Some people swear that all tethers are bad. Some people recommend attaching a tether to robots in order to provide power (to save the mass and volume of the batteries), for reliable fast communications, transfer of pressure or fluid, to track a robots position, or as a safety harness (in case the robot needs to be dragged out). However before designing a tether there are several things that you need to consider.
Here are some things to think about:
1. What should be in the tether. For example can you put power on the robot and then only run communications to the robot?
2. Tethers can easily snag on obstacles as the robot drives. This can cause your robot to get stuck and not be able to proceed forward or get back out.
3. Tether needs to be managed so that you do not get snagged (as discussed above) and so that you do not drive over it which can damage the tether.
4. Tethers can get bulky. The longer the tether you need, the more mass and volume you will need to carry and the more heat you will produce.
5. Tethers introduce drag, which the robot will need to overcome while driving.
6. Abrasion of the tether with use
7. Cables, wire, and tubes in the tether can break which might incapacitate the robot. If the robot is going into a critical environment you might not be able to retrieve the robot should it fail.
The image at the top of this post shows how a tether can tighten around corners as the robot drives. As the tether gets pulled into the corners the force on the tether increases, and increases the chance of the robot getting stuck, breaking, and making mobility more difficult.
Tension on tether base (neglecting the coefficient of friction from contact points) can be computed as shown in the image below.
For the reasons above tethers are often deployed from the robot and not from base equipment. In underwater applications you can usually feed the tether from the base without the problems seen on land. When choosing where to deploy the tether from you need to consider:
· Can your robot support the volume/mass of the tether
· Where are the snag points
· Volume of the tether which is: Volume = Area of cable x length of the cable
· Heat generated by the tether from I2R losses.
This paper from Dante is a must read for anyone developing a tethered robot. Dante is a robot that flipped while trying to climb out from a volcano partially due to bad tether angles on difficult terrain. While people often point to Dante as an example of why tethers are bad, there are many more examples of tethers being used successfully. In the nuclear accident of Chernobyl many robotic (tele-operated) vehicles (click for robot pictures)were used in the recovery and cleanup. The robots were used for many things such as inspection, pushing radioactive material out of the way, turning over radioactive dirt and moving containers. Most of those robots were tethered (about 55 of the 60 vehicles). Many of those robots ultimately died due to tether malfunctions, but that was after operating for extended times and doing good work. With new technology, better cable design, lower powered devices, better proprioception of the tether we should be able to do a better job building tethers.
TReX is another paper that you need to check out before designing a tethered robot.