I remember when the Freedom Chair was a brainstorming session on a whiteboard, in a long-neglected building in the northwest corner of the MIT campus, in a room we affectionately called the "MIT Mobility Lab." We were trying to reinvent the wheelchair, to design something that could help people with disabilities travel long distances outdoors, over rough terrain and pavement, and then move around indoors when they got to their destinations. Existing solutions didn't work: handcycles were great for distances but were too big to use indoors, and regular wheelchairs were too hard to push off-road or for long distances on-road.
We started with first-principles: the basic underlying physics and biomechanics of the problem. We asked ourselves: what's the most efficient way to use the upper body for locomotion?
We spent the next few weeks reading papers. We learned that regular wheelchair efficiency is really low, typically under 10%. This means that 90% of the energy a wheelchair rider uses is wasted! This is due to regular wheelchair propulsion using a lot of small muscles (rather than a few large ones) and the push-rim motion requiring a lot of effort that doesn't necessarily push the chair forward, such as the energy required to maintain a grip on the push-rim.
We wanted to think outside of the box, so we looked at anthropometric data that shows how much force people can exert with their arms in all sorts of positions. Using this data, we could map out ideal movements that would maximize the power we could get out of the rider.
After exploring all the options, we opted for a lever-drive system. It was more efficient than regular push-rims, easy to fit within the confines of a wheelchair frame, and offered the opportunity to change the mechanical advantage by shifting hand position on the levers.
We wanted a way for Freedom Chair riders to "change gears," just like in a manual transmission car or a multi-speed bicycle. Some lever wheelchairs on the market use complicated gear systems to accomplish this, but we wanted something simpler, easier to use, and less likely to break.
Our insight was that by sliding one's hands up and down the levers, one can have the same benefits as changing gears.
Grabbing at the top of the lever is like grabbing at the end of a long wrench or sitting at the end of a see-saw. It gives the rider a lot of leverage. Push force on the lever is amplified by nearly a factor of 10 being transmitted through the chain and to the wheels, making it really easy to roll over grass and to climb hills.
On the other hand, grabbing at the bottom of the lever is like grabbing near the bolt when you're using a wrench or sitting near the middle of the see-saw. You don't have a lot of leverage. However, you can push the lever through a longer stroke, which means that for each movement of your arm you can make the wheel rotate more: you roll faster!
As engineers, we didn't just want to design a lever system. We wanted to design the best possible lever system. So we started a process of optimization. We thought about a lot of factors: the variety of different terrains riders would roll over (sand, grass, gravel, pavement, snow, etc.) and what kind of friction they would present. We thought about different slopes that were common in day-to-day life outside of the ADA-compliant world. We thought about what gear sizes were commonly available for bikes. We looked at how much force people could exert at each point of the lever stroke and we interviewed dozens of wheelchair riders to find out what worked for them.
We ran the numbers and tried to figure out a few things: what's the best configuration that would let a rider exert their maximum possible force to climb over an obstacle? And what's the best configuration that would let a rider cruise most efficiently on flat ground?
We sized the Freedom Chair's levers and gear ratios based on these findings, ensuring our riders have the best possible solution for the widest range of riding conditions.
The last step in our process was to test. Running all sorts of numbers in Microsoft Excel is one thing, but we needed to make sure our hypothesis worked out in the field. We designed and built our own data acquisition system that measured how hard riders were pushing, what slopes they were riding over, where their hands were on the levers, their heart rate, and their oxygen consumption. We had riders travel over their regular commute, in both our lever chair and their regular wheelchair, and compared the data we collected.
We were excited to find that the lever system was far better than their push-rim wheelchairs. It's:
- 76% faster than a wheelchair over the same terrain. Riders got there faster.
- 41% more efficient. Riders used a lot less energy.
- 51% higher peak propulsion force. Riders were able to roll over obstacles easier.
Want more detail? Check our our published peer-reviewed academic papers:
- THE DESIGN AND TESTING OF A LOW-COST, GLOBALLY-MANUFACTURABLE, MULTI-SPEED MOBILITY AID DESIGNED FOR USE ON VARIED TERRAIN IN DEVELOPING AND DEVELOPED COUNTRIES
The GRIT Freedom Chair is the most versatile chair on the market, designed from the ground up to handle any terrain. From trails to grass to snow, the Freedom Chair is built for you to push yourself. Born out of research at MIT, the Freedom Chair's patented easy-push levers reduce shoulder strain and put you in control of your mobility. Ready to hit the trails? Learn more about the GRIT Freedom Chair at www.gogrit.us