated, the electrodes may be launched from the cartridge in the grip end. The electrodes may be disposed in the cartridge at an obtuse angle relative to the placement of the opposite electrode. The obtuse angle may enable the electrodes to be deployed effectively at short range.

A conducted electrical weapon may include an interposer. The interposer may be disposed in a bay of the conducted electrical weapon or may be coupled to a magazine insertable within the bay of the conducted electrical weapon. The interposer may include a cartridge separator. The cartridge separator may logically or physically define a plurality of cartridge compartments. Each cartridge compartment may be configured to receive and align with a cartridge loaded into a magazine.

The invention relates to a non-lethal remote-acting electroshock weapon with electrical stunning means for use by law enforcement agencies and for civilian self-defense. The result achieved is the creation of a small remote-acting electroshock weapon capable of displaying an electrical spark discharge and operating in direct contact when loaded with a firing cartridge, and of allowing rapid reloading of the weapon with increased safety for the user. A small remote-acting electroshock weapon comprising a non-conductive housing with a cavity for a firing cartridge activated by a low voltage and having launchable current-conducting wires and a pyrotechnic device arranged inside the firing cartridge for releasing the firing cartridge from the housing of the weapon, a source of electrical energy, and a high-voltage stunning pulse generator having an electrical deactivation switch, is characterized in that it has: a movable mechanical safety trigger which can be controlled by a finger of a hand holding the weapon and interacts with the electrical deactivation switch of the high-voltage stunning pulse generator and with an additional electrical switch for preventing firing of the firing cartridge; a safety lock for preventing movement of the safety trigger in the event of unauthorized movement thereof and for locking the firing cartridge in the housing during firing; and a catch for locking the firing cartridge in the housing, said catch being controllable by the hand with which the user is holding the weapon.

A projectile cartridge that can be removably attached to a flying vehicle is disclosed. A system can include a first flying vehicle, a projectile attachment mechanism configured with the first flying vehicle, a projectile cartridge that contains a projectile, the projectile cartridge being removably attachable to the projectile attachment mechanism, a weight attached to the projectile, the weight being configured in a releasable configuration in the projectile cartridge and a drawstring configured with the projectile. After firing the projectile, when tension is applied to the drawstring as the projectile approaches or envelops a second flying vehicle, the tension can cause the drawstring to close the projectile down to secure the second flying vehicle.