Robot for pipe navigation

The invention claimed is: 1. A robot, comprising: a first module including a first body, a second module including a second body, and a jointed connection mechanism disposed to jointly connect the first body with the second body configured for steering; at least two legs connected to the first body, and at least two additional legs connected to the second body, each of the at least two legs and the at least two additional legs are independently driven and comprise: a linkage connected at one end to the first or second body, and a pipe engaging member connected at another end of the linkage; wherein each linkage includes a plurality of linkage segments pivotally connected to one another by a pivot joint at their ends, including a first linkage segment pivotally connected to a respective first or second body and a last linkage segment connected to the pipe engaging member, and is configured to operate between a stowed position, in which the pipe engaging member is disposed adjacent to the first or second body, and an extended position, in which the linkage is adapted to cause the pipe engaging member to contact an inner surface of a pipe; and a spring element disposed at each joint between adjacent linkage segments, the spring element biasing two adjacent link segments such that the linkage is biased towards the extended position; a powered winch disposed in the respective first or second body; and a cable connected between the winch and an end of the last linkage; wherein the powered winch is configured to tension the cable and counter the biasing of the linkage towards the extended position to set the linkage to a desired position. 2. The robot of claim 1 , wherein when the first and second bodies are disposed within the inner surface of the pipe, the at least two legs and the at least two additional legs are extended by a same extent such that the first and second modules are generally disposed concentrically within the inner surface of the pipe. 3. The robot of claim 1 , wherein the jointed connection mechanism is a differential joint. 4. The robot of claim 1 , wherein at least one of the pipe engaging members is a wheel that includes an integrated motor for autonomous and independent rolling motion along the inner surface of the pipe, the motor controlled by a robot controller associated with the first and/or second body. 5. The robot of claim 1 , wherein the at least two pipe engaging members are adapted to engage the inner surface of the pipe at diametrically opposite locations. 6. The robot of claim 1 , further comprising at least two more legs connected to the first body and at least two more additional legs connected to the second body, the legs being spaced symmetrically apart in pairs around the respective first and second bodies. 7. The robot of claim 1 , wherein each pivot joint contains the spring integrated with a pulley, wherein the cable wraps over consecutive pulleys from an anchor point along a preceding linkage segment A to an anchor point B on a following linkage segment after wrapping around the two consecutive pulleys. 8. The robot of claim 1 , wherein each of the first and second bodies has a length, L, and a width, w, and wherein the inner surface of the pipe is circular and is selected to have a minimum diameter that is equal to about (L/2+w)(sin 45°). 9. A method for inspecting an inner surface of a pipe using a robot, the method comprising: providing a robot having at least a first module including a first body and a second module including a second body, the first and second bodies being connected by a jointed connection mechanism disposed to jointly connect the first body with the second body configured for steering; providing at least two legs connected to the first body, and at least two additional legs connected to the second body, each of the at least two legs and the at least two additional legs are independently driven and comprise: a linkage connected at one end to the first or second body, a pipe engaging member connected at another end of the linkage; a plurality of linkage segments pivotally connected to one another by a pivot joint at their ends, including a first linkage segment pivotally connected to a respective first or second body and a last linkage segment connected to the pipe engaging member; providing a spring element disposed at each joint between adjacent linkage segments, the spring element biasing two adjacent link segments such that the linkage is biased towards the extended position; connecting a cable between each of the first and second powered winches and an end of the last linkage segment; wherein each of the first and second powered winches is configured to tension the cable and counter the biasing of the linkage towards the extended position to set the linkage to a desired position. 10. The method of claim 9 , wherein when the first and second bodies are disposed within the inner surface of the pipe, the at least two legs and the at least two additional legs are extended by a same extent such that the first and second modules are generally disposed concentrically within the inner surface of the pipe. 11. The method of claim 9 , wherein the jointed connection mechanism is a differential joint. 12. The method of claim 9 , wherein at least one of the pipe engaging members is a wheel that includes an integrated motor for autonomous and independent rolling motion along the inner surface of the pipe, the motor controlled by a robot controller associated with the first and/or second body. 13. The method of claim 9 , wherein the at least two pipe engaging members are adapted to engage the inner surface of the pipe at diametrically opposite locations. 14. The method of claim 9 , further comprising providing at least two more legs connected to the first body and at least two more additional legs connected to the second body, the legs being spaced symmetrically apart in pairs around the respective first and second bodies. 15. The method of claim 9 , wherein each pivot joint containing the spring integrated with a pulley, wherein the cable wraps over consecutive pulleys from an anchor point along a preceding linkage segment A to an anchor point B on a following linkage segment after wrapping around the two consecutive pulleys. 16. The method of claim 9 , wherein each of the first and second bodies has a length, L, and a width, w, and wherein the inner surface of the pipe is circular and is selected to have a minimum diameter that is equal to about (L/2+w)(sin 45°). 17. A robot, comprising: a first module including a first body, a second module including a second body, and a jointed connection mechanism disposed to jointly connect the first body with the second body configure for steering; at least two legs connected to the first body, and at least two additional legs connected to the second body, each of the at least two legs and the at least two additional legs comprising: a linkage connected at one end to the first or second body, and a pipe engaging member connected at another end of the linkage; wherein each linkage includes a plurality of linkage segments and each of the linkage segments being connected to one another by a pivot joint such that each linkage is configured to operate between a stowed position, in which the pipe engaging member is disposed adjacent the first or second body, and an extended position, in which the linkage is adapted to cause the pipe engaging member to slide against an inner surface of a pipe; and each pivot joint contains a spring integrated with a pulley, wherein a cabl