A hand control apparatus including an extracting unit extracting a grip pattern of an object having a shape closest to that of the object acquired by a shape acquiring unit from a storage unit storing and associating shapes of plural types of objects and grip patterns, a position and posture calculating unit calculating a gripping position and posture of the hand in accordance with the extracted grip pattern, a hand driving unit causing the hand to grip the object based on the calculated gripping position and posture, a determining unit determining if a gripped state of the object is appropriate based on information acquired by at least one of the shape acquiring unit, a force sensor and a tactile sensor, and a gripped state correcting unit correcting at least one of the gripping position and the posture when it is determined that the gripped state of the object is inappropriate.

This disclosure relates to a technology for grasping an object while adjusting a grasping force according to stiffness of the object measured by a tactile sensor module, especially to a robot-hand, which includes a tactile sensor module for measuring a normal force applied when grasping an object, a phalange sensor module having an actuator to generate a driving force and configured to measure a rotational displacement of a motor, and a hand back control unit for operating the actuator by generating a desired displacement signal to control a grasping force so that a grasping motion is stably and accurately achieved by applying a minimum grasping force to soft object with no sliding and minimized deformation, wherein the desired displacement signal is generated based on stiffness which is calculated from the normal force data and the rotational displacement data.

A modular robotic vehicle (MRV) having a modular chassis configured for a vehicle utilizing two-wheel steering, four-wheel steering, six-wheel steering, eight-wheel steering controlled by a semiautonomous system or an autonomous driving system, either system is associated with operating modes which may include a two-wheel steering mode, an all-wheel steering mode, a traverse steering mode, a park mode, or an omni-directional mode utilized for steering sideways, driving diagonally or move crab like. Accordingly, during semiautonomous control a driver of the modular robotic vehicle may utilize smart I/O devices including a smartphone, tablet like devices, or a control panel to select a preferred driving mode. The driver may communicate navigation instructions via smart I/O devices to control steering, speed and placement of the MRV in respect to the operating mode. Accordingly, GPS and a wireless network provides navigation instructions during an autonomous operation involving driving, parking, docking or connecting to another MRV.

A thumb structure includes a proximal phalanx, a distal phalanx rotatably connected to one end of the proximal phalanx, a fixing member connected to the proximal phalanx through a first ball joint, a linking member having opposite ends that are connected to the distal phalanx and the fixing member through a second ball joint and a third ball joint, a first actuating assembly to drive the proximal phalanx to swing in a direction of a first degree of freedom, and a second actuating assembly to drive the proximal phalanx to swing in a direction of a second degree of freedom.

A system for loading a warewasher, which is embodied as a commercial conveyor warewasher. The loading system includes a gripping system having at least one parallel gripper (1), wherein the at least one parallel gripper (1) includes at least two clamping jaws (2, 3), between which a gripping region of the parallel gripper (1) is defined, wherein at least one of the at least two clamping jaws (2, 3) is segmented such that the at least one clamping jaw (2) is preferably automatically and/or self-adjustable at least in regions to a surface contour of a piece of washware to be gripped by the at least one parallel gripper (1).

A robotic finger structure includes a proximal phalanx; a middle phalanx rotatably connected to one end of the proximal phalanx; a distal phalanx rotatably connected to one end of the middle phalanx and defining a distal phalanx opening in a front side thereof and at one end adjacent to the middle phalanx; a connecting rod having opposite ends that are rotatably connected to the proximal phalanx and the distal phalanx, and an actuating assembly to drive the middle phalanx to rotate with respect to the proximal phalanx. The connecting rod includes a first angled segment having a first recess facing a back side of the middle phalanx. When the distal phalanx is flush with the middle phalanx, the first angled segment passes through the distal phalanx opening, and a first end of the distal phalanx opening extends into the first recess.

Logistic device, for handling a package being collected that defines a contact surface with items not being collected, including a first robotic arm including adaptive gripper having at least three degrees of freedom to modify adaptive gripper position and spatial orientation; a second robotic arm including an end effector defining a resting surface and three degrees of freedom to modify end effector position and spatial orientation; control unit to command the first robotic arm to contact the adaptive gripper and package, to deform the adaptive gripper according to adhesion surface between the package and move the package from a storage position wherein the contact surface contacts the items and a collection position wherein the contact surface does not contact the items; the second robotic arm bringing the end effector resting surface into contact with the contact surface; and then the second robotic arm to move the package.

A robot hand is provided. The robot hand includes a first and second drive gears rotated by first actuator and second actuators; a first interlocked gear interlocked with the second drive gear to rotate in opposite directions; a second interlocked gear interlocked with the first drive gear to rotate in opposite directions; a first inner link engaged with rotation of the first drive gear; a first outer link engaged with rotation of the first interlocked gear; a first end link connected to the first inner link and the first outer link opposite the first actuator; a second inner link engaged with rotation of the second interlocked gear; a second outer link engaged with rotation of the second drive gear; and a second end link connected to the second inner link and the second outer link opposite the second actuator.

The present invention improves the stability while suppressing increases in the size and heat generation amount of motors used in a hand mechanism. The hand mechanism includes a first driving mechanism for driving a first joint portion of each finger portion and a second driving mechanism for driving a second joint portion of each finger portion, the second joint portion being positioned further away from a tip end portion of the finger portion than the first joint portion. Further, the second driving mechanism is a mechanism having smaller back-drivability than the first driving mechanism. When pressing force is to be exerted on the object from gripping finger portions that are in contact with the object, the motors of the first driving mechanisms are driven to rotate in a direction for bending the first joint portions while the motors of the second driving mechanisms are held in a stopped state.

A robotic end effector and method for use thereof are provided. The robotic end effector can include a rigid base structure (230), a plurality of rigid proximal phalanges (210) connected to the rigid base structure (230), a plurality of rigid distal phalanges (200) connected to the proximal phalanges (210) respectively, and a plurality of bellows (250), wherein one end of a proximal phalange (210) is connected to one end of the base structure (230) by a bellows (250), wherein one end of a distal phalange (200) is connected to a proximal phalange (210) by a bellows (250), and wherein a portion of the base structure (230), each proximal phalange (210), and each distal phalange (200) are covered in silicone rubber. It can achieve a high output force to input pressure ratio, and cost efficiently.