Design and development of a cable actuation unit
A Cable-driven manipulator system has the potential to perform tasks that could not be performed by a conventional robot system. In a cable-driven system, the rigid links of the normal manipulator are being replaced by cables, thus reducing the inertia of the system. This allows the cable-driven...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2010
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/40590 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | A Cable-driven manipulator system has the potential to perform tasks that could not be
performed by a conventional robot system. In a cable-driven system, the rigid links of the normal
manipulator are being replaced by cables, thus reducing the inertia of the system. This allows the
cable-driven system to possess high load capacity, high speed and large workspace
simultaneously. However, there is redundancy in actuation as the number of actuators needed is
more than the degrees of freedom. This is due to the unilateral property of cables. All Cabledriven
Systems require an actuation unit to control the each cable for coordinated motion of the
end effector. Therefore, the design of an actuation unit with good performance characteristic is
important in order to achieve control of the end effector.
This report concerns the design of a cable actuation unit that will meet to the proposed design
requirements and parameters. The emphasis of the design is placed on accuracy, simplicity and
cost, aiming to achieve one that is easy to manufacture and maintain. From the conceptual stage
to embodiment and detail design stage, each part of the design is examined closely to refine the
preliminary layout. The objective is to produce a more compact and efficient design that will
cater to the functionality of each individual part. In addition, tests are also conducted on different
cables to obtain a better understanding of the characteristics and aid in the selection. The design
is fabricated and tested with the selected cable for accuracy, repeatability and performance.
The experimental results show that the prototype is able to meet the design requirement. In
particular, it is able to pull a load of 100N at a speed of 0.10 m/s over a distance of 0.15m.
Furthermore, the total cost to produce one prototype exclusive of the motor is kept below $400.
This means that the prototype is feasible for system that requires many actuation units and is
capable of accurate and precise results. The balance between cost and performance will enhance
the potential of cable manipulator systems in many applications. |
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