The Differential Drive - A New Breed of Actuator

At the end of the day, every engineer's true desire: " It does look good and it is shiny".

They are used in tracked vehicles and are called adder/subtractor gear boxes. Essentially two differentials linked together. They allow one high torque motor to provide the main motive force to two outputs and a second lower torque motor to add and subtract its speed to those outputs. It allows precise control over the relative speeds of the outputs even with motors of similar torque.

Little fun fact:
The Toyota Prius is using a planetary differential to couple an electric generator, motor (and ice engine) and the driveshaft.
This system is widely belived to be the most cost effective and efficient way to build a hybrid drive train. In german, we call this system a "Leistungsverzweigter Hybridantrieb". 😅😁

You just described the “transmission” of the Prius, except that the Prius uses three input motors, mg1, mg2, and ICE.

The "reverse" differential drive you describe was used for a century (I believe) to actuate rudders on ships. Two large DC traction motors ran in opposite directions at high speed, with the rudder linked to the output shaft. The rudder could then be moved by varying the electrical power fed to the motors, one more and one less, resulting in a high torque at the rudder very quickly. This was before the days of sophisticated hydraulics, and avoided the need to spin up a single traction motor from rest every time a rudder movement was required.

The best way to learn is to fail :)
Congrats on not giving up!

This is beautiful. And your style is flawless.

I love that you turned a "failure" into a video about what you learned. Quality video!

15:42 "you live, you learn." - Great dude!

Beautiful build quality. Great presentation and example of the value of lab tests in conjunction with thought experiments. The first computer I worked on professionally, used physical differentials to perform vector math based on heading to integrate acceleration, and speed into distance traveled in latitude and longitude for the F4 fighter jets. It worked well - Back in my day. The entire navigation and weapons delivery was done in analog computing and was build before Apollo.

This is exactly why I love the CZcams community. 5 minutes in my brain is all fireworks and i’m sketching and writing out ideas to compare with your findings at the end. You’ve earned a follower! Keep up the great work.

Awesome video, I like that you show where you went wrong, really showing people that engineering is about analyzing failures and not only about making perfect systems all the time.

I just returned to this video after having seen it back when you first posted it. It’s clever and very well-explained!
I realized that this is essentially the same principle used in the ancient “north-pointing chariot”. There, the inputs were the rotation of the two chariot wheels, and the output was a pointer that s always pointed in the same direction, regardless of how you rotated the chariot.
Anyway, a great project and explanation of the project!

I never thought of a rear differential as being a planetary gear pulled into 3D, or a planetary being like a rear differtial folded inside out and flattened. Thanks for that!

I love this old black/white video explaining a differential, it´s genius and way way ahead of it´s time.

Not only is this a really interesting video, it is incredibly generous and presented with admirable humility. Thanks so much for taking us on your journey of exploration. Coming up with novel ideas, such as this, and testing them out is how we ultimately advance technology. Really, really enjoyed this. Fantastic project and presentation!

"I'm not saying I'm the first to ever invent this, but I am saying I developed it independently"

Brilliant and quick explanation of the differential gear - not an easy task. Well done!

What a humble learner!

I like that you posted a video about a “failure”. You live and learn is something it seems many people do not subscribe to these days. It is nice to actually see the failures that contribute to the overall successes. We can all learn from your learning experience. Thank you.

I designed this and applied for a patent on it about 12 years ago, it is a great system never put in market

I really appreciate you documenting and sharing your experiments. Great work.

Dude! This is cool! I love being along for the ride of discovery!

This was great, thanks for you work. Your inclusion of your failed hypotheses and your thought processes prior and after testing made for an authentic watch.

This is pretty similar to a differential swerve drivetrain that some FIRST robotics teams have experimented with before. It is also similar to some types of robotic gripper/wrist mechanisms, since you can actually pull two outputs out of the differential.

Really cool! Looking forward for the speed and precision test

It is the first time for me as well to see this idea. Very neat. You might be able to write a publishable paper on it.
Core XY mechanisms technically also double the speed achievable, although not in all directions thus strictly speaking don't double the velocity.
Even a 'failure' is a success, because something new is learned.

Paused the video to come say how much I appreciate that you laid out your hypotheses up front, admitted two were wrong (rather than cutting them), then moved on. Thumbed up and subscribed right away.

That was very educational, Mr. Janssen!

all you have to do is invert one of the inputs and you've just created the mechanical equivalent to an electronic operational amplifier where the gear ratios determine the "gain" and you can even feed the output back to one of the inputs with a variable gear ratio and you can change the "gain" or input to output ratio of the drive unit.

Fascinating - great video - seeing the process and your knowledge, is impressive

Very cool! Congrats on surpassing one million total views!

Very Awesome my man! well done!

Thank you for showing us your whole development process and not just the successful parts.

No way, I was literally just working on one of these. Great job as always!

Quality content Levi! I'm so glad your videos are getting traction!
- Kaleb Rush

Keep up the good work. You're getting somewhere!

Good video man. I appreciate your transparency.

Most interesting video I've watched in a while - comments are cool too! Subscribed

Geez, someone hire this guy! This is very impressive.

Great job, including hypothesis was great

That is a really good educational video on systematic testing of ideas and building knowledge. So thanks!

Fantastic experimenting, kudos!

I used something like this in a lego truck a while back so that when stationary the model engine would run at an idle speed and then rev up when it started moving. Cool to see it implemented on this scale.

Levi, you're an awesome man. One day, you'll save us all. (hopefully, you'll long be done by then, with these dark and awkward DARPA projects) !

I really appreciate that you show when things go wrong, really true to life haha

I used this same technique to win an electric tractor pull competition in 2011. This is a cool investigation and explanation :)

Very cool. Sure it's been done before but it's the first time I'm seeing this concept. 👍

I'd really like to see a demonstration of the variable speed feature you described. Put encoders on the motors and output and test your theory.
It might be my bias in favor of encoders, but I have a hard time believing this mechanism will allow precise speed control. As with standard gearboxes, I think changing loads will require adjusting the power input to maintain a desired speed.
Excellent video. Thanks for sharing your projects with us.

This is why we do experiments. You didn't get the result you hoped for, but we all learned something. Great job, keep experimenting, who knows what you will develop.

Very good idea; also i personally like very much this scientific method approach!! Well done

Before smart electronics, this was a common way to drive an equatorial telescope to both track the natural apparent motion of the sky and also position the telescope automatically to a new object. Because the "sky would move" some distance during the time of the reposition operation, the known destination (number of motor steps or encoder counts), would always be incorrect. By using a differential with one motor tracking and the other positioning, at the end of the move (in either direction), the desired object would be in the center of the field. In the early 1980s, while working on a telescope for the Navy's sky transparency survey, I found that making a numerical model of such a differential simplified the design equations significantly. Good memories.
Cheers on your clever design.

Great vid!
You sir have my attention and earned a sub.

2:20 this method of planetary gears is used in many hybrid cars, the Chevy Volt does this where the outer ring gear can be held and use the reduced speed of the planetary or the planetary gears can be held to overdrive the ring, which it uses to recharge the battery. Great video!

Wow this is really well applied! In 2018 I actually did my high school senior year engineering project on this concept using a 3D printed herringbone planetary gear set. It was designed as a way to include two motors on an RC car. In my prototype I opted for biasing the gear ratio to take advantage of torque and power over a wide range of rpm. (The concept was designed around putting an electric assist engine on a gas powered RC by replacing the transmission and clutch, creating a unique RC hybrid) it was pretty cool Bc theoretically the electric can spin in reverse in order to let the gas engine idle without a clutch, and also combine the power of both engines for max power during runtime. Back driving the electric motor was an issue, just like it was in your test, so I think any future version of the coupler I made would need some sort of servo actuated or electric brake on the electric motor. 3D printed transmission burned out in only a few minutes but it was a fun project!

Thanks for sharing!

Love this content!

Great design!

Very cool!

Thumbs up, and Subscribed. Great job!

The most important is to have an idea and try to develop something new... Thanks for your story !

Absolutely invertable , nice

I was wondering how to do this. Amazing youtube algorythm. Kings to you my friend. Brilliant

The outboard spoilers (used for additional roll control at lower air speeds) on A B-1b aircraft use triple redundant motors driving through two differentials. I was the product engineer for the electronics that control them for most of the production run.

This is cool shit..... glad to have found the channel

Ooh, I built something like this a while back to make a two wheel drive robot go straight. I used a differential style input to each wheel with a drive motor and a steering motor. The steering motor added to one side and subtracted from the other. The motors were set up with different ratios because you never want to steer as fast as you drive, the steering motor was smaller and I was trying to avoid back-driving the steering so it had a higher ratio. Very interesting to see the more general application... I thought it was interesting at the time, but never played with it further.

This reminds me of a constant-speed drive system from an aircraft alternator. It uses a differential kind of mechanism to limit the output shaft to be a constant speed regardless of whether the aircraft engine was spooling at idle or at max thrust. It uses a motor to spin the other side of the differential to change what the speed of the output is. It's not exactly what you've done here but it is similar and I'd recommend looking into that mechanism

I like how it look like, very nice aluminum + 3D printed, nice video for people who like mechanics and we like to try different types of drivers.

You should look at the drive system for the Sherman tanks, they use the difference of 2 motors to do forward backward and speed control. It is a very old idea

As far as I know they use such gearsets to drive the shaft of big ships. Seamless way to add a second motor to the output. really nice video & work!!

New viewer here: cool video! Well done, really enjoyed the editing and pace. Small tip: I got a bit distracted by the reflections om your glasses though. Have a good one!

you gave this a lot of thought. Keep those gears turning, congrats

Your brain works a lot like mine, so I instantly thumbs up, and subbed. Digging the channel already.

I like your analogous to the differential drive, I think what happened is similar to a car sitting on it's belly,
If your car is stuck in the sand in a way which one wheel (left) is touching the ground and one (right) is floating in the air, with an open differential, that right floating wheel will get spun rapidly and the left one will not get any power
Your output is like the left wheel, but since yours isn't locked to the ground, it fails to hold a weight and drops
I think it could be cool if you could design a *locking mechanism to your differential* which can be released after some speed is gained. Maybe even clutch it for smooth transition between modes
Love the ingenuity! Keep up the amazing work 💪🏾

Really cool video. I have actually used this method several times when building with Legos. The lego motor system is usually full power on or off. So when building a tank for example the turning is not smooth and can be hard to control. Using this method of adders and subtracters by means of a differential I was able to add speed to one side while subtracting from the other side. This would create smooth turns and allow for more functionality and tank like movements.

What a great video! Thanks for sharing your ideas. This line of thinking could be relevant to a hybrid drive system. The idea reminds me of a Toyota Prius drive system where a motor/generator and an engine share inputs to a differential and torque is routed to where is is needed.

Brilliant. Really fun to watch, and it does look cool as hell. Edit tip for next time: drop the bg music, it’s not adding anything or making the video itself any better. Regardless you’re an instant subscribe and I look forward to the next.

Interesting idea! Everyone is using cycloidal nowadays. :)

good video. I like the original ideas.

This is already done for agriculture machinery, high torque hydraulic motor (s) coupled to Diesel engine crankshaft to adjust for loads.

Hey I did this back in highschool with a vex robot, I used a planetary gear model instead of a cycoidal drive, but it still had to use a chain to reach in the gear and drive the planet gears directly, it was one of my favorite designs to work with, I wasn't useful for any of the competitions but was very fun anyway

This will work great for my rc cars. I've been dabbling with a similar concept just with 3 planetary gears and 2 motors

I'm a retired aircraft mechanic. If you can get this thing to work fully, then it sounds like it might make a GREAT aircraft Flap and Undercarriage, and undercarriage Door actuator motor. Over to you, genius.
M. M.cLaren, Brisbane, Australia

I have cnc mill, lathe and wire edm but my favorite is my 3d printer. Best tool to bring simple to complex ideas to life quickly and go through the revision process with minimal pain.

One application for driving one shaft with two engin is in ships. The concept is called "Vater Sohn Antrieb" (German), "father son drive".
I wasn't able to find anything on the internet with this phrases.
The idea is coupling two motors to on propeller shaft to get the option to run any of the motor under optimum efficiency conditions under different load condition.
The father motor has around twice the power of the son motor.
So using only the son, the ship can cruise low speeds at maximum efficiency of the small motor. For maximum both motors are engaged.
This concept is used on tugboats and a specially on riverboats.
For example on some passages of the Reihn ships need very high power to go uphill but for going downhill they need only little power to enable enough flow at the ruder to maintain stearebillity.

So I have seen something very similar to this on industrial box making machines. The machine is made of many pairs of drums that pull the board through the machine and cut/print on it.
In order to adjust the registration of the cuts/prints to the cardboard there is a registration motor. You can rotate the drum in relation to the main drive bull gear. Either while the machine is stopped (for setup) or while it's running.
There are two ways this is usually done. One is actually to have a motor that is bolted to the drum and spins with the drum, like an overdrive. I think this is an older way of doing it since it was only on the older machines. The newer machines all had various complicated ways of using planetary gears to do this. Very similar to the first diagram you showed.
An interesting use of this mechanism beyond just alignment of cut/print.
As you wear down the anvil that the blades are cutting into the diameter of the drum is reduced. Meaning you have to spin the anvil drum faster than the top cutting drum or you will bend the blades on the top drum. So it can also be used as diameter compensation.
Just thought I'd share where this kind of technology is used in industry that I've seen.

That intro was lit!

Check out the old mechanical computers that were used for calculating projectile trajectories on ships during WWII. They used this same idea of summing two input speeds with a differential to great affect. There are some really good military(US Navy I think) training videos on CZcams about this topic.
Also, I really appreciate your candidness in this video. It's really cool to see people documenting their thinking and missteps.

There seems to be a common misunderstanding that two motors coupled to a differential solves the problem of creating a non-frictional-contact CVT, and I assumed that would be the claim of this video. Instead I am pleasantly surprised that you did a solid analysis of the mechanism, showing what is and is not good for. Kudos! And great work on the physical construction!

I hadn't thought about this. I'm glad you did and tracked vehicle constructors too! Do some more thought experiments and realize them. The learning can be great.

This is an extremely impressive video. Fantastic work mate and well done on being so honest about your hypothesizes.
How is the backlash? I'd be guessing that you could code the motors to reduce it to an acceptable level.

I know of at least one radio telescope that uses two motors driving a gear. By having one pushing against the opposite gear faces, there is zero backlash, and driving in either direction is simply a matter of increasing torque on one and decreasing torque on the other. It’s good for arc second stability.

Nicely done to arrive at this design on your own. As an aside, if I'm not mistaken this is more or less how the hybrid synergy drive in the Toyota Prius worked.

Same idea in some mechanism that have to be able to move fast and slow using different reductions in each motor you can achieve A+B/2 A-B/2 in both directions.
Some aircraft system that require redundancy in the motor but not in the driveshaft has similar setups.

I Would Like To See Your Rendition Of The Dual Drive Planetary. This Is A Great Video With Detailed Explanations And Good Science. Slip Gear Came To Mind For Some Reason.

An IVT from a Toyota hybrid uses the same operating principle. The benefit is that you effectively "blend" the two ratios, allowing for a combination of generation and drive, as well as the fact that you can run the electric motors in reverse, or idle them, allowing the petrol motor to run without stalling even when the output isn't operating.

A similar system is use on Aircraft to drive generators at the correct frequency, it's called a Constant speed drive unit (CSDU). At low engine speed the drive speeds the alternator up with a motor, at high engine rpm the motor is driven in reverse to lower the alternator frequency. Avionics on Aircraft are frequency sensitive unlike cars that have frequency wild alternators.

Nice video. An other benefit of such a system is that you have higher total acceleration. That is a benefit for example in a simulator where you can do very fast small motions.

Check out the "power split" transmission used in heavy off-road vehicles eg. Fendt Vario tractors. Often by splitting engine power into two paths: 1) a gearbox with fixed ratios 2) a continuously variable hydrostatic transmission. Then summing the two with a differential gear. Result is a high efficiency transmission with continuously variable ratio. Only a fraction of the total power is transmitted through the variable element, which typically has lower efficiency than the gearbox.

The CVT in IH tractors also works this way, main engine on one input and hydraulic motor on the other, then steps through gears at max fwd max rev speeds of the hyd drive.