Design
Introduction
The full device assembly is shown below. Highlighted are the electronics housing (red), rotation linkage (blue), vertical parallelogram linkage (yellow), and claw linkage (orange).
Mechanism Design
While designing the mechanism, we let the original goal and the kinematic requirements control as many parameters as possible, and optimized the rest for simplicity of design and robustness.
The actuator, a 1:131 Pololu motor/gearbox combination, drives a single 9-bar mechanism. The mechanism consists of a 4-bar and 6-bar linkage which share one link and are coupled using a gear train.
4-Bar (Tower Oscillation)
The 4-bar mechanism is used to oscillate the main tower back and forth between two positions that are 180 degrees apart. This mechanism passes through a toggle position in the middle of its motion, when all the links align. In our design, the tower has enough inertia to force the linkage through this toggle position and cause it to oscillate correctly.
We used Matlab to find the proper link lengths for this linkage. The requirements were as follows:
The mechanism must be Grashof (because the linkage works with a single continuously-rotating motor).
The ground link must be no more than 12 inches long (to fit within device bounds).
The limit of the joint motion must be 180 degrees.
By using the last requirement, the Pythagorean theorem can give the relationship between three lengths: the ground link, output link, and the sum of the coupler and driving link. The Grashof condition puts limits on the link lengths but does not dictate the lengths, so this is a bounded system of equations that has infinite solutions. We chose an input link length of 4 inches and output length of 5 inches to maintain a reasonable mechanical advantage.
Toggle Position
Before we put the arms on the tower, we placed a steel mallet on the rotating tower base to simulate the rotational inertia of the mechanisms. This allowed the tower to rotate through the toggle position and oscillate as designed. Unfortunately, the weight of the mallet did not accurately simulate the opposing force from the arm to the bevel gear at the tower base. As a result of the power train, the tower resisted travel through the toggle point and instead oscillated on one side of the linkage, as seen in the following video.
We solved this issue by creating slots in the motor mount which allowed it to slide forward and back. This meant that the linkage a) had more play, and b) could build up more momentum to power through the toggle position. Given the amount of issues that we had with this particular portion of the design, we strongly suggest against designing a linkage to pass through a toggle position.
Gear Train
The gear train includes two bevel gears, one of which is attached to the coupler of the 4-bar mechanism. The second bevel gear connects to a drive shaft which
drives a 3:1 spur gear. The spur gear turns the driving link of the 6-bar mechanism, which is designed with gear teeth on the back end.
6-Bar (Vertical Motion)
The 6-bar mechanism is a 4-bar which causes the tower's arm to move up and down plus a parallelogram linkage to keep the marble platform level.
We wanted this linkage to sweep out approximately 90 degrees. Since it is being driven by a bevel gear attached to the tower rotation coupler, its input is already oscillating. This removes the need for a Grashof mechanism. The input angle has a range of over 210 degrees, which is the total sweep of the joint between the horizontal coupler and the tower. This dictated the use of a 3:1 gear ratio, giving and output of approximately 70 degrees for vertical motion.
To compensate for the vertical motion being less than 90 degrees, the parallelogram link lengths were increased to 11.31 inches from their original 10 inches. This caused our robot to travel slightly outside of the 2' cube that we initially set as bounds, but we decided this was an acceptable compromise.
Joint Design
Most of the joints in the assembly consist of a single nylon bushing, 1/4" machine screw, 1/4" locknut, and washers as necessary. This joint design allows the bolt (the joint pin) to freely rotate while still preventing the pin from falling out. The bushing reduces friction even further, but it is not strictly necessary - the hole in the second link could simply be made smaller.
The main tower rotation uses a 4-inch ball-bearing turntable purchased from McMaster. Because of the weight on this joint, it was critical that it have low friction, which the ball bearings provided. The turntable we used was designed for thrust loading, but not for tension loading, so we experienced some friction due to the moment exerted by the arm. This did not necessitate any change to the design, but we recommend researching bearings which can better withstand a bending moment, especially for robots with longer life spans.
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