Abstract: According to one embodiment, an instruction device causes, in shipping processing, a plurality of transport devices transporting articles to move respectively to a first area and a second area. The first area and the second area faces each other with a work area interposed. A worker is in the work area. The instruction device further causes one of the plurality of transport devices to transfer the article with the worker in a first section adjacent to the first area. The instruction device further causes another one of the plurality of transport devices to transfer the article with the worker via a take-out device in a second section adjacent to the second area. The take-out device removes the article from the other one of the plurality of transport devices.

Abstract: According to one embodiment, a control system controls a robot. The control system includes a first system and a second system. The first system transmits a first command and supplementary data. The first command is represented using a specification different from a control command specification used by a controller of the robot. The supplementary data corresponds to the first command. The second system generates a second command based on the first command, attaches the supplementary data to the second command, and transmits the second command to the controller. The second command corresponds to the control command specification.

Abstract: According to one embodiment, a control system controls a robot. The control system includes a first system and a second system. The first system transmits a first command and supplementary data. The first command is represented using a specification different from a control command specification used by a controller of the robot. The supplementary data corresponds to the first command. The second system generates a second command based on the first command, attaches the supplementary data to the second command, and transmits the second command to the controller. The second command corresponds to the control command specification.

Abstract: A gripping tool includes a plurality of clamping portions for clamping an object. The plurality of clamping portions extends in an extending direction. The clamping portion includes a clamping body having a clamping surface in planar to which a clamping direction for clamping the object crosses; a friction-holding elastic member disposed on the clamping surface of the clamping body; and an elastic body disposed between the friction-holding elastic member and the clamping surface, the elastic body being lower in elastic modulus than the friction-holding elastic member. The clamping portion has a deformation-restrictor extending along opposite sides of the clamping surface. The opposite sides is separate from each other in a width direction of the clamping surface. The width direction crosses the extending direction of the clamping portion. The deformation-restrictor is configured to restrict, in the width direction, deformation of the elastic body.

Abstract: According to one embodiment, a control system controls a robot. The control system includes a first system and a second system. The first system transmits a first command and supplementary data. The first command is represented using a specification different from a control command specification used by a controller of the robot. The supplementary data corresponds to the first command. The second system generates a second command based on the first command, attaches the supplementary data to the second command, and transmits the second command to the controller. The second command corresponds to the control command specification.

Abstract: According to one embodiment, a control system controls a robot. The control system includes a first system and a second system. The first system transmits a first command and supplementary data. The first command is represented using a specification different from a control command specification used by a controller of the robot. The supplementary data corresponds to the first command. The second system generates a second command based on the first command, attaches the supplementary data to the second command, and transmits the second command to the controller. The second command corresponds to the control command specification.

Abstract: According to one embodiment, a robot hand grips an object. The robot hand includes first and second communicators, and a hand controller. The first communicator communicates grip data with a first device. The grip data is related to a gripping operation. The second communicator communicates a start notification and an end notification with a second device. The second communicator can communicate faster than the first communicator. The start notification is for starting the gripping operation. The end notification indicates an end of the gripping operation. The hand controller controls the gripping operation. In response to the start notification input to the second communicator, the hand controller starts the gripping operation. In response to the end of the gripping operation, the hand controller performs outputting the end notification, and outputting at least one of a result of the gripping operation or a state of the robot hand.

Abstract: According to one embodiment, an inspection system inspects equipment including a first structural object and a second structural object. The first structural object extends in a first direction. The second structural object is provided around the first structural object. The second structural object has a first surface opposing the first structural object. A first protrusion is provided in the first surface. The first protrusion extends in the first direction. The system includes a robot and a controller. The robot includes an imager. The robot moves between the first structural object and the second structural object. The imager images the first protrusion. The controller detects, from a first image acquired by the imager, a first edge portion of the first protrusion in a circumferential direction around the first direction. The controller controls a movement of the robot by using the detected first edge portion.

Abstract: According to one embodiment, a holding device includes: a support member; a first holding unit having a first holding portion configured to hold a holding object; a second holding unit having a second holding portion configured to hold the holding object; and a controller configured to control an operation of the first holding unit and the second holding unit. The controller is configured to switch which of the first holding unit and the second holding unit is used for holding the holding object, by rotating the first holding unit and the second holding unit in a state where the first holding unit and the second holding unit face different directions, and control to change an orientation with respect to the support member, by rotating at least one of the first holding unit and the second holding unit with respect to the support member.

Abstract: According to one embodiment, a holding device includes: holding parts; a holding part opening/closing part that opens and closes the holding parts; a first sensor that detects a load received by the holding part; and a controller that controls an operation of the holding part. At least one of the plurality of holding parts includes a claw member displaceable along a length direction of the holding part, a second sensor that detects a displacement amount of the claw member, and a reaction force applying part that applies a reaction force corresponding to the displacement amount of the claw member to the claw member. The controller controls the operation of the holding part, based on a detection value of the second sensor when the displacement amount is equal to or less than a threshold value, and based on a detection value of the first sensor when the displacement amount exceeds the threshold value.

Abstract: According to one embodiment, a control system controls a robot. The control system includes a first system and a second system. The first system transmits a first command and supplementary data. The first command is represented using a specification different from a control command specification used by a controller of the robot. The supplementary data corresponds to the first command. The second system generates a second command based on the first command, attaches the supplementary data to the second command, and transmits the second command to the controller. The second command corresponds to the control command specification.

Abstract: According to one embodiment, an inspection system inspects equipment including a first structural object and a second structural object. The first structural object extends in a first direction. The second structural object is provided around the first structural object. The second structural object has a first surface opposing the first structural object. A first protrusion is provided in the first surface. The first protrusion extends in the first direction. The system includes a robot and a controller. The robot includes an imager. The robot moves between the first structural object and the second structural object. The imager images the first protrusion. The controller detects, from a first image acquired by the imager, a first edge portion of the first protrusion in a circumferential direction around the first direction. The controller controls a movement of the robot by using the detected first edge portion.

Abstract: According to one embodiment, an inspection system inspects equipment including a first structural object and a second structural object. The first structural object extends in a first direction. The second structural object is provided around the first structural object. The second structural object has a first surface opposing the first structural object. A first protrusion is provided in the first surface. The first protrusion extends in the first direction. The system includes a robot and a controller. The robot includes an imager. The robot moves between the first structural object and the second structural object. The imager images the first protrusion. The controller detects, from a first image acquired by the imager, a first edge portion of the first protrusion in a circumferential direction around the first direction. The controller controls a movement of the robot by using the detected first edge portion.

Abstract: According to one embodiment, an inspection system inspects equipment including a first structural object and a second structural object. The first structural object extends in a first direction. The second structural object is provided around the first structural object. The second structural object has a first surface opposing the first structural object. A first protrusion is provided in the first surface. The first protrusion extends in the first direction. The system includes a robot and a controller. The robot includes an imager. The robot moves between the first structural object and the second structural object. The imager images the first protrusion. The controller detects, from a first image acquired by the imager, a first edge portion of the first protrusion in a circumferential direction around the first direction. The controller controls a movement of the robot by using the detected first edge portion.

Abstract: An electroplating method according to an embodiment is a electroplating method of generating a metal film on a cathode surface by setting a negative potential to a cathode of an anode and the cathode provided in a reaction bath, including mixing and accommodating a plating solution containing at least plated metal ions, an electrolyte, and a surface active agent and a supercritical fluid in the reaction bath and applying a current in a concentration of the supercritical fluid and a cathode current density in which a polarization resistance obtained from a cathode polarization curve while the plated metal ions are reduced is larger than before the supercritical fluid is mixed.

Abstract: An electroplating method according to an embodiment is a electroplating method of generating a metal film on a cathode surface by setting a negative potential to a cathode of an anode and the cathode provided in a reaction bath, including mixing and accommodating a plating solution containing at least plated metal ions, an electrolyte, and a surface active agent and a supercritical fluid in the reaction bath and applying a current in a concentration of the supercritical fluid and a cathode current density in which a polarization resistance obtained from a cathode polarization curve while the plated metal ions are reduced is larger than before the supercritical fluid is mixed.