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from Team Run Amok |
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Team Run Amok receives a lot of email asking about the design and operation of combat robots. In 2003 my son and team member Aaron Joerger (now 22) requested a question and answer page to document our responses. Aaron answers most of the questions, but I'll step in if it gets very technical. | ||
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Special Announcements
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April 22, 2013 -- in a brief post to the Robot Fighting League forum site, David Calkins announced that the just-completed RoboGames 2013 was the last event that ComBots would host. David did not cite specific reasons for his decision, but he did offer thanks to the community "... for all your years of support." ComBots has been hosting robot combat events in the San Francisco Bay area since 2004. Their annual RoboGames (April) and ComBots Cup (October) events were the last surviving competitions for heavyweight robots. |
Recent QuestionsQ: I have made a 15 pound drum robot and I'm going to start the three pounders. I want to make a over head spinner or full body spinner. Which do you suggest would be easier and cheaper? Also, can I direct mount the weapon to the motor or should I use pullies? [Florida]
A: We have a HUGE PILE of information on spinner weapon design choices and drive requirements in the 
archive, and some specific advice on insect class spinners in the 
archive. I strongly suggest you browse those archives. Briefly:
- An overhead spinner is a metal bar with a hole in the middle. A full body spinner is a precision machined and balanced dome or cylinder. Which do you think is easier and less expensive? Hint: metal bars are cheap.
- Look at successful beetleweight robots. Do you see any overhead spinners? Any FBS? Why not? It isn't because they haven't been tried.
- I don't recommend direct driving a large spinner weapon. Direct drive places huge loads (lateral and shock) on the motor bearings. It also slows the spin-up time (important in a small insect arena) and will typically spin the weapon too fast for adequate weapon 'bite' (read the archives).
Robot haiku:
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Effective spinners Take work and careful planning. Some work - most do not. |
Q: I'm designing a budget beetle weight(Less than 100 dollars, and I already have a DX5e) and I'm fairly sure about most of the robot, except one thing, how do I attach a lite flite to a B&D screwdriver? The only things I could think of is to either drill a hole and run a pin through the shaft and hub of the wheels or too take the tires off the hubs and epoxy them on.
A: There are several different Black & Decker power screwdrivers, but they all have the same output shaft design: a tube about 3/8" in diameter with an internal 1/4" hex drive. Those dimensions are WAY too large for the Lite Flite wheels (max drill out 3/16"), and I certainly can't recommend glueing the tire directly to the gearbox output shaft! You'd have no lateral support, and no way to quickly replace a shredded tire.
The best wheel solution might be to run the BaneBots 3/8" hub with BaneBots 3/4" hex mount wheels. Measure your output shaft diameter carefully -- you may need to reduce the diameter a bit. The hubs are heavy, a little expensive, and overkill -- but that large gearbox shaft is really awkward. I hear that you're on a tight budget, but a hub solution is NOT the place to economize! I think I've seen more robots fail from poor/hacked hubs than any other single cause.
I should also point out that the 'bot is going to be slow. Power screwdrivers are more about torque than speed, and unless you're running serious overvoltage and really big wheels, you're gonna be at slow walking speed. I think you might be money ahead to switch to more conventional gearmotors to gain speed and the ability to use standard hubs and wheels.
Robot haiku:
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Power screwdrivers? You're starting to figure out Why they are not used. |
Q: what does hhx mean on a synchronous belt mean [Florida]
A: I don't know of an 'HHX' desination for timing belts, but I do know about 'XXH'. There are six standard 'pitches' of synchronous timing belts for different levels of power transmission:
| MXL | Mini Extra Light | 0.080" pitch |
| XL | Extra Light | 0.200" pitch |
| L | Light | 0.375" pitch |
| H | Heavy | 0.500" pitch |
| XH | Extra Heavy | 0.875" pitch |
| XXH | Double Extra Heavy | 1.250" pitch |
For more information about timing belts than you'll ever need, take a look at GatesFacts: Differences in Synchronous Belts.
Robot haiku:
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Match the pitch and width Of belt to motor power Or you'll watch it fail. |
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Q: Dear aaron, I know that team whyachi has a robot called warrior SKF.Do you have any information about it? How its toothed spining ring powered the flipping arm? & can you please give me its tech specification about its drive, weapon &its design . [Mumbai, India]
A: We have discussed 'Warrior SKF' several times previously. Search the Robot haiku:
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Q: Hi, i bought a E-Flite HP6DSM Spektrum, the transmiter when i turn it on makes 3 sound signals, shows the voltage but the red led doesn´t blink and stay fix, why? [Aveiro, Portugal]
A: You might benefit from reading this post on RCGroups.com. If that doesn't help, your closest support center is Horizon Hobby Limited in the UK:
Robot haiku:
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Transmitter made for Blade SR Helicopter. Not good for much else. |
Q: Hi Aaron :)
I'm building a robot with 4 wheels, each of which are driven by an individual motor per wheel... These motors will be driven by two modified rc car ESC one for forwards/reverse, the other for steering...
My question is, would a gyro improve the handling of this setup (assuming wheel size and spacing has already been optimized for stability)? what I'm hoping a gyro would do is tighten up the robots movements so that it moves with a greater degree of precision, and in turn give the user more control.
If so... am I correct in thinking that I would only install this between the RX and the ESC for the steering? or would I need one gyro per ESC?
and finally, is there a specific type of gyro I want to be using for this purpose?
I've been searching for days through hoards of gyro types, most of which seem to be for planes and helicopters, and for each of those formats there seems to be units for very specific purposes... yet not much info on how they fundamentally work, and there's not really anything that I could find to do with robotics...
Thanks for your time
Neil
A: First, I need to talk you out of your ESC setup. It's generally a really awful idea to attempt to control a motor with two ESCs -- particularly if those two ESCs are providing different power levels and polarities! An ESC controls power by switching it on and off very rapidly. The relative time spent 'on' determines the power supplied to the motor(s). With your setup, if you are moving forward and attempt to turn, the motors on opposite sides of the robot will get conflicting power pulses from the ESCs:
- The motors on the 'outside' of the turn will receive one set of power pulses from the drive ESC at one power level, and a second set of pulses at a different level from the turn ESC. Sometimes these pulses will overlap, sometimes they will be independent. The result will be unpredictable motor speed.
- Far worse, the motors on the 'inside' of the turn will also be receiving overlapping/independent power pulses -- but with opposing polarity! This is a wonderful way to melt both of the ESCs. You're essentially creating a direct short circuit.
for a wiring layout for this type of ESC control.
Your questions about robot gyros are answered in the Team Run Amok Beginners Guide to Combat Robot Gyros. I'd suggest you test the robot without a gyro and consider adding one only if you have trouble maintaining a consistent turn rate or have issues with the robot 'spinning out'. Note the warnings in the gyro guide concerning invertible robots.
Robot haiku:
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Multiple motors From one ESC is fine. Not the other way! |
Q: Hey Aaron,
I've been working on re-designing my 120 after it got mangled at Robogames. I had been using an Ampflow F30-150 to spin my horizontal weapon disc (it worked great). A problem I had in initial design was that in order to mount the motor vertically, I needed a fairly high-profile chassis (the pulley to the weapon disc sat on the shaft, about 6" high). I'm trying to make my next design more streamlined. I've been thinking about building a small right-angle gearbox so that my motor can mount horizontally and my output shaft would be more low profile. However, I know how bevel gears can be tricky - not to mention I'm not sure how well they would perform at speeds of 6000+ rpm.
Do you have any advice? Is this endeavor worth it? Or is there some economical gearbox I can buy online, and use a direct coupling to the motor?
Thanks for your help.
A: Your concerns are well founded. Bevel gears are inefficient at power transfer, and are sensitive to shock and misalignment. Off-the-shelf gearboxes are expensive, limited in speed and power inputs, and difficult to interface.
Your current belt drive is very efficient, tolerates shock loading, and can handle misalignment -- a great deal of misalignment. Consider a quarter-turn belt drive. You may run into some problems that will require some tweaks to the design, but I'd rather try a quarter-turn belt drive than a bevel gear system.
I can't directly comment on whether going to a horizontal weapon motor is worth the effort. If your weapon was working well, perhaps you shouldn't tamper with the design. Keep it simple.
Robot haiku:
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Don't complicate things. Change things that break or don't work. If it works, keep it. |
Q: Whilst talking to with my US roboteer brethren, a question came up that I'd like your opinion(s) about: Would a UK- style touring event business model work in the USA? Not saying it would ban HW spinners as that's largely an insurance problem in the UK - No guarantees of the same conditions of contract. [Luton, United Kingdom]
A: I think it's way too late. The UK touring events - like Robots Live - were able to get on their feet while the interest from Robot Wars was still very strong. The robots and teams were well-known to a large potential audience, and the transition from popular television show to live event went quickly and smoothly.
It's also a simpler task to drag an arena and robot teams around a relatively small area like the UK than it would be to do the same with major venues in the US. I don't see a touring event working in the current US combat robot environment.
Robot haiku:
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The UK maintained Momentum from Robot Wars. Too late for US. |
Q: Dear Aaron, I know that Team Velocity has a robot called Velocity. Do you have any information about it? Are there any videos? [China]
A: I don't know of any Team Velocity robot named simply 'Velocity'. You may browse thru the team's robots at the Team Velocity Website for information on their 'bots.
Robot haiku:
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They have a 'bot named 'Terminal Velocity'. Middleweight spinner. |
Q: Dear Aaron, I know that Team Velocity has a robot called Trilocity. Do you have any information about it? Are there any videos? [China]
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A:This time you got it right! We know 'Trilocity' -- we fought it at one of the DaVinci Days events (we won!). 'Trilocity' is a beetleweight thwackbot with an overall record of 9 wins / 5 losses. It's very difficult to get a twackbot to work in a small insect arena, but 'Trilocity' was quite successful due to a well thought-out design and a great deal of drive power.
I don't know of any available videos. Robot haiku:
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Q: What is the difference between starter motor and the ampflow motor?? Is it possible to run the weapon(8kg wt) on out runner motor? if yes, please explain the electrical setup. [Assam, India]
A: Mark J. here: a typical starter motor is of an essentially different design than the AmpFlow motors.
Many small robots use brushless 'outrunner' motors for their spinner weapons, but an outrunner motor powerful enough to spin a weapon for a large robot would be expensive, difficult to find, and untested. All brushless motors require a special brushless motor controller to provide correctly timed and directed current pulses to the field windings of the motor. A diagram depicting the electrical layout of the brushless controller/motor can be found here.
I assume your '8kg' weapon is a spinner? Calculations for the power requirements of a spinning mass weapon require more than just the mass of the spinning element. The shape and dimensions of the element are needed to calculate the moment of inertia, which determines the energy storage capacity of the element. Suggest you take a look at the Team Run Amok Excel Spinner Spreadsheet for more info.
Robot haiku:
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For component choice, Use proven and tested parts. There are good reasons. |
Q: hey Aaron, I wanted to know if I could use the Harbor freight 900 rpm motor effectively for my spinning disk ? it is a 6 kg 1cm thick spinning disk which I'll use as my main weapon ......will the motor be good enough ? [Maharashtra, India]
A: Mark J. here: the diameter of the weapon disk is critical in the computations. If the disk is aluminum, I can estimate the diameter of the disk at 50 cm to get a 1 cm thick disk up to 6 kg. I'll also assume this is for a 60 kg 'bot.
An effective spinner weapon should have at least 16 joules of energy per pound of the weight class -- in your case that's a little over 2000 joules. You also need to be able to spin the weapon up to speed before your opponent can sprint across the arena and ram your weapon to slow it and keep it from reaching dangerous energy levels.
The Team Run Amok Spinner Spreadsheet says that the HF drillmotor/gearbox can spin your weapon disk up to about 800 joules in six seconds. That's too long a spin-up time for a small arena and too little weapon energy for a 60 kilo robot. You'll need both more power and speed.
Aim to spin the weapon disk to about 1500 RPM, reaching 1000 RPM in the first 2 seconds. You'll need about 1.5 horsepower to do that, and the 18 volt HF drill motor is good for only about 0.5 horsepower.
Robot haiku:
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Question, India: If you lack heavy motors, Why build heavy 'bots? |
Q: hey Aaron its that 900 rpm HF guy again, actually its for a 25 kg bot .....the disk will be 12 cm in diameter and made of cast iron ......maybe 6 kg will be too heavy , so m planning to use 4 kg , 1 cm thickness .....what now ? .....can u suggest any better material ?
A: Your calculations are off someplace. A 12 cm diameter cast iron disk 1 cm thick has a mass of only 0.9 kilo. That's WAY too small to be an effective weapon. Note that our spinner spreadsheet asks for the radius of the disk in its calculations, not the diameter. A 12 cm radius cast iron disk 1 cm thick has a mass of 3.5 kilos -- let's go from there:
| 16 joules times 55 pounds = 880 joules of energy storage needed |
You'll need to spin that disk up to 2600 RPM to get that much energy storage. The HF motor has enough power to spin this disk up to that speed in a reasonable amount of time, picking up nearly 400 joules in the first 2 seconds.
You'll need to scrap the HF gearbox and find another gearing solution, as the weapon would have barely 100 joules of energy at 900 RPM. If you want to keep the motor/gearbox combination, you'll need a much larger diameter disk. A 25 cm radius steel disk 0.4 cm thick would weigh about 6 kg and would store about 800 joules of energy at 900 RPM. Spin-up time would still be good, but that's a pretty big disk for a 25 kilo 'bot.
As to your material choice, cast iron is brittle -- it tends to shatter when hit hard. Most spinner discs are made from aluminum alloy with tough steel impact blades bolted on. All steel construction could work for your weapon.
Robot haiku:
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Spinner must be tough. If it shatters on impact You will loose your match. |
Q: hey Aaron , I am making a 20 kg bot and m using 6 motors having torque of 12 kg cm and 250 rpm ....I wanted to know to what force will b left to push a robot ( after using force to move itself ) it should b able to push a 22 kg bot .....will the torque be enough ?? BTW its a wedge bot [Pune, India]
A: Mark J. here: those are very weak motors for a 20 kilo robot. Even with six of them, you'll need small wheels (about 2.5" diameter) to generate maximum pushing power without stalling the motors, and the top speed will be only 2 MPH. Sitting duck! Consult our Optimum Gearing for Combat Robots guide for information on speed, torque, and gearing.
The ability of one robot to 'push' another robot depends on many factors. Interestingly, the torque and speed of the drive motors are NOT directly among those factors. Correctly geared, more powerful motors won't give you more direct pushing power, but you'd gain much greater speed and ramming ability.
I don't have the space or time to run thru the full course in kinetics principles, but here are the high points:
In short, there are WAY to many variables for me to give you a simple answer to your question. Your ability to push your opponent will depend on your opponent's actions and the effectiveness of your wedge.
Robot haiku:
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Push them or be pushed. It all depends on traction, Not motor power. |
Q: I am thinking of using 2 18v new style DeWalt motors with 3 speed gear box. Will it be beneficial for us for 80kg bot? Can you please suggest motors other than amp-flow and NPC?? budget for drive motors is 350$(excluding shipping). Thanks in advance. [Pune, India] :-)
A: A pair of the 'new style' DeWalt 18 volt motors running at 24 volts would typically be used in a robot no heavier than 120 pounds, but will give fair performance for an 80 kilo 'bot in a small arena. I suggest locking the transmission in 'low' and fitting wheels about 4" in diameter. Peak current consumption will be close to 50 amps per motor at full push.
Many builders prefer the 'old style' 18 volt DeWalt motor and 2-speed transmission, viewing it as stronger and easier to adapt to robot applications. With either motor you will need to develop your own output shaft and bearing support solution. Team Delta offers 'old style' DeWalt motor mounts, bearing blocks, and output shafts that you may find useful -- but I'm not certain that they are still in stock.
There aren't many proven motor options available for your weight class and budget. If you're willing to consider 4-wheel drive, four of the inexpensive Harbor Freight 900 RPM 18v Drills may be disassembed to provide motors and gearboxes suitable for robot applications. Many budget robots have been powered by these motors with good result -- a web search for "harbor freight drill hack robot" will take you to info on using these motors in a combat robot. Four would give power comparable to two DeWalts.
Robot haiku:
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OK power if 'Bot has an active weapon. Rammer? More power. |
Q: After reading the product manual for the 18 volt Harbor Freight cordless drill the max torque shown in specs is 7ft-lb... and 84ft lbs on the link you provided. Can you please sort it out?
A: One of the things you pay for when buying premium components is correct specifications. Cheap gear typically has either no specs or unreliable specs. The 84 ft-lb torque number on the webpage is a typo that should read 84 in-lbs, which correctly converts to the 7 ft-lbs figure given in the manual.
Robot haiku:
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Premium products Take time to give you good specs. Cheap stuff, not so much. |
Q: How to build a 4- bar mechanism [Rosedale, Maryland]
A: Kind of a broad question. We've discussed the design of 4-bar mechanisms many times previously -- you can find those discussions in the archive. Search there for '4-bar'.
If you have specific questions on topics not previously covered, write back.
Robot haiku:
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Specific questions Will get specific answers. Please check the archives. |
Q: For an antweight wedge with two B16 motors, would you recommend 2" Lite Flite wheels or 1 7/8" Banebots wheels? The Lite Flite wheels have a 3.97mm bore, can I just push them onto the 4mm motor shafts, or do I need the expensive aluminum Dave's Hubs? Thanks.
A: If the wheels are protected, I like BaneBots. If the wheels are unprotected, the tougher LiteFlites are a better choice.
DO NOT try to get away with press-fitting wheels onto motor shafts! Dave's Hubs are very strong, compact, and make it simple to replace the tires when they get chewed up. I think they're well worth their price, but there are other options. The Astroflight prop adapter makes a good hub solution if you're willing to drill out the Lite Flite wheel a bit, and the FingerTech hubs are functional and very light. Whichever you choose, check the tightness of the hub set screws before every match.
Also, consider a larger diameter wheel with the B16 motors in an antweight. A 2 1/2" wheel would give great performance in an 8 foot arena.
Robot haiku:
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Lite Flites absorb hits That would destroy the BaneBots. I'd buy the good hubs. |
Q: flipper guy again. Wt material should i use to make a flipper of 4 bar mechanism?? more specifically, which grade of aluminium?
A: See #17. Performance of a robot component depends on both the material and the design -- I can't recommend a specific material.
Mark J. here: Aaron is correct, but on a practical note your choice of aluminum may come down to what you can find. The 6061 alloy is widely available in a variety of shapes and forms, while the stronger 'aircraft grade' 2024 and 7075 alloys are harder to find -- as well as being more difficult to work with. Don't design for material that isn't available.
Robot haiku:
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Too little info. Material and design Must work together. |
Q: In RioBotz tutorial it is given that the AmpFlow motors power is measured without adding the battery and electronics, so in actual practice power output is less than the given . Ex: AmpFlow A28-150 has power 3 hp and after adding all the resistance it comes to 1.5 hp .
Now for the NPC motors they have give power from dynamometer result and the power of NPC 02446 is 0.7 hp . So this power is even good than F series ampflow in less price .
So what will you suggest AmpFlow or NPC ?
A: Mark J. here: I don't think the RioBotz tutorial got this bit quite right. In real-life conditions, the NPC-02446 is in no way comparable in power to the AmpFlow F30-150 -- or even the E30-150.
Here's the deal: in actual robotic application, the additional resistance of the battery and speed controller can be important when calculating the maximum (stall) torque of high-output motors. The lower the armature resistance of the motor, the larger the effect will be. However, a permanent magnet DC motor generates maximum horsepower at 50% of maximum RPM -- at a point where the counter-electromotive force generated by the rotating armature adds a considerable effective resistance. The impact of battery/controller resistance on horsepower is much smaller than the values cited by RioBotz.
Second consideration: I suspect that those NPC numbers from the dynomometer use a really huge low-resistance battery and no controller at all. You must be VERY careful when comparing motor power measured under apparently different conditions.
A simple method to compare the approximate output power of two brushed motors is to use the following formula on each motor:
The formula makes many assumptions, including equal efficiency of the motors, but it gives an estimate of the power output that is independent of variables such as battery and controller resistance. Using this formula, the numbers come out as follows:
- NPC-02446: 488 watts = ~0.65 HP
- AmpFlow E30-150: 750 watts = ~1.0 HP
Robot haiku:
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Be sure to compare Numbers that mean the same thing: Apples to apples. |
Q: What do you think of the new FingerTech lifter/clamp kit? Do you think the building method is solid? [Woodburn, Oregon]
A: The FingerTech kit is largely a collection of components and raw materials that requires a good amount of fabrication and finishing to turn into a combat robot. It is suitable for a builder with good basic shop skills and a collection of suitable shop tools.
The quality of the finished robot is likely to vary greatly with the skill level of the builder. I would not recommend the kit for a novice builder. Review the kit instructions and make a realistic decision as to whether your building skills are up to the task.
Mark J. here: one comment on the construction techniques used by the kit. The design calls for mounting holes to be drilled very close to the edge of Lexan armor, placing high localized stress on the Lexan and possibly causing cracking and break-thru in those areas. I would suggest cutting the Lexan wider and/or changing the mounting points to move those high-stress areas further away from the armor edge.
Robot haiku:
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If you've got the skills, Maybe you don't need their kit. Make one for yourself. |
Q: Hello Sir, we have decided to construct a bot with 4 bar mechanism flipper on its front and spinner or cutter on its back. Is is possible to construct? Main problem is air tank for flipper. Where do we get the tanks like ziggy? What are the advantages of co2 over normal air in combat robotics? The bot will be of 60 kg. Which motors can we use for drive other than amp flows?? motor from RobotMarketPlace- PDX26 - 26:1 Gearmotor is good for drive??????? [Maharashtra, India]
THANKING YOU
A: A very ambitious project! Several comments:
Robot haiku:
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Undesireable!
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We welcome combat robot questions. Search the Ask Aaron Archives first to see if we've already answered your question. Recent Q&A are posted above. |
Copyright 2009, 2010 by Mark Joerger All rights reserved. | Who in the world is reading 'Ask Aaron'? |