Abstract: A surface clinging robotic device. The device includes a supporting structure or base, on which is mounted (a) a lead pivoting support surface, such as a pivoting wheel, and (b) two or more traction drives, such as drive wheels. Each of the traction drives are independently driven by a separate drive motor. A plurality of vacuum cups are mounted on the bottom of the base. The vacuum cups each have a low friction foot designed for movement over a surface with minimal friction while vacuum is maintained. The low friction foot portion is provided by a generally surface direction oriented C-shaped Teflon skin. The robotic device can move over gaps or obstructions in the surface without losing vacuum in all of the vacuum cups, using a fluid limiting valve at each vacuum cup to interrupt flow in the event of loss of vacuum in that vacuum cup.

Abstract: A surface clinging robotic device. The device includes a supporting structure or base, on which is mounted (a) a lead pivoting support surface, such as a pivoting wheel, and (b) two or more traction drives, such as drive wheels. Each of the traction drives are independently driven by a separate drive motor. A plurality of vacuum cups are mounted on the bottom of the base. The vacuum cups each have a low friction foot designed for movement over a surface with minimal friction while vacuum is maintained. The low friction foot portion is provided by a generally surface direction oriented C-shaped Teflon skin. The robotic device can move over gaps or obstructions in the surface without losing vacuum in all of the vacuum cups, using a fluid limiting valve at each vacuum cup to interrupt flow in the event of loss of vacuum in that vacuum cup.

Abstract: A surface clinging robotic device. The device includes a supporting structure or base, on which is mounted (a) a lead pivoting support surface, such as a pivoting wheel, and (b) two or more traction drives, such as drive wheels. Each of the traction drives are independently driven by a separate drive motor. A plurality of vacuum cups are mounted on the bottom of the base. The vacuum cups each have a low friction foot designed for movement over a surface with minimal friction while vacuum is maintained. The low friction foot portion is provided by a generally surface direction oriented C-shaped Teflon skin. The robotic device can move over gaps or obstructions in the surface without losing vacuum in all of the vacuum cups, using a fluid limiting valve at each vacuum cup to interrupt flow in the event of loss of vacuum in that vacuum cup.

Abstract: A surface clinging robotic device. The device includes a supporting structure or base, on which is mounted (a) a lead pivoting support surface, such as a pivoting wheel, and (b) two or more traction drives, such as drive wheels. Each of the traction drives are independently driven by a separate drive motor. A plurality of vacuum cups are mounted on the bottom of the base. The vacuum cups each have a low friction foot designed for movement over a surface with minimal friction while vacuum is maintained. The low friction foot portion is provided by a generally surface direction oriented C-shaped Teflon skin. The robotic device can move over gaps or obstructions in the surface without losing vacuum in all of the vacuum cups, using a fluid limiting valve at each vacuum cup to interrupt flow in the event of loss of vacuum in that vacuum cup.

Abstract: A robot for performing a working operation on a surface. The robot comprises a frame which supports a pair of parallel tracks. An endless link chain is mounted for travel on each track and each chain is driven by an independent motor mounted on the frame. Each track is provided with at least two recesses with each recess having an open side facing the respective chain. A series of vacuum cups are mounted on each chain and are adapted to engage the surface to be traversed. A first series of ports connect a first recess of each track and a first group of vacuum cups on each chain, while a second series of ports communicate between the second recess of each track and a second group of vacuum cups. A source of vacuum is connected to the recesses and acts through the ports to the respective vacuum cups to enable the vacuum cups to grip the surface. In a preferred manner of use, the robot is employed with a laser tracking system in the non-destructive inspection of an aircraft.

Abstract: A robot for performing a working operation on a surface. The robot comprises a frame which supports a pair of parallel tracks. An endless link chain is mounted for travel on each track and each chain is driven by an independent motor mounted on the frame. Each track is provided with at least two recesses with each recess having an open side facing the respective chain. A series of vacuum cups are mounted on each chain and are adapted to engage the surface to be traversed. A first series of ports connect a first recess of each track and a first group of vacuum cups on each chain, while a second series of ports communicate between the second recess of each track and a second group of vacuum cups. A source of vacuum is connected to the recesses and acts through the ports to the respective vacuum cups to enable the vacuum cups to grip the surface. In a preferred manner of use, the robot is employed with a laser tracking system in the non-destructive inspection of an aircraft.