|
Q: I used the on-line robot drive motor sizing tool at robotshop.com to help me pick drive motors and batteries for my robot, but the numbers it's giving seem very small. Can I really power my 60kg combat wedge robot with a pair of 175 watt motors geared for 7 mph and draw only 15 amps total at 24 volts? [Nepal via Facebook]
A: [Mark J.] The RobotShop calculator is for hobby and utility robots that glide along smooth floors and up gentle ramps, not combat wedges that push full-throttle against opponents that push back equally hard. I'd suggest evaluating drive motor performance with a tool intended for combat robots.
The Team Tentacle Torque Amp-Hour Calculator says that a 60 kg robot with pair of typical 175 watt electric scooter motors geared as you suggest would take a leisurely 3 seconds and more than 20 feet to accelerate to 7 mph. Pushing hard against an opponent on a typical arena surface would bog down the motors near stall and rise total current consumption toward 60 amps for the pair: way too much current for those motors to handle and 1400 watts of drain on the battery.
Q: I wired up my spinner 'bot with a pair of 3-cell lipos to run each of the drive motors at 11.1 volts and my weapon motor at 22.2 volts - see the attached sketch. When I plugged in the batteries one drive motor kinda worked for a second but before I could test the weapon motor (no belt to the spinner) the receiver cables to the ESCs melted and smoked.
I checked the wiring and it's exactly as I've drawn it. What went wrong? [Columbus, Ohio]
A: [Mark J.] I've re-drawn your wiring sketch and removed the weapon components to focus on the problem.
I hesitate to mention this, but it is possible to get this circuit to work without smoke and explosions. I don't recommend this style of circuit but I will provide a diagram in case you should decide to live dangerously. You will require an 'optical isolator' in the receiver cable to each ESC that is connected to a floating ground. Keep the red wire in the receiver cable to the isolator intact -- the isolator requres receiver power to function.
Q: Hello, it's Jacksonville lifter guy again! I was sitting around, minding my own business, when I suddenly got an idea: rather than having a huge plow that can lift up and down, what if I used a small lifting arm in-between two hinged wedges? Any advantages and disadvantages to having a small lifter like that rather than a wide plow? [Jacksonville, Illinois]
A: [Mark J.] It's kinda dangerous to let ideas sneak up on you like that. Stay vigilant. Some random lifter observations:
Spring Powered Flipper Weapons
Pneumatic flipper weapons are awesome but their complexity can be troublesome, particularly in smaller combat robots. Flippers powered by mechanical energy stored in springs or elastic bands could offer attractive alternatives to pneumatics if designs that use electric gearmotors to trigger and reset spring flippers were better known to builders. I've put together animations and discussion of four poorly known spring flipper designs and wrapped them up in a new webpage: the 'Choo-Choo' overrunning clutch winder, the constant-torque 'Snail Cam', the compact 'Slip Gear' ratchet, and the elegant and stable 'Servo Latch' reset.
A: [Mark J.] By Grabthar's hammer, everybody knows who the best and most effective robot is. Now please, never mention 'Moist Pony' again. 
Q: What do you think of brush wheels for antweights? Too flimsy? [Syracuse, New York]
A: [Mark J.] Are we talking 'bristlebots'? Calling them 'brush wheels' is misleading -- wheels spin, bristle brushes just hop up and down.
Combat bristlebots like 'Vibrant' are novelties: poor speed, awful pushing power, no reverse. What part of that do you like? Some builders enjoy making weird 'bots just to be different. Avoid if you're trying to win.
Q: Would an HDPE unibody work for a beetle wedge if it was protected by grade 5 titanium plates? I was hoping the unibody would work as a sort of shock absorber to protect against high energy spinners. [Oak Harbor, Washington]
A: [Mark J.] Polyethylene unibodies are common and successful in insect class combat robots, but UHMW polyethylene is preferable to HD. An image search for 'UHMW beetle robot' will provide many examples. No metal cladding is needed -- save the grade 5 titanium for your wedge. Q: Hey, Mark. It's time I show the idea I've been throwing about. While I had admittedly planned on a FBS, I'm leaning more towards a lifter for simplicity and the fact I've grown to become a fan of the DUCK! method of using my face to break your fist. I made a post in regards to the lifter designs themselves here:
Please share any comments or critiques you have in regards to both designs! Thanks again! [Jacksonville, Illinois]
A: [Mark J.] I don't split comments across 'Ask Aaron' and other forums/venues. If you ask a question here I will comment here. If you post on the Facebook Combat Robotics group I may comment there. However, I will not comment here on an active discussion elsewhere, and I will not link to an active forum thread.
If you want my opinion, ask here. If you want a grab bag of forum comments, ask there.
I wanna note that I would've built a wedge as a featherweight, but EOH requires a weapon that's at least 6 pounds in order to qualify unless the design is approved with a weapon that's less than that.
I was planning on using a 182:1 gearbox and a Banebots 775 motor for the lifter. However, I've come across a big thing in regards to their designs. One of them is inspired by 'DUCK!', with a short, beefy lifter on the front while the other is based off of the UK heavyweight 'Shockwave', with a lifter that can rotate 360 degrees around itself. I'd assume that one version is better at doing something than another, I just wouldn't happen to know what that is.
A: [Mark J.] How did you decide on a 182:1 gear ratio for your lifter before you settled on a lifter design? The gear ratio determines the torque available to the lifter, and the torque required for a simple lever-arm lifter depends on the length of the arm from axle to tip. Examples:
Shock Reduction
Your proposed 1:1 geartrain connecting the gearbox to the lifter will not reduce loading on the gearbox -- a shock load on the lifter will be passed on at a 1:1 ratio the the box. You will often see additional gear reduction between a lifter and a gearbox, and that DOES reduce shock transmission! An external 4:1 reduction will increase the torque from the gearbox to the lifter by a factor of four, and will reduce the torque of shock transmitted back along the lifter toward the gearbox by the same factor.
Pros and Cons
Q: I want to build a switch! I'm looking at Team Whyachi's pictures and drawings on their website, and I'm confused as to how how they're able to use a metal socket screw to close the circuit. Even if there was a nylon washer separating the cap from the copper "bridge" and the two contacts, wouldn't the thread/screw body still touch and you'd get shocked if using a metal allen key? And how do they know how many turns it takes for full contact without overtightening the screw?
The Whyachi switch uses spring pressure to make contact, not screw pressure.
Q: I asked '@the_guy_who_has_a_robot' and he recommended you to me. Can you design an antweight 18mm thick 50mm long 5mm shaft hole monotooth vertical spinner (just spinner) for me and send the stl to [email address redacted] please? [Camarillo, California]
A: [Mark J.] I don't know '@the_guy_who_has_a_robot' and he apparently does not know what we do here. From the Ask Aaron mission statement:
Q: I am '@the_guy_who_has_a_robot' and I would like to apologize. I told the guy who had a question about the mono tooth spinner to go to you if with his question. I didn’t know how to awnser it and I told him about you. I told him to give him lots of details. Not to ask you to make it. I apologize. Please accept my apology [Omaha, Nebraska] A: Thanks for the explanation, Omaha. Getting caught in the middle requires no apology. Q: Hey Mark. Let's talk theory.
My initial theory on this was that because the area of potential impact is increased, the energy in those hits would be spread out over a larger area and would actually be weaker, but covering more ground. A bit like throwing a stiff jab when you were born with hands that would make Andre The Giant blush. However, I'm finding the reality to be a little different and I'm not sure why. It appears that the impacts are actually NOT weaker, but instead far more powerful than anticipated. It's as if the larger area of impact is increasing the percentage of energy transferred because it has more area to transfer TO. But then again, I'm just a guy with a few crazy ideas and a garage full of tools. Do you have a little bit of insight about what might actually be happening here? David Rush [Livermore, CA]
A: [Mark J.] OK, let's get theoretical. A spinner weapon needs a combination of things to land a powerful impact:
Granted, your opponent is not made of melon -- but the various materials from which they are made can and will absorb energy by deformation. If you're trying for localized damage by tearing into your opponent to grab or rip away material, a small and possibly sharpened impactor will serve that purpose. If you're trying to 'swat' your opponent and send it flying with as much energy transfer as you can manage, a large impactor area will minimize localized deformational energy dispersion and transfer more of the kinetic energy to your opponent as a whole.
Q: So I’m making a new 1lb and 3lb competition in the midwest. As a builder what do you suggest I should do. ( box size. Large sheets of lexsan and where I can get is) thank you very much [Omaha, Nebraska]
A: [Mark J.] What would I suggest? I'd suggest that you attend combat robot competitions and talk with event organizers until you no longer need to ask me to sumarize in a couple of paragraphs everything you need to know to put on a safe and well-run competition.
Unwilling to do that? Head over to SPARC: Standardized Procedures for the Advancement of Robotic Combat and read every word in their 'Event Resources' section - top of page on the right. The last item in their event resouces section is the 'SPARC Arena Construction Best Practices' which provides construction considerations, cost estimates, material recommendations, and example arena photos.
Check local plastics suppliers for polycarbonate ("Lexan") sheet. If you cannot source locally, a quick web search will turn up multiple suppliers -- but shipping on large sheets can get expensive.
Q: Hey, Mark! Back once again with another question. I noticed in a recent post that 'Sandstorm' used two individual gearboxes connected jointly in order to give its [lifter] weapon power. Is this, in any way, more effective than using one gearbox with more power? If so, why? I was thinking, for example, would there be any benefit from using two Banebots gearboxes with 129:1 ratios over one Banebots gearbox with a 182:1 ratio. As an off-topic question, if using two motors has any advantage, would using two Banebots gearboxes with 64:1 ratios be a good option, or would they be too weak for a decent lifter? [Close to Champaign, Illinois]
Why use two gearboxes/motors rather than one gearbox with a motor twice as powerful? Electric lifter weapons require a great deal of torque, but there is a limit to how much torque a given gearbox can handle without destroying itself. BaneBots gives this warning for their P60 gearboxes in all ratios:
We recommend maximum torque not exceed 35 ft-lb for all P60 Series Gearboxes. It is possible to mount motors that will exceed this in higher gear reductions. Higher reduction gearboxes should be utilized primarily for speed reduction. Designs utilizing a P60 gearbox / motor combination that will exceed 35 ft-lb should include a method of limiting torque to prevent damage to the gearbox.
The suitability of any gearbox or gearbox pair requires analysis of the loads that will be placed on the gearbox shaft(s) by your specific lifter design. I can't make a general comment about specific gearboxes without knowing much more about the lifter design. Several posts in the Ask Aaron Robot Weapons archive give examples of lifter analysis -- search there for "calculate how much torque" for a start.
Q: Do you still go to fights as a spectator; if so, where? [Hagerstown, Maryland] A: [Mark J.] I'm reluctant to discuss my travels. I don't even tell Google. Q: Do you know if BaneBots P60 gearbox's gears are interchangeable? I have a 4:1 that I want to change to 5:1. What would I need to make this work? [Hagerstown, Maryland] 111
Q: Apparently there is no 5:1 pinion for a 5mm shaft, Any ideas?
A: A few...
Q: I have a brushless motor that is rated 12 to 15 volts and two drive motors that are rated 3 volts. How do I power them without burning up the drive motors or not giving the brushless motor enough power? [Danville, Illinois]
If you insist on running Tamiya gearmotors, or if you've got a motor I don't know about, you can use a 4-cell LiPo battery (14.8 volts) and program your radio transmitter to limit the drive motor controller output to a maximum 25% of full throttle -- effectively limiting motor voltage. Twenty years ago we ran Tamiya motors at more than 7 volts without trouble; if you're afraid of burning up drive motors you're in the wrong sport.
You'll need an R/C transmitter that has 'Adjustable Travel Volume' (ATV), sometimes called 'Travel Adjustment'; check your radio manual. Most combat-capable radios have this feature. Set the travel volume on the drive train throttle and turning channels to 25%, and leave the weapon channel at 100% so your brushless weapon motor will get the full 14.8 volts. This technique is a little hard on the drive motor controllers, but those Tamiya motors draw so little power that it won't be an issue.
I'd much rather see you get proper drive motors and a weapon motor that can all run on at the same voltage -- they're certainly available.
Q: Hi Mark, Had a conceptual question about impactors on horizontal spinners. Traditionally, the inserts come to a triangle point with the hypotenuse facing bot. Is there any sense in making a vertical ramp impactor to get under opponents instead of a straight line to hit anywhere in the height of the weapon?
Many Thanks. [Pittsburgh, Pennsylvania]
A: [Mark J.] I'm confused by your question. I'm not sure why you'd want to use a horizontal spinner to try to 'get under' your opponent when the weapon is designed to tear them apart. If you want to get under them, build a wedge.
The impactors and inserts I typically see on horizontal spinner weapons are typically flat, hardened, vertical surfaces designed to transfer destructive impact energy against an opponent's hard surfaces. Some spinners have special blades with sharp leading edges to swap-in against softer-armored opponents, but hitting a hardened surface with a sharp blade blunts it immediately. See the comparison of 'Tombstone' bar weapons at right.
For a reader question (now in our Ants, Beetles, and Fairies archive) I asked builder Jamison Go why he sometimes replaces the single-tooth disk (STD) with a saw-edged impactor in his beetleweight horizontal spinner 'Silent Spring'. His answer:
What if the opponent has no such grabbable surfaces? Say for example, a robot made of rubber or foam? The traditional STD would be ineffective unless sharpened every match and even then its likely only good to the first few hits because it is THE singular wear point.
The saw-blade is for whittling opponents who have only compliant armor or soft things at the hitting surface. Instead of going for one big impact which would normally be absorbed, I flake material away at a high rate. What happens is I end up grabbing the same amount, but only after several milliseconds of tearing deep into them.
[My opponent was going to] use his over undercutter attachment which meant the only hitable surfaces were his wheels, hence the decision for that type of blade.
Q: Hi Mark! I was wondering if there were any robots with instead of a single drum, Had two or three disks next to each other to make more power from all three motors? Thanks! (Also go RunAmok) [Lynn, Massachusetts]
A: [Mark J.] Thanks for the 'Run Amok' shout-out, Massachusetts.
You'll note that all of these designs are horizontal spinners, and that none of them are terribly successful. The potential benefits of multiple vertical drums or disks are even more difficult to imagine. Why bother with three small independent disks and three small motors when you can have one larger drum and a large motor three times as powerful? A hit anywhere on the drum would transfer full impact energy to the opponent, whereas a less-than-perfectly-aligned hit from a triple disk might only transfer impact energy from one of the disks. Sorry, but I'm seeing added weapon complexity and weight with no real advantage. Simple robots win.
Q: Is there a reason those who use brushless only have used the ones made for airplanes? Why not cars? Something like this: Turnigy 1/8th Scale 4-pole 2100KV.[Hagerstown, Maryland]
A: [Mark J.] There are two broad types of brushless motor design:
As robots get larger you see more inrunner designs in use. Larger inrunner motors spin more slowly than the tiny ones which makes them a workable option for both drive and weapon power. The Turnigy motor you referenced has about the right amount of power for a hobbyweight weapon but spins at better than 38K RPM, which could be difficult for a belt drive to handle -- simpler to use an outrunner. For drive use, a pair of the Turnigy inrunners would have enough power for a featherweight 'bot, and this is probably the lightest class where I would consider using inrunner drive motors.
By the time you get up to heavyweight 'bots, the outrunner motor styles have disappeared and everyone uses inrunners if they're using brushless.
Q: Can I use my Quantum pistol-grip radio for an antweight robot? [The Aether]
A: [Mark J.] Yes, with a little added hardware. Your Quantum radio, like most pistol-grip R/C systems does not have the 'mixing' capability to to control a robot. Your steering 'wheel' (radio channel 1) controls your steering servo servo to point your front wheels, and your throttle 'trigger' (radio channel 2) controls the motor speed controller for forward/reverse motion. To control a 'tank-steer' robot the control channels must be 'mixed' to each control the motor(s) on each side of the robot, but in different ways:
Q: what flavor of Machine screws are best for a battle bot? (GR 8/alloy steel, Titanium, stainless) specifically what is needed for holding armor on? Is harder always better? [Hagerstown, Maryland]
A: [Mark J.]
The desired material and temper of the bolts depends a great deal on the armor mounting style, but there are some general considerations. Grade 8 bolts are strong, but their added hardness results in a lack of 'toughness' needed to survive shock loads. Stainless steel fasteners have much greater toughness, but are not nearly as strong overall. Titanium falls in between, but the added expense and bother far outweigh any advantage. What you most commonly see in use are standard grade 5 steel bolts: greater strength than stainless and greater toughness than grade 8. The loss of strength can be made up by adding a few extra bolts.
Need more info on machine screws? Curious Inventor: All about screws.
You might also be interested in searching the Ask Aaron Materials and Components archive for 'shock mount'.
Q: Hey, Mark! I've been goofin' around with the Tentacle Calculator, and I've come up with a couple questions about it:
2) Is there a way to determine the speed of a shufflebot? I ask because the calculator does calculations for wheels, and IDK if there's a way to calculate for shufflebots. Thanks again! [Jacksonville, Illinois]
A: [Mark J.] By the numbers...
If you want an estimate from the Tentacle calculator of how fast it would be going if it wasn't hopping, double the offset distance for a lobe on the shufflepod cam and enter that value as the 'wheel' diameter. But seriously...
Q: How much can the performance of a brushless ESC be improved by swapping capacitors? I saw on Charles Guan's website when he was learning brushless drive setups that he swaps the capacitors out on all his ESCs for high-performance capacitors. I know this is supposed to help shield the ESCs and prevent burnouts from current surges when the motors are pushing at low RPMs, but how much does it help, and how much should I upgrade the capacitance of my ESC? To be more specific, I have a 30 amp brushless ESC with a pair of 25v 550 uf capacitors. Would it make sense to swap those for a pair of 35v 2200 uf capacitors? They only weigh 6 grams and the ones I'm losing are probably 3, so if I can get any increased survivability for my ESC that kind of weight would be worth it. The ESC will be running a .102 Ohm 4S 580kv brushless motor with a 1.8:1 pulley reduction to power a large horizontal spinner (about .0025 Kg M2). Also, I read on some hobby forums that ESC capacitors should generally be rated at twice the voltage of the system, is that true? My system is 15v, and the current caps on the ESC are 25v so is it worth it upgrading for that alone? Thanks again for all your help! The bot is coming together nicely and I've registered for the Robothon in Seattle in October. [Mark from Vancouver]
Charles Guan is an MIT engineer who designs and manufactures ESCs in his spare time 'cause he thinks it's fun. He absolutely knows what he's doing. If you're not a electrical engineering graduate of a respected school you're likely gonna to do as much harm as good by tinkering with the components of a complex digital electronic device.
That said, the little brushless ESCs robot builders 'borrow' from the hobby R/C aircraft industry are designed for very different performance targets than we expect from them in our applications. Bumping up the voltage rating of the filter capacitors will do no harm and may provide some level of extra reliability.
Blindly increasing the capacitance is another matter. I'm pretty sure that Charles Guan had his drive system fully instrumented and was watching voltage spikes on a oscilloscope as he changed the capacitor values. Simply pouring in more capacitance is shooting in the dark.
A drive motor ESC sees a lot of high-load/low-speed action that can benefit from added capacitance, but a spinner weapon ESC operates much closer to the propeller-spinning job for which the unit was designed. I'd suggest keeping the factory capacitance value as-is unless you discover a specific reliability problem as too much capacitance can adversely effect high-speed operation. If you really want to tinker, keep the increase to no more than double the original value. I suspect that most spinner ESCs fail for reasons that more capacitance isn't going to overcome.
P.S. - I'm happy to hear that your build is going well and that you're registered for Robothon - that's a great event. Say 'hi' to the Seattle crowd for me.
Q: I've had difficulty sourcing tool steel for my beetleweight bar spinner, so I've been looking into methods to harden mild steel. Have you heard of Robb Gunter's "Super Quench" method? It sounds like you can get a good facsimile of tool steel out of mild steel fairly easily (well, as easy as other home blacksmithing techniques anyhow). Have you heard of this method, or do you know of any teams who have tried this? Would it be effective for a bar spinner? I think I'm going to give it a shot, unless I hear a good reason not to. [Mark from Vancouver - again] A: [Mark J.] What do the things in this list have in common?
There's a long list of desirable and required metal properties for spinner weapons, and if Billy Bob's mystical backyard hardening provided a reasonable mix of those properties you wouldn't have to search the back alleyways of the internet to find out about it. Don't waste your time.
Tool steel and abrasion resistant steel are fine spinner materials, but if you can't lay hands on them a nice bar of 'cheap and widely available' 4130 steel (AKA 'chromoly') is your go-to substitute. You can harden chromoly using standard practices and when you're done you'll know what you've got.
The lower the carbon content of steel, the faster the cooling temperature drop has to be in order to create the crystaline structure needed to harden that alloy by heat treating. 'Mild steel' has a very low carbon content (0.05% to 0.30%) and is generally not hardened by heat treatment because the techniques needed to chill mild steel quickly enough to achieve barely significant hardening are simply not worth the effort. It's ever so much simpler and more productive to start with a higher carbon alloy.
So far so good, but then some backyard metal bangers dredged up work done by a metalurgical researcher who was able to add a little heat hardening to "unhardenable" mild 1018 alloy steel as kind of a parlor trick. The internet has built this 'super quench' mild steel up to mythical proportions, touting it as a substitute for tool steel. In truth, the stuff isn't even a match for common low-alloy steels.
Q: Hi Mark, I'm designing a 'Breaker Box' style rammer bot for 15# competition. I was curious about different types of drive motors. There are several variations that will allow the full pushing force, but I imagine a higher torque motor would win in a pushing match. In my area, Leopard and Castle Creation 540 size motors attached to Banebots gearboxes are most common. I was curious if you can use an outrunner with the same or similar bolt pattern, hooked up to a Banebots gearbox, as a drive motor. I know AmpFlow motors are all the rage in the higher weight classes, would one be suitable here? I was also wondering how to maximize grip on the area floor. I have cut treads in tire and clean my wheels religiously with mixed results. Do lower shore hardness wheels offer better grip, ex green banebots vs black banebots or Colsons? Has anyone had success with adding "grip" to the tire? I was thinking studs like Riobots did, low grit sandpaper, two sided tape or something that can be sprayed on that adds grip. Your insight and experience is much appreciated. [Pittsburgh, Pennsylvania]
Here are some quick topic highlights -- search thru the archives for details:
Q: Hey Mark, question about insect-class pneumatics: I understand that a larger cylinder bore equals more useable force, however, how do you calculate the limit of this, when the slower piston speed due to larger bore becomes a greater limitation than the additional force? For example, say my valve has a flow rate (scfm) of 2.1469; I am thinking of switching from a cylinder with 5/8" bore to 3/4". Could you point me in the right direction, even external links on the math behind calculating this? Thanks! [Utrecht, Netherlands]
A: [Mark J.] It's very difficult to model the speed of pneumatic systems, in part because of the interaction of multiple system elements on gas flow and in part because of the compressible nature of gasses. Ultimate force is easy, but actuator motion starts as the pressure first builds past the force preventing system movement and may be complete before the force even approaches full theoretical force.
You can find a discussion of factors effecting pneumatic system speed at the Machine Design: Pneumatic Speed page, and you can poke thru the Team Run Amok: Pneumatic Tricks page for tips on improving speed.
In wildly over-simplified terms both your speed and force are related to the cross-sectional area of the actuator bore: double the area = double the force and double the time to extend.
Switching to the larger actuator should yield Q: I'd like to try brushless drive motors for a new robot, but I can't figure out how to input brushless motor data into the Tentacle drive train calculator. How do I calculate the stall torque and torque constant for a brushless motor? [West of the Pecos]
A: [Mark J.] The
Team Tentacle Torque/Amp-Hour calculator
was designed for brushed motors and assumes an inverse linear relationship between motor speed and torque. Common hobby brushless motors do not have that speed/torque relationship, and the entire concept of brushless 'stall torque' doesn't really make sense. To further complicate the issue, the torque curve of a brushless motor is highly dependent on motor controller firmware and on the specific user-adjustable firmware settings. The Tentacle calculator is nearly useless for designing a brushless drive train.
See what successful bots in your weight class are using for brushless drive motors, gearboxes, ESCs, and (importantly) controller firmware/settings. In general you'll find motors with high Kv constants, high reduction ratio gearboxes, and controllers flashed with SimonK or maybe BLHeli firmware. Brushless is a whole lot more complex than brushed drive, and I'd strongly recommend that you start with a proven combination. Experiment after you have a working drive train.
Q: Great site! I'm getting a lot of good info as my son and I are building a beetleweight.
He wants to use a pistol-grip style radio, we're looking at the Spektrum DX5C with the SRS6000 receiver due to its built-in gyro. My concern is that it only lists a failsafe on the throttle channel. I see that some of the Spektrum receivers have the (sometimes undocumented) ability to switch to a mode where all of the channels will fail in the bind position if you bind it the right way, but I have not found any info on this receiver yet. Looking through the radio archives, you have a lot of suggestions for radios/receivers with good (or at least passable) failsafe capabilities. However, when I search for them they seem to all be coming up as "discontinued" items. Do you have any suggestions for current receivers, or know of a good list somewhere? [Fredericksburg, Virginia]
A: [Mark J.] Well, now you've opened up the jumbo can-o-worms. Where to start...
Radio gear has been changing at a ridiculous rate since Chinese manufacturers jumped into the game headfirst a few years back. New transmission protocols, open-source firmware, onboard serial networks... which is why all the receivers you've found in the radio archives are outdated and no longer in production. Our robots don't really need all this new fancy stuff that's aimed mostly at the drone market, but we make up such a tiny portion of R/C gear sales that we have to go along with whatever happens in the larger industry.
The upside of the Chinese R/C takeover is a stupendous drop in prices. The downside... well there are several downsides:
Taranis Q X7 A very sexy system widely used in robot combat. Better than usual quality, looks great, but it's a complex radio that will intimidate novice builders. Does not come with a receiver, but multiple full-featured receivers are available.
One last thing I don't recommend receivers with built-in gyros. A gyro has to be specifically oriented within the robot relative to 'up' and 'forward'. This can make fitting your receiver-gyro unit into a small robot awkward. Robots also have special requirements for gyro shut-off when the robot happens to be inverted that a receiver-gyro combo is unlikely to provide. I you want a gyro, get a stand-alone unit.
Sorry for the long and rambling answer, but I did warn you that this is a big can of worms. If you'd like to hear other opinions on this subject there is an active 'Combat Robotics' group on Facebook that would love to give you a full spectrum of opinion -- and then some.
A: [Aaron] Few people in Nebraska are threatened by hurricanes, so send a swarm of killer robots into low Atlantic and gulf coastal areas to drive the puny human inhabitants toward Nebraska. Problem solved.
Robot haiku:
|
Q: OK, Mark! 
A: [Mark J.] The Whyachi switch socket screw is completely isolated from the electrical circuit by a nylon 'top hat' grommet that extends thru the contact bar hole. The screw is isolated only to prevent the Allen wrench from accidentally shorting to another exposed electrical component. Direct current at normal robot-level voltages will not give you a 'shock' on touching a terminal -- you won't even feel it.
I've been more or less dubbed the "horizontal drum" guy due to my choice of over-sized and thick horizontal weaponry that I tend to favor. While most builders in the ant and beetle class tend to use horizontal weapons with a thickness ranging between 3mm and 3/8", my weapons range between 3/4" and 1" in thickness. The basic idea is to increase the impact zone, much like a drum, instead of a smaller, more focused zone of impact.
A: [Mark J.] Don't confuse 'power' and 'torque', Champaign. Mechanical power is expressed as rotational force (torque) multiplied by its rotational speed (RPM). A reduction gearbox will increase output torque and decrease speed in equal measure -- there is no increase in 'power' regardless of the gear ratio.
A: [Mark J.] Yes, you can turn the 4:1 P60 into a 5:1 P60. Parts cost is about $25 - shipped.
A: [Mark J.] The only '3-volt' gearmotors I know of are made by Tamiya, and they are not nearly strong enough for the current level of robot combat. The motors are weak, the plastic gearboxes shatter, and the skinny little axles bend. Worse, I don't know of any electronic speed controllers that will work from a 3 volt power supply -- most won't operate below 6.5 volts. You'd be well advised to dump those motors and go with something more commonly used in combat robots.
Everyone is hype about single tooth blades for "bite" but why? What does bite actually do for you? It is heavier engagement on a piece of material which is arguably more energy dissipated just because it has nowhere to go.
There have been several multi-spinner combat robots, but the spinners are usually located on opposite ends of the 'bot. A current example of that design is BattleBot 'Rotator', armed with large independent horizontal disks on front and back. The flaw in this design is that only one of the two disks can impact your opponent at a time, limiting the damage the system can inflict.
An alternative twin-spinner system design is employed by 2018 BattleBots competitor 'Double Dutch'. Their design features counter-rotating bar spinners placed above and below the robot body. The two bars are powered by a single electric motor. Although both weapon bars can attack an opponent at the same time, it's likely that one bar with strike before the other and throw the opponent clear before the second bar can impact. Almost certainly the two potential weapon impacts will strike different locations on the opponent, which will also limit their effectiveness.
A different double-spinner approach is seen in antweight 'Not So Free Hugs' which has twin saw blades on articulated arms. The idea here is not impact damage but the ability to trap and saw into soft wheels or plastic side armor. Here the ability to access different locations on the opponent is a benefit as it gives a greater chance to find something vulnerable to saw damage.
Machine screws / bolts are designed and rated to resist a 'pull' force that is tested by a machine that applies a gradually increasing force. That type of strength is important in many applications, but it is not the type of load fasteners will face when holding combat robot armor. Forces encountered in combat are typically sudden 'shock' loads that may have a high 'shear loading' factor. Ideally, mounting should be designed to prevent shear load on bolts, but combat impact vectors are unpredictable -- you need to design for all possible loads.
If your bolt heads are exposed to possible spinner attack, you'll want to countersink the heads to prevent the spinner from grabbing exposed 'spinner bait' and tossing your 'bot and/or shearing the bolt heads.
1) Is there a way to determine the gearing ratio on a robot with a chain or belt-driven drive with front and rear wheels of different sizes? For instance, the rear wheels are 3", and the front wheels are 4". The rear has, say, a 1.75" sprocket, the motor itself has a 2" sprocket, and the front has a 3" sprocket. These aren't real numbers, they're just random numbers to be used as an example.
A: [Mark J.] How much extra salt should you shake onto your hamburger? Some need a little, some need a lot, some have too much already.
A: [Mark J.] You're asking about very popular design topics. A search of the 
Alright, so what do I recommend? I personally prefer Futaba radio gear such as the '6J' for high quality and 
