A balancer is provided on robot including a first arm and an arm support for the base end of the first arm to rotate freely via bearing members that have a first axis line extending in the horizontal direction as a central axis; and a gas spring mechanism for causing the first arm to generate torque centered on the first axis line by elastic expansion or elastic contraction in a direction opposite the torque centered on the first axis line that is generated by gravity acting on the first arm between a first angular position and a second angular position in which the slope with respect to the vertical direction is greater than the first angular position.

A gas pressure detection device 10 detects a decrease in a pressure of gas of a gas balancer 8 of a robot 2. The gas pressure detection device 10 includes a calculating part configured to calculate a parameter Rt(?) indicating a magnitude relation between a reference pressure Pa(?) at a rotational angle ? of a rotary arm 14 and a measured pressure Pt(?) measured at the rotational angle ?, calculate a plurality of parameters Rt(?) based on a plurality of measured pressures Pt(?) at different measurement times, and calculate a moving average Rtj(?) of the parameter Rt(?) at a measurement time tj that is a j-th measurement time of the measured pressure Pt(?) (j representing a natural number of 2 or above), and a determining part configured to compare the moving average Rtj(?) with a reference value R to detect the decrease in the pressure of the gas.

Dynamic control of a center of mass position is based on replacement of discrete motion of macro body (counterweighing solid or counterbalancing mechanisms) for continuous molecular flow of counterweighing liquid. Redistributing liquid counterweight between chambers attached to independently moving parts of robot allows its motion to new stable position without disruption in static stability and dynamic balance. Various embodiments include bipods/humanoids, wheeled locomotion robots and hybrid wheeled/multi-pod bio-like robotic systems; some embodiments allow reversible mutual reconfiguration between various structural arrangements. In humanoid embodiments, method allows moving on uneven terrain or ascending staircases while maintaining static stability; method also decreases the probability of fall and secures self-rising if a fall occurred. In some embodiments liquid counterweight may be transferred upon high barriers exceeding the height of robot by a few folds, such as walls of the building or ledge or steep slope in mountains, thus providing robots with capability principally not available to prior art.

New multi-computers architecture allows protection of personal computer by the combined hardware and software means reinforcing online security to the safety level not achievable using software security means alone. The disclosed system encompasses intermediate lock-computer and unidirectional internal interfaces based on novel principles providing complete security while sending information to world wide web and reliable filtering out of unwanted software while receiving information from Internet. One of the key principles underlying the present invention is physical separation of dataflow from web-connected computer to intermediate lock-computer to the main personal computer and the counter dataflow from main computer to lock-computer to web-connected computer. The interfaces in direct data flow from Internet to personal computer and in the counter dataflow may be based on different physical and system principles including novel two-dimensional image-based interface. Effectively, the disclosed methods and apparatuses provide five levels of computer defense, including four principally new levels of defense.

A lifting device includes a framework (2) and a manipulator arm (8) pivotally connected to the framework. The manipulator arm includes a first end portion (19) and a second end portion (13) adapted to carry a tool (20). A balancing arrangement (7; 30, 39) includes a first part (7a; 30a; 39a) connected to the framework and a second part (7b; 30b; 39b) adapted to interact with the first end portion. At least one of the manipulator arm and the balancing arrangement includes a first balancing device (11; 31; 34), which is extendable to ensure that interaction between the second part and the first end portion is maintained. The first balancing device is adapted to generate a first balancing force which maintains a moment balance about the first joint. The manipulator arm has at least two rotational degrees of freedom in a first spherical coordinate system (17).

A load-bearing exoskeleton capable of supporting at least part of the weight of a shielding garment. Additionally, some of the user's upper-body weight, resulting from the rotational moment about the hip caused by the user's trunk in flexion, may be supported. The load-bearing exoskeleton may be a completely passive orthosis, or it may include one or more active orthotic elements. The exoskeleton may include one or more sagittally-extending load-bearing structures that provide a supportive force to counteract at least some of the weight of the shielding garment. The exoskeleton may include a shielding garment attachment mechanism, a pelvis assembly, and one or more leg assemblies that are configured to allow for user movement when in one or more unlocked positions, while facilitating a greater transmission of weight of a shielding garment when in one or more locked positions.

A device comprising a main body, an arm assembly comprising first arm member, a first joint, a second arm member, a second joint, orientation control means for adjusting the orientation of the arm members and/or joints of the arm assembly relative to the main body, one or more passive actuating means for counterbalancing at least a part of the weight of the arm assembly, wherein an adjustable lever mechanism is arranged between the main body and the arm assembly, drive means configured for adjusting the lever arm, one or more orientation sensors for determining the orientation of the arm members and/or joints of the arm assembly relative to the main body, and lever arm control means for adjusting the lever arm of the adjustable lever mechanism with the drive means. The invention further relates to a method of adjusting a lever arm of such a device.

The present invention is a novel passive adjustable gravity compensation apparatus which utilizes an internal-pressure-variable cylinder. With the coordination of cam, rod, or the combination of the fore mentioned, the internal-pressure-variable cylinder obtains the characteristics of a linear elastic device which has variable elastic coefficient. Through appropriately adjusting the internal pressure of the internal-pressure-variable cylinder, the cylinder would perform as a linear elastic device with proper elastic coefficient to fully or partially compensate the gravitational effect of the manipulator system and the load it holds. Thus, the proposed invention can fully or partially compensate the gravitational effect of the manipulator system at different loading conditions without changing its geometric configuration.

A work transfer system includes a robot having a hand which holds a workpiece and a sensor which can detect external force acting on the hand, a balancer connected to the hand and can generate lifting force for lifting the hand in a vertically upward direction, a shape measuring device which conducts measuring of a shape of the workpiece, and a controller controlling the robot and the balancer based on the shape of the workpiece, and the controller adjusts a holding position of the workpiece by the hand based on the shape, and controls the lifting force so that an absolute value of the external force in the vertical direction detected by the sensor becomes equal to or smaller than a predetermined first threshold when the workpiece is held at the adjusted holding position and lifted.

Milking robot device for automatically milking a dairy animal, comprising a milking box having milking cups and a robot arm having an end effector for applying the milking cups to the teats of the dairy animal, on which milking box the robot arm is suspended above the dairy animal to be milked. The robot arm comprises a first arm part connected to the milking box by a first joint, and a second arm part connected to the first arm part by a second joint and provided with an end effector. The first and second arm part, respectively, is pivotable in a vertical plane with respect to the milking box and the first arm part, respectively, by a first and second actuator, respectively. The end effector is movable within an operating range by the robot arm. The milking robot comprises a weight compensation device having a spring device between the milking box and the robot arm. This is configured to exert a first torque about the first joint and a second torque about the second joint, in such a way that, viewed over the operating range, the first torque compensates for the torque exerted by gravity on the arm about the first joint by at least half, in particular by at least 90%, and the second torque compensates for the torque exerted by gravity on the arm about the second joint by at least half, in particular by at least 90%. Consequently, a compact robot arm is provided, the joints which are suspended relatively high up can be protected from dirt in an efficient manner, and they can be operated using much lighter actuators, so that a great deal of energy can also be saved.