Abstract: Embodiments described herein related to a robotic system for transporting a container. The robotic system includes a lifting mechanism and a container storage assembly coupled to the lifting mechanism. The container storage assembly includes at least one bracket assembly that further includes a bracket elongated member. The bracket elongated member includes a surface having at least one slot and a locking mechanism within the at least one slot. The at least one slot and the locking mechanism are configured to slidably receive and positively lock at least one locking member of the container.

Abstract: An assistive robot system includes a lifting mechanism, a movable arm assembly, a processing device, and a non-transitory, processor-readable storage medium in communication with the processing device. The processing device transmits a command to the lifting mechanism to cause the lifting mechanism to move the movable arm assembly such that a container is gripped within the movable arm assembly, transmits a first one or more signals to the movable arm assembly to cause the movable arm assembly to extend in a system longitudinal direction such that the movable arm assembly grips the container. The movable arm assembly is positioned at a release location and transmits a second one or more signals to the movable arm assembly to cause the movable arm assembly to extend in a system lateral direction such that the container gripped within the movable arm assembly is released from the movable arm assembly at the release location.

Abstract: A robotic system that includes a body, a hitch assembly coupled to the body, and a sensor array coupled to the body. The robotic system includes a processor and operating logic containing programming instructions thereon that, when executed, causes the processor to detect, via the sensor array, a location of a vehicle relative to the body. The programming instructions of the operating logic further cause the processor to detect, via the sensor array, a position of a hitch receiver along the vehicle and move the body toward the vehicle to position the hitch assembly proximate to the hitch receiver. The programming instructions of the operating logic further cause the processor to move the hitch assembly relative to the body and in alignment with the hitch receiver and engage the hitch assembly to the hitch receiver to securely couple the body to the vehicle.

Abstract: Embodiments are directed to an assistive robot system. The assistive robot system includes a lifting mechanism, a movable arm assembly coupled to the lifting mechanism, a container tilting arm assembly, a processing device communicatively coupled to the lifting mechanism and the movable arm assembly, and a non-transitory, processor-readable storage medium in communication with the processing device. The non-transitory, processor-readable storage medium causes the processing device to transmit a command to the lifting mechanism to cause the lifting mechanism to move the movable arm assembly such that the container tilting arm assembly makes contact with a container and transmits one or more signals to the movable arm assembly to cause the movable arm assembly to extend in a system longitudinal direction such that the container within the movable arm assembly is pivoted against the container tilting assembly to tilt the container within the movable arm assembly.

Abstract: An assistive robot includes a manipulator, a base coupled to the manipulator, the base defining a front end and a rear end positioned opposite the front end, the base including a chassis body, a front conveyor assembly positioned at the front end of the base, the front conveyor assembly including a front conveyor defining a conveyor pathway that extends at least partially within the chassis body and a front toe extending outward from the front conveyor, and a rear conveyor assembly positioned at the rear end of the base, the rear conveyor assembly including a rear conveyor defining a conveyor pathway that extends at least partially within the chassis body and a rear toe extending outward from the rear conveyor.

Abstract: A robotic system that includes a body, a hitch assembly coupled to the body, and a sensor array coupled to the body. The robotic system includes a processor and operating logic containing programming instructions thereon that, when executed, causes the processor to detect, via the sensor array, a location of a vehicle relative to the body. The programming instructions of the operating logic further cause the processor to detect, via the sensor array, a position of a hitch receiver along the vehicle and move the body toward the vehicle to position the hitch assembly proximate to the hitch receiver. The programming instructions of the operating logic further cause the processor to move the hitch assembly relative to the body and in alignment with the hitch receiver and engage the hitch assembly to the hitch receiver to securely couple the body to the vehicle.

Abstract: An assistive robot includes a manipulator, a base coupled to the manipulator, the base defining a front end and a rear end positioned opposite the front end, the base including a chassis body, a front conveyor assembly positioned at the front end of the base, the front conveyor assembly including a front conveyor defining a conveyor pathway that extends at least partially within the chassis body and a front toe extending outward from the front conveyor, and a rear conveyor assembly positioned at the rear end of the base, the rear conveyor assembly including a rear conveyor defining a conveyor pathway that extends at least partially within the chassis body and a rear toe extending outward from the rear conveyor.

Abstract: An assistive robot system includes a lifting mechanism, a movable arm assembly, a processing device, and a non-transitory, processor-readable storage medium in communication with the processing device. The processing device transmits a command to the lifting mechanism to cause the lifting mechanism to move the movable arm assembly such that a container is gripped within the movable arm assembly, transmits a first one or more signals to the movable arm assembly to cause the movable arm assembly to extend in a system longitudinal direction such that the movable arm assembly grips the container. The movable arm assembly is positioned at a release location and transmits a second one or more signals to the movable arm assembly to cause the movable arm assembly to extend in a system lateral direction such that the container gripped within the movable arm assembly is released from the movable arm assembly at the release location.

Abstract: Embodiments are directed to an assistive robot system. The assistive robot system includes a lifting mechanism, a movable arm assembly coupled to the lifting mechanism, a container tilting arm assembly, a processing device communicatively coupled to the lifting mechanism and the movable arm assembly, and a non-transitory, processor-readable storage medium in communication with the processing device. The non-transitory, processor-readable storage medium causes the processing device to transmit a command to the lifting mechanism to cause the lifting mechanism to move the movable arm assembly such that the container tilting arm assembly makes contact with a container and transmits one or more signals to the movable arm assembly to cause the movable arm assembly to extend in a system longitudinal direction such that the container within the movable arm assembly is pivoted against the container tilting assembly to tilt the container within the movable arm assembly.

Abstract: Embodiments described herein related to a robotic system for transporting a container. The robotic system includes a lifting mechanism and a container storage assembly coupled to the lifting mechanism. The container storage assembly includes at least one bracket assembly that further includes a bracket elongated member. The bracket elongated member includes a surface having at least one slot and a locking mechanism within the at least one slot. The at least one slot and the locking mechanism are configured to slidably receive and positively lock at least one locking member of the container.