Battle Robot Building Tips

Introduction
Do your research
Basic plan and body design
Assemble a team and a workshop
Build a frame
Select your armor
Consider your mode of locomotion and turning
Steering control options
Motors, engines, and drive trains
Batteries
Speed controllers
Radio controllers
Building your weapon(s)
Pneumatics
Miscellaneous parts
Getting funding

While this was written many years ago with Battlebots in mind, the information still applies to robot building. All links mentioned below were last verified May 2012. If you want to relive some of the many great Battlebot moments, check out these videos.

Introduction:

Given the increasing popularity of robotic combat sports such as Comedy Central's BattleBots, a growing number of people are thinking about building a fighting robot of their own. If you are one of these individuals and you have no idea where to start then I highly recommend that you carefully read through this tips section. My background is in chemistry and computer science but I've recently been gathering a lot of information on building fighting machines and I'd like to share what I have learned with you. Many additional links can also be found in this text.

The first thing that I would like to make clear is that building a BattleBot of competitive quality is not easy. It takes a lot of hard work, both physical and mental. I should also mention that you will need to be prepared to spend a significant amount of money. Even lightweight competitors usually spend over a thousand dollars on construction and some super-heavyweights can cost tens of thousands to build. I'll try to present some money saving ideas to help in this respect. With that said, if you are willing to spend the time and the money, then just about anyone can build his or her own fighting machine. Keep safety in mind as well and be sure to have proper adult supervision if you are under eighteen.

Do your research:

There is a lot of information out there on the web if you are willing to look for it. I hope that this resource is a helpful start, but by no means should you rely on a single source for all of your construction advice. Visit our links section for just a small taste of what you can find on the web. Construction tips from experienced competitors are especially helpful. Spending a few hours on research can save you weeks of construction time and thousands of dollars. Try http://www.puppetmaster-robotics.com/faq.html for a good FAQ's page. It also helps to be familiar with the rules of whatever event you are planning to attend. Unfortunately, the rules and weight classes vary significantly from one competition to another, thus building a single bot for multiple competitions can be troublesome.

Watching the competitions is another valuable source of ideas. You can see first hand which general design principles are successful and which ones fail. My students and I often videotape and replay the televised matches. Don't get me wrong, no one likes a copycat and there is no fun in just copying someone else's design; but you don't have to reinvent the wheel either. Take a few ideas here and there and add some of your own original concepts to produce a quality bot that you can call your own.

Assemble a team and a workshop:

So now that you have decided that you're ready to build a killer robot, you have to be sure you have the tools and manpower that you'll need. Very few builders work alone because of the huge number of man-hours involved. It is favorable to have someone with metalworking skills and someone with a background in electronics on the team. Most people that wake up one morning and decide they want to compete in Battlebots tend to be tinkerers of one sort or another. So chances are you have a workshop of some kind already if you are reading this article. But if you don't I suggest you have the following at your disposal: a big open area where you can make a real mess without getting in trouble, table saw, chop saw, rotozip, jig saw, hacksaw, drill press, hand drill, ratchets, screwdrivers, hammers, rivet gun, quick clamps, vice, vice grips, T-square, tape measure, grinder, sander, welder of some type, and finally a shop vac to clean up that really big mess you just made.

Basic plan and body design:

Before you start to build or order any parts, come up with a list of some key features that you want your robot to have. This is usually a system of give and take. Perhaps you want a bot with really thick heavy armor, or maybe that weight is better spent on larger motors to give your bot a speed advantage. Weight is a constant concern and you'll probably find it challenging to stay within the limits of whatever weight class you decide to compete in. Keep in mind that as your bot goes up in weight, the construction costs will dramatically increase as well.

Once you know your weight class and the special features you want your robot to have, you need to decide on a general body design. These include, but are not limited to, boxes, wedges, spin bots, and walkers. Naturally, more complex designs are fair game too, however, highly complex shapes result in large surface areas relative to their volume. Thus a dodecahedron bot design will cost you a lot of armor weight.

Various derivations of the basic box-like design are very common because it drastically simplifies the engineering process. Properly designed wedge bots have been quite successful in the past as well, however this design is getting rather old. Spin bots are an interesting concept that uses the external spinning shell of the bot as both the armor and the weapon. Team Blendo has an excellent site explaining the primary advantages and disadvantages of spin bots at http://www.m5industries.com. Walkers are bots that use some means of locomotion other than wheels. They have not been very successful because they tend to be slow and cumbersome. Realizing this inherent disadvantage, many competitions give walkers significant weight handicaps.

No matter what body type you decide to go with, try to keep your center of gravity as low as possible. Tipping over and being incapacitated can be your worst nightmare. If you really want to play it safe, design your robot to be invertible. The ability to drive even after being flipped was one of our team's key concept points. This does limit your weapons options, but we thought it was a worthwhile sacrifice. Keep in mind that there are a growing number of robots such as Toro that are exclusively designed to flip their opponents. A flippable design renders this attack almost useless as long as you have a sturdy construction that can handle the shock forces involved. Keeping your ground clearance as low as possible also helps to prevent flip bots and those pesky wedges from getting under you. I suggest having about half an inch of clearance.

My final piece of advice is to try to keep your design plans flexible and open to new ideas. Bounce your ideas off some friends. It's easy to fall in love with your own creation and we all know that love is blind. An impartial friend may be able to point out some obvious vulnerabilities that you overlooked. Leaving a little open space inside your robot can help a great deal towards making modifications. I would advise against designing the entire robot around a single weapon. Build a sturdy, reliable weapons delivery platform, and consider a modular weapons section. This way you can compete in different competitions or even different weight classes with your latest and greatest attack strategy without having to design and build an entirely new bot from scratch.

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Build a frame:

A solid frame is the key to holding everything in place. Imagine the forces involved when a pair of three hundred pound robots collide head on at twenty miles per hour. Some builders simply attach everything to a bottom platform and place an armor shell around it. This is a mistake in my opinion, as a well-designed frame can add a great deal of structural integrity at a very low cost in weight. Your main options are to use round or square tubes. Round tubes tend to be slightly stronger pound for pound than their square counterparts. The problem with round tubes is that they can be harder to work with, especially if you are going to be bolting things in place. We decided to go with square aluminum tubing for Logan. Some other options would include I-beams or angle beams.

When you are designing your frame, try to determine the most likely directions of the most significant forces that your robot is likely to sustain. Don't waste valuable weight on unnecessary support. Finally, consider welding your frame together rather than using bolts or rivets. Welds are almost always stronger. If you have no means of welding, consider contacting some local metal shops. You'll probably be able to find a welder willing to work with you on such a cool project. High school vocational schools may also be willing to help out. Kids love this stuff.

Select your armor:

It doesn't take a genius to realize that these machines need to be designed to take a lot of abuse. Your armor is all that stands between your vital electronics and your opponent's weapon. First, try to determine what locations are most likely to be hit during combat. Many builders place extra armor on the front of their robots. The new and improved kill-saws in the BattleBots arena, which pop up from the ground, shouldn't be overlooked either. You'll also have to decide if you want to bolt your armor in place or weld it onto the frame. Welding it to the frame is definitely stronger, but this makes it much harder to repair damaged sections. If you are going to go with the welding approach, you need to make sure that the armor and frame are built from the same material. Dissimilar metals such as steel and aluminum cannot be welded together. Even different grades of the same material can make the welding process more difficult. There are an amazing number of materials to choose from to armor your robot. I won't cover the more exotic varieties, but some common options include wood, steel, aluminum, titanium, and Lexan. I'll break down some of their advantages and disadvantages.

There really isn't much to say about wood. Ummm� I think it comes from trees. It's probably the least expensive option and you may have more experience in working with this material. Given the quality of today's combat robots, I don't think that one could expect wooden armor to last very long. Perhaps a 2X4 could be placed here and there as extra protection because wood does offer good compression, which could act like a crumple-zone to absorb shock damage.

Steel will offer you the highest level of protection dollar for dollar. If money is tight, I suggest you go with steel. It is very strong and is easy to weld. You'll go through many blades, but cutting it is fairly simple as well. Just be sure to use a metal cutting blade, not a wood cutting blade. There is only one major disadvantage to using steel. It has a very high density. A square foot of quarter inch steel (1018 grade) weighs a whopping 10.33 pounds. So to armor just a small cubic foot with this armor would cost you 62 pounds! You have various grades of steel to choose from as well. You can obtain detailed technical specs on many types of metal alloys and other materials at http://www.matweb.com.

Aluminum is not quite as strong as steel but it is significantly lighter. It also tends to be more expensive and slightly harder to weld. Despite these disadvantages, the huge weight savings that it provides often make it the material of choice, especially in lower weight divisions. A square foot of quarter inch aluminum (6061-T6 grade) weighs 3.53 pounds. As a rough rule of thumb, a high-grade aluminum alloy is about one half the strength but only one third the weight of an equivalent piece of steel. An excellent source of custom-cut aluminum can be found at http://onlinemetals.com.

Titanium alloy armor has been gaining popularity amongst higher budget robots. It can be prohibitively expensive but it's much stronger than aluminum and much lighter than steel. Plus it just sounds cool to say that you have titanium armor. I have never worked with this material, but I have been told that it can be quite difficult to machine and weld. To help a bit with the cost, you can look for sources of scrap titanium pieces such as listed at http://www.metalworld.com/a/0166.html.

Lexan has also gained much notoriety in the robotic combat community. Lexan is a high-grade form of polycarbonate (PC) manufactured by GE. It's even much lighter than aluminum and is very resistant to penetration. As a fairly non-scientific explanation of its strength; we found that an overhead swing from a large pickax failed to penetrate a quarter inch thick piece. Its flexibility also gives it good shock absorbing characteristics and makes it almost impossible to dent. The two primary disadvantages of this material are its expense and the fact that it can be easily cut. If you are going up against a large bladed weapon, Lexan may not be the ideal choice. If you are going to use this material, do not use regular paint or other organic solvents on it. You may not see any damage done, but it will significantly weaken the material on a molecular level. Use water based paints and cleaners if you must. Colored Lexan is also available. You can purchase and get more information about PC at http://www.goodfellow.com/static/A/CT30.html.