Mechanisms & Manipulators FRC Conference 4/21/05 By Raul Olivera
Some Basic Physics Forces, Angles & Torque Power
Forces, Angles & Torque Example #1 - Lifting –Same force, different angle, less torque 10 lbs < D D
Forces, Angles & Torque Example #2 - Pulling on object –One angle helps secure object –The other does not
Forces, Angles & Torque Example #2 - Pulling on object (cont’d) This one want to rotate clockwise and let go This one want to rotate counter- clockwise and grab even harder
Power Power = Force x Distance / Time OR Power = Torque x Rotational Velocity Power is all about how fast you can move something
Power Example - Lifting –Same torque, different speed 10 lbs 0.1 HP, 100 RPM Motor w/ 1” sprocket 0.2 HP, 200 RPM Motor w/ 1” sprocket OR 100 RPM w/ 2” sprocket
Power In Summary: –All motors can lift the same amount (assuming 100% power transfer efficiencies) - they just do it at different rates BUT, no power transfer mechanisms are 100% efficient –If you do not account for these inefficiencies, your performance will not be what you expected
Structural Integrity Materials Shapes / Weights Fabrication processes Environment
Materials Steel –High strength –Many types (alloys) available –Heavy, rusts, –Harder to processes with hand tools Aluminum –Easy to work with for hand fabrication processes –Light weight; many shapes available –Essentially does not rust –Lower strength
Materials Lexan –Very tough impact strength –But, lower tensile strength than aluminum –Best material to use when you need transparency –Comes in very limited forms/shapes PVC –Very easy to work with and assemble prefab shapes –Never rusts, very flexible, bounces back (when new) –Strength is relatively low
My Favorite Materials Spectra Cable –Stronger than steel for the same diameter –Very slippery Easy to route Needs special knots to tie –Can only get it from Small Parts and select other suppliers Pop Rivets –Lighter than screws but slightly weaker - just use more –Steel and Aluminum available –Great for blind assemblies and quick repairs
Structural Shapes Take a look at these two extrusions - both made from same Aluminum alloy: –Which one is stronger? –Which one weighs more? 1.0” 0.8” Hollow w/ 0.1” wallsSolid bar
Structural Shapes The solid bar is 78% stronger in tension The solid bar weighs 78% more But, the hollow bar is 44% stronger in bending –And is similarly stronger in torsion
Stress Calculations It all boils down to 3 equations: Where: = Bending Stress M = Moment (bending force) I = Moment of Inertia of Section c = distance from Central Axis Where: = Tensile Stress F tens = Tensile Force A = Area of Section Where: = Shear Stress F shear = Shear Force A = Area of Section BendingTensileShear
Structural Shapes I am willing to bet that none of our robots are optimized with respect to strength to weight ratios –We all have more material than we need in some areas and less than we need in others. –It would take a thorough finite element analysis of our entire robot with all possible loading to figure it all out –We only get 6 weeks!! But, this does not mean we cannot improve
Structural Shapes Things to avoid or carefully design: –Sharp inside cuts - leave a radius / fillet –Fastener holes that are too close to an edge –Welding corners without adding a gusset –Brittle materials - bending is easy to repair - cracks are not Things that might help: –Add thin tension members to stabilize structures i.e. guy wires, strips of sheetmetal –Use multiple smaller fasteners rather than one big one (did I say I like pop rivets?) –Design in mechanical fuses - a desired place for failure during excessive and unusual forces to avoid catastrophic failure Crumple zones Break-away parts - using weaker fasteners that can break (i.e. aluminum pop rivets)
Fabrication Processes Laser cutting causes localized hardening of some metals –Use this to your benefit when laser cutting steel sprockets Cold forming causes some changes in strength properties –Some materials get significantly weaker –Be aware of Aluminum grades and hardness's Welding - should not be a problem if an experienced welder does it
Environmental Effects UV exposure - causes some plastics to change their structure and become brittle –ie. Lexan, PVC Cold temperatures - cause some materials, especially plastics to become brittle –Can cause damage when shipping from cold climates
Going Up Arms Vertical Lifts Arms vs. Lifts Passive Assistance
What is an “Arm”? An “Arm” is a device for grabbing and moving objects using members that rotate about their ends
General Arm Advice Thin Walled Tubing is your friend –1/16 wall is a good compromise Known good sources –Mcmaster.com –Onlinemetals.com –Airpartsinc.com
General Arm Advice Every Pivot has to be engineered –reduce, reuse, recycle ;-) “Virtual 4 bars” –Drive motors low with chain acting as “4 bar” –Advantage over real 4-bar: low motor range of motion Think about operator interface – very important
General Arm Advice Feedback Control is HUGE –Measure Current Position –Compare to Desired Position Calculate Error –Take Action Based on Error (Search Internet for PID control) –SW/Feedback cannot fix all control problems effectively
Four Bar
Four Bar - Design Considerations Pin Loadings can be very high Watch for buckling in lower member Counterbalance if you can Keep CG aft
Vertical Lifts Extension Scissors
Extension
Scissors
Scissors vs. Extension Advantages –Minimum retracted height - can go under field barriers Disadvantages –Needs to be heavy to be stable enough –Doesn’t deal well with side loads –Must be built very precisely –Stability decreases as height increases –Loads very high to raise at beginning of travel I recommend you stay away from this!
Extension - Design Considerations Should be powered down as well as up –If not, make sure to add a device to take up the slack if it jams Segments need to move freely Need to be able to adjust cable length(s). Minimize slop / freeplay Maximize segment overlap –20% minimum –more for bottom, less for top Stiffness is as important as strength Minimize weight, especially at the top
Extension - Rigging Continuous Cascade
Extension - Rigging - Continuous Cable Goes Same Speed for Up and Down Intermediate Sections sometimes Jam Low Cable Tension More complex cable routing The final stage moves up first and down last Slider (Stage3) Stage2 Stage1 Base
Extension - Rigging - Continuous - All Internal cabling Even More complex cable routing Cleaner and protected cables Slider (Stage3) Stage2 Stage1 Base
Extension - Rigging - Cascade Up-going and Down-going Cables Have Different Speeds Different Cable Speeds Can be Handled with Different Drum Diameters or Multiple Pulleys Intermediate Sections Don’t Jam Much More Tension on the lower stage cables –Needs lower gearing to deal with higher forces I do not prefer this one! Slider (Stage3) Stage2 Stage1 Base
Arms vs. Extension Lifts Arms can reach over objects; lifts have limited reach Arms can right a flipped Robot; lifts probably not Arms can fold down to “limbo” under barriers; lift stay tall Arms require complex controls and counter-balances; lifts use simple controls Lifts maintain a better center of gravity over the base; arms do not - can cause tipping Lifts can operate in confined spaces; arms need space to swing up Lifts can reach to any height with minimal added complexity; arms need extra articulated joints to reach higher Combo may be best in some cases
Passive Assistance What is passive assistance? –SPRINGS or BRAKES! –Use Elastic Energy to your advantage. –Surgical Tubing –Constant Force Springs –Gas Springs –Torsion Springs –Follow FIRST Regulations!
Braking - to Prevent Back-driving Ratchet Device - completely lock in one direction in discrete increments – ie. winches Clutch Bearing - completely lock in one direction Brake pads - simple device that squeezes on a rotating device to stop motion - can lock in both directions –Disc brakes - like those on your car –Gear brakes - applied to lowest torque gear in gearbox High ratio worm gear (window, van-door motors) –Note : any gearbox that cannot be back-driven is probably very inefficient
Handling Objects (Balls) Accumulators Conveyors
Accumulators Accumulator = rotational device that pulls objects in Types: –Horizontal tubes - best for gathering balls from floor or platforms –Vertical tubes - best for sucking or pushing balls between vertical goal pipes –Wheels - best for big objects where alignment is pre-determined When it comes to gathering balls, there is nothing more efficient –If set up in the proper orientation, will not knock the ball away, just suck it in
Accumulator as Gripper Rolling balls into and out of gripper can be VERY Effective Examples Off the top of my head: –Team 222 in 1996 –Team 177 in 1998 –Team 95 in 1998 –Team 45 in 2004 –Team 111 in 2004
Conveyors Conveyor - device for moving multiple objects, typically within your robot Types: –Continuous Belts Best to use 2 running at same speed to avoid jamming –Individual Rollers best for sticky balls that will usually jam on belts and each other
Conveyors Why do balls jam on belts? - Sticky and rub against each other as they try to rotate along the conveyor Solution #1 - Use individual rollers - Adds weight and complexity Solution #2 - Use pairs of belts - Increases size and complexity Solution #3 - Use a slippery material for the non- moving surface (Teflon sheet works great)
Other Clever Mechanisms Wonderful Uses for Spectra cable Chain turnbuckle
Wonderful Uses for Spectra Cable First you must learn to tie a proper knot in this stuff –I use a “triple pretzel knot” ( I doubt you will find this name in any scouting book - I made it up ) : Simple lift cables - pretty obvious use, but how do you adjust the slack (steel cables use turnbuckles)? –Use a tourniquet like device - use a dowel pin to twist the cable on the outside of the spool or actuated device, and tie-wrap in place –This works great for adjusting the location of travel also If slack can occur, add a latex slack tensioner Remote actuations - this cable is so easy to route within your robot frame efficiently –Linear motions (come see team 111 bumper actuation) –Rotary motions
Spectra Cable (cont’d) Remote Rotary Actuations - instead of chain
Chain Turnbuckle Parts Needed: - 1/2” Sq Aluminum bar - 1/4-20 Nut - 1/4-20 Screw - 3/8” dia. CRS rod - 1/16” dia. Steel Dowel pins 1/4-20 Screw (grind flats) 1/4-20 Nut1/2 Alum Sq Bar 3/8 Dia. Rod Dowel Pins
Pneumatics vs. Motors Some, but not all important differences Cylinders use up their power source rather quickly the 2 air tanks we are allowed do not hold much Motors use up very little of the total capacity of the battery Cylinders are great for quick actuations that transition to large forces Motors have to be geared for the largest forces Our ability to control the position of mechanisms actuated by cylinders is very limited We are not given dynamic airflow or pressure controls We are given much more versatile electronic controls for motors Since air is compressible, cylinders have built-in shock absorption Cylinders used with 1-way valves are great for Armageddon devices - stuff happens when power is shut off This could be good or bad - use wisely
Force Values
Pneumatics Warning: rated load is only for holding Actual power curve is much lower