A robot with an impact buffering member on the surface of a robot arm for alleviating the impact when the arm contacts an object; and a contact detection unit for detecting a contact between the robot arm and object. The unit has a soft porous member on the front surface side of the impact buffering member and softer than the member; a housing member including the soft porous member and formed of a flexible material; a fluid discharge pipe for discharging a fluid inside the housing member when the object makes contact so the volume of the housing member decreases; and a volume change detection portion for detecting a change in volume of the housing member by utilizing the discharged fluid. It is possible to secure sufficient safety in a cooperative work between a person and a robot or the like, even when the person contacts the robot arm.

A robot with an impact buffering member on the surface of a robot arm for alleviating the impact when the arm contacts an object; and a contact detection unit for detecting a contact between the robot arm and object. The unit has a soft porous member on the front surface side of the impact buffering member and softer than the member; a housing member including the soft porous member and formed of a flexible material; a fluid discharge pipe for discharging a fluid inside the housing member when the object makes contact so the volume of the housing member decreases; and a volume change detection portion for detecting a change in volume of the housing member by utilizing the discharged fluid. It is possible to secure sufficient safety in a cooperative work between a person and a robot or the like, even when the person contacts the robot arm.

An autonomous mobile robot includes a flexible member including a polymer layer extending along an entire length of the flexible member, and an end portion vertically movable away from a body of the robot. A first portion of a fastening mechanism extends along a first lateral edge of the polymer layer and a second portion of the fastening mechanism extends along a second lateral edge of the polymer layer. The first portion of the fastening mechanism is attached to the second portion of the fastening mechanism and forms a conduit to support the image capture device. The conduit includes an inner surface and an outer surface, and the outer surface of the conduit is at least partially defined by the polymer layer. An image capture device is mounted to an end portion of the flexible member.

A robot casing includes, in a hollow resin body portion, two attachment openings and one work opening that communicate between an inside and an outside of the body portion. The two attachment openings are respectively provided in both end portions of the body portion; a metal member constituting an attachment surface is embedded in a resin constituting the body portion at a periphery of the attachment opening; the metal member is provided with attachment holes that allow attachment screws, which are used for attachment to the attachment surface, to penetrate therethrough or to be fastened thereinto, and is also embedded in the resin in a state in which the attachment surface is exposed; and components can be respectively attached to the two attachment openings by utilizing the work opening.

An apparatus including a plurality of robot arm links movably connected to one another, where a first one of the robot arm links includes a frame, where the frame has a first end movably connected onto a second one of the robot arm links; and at least one vibration damper arrangement on the frame of the first robot arm link, where the at least one vibration damper arrangement includes at least one viscoelastic element connected to the frame of the first robot arm link by a connection such that, as the frame of the first robot arm link experiences vibrations, the at least one viscoelastic element dampens the vibrations in the frame of the first robot arm link based upon viscoelasticity and the connection of the at least one viscoelastic element to the frame of the first robot arm link.

A remote control vehicle includes a vehicle body and an acoustic vibration detection device. The vehicle body includes a protection cover. The acoustic vibration detection device is located at a side of the protection cover away from an external surface of the protection cover and configured to detect acoustic vibration generated when the protection cover is hit by an external object. The acoustic vibration detection device includes a housing body, a damping assembly, and an acoustic sensor. The housing body includes a chamber. The acoustic sensor includes a microphone arranged in the chamber through the damping assembly.

A light emitting capacitor can include a first and second electrode, an electroluminescent layer, and at least one elastomeric layer. The electroluminescent layer, which can include an elastomeric material doped with semiconducting nanoparticles, can be disposed between the first and second electrodes. The elastomeric layer can encapsulate the first electrode, second electrode, and electroluminescent layer. The first and second electrodes can be hydrogel or conductive electrodes. The light emitting capacitor can provide dynamic coloration or sensory feedback. The light emitting capacitor can be used in, for example, robotics, wearables (displays, sensors, textiles), and fashion.

A 6-dof parallel robot with a double-gyroscopic component comprises a fixed platform (1), a moving platform (2) and two modules of 3-dof translational robotic component (3); wherein two modules of 3-dof translational robotic component (3) are connected between the moving platform (2) and the fixed platform (1). The 6-dof parallel robot with a double-gyroscopic component provided by the present invention has the following advantages: excellent dynamic performance, compact structure, six degrees of freedom motion with no singularity, high rigidity, high precision, good stability, a large rotational workspace, etc., thus having a broad prospect in both scientific research and industrial application.

Provided is a robot including at least one joint, and at least two links and coupled with each other by the joint. At least one of the links and includes an inner layer made of carbon fiber reinforced plastic, and an outer layer made of elastic material and covering an outer peripheral surface of at least part of the inner layer in a longitudinal direction over an entire circumference, the layers being integrally stacked.

A skin or skin system for a robot or robotics assembly is provided that includes one or more integral elastomeric links (or bars) (IELs) that are configured for receiving and connection with coupling elements or members (e.g., pivot pins) at the ends of mechanical links/bars. The IELs are also configured to act as a final link of a mechanical linkage made up of these mechanical links to provide a closed chain. For example, the body of each of the IELs, or a portion of the IEL body extending between connection points with the coupling elements of the links/bars of the mechanical linkage, provides a final link in a mechanical linkage forming a closed chain to allow it properly function.