In an approach to creating assembly plan for disaster mitigation, one or more computer processors identify one or more triggering events. The one or more computer processors receive one or more configuration parameters for one or more assembly plans pertaining to the one or more triggering events. The one or more computer processors analyze the one or more configuration parameters to determine necessary configuration parameters based upon the identified one or more triggering events. The one or more computer processors create the one or more assembly plans containing one or more instructions for one or more self-assembling robots based on the determined necessary configuration parameters. The one or more computer processors send the one or more assembly plans to one or more self-assembling robots.

In an approach to creating assembly plan for disaster mitigation, one or more computer processors identify one or more triggering events. The one or more computer processors receive one or more configuration parameters for one or more assembly plans pertaining to the one or more triggering events. The one or more computer processors analyze the one or more configuration parameters to determine necessary configuration parameters based upon the identified one or more triggering events. The one or more computer processors create the one or more assembly plans containing one or more instructions for one or more self-assembling robots based on the determined necessary configuration parameters. The one or more computer processors send the one or more assembly plans to one or more self-assembling robots.

A robotic arm includes an arm with a plurality of degrees of freedom and a gripper configured to manipulate a plurality of tools. The gripper includes a pair of claws. Each claw of the pair includes a first portion of a connector that is configured to connect to a second portion of the connector integrated on each of the plurality of tools.

In an approach to creating assembly plan for disaster mitigation, one or more computer processors identify one or more triggering events. The one or more computer processors receive one or more configuration parameters for one or more assembly plans pertaining to the one or more triggering events. The one or more computer processors analyze the one or more configuration parameters to determine necessary configuration parameters based upon the identified one or more triggering events. The one or more computer processors create the one or more assembly plans containing one or more instructions for one or more self-assembling robots based on the determined necessary configuration parameters. The one or more computer processors send the one or more assembly plans to one or more self-assembling robots.

A shock absorbing disruptor mounting system for a robotic arm includes a rack comprised of a linear guide structure and a carriage which is configured to travel on the linear guide structure. The carriage is selectively movable between a retracted position and an extended position and includes a plurality of wheels along its length. Each of the wheels has a wheel axis of rotation which is transverse to the direction of the linear guide structure centerline to facilitate rotation of the wheels on at least a portion of the linear guide structure responsive to the travel.

A platform including at least one industrial robot, wherein the platform is arranged to be carried by a vehicle to a working site where the at least one industrial robot is to perform a task in relation to the working site. The platform includes a platform body, a platform control unit and a connecting arrangement with a connecting device arranged to be connected to a vehicle arm of the vehicle such that the platform can be carried by the vehicle arm of the vehicle. The connecting arrangement further includes an actuator arranged to cause the platform to rotate around an axis X-X defined by the connecting device according to instructions from the platform control unit. A vehicle including the platform is also described.

Systems (100) and methods (1400) for operating a Spool Mechanism (SM). The methods comprise: transitioning an operational mode of SM from a first operational mode in which a drag torque is not settable to a second operational mode in which the drag torque is settable; selectively mechanically coupling a rewind motor to a spool (612) of SM by engaging a coupler (1014) in response to the SM's transition into the second operational mode; activating the rewind motor (610) such that the rewind motor applies a motor torque having a pre-defined value selected for facilitating a setting of the drag torque to an optimal value; mechanically gradually adjusting an amount of drag resistance applied to the spool by a drag mechanism (1012); and discontinuing the mechanical adjustment of the drag resistance when the spool's speed is within a threshold percentage range of a zero resistance speed.

In an approach to creating assembly plan for disaster mitigation, one or more computer processors identify one or more triggering events. The one or more computer processors receive one or more configuration parameters for one or more assembly plans pertaining to the one or more triggering events. The one or more computer processors analyze the one or more configuration parameters to determine necessary configuration parameters based upon the identified one or more triggering events. The one or more computer processors create the one or more assembly plans containing one or more instructions for one or more self-assembling robots based on the determined necessary configuration parameters. The one or more computer processors send the one or more assembly plans to one or more self-assembling robots.

A system, method, and apparatus comprising a robotic payload platform, an operator control module, a finger joystick controller, and a camera display. A single operator controls the robotic platform system to provide immediate-vicinity reconnaissance and payload delivery during ground assault operations. The robotic platform system is able to be secured to a tactical vest and engaged with minimal setup, deliver commonly available payloads with maximum flexibility, and traverse different terrains.

A platform including at least one industrial robot, wherein the platform is arranged to be carried by a vehicle to a working site where the at least one industrial robot is to perform a task in relation to the working site. The platform includes a platform body, a platform control unit and a connecting arrangement with a connecting device arranged to be connected to a vehicle arm of the vehicle such that the platform can be carried by the vehicle arm of the vehicle. The connecting arrangement further includes an actuator arranged to cause the platform to rotate around an axis X-X defined by the connecting device according to instructions from the platform control unit. A vehicle including the platform is also described.