DIY Pedal Build - Load Cell, Linear Pot & Clutch Cover

This thread will cover the design and build of my sim racing pedals.

First a few photos of the work so far before I get into the detail.

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The Brake Pedal (work in progress)

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The clutch pedal (Work in progress)

Background:

I used to play Grand Prix Legends back in 2000 with a red Logitec wheel and pedals, dial up internet and a large speaker behind my seat (early tactile!) Then I stopped to concentrate on the build of my race car, which I developed and competed in. It was sold 8 years ago.

Fast forward to 2019 and I happen to see modern day sim racing on you Tube and was very impressed and decided I needed to get back into it.

After lots of research I decided I could build my own pedals quite cheaply. I had previously built a car from scratch, have a work shop with a lathe and TIG plus lots of material left over.

I intend to build the pedals using as much material from stock. So the designs may not be perfect but they make use of the material I have.

Electronics

Using Leo Bodnar components, it appears to be very easy to make transducer and load cells into game controllers. Time will tell if it is really that easy!

Brake

My race car experience taught me that it is easier to modulate pressure than movement, this then dictated that I need a load cell based system rather than a rotary or linear potentiometer. I looked at beam, button and S load cells and looked at prices.

My original plan was to use a beam vertically and mount the pedal directly to it, so in effect a solid pedal. Talking to the electronics guy at work I was advised that the cheap Chinese load cells do not tolerate any side loads, so this idea would not work. He also advised not to overload the load cell.

To get straight motion on the load cell I needed a linear bearing. My race car also had a small about of pedal travel then went solid. So I wanted to replicate this feel.

To understand brake loads so I could specify a load cell I put my bathroom scales in the passenger footwell of my car and pressed hard and noted the loads. I could press 50kg, which equates to around 500N. With leverage and availability I decided on a 100kg (1000N) beam load cell.

Most commercially available pedals feature large amounts of adjustability. I decided I didn’t need this as I was making them for me and not trying to replicate a particular car.

I also considered a hydraulic set up but considered it too complex.


Clutch

I decided I wanted a clutch. I looked at many designs to understand how to get the correct pedal feel of a clutch (increasing pressure then less pressure). All these designs needed springs. I quickly realised that springs are expensive. Plus, I probably would have to play with rates to get the correct feel. That would take time and cost money.

So, I decided to use a real clutch cover. A quick look on eBay indicated new ones can be had cheaply. That would definitely give the correct feel. Originally, I was going to use a master cylinder and concentric release bearing, but then I realised I was again making it over complicated. Why not have a mechanical direct acting set up? It is only a matter of getting leverages correct. Hydraulics give mechanical advantage just as levers do.

I kept an eye on eBay looking for a new small diameter cover, plate and release bearing. Eventually I bought a new small Renault kit for £14 delivered!

After discovering linear bearings I decided linear bearings would be ideal to actuate the clutch.

A rotary pot will be used.

Accelerator

Originally, I was going to use a rotary pot but was concerned about only being able to use a maximum of 120 degree of rotation. I have read articles stating it doesn’t matter that you are not using the whole rotation but I thought if I could it will not harm. I looked at many ways of converting linear motion to rotary such as rack and pinion, cable around a pulley and increasing rotary such as gearboxes but decided that a linear potentiometer would be best. The only downside of linear pots is cost, but I found a couple of options at reasonable cost.

I also looked at hall sensors and discussed them with the electronics guy at work but decided they were not the best solution.

Having discovered linear bearings I decided to use them for the accelerator too.


Brake Detail
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The brake is a linear bearing block mounted on a block of aluminium. A 16mm dia rod slides through the middle. A 100kg load cell is bolted vertically. The advantage of the block is it is easy to keep everything square and in line, plus is easy to drill and tap into.
There is a rubber buffer acting on the load cell. This screws into the 16mm dia rod. It is set up with a small gap to the load cell. This will give the initial slight pedal movement.
At the pedal end a Lancia Integrale inner valve spring (had it in stock!) ensures the pedal returns and there is some initial pedal pressure.
The pedal pivots on cartridge bearings which are old ones from my mountain bike pivots. To be honest bearings are not really required due to the very small amount of pedal pivot but as I had them it was cheaper than buying plastic bearings or bushes.

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Detail of the pedal end of the linear bearing block. The aluminium disc between spring and linear bearing is held onto the linear bearing with Loctite 638 bearing fit.
The spherical rod ends are M6.

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Detail of the rubber buffer and aluminium spacer.




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This photo shows how I ensured the linear bearing block was mounted inline. Using the 16mm rod I was able to check everything was in line. The fact that the rod was long amplified any error and made it easier to ensure it was straight.


The 16mm rod is surface hardened. The only way to cut it to length was to grind it using a 1mm thick cutting disc. It was also hard to tap. I had to turn the tap a few degrees and then back it off. Time consuming but I didnt want a tap breaking off in the rod.

Work to do on the brake
Brackets to hold the block onto the box section
Brackets to hold the spherical bearing to the pedal
Spacers either side of the spherical bearing
Weld everything up - My gas has run out and now lock down is easing I should be able to get some more.
Mounts to my rig (which I will build)
Tactile

Tactile
I intend to add some tactile to the set up. First thoughts is an exciter to the pedal stem. I can easily isolate the above set up and isolate my heel pad. In fact I can easily isolate every pedal and every heel plate separately from each other and the rig. My plan is to build this in so I can add tactile as I learn about it / choose what to do.
I am currently researching isolators so I know the best to use.

Next time the clutch.
 

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The Clutch Pedal

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The clutch pedal uses a clutch cover bolted to a thick piece of aluminium (flywheel). There are two linear bearing blocks, one each side of the clutch and a 16mm rod runs through the clutch. The release bearing is fixed to the rod. The pedal will push the rod and activate the clutch.


The first job was to mount the cover to the dummy flywheel (aluminium plate). It was drill and tapped so I could bolt the cover on. I didn't bother with dowels like on a flywheel as they are not required.

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The aluminium plate bolts to the two large diameter bosses at the bottom. These will be welded to the rest of the pedal.

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The linear bearing on the back side of the aluminium plate.

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Side view of the assembly

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The thrust bearing was removed from its plastic housing and I turned an aluminium housing. This will be attached to the 16mm rod with Loctite bearing fit. I hope it will hold, otherwise I will pin it, though the 16mm rod is case hardened so I will probably struggle to drill it.

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I didn't know how much movement was required to release the clutch plate. So I rigged the cover and plate up in the lathe and pushed the release bearing with the tailstock. I was surprised that it only took 7mm of travel to release the plate. I needed to know this measurement so I know how much travel to allow with the 16mm rod.
The pedal travel will be around 35mm which is similar to my race car clutch. That clutch was on / off


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Details of the pedal pivot. The bearings are from my mountain bike pivots. They will be held onto to the inner shaft with Loctite 638 bearing fit. The bearings will also be held into the brake pedal with 638. I love Loctite as it removes the need for mechanical fittings such as circlips to hold bearings in. It is also much easier to machine the parts as I dont need to make them to such a tight tolerance.


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M6 spherical rod ends connect the pedal to the 16mm rod. The socket is there to hold things in place for the photo.


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The blue lines show where I will put thin tube members to support the top of the clutch.
The red is where the rotary pot will go. These will be added once I have welded the rest together. I need to be careful in the order I weld things to ensure alignment of the 16mm rod from one linear bearing to the other.
 
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Thanks for the detailed description! Fun build.

I wonder, do you really need the bearing on the back of the clutch plate? I would think the first linear bearing would do all the work. If you omit the back bearing and just leave a clearance hole then you can have much looser tolerance for your welding.

Looking forward to the rest.
 
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Accelerator

I have been working on the accelerator over the last few weeks. I spent quite a bit of time researching linear potentiometers. Many of the cheaper ones only have a life of under 100,000 cycles which I calculated wouldn't last that long. There are plenty around with long life but many are over £100. However I found a good range from Variohm Here for reasonable money. I bought mine from RS Components and went for a 50mm long version.
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I used linear bearings to make a sliding carriage that would operate the transducer. As the linear transducer is quite delicate I wanted to ensure it didn't get any side loads.

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I have two 8mm rods with linear bearing blocks sliding on them. I can fine tune the length of motion by putting washers on the rods to restrict the movement of the carriage.

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The picture above shows how the pedal will be arranged.

Originally I was going to have a compression spring on one of the bars.
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One rod (top in this picture) would control the length of the carriage and the bottom rod would hold the compression spring. However I didn't follow this route as I struggled to buy at reasonable cost a decent long compression spring. Also I wanted to keep all the forces on the carriage low without twisting forces.

I am now going to use tension springs, which I will cover in a further installment.

I also started to think about pedal spacing and mocked up some pedals to see what spacing I would need. Plus i had to ensure I could heel and toe. The pedals will have foot plates on them.
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I have decided on 130mm pedal spacing. Ideally my accelerator would be closer to the brake but due to my tactile plans I need equal pedal spacing as I am going to have heel plates that can change over so I can either connect the brake and accelerator or clutch and brake depending on if I am using 2 or 3 pedals. I plan to have a transducer at each side of the pedals. There will be more on this later.

I have also been thinking of how to isolate the pedals and will probably mount my bobbin isolators horizontally as fore and aft is the direction of the main loads, not up and down.

Seat sliders have been purchased to mount the pedals on. This will mean I can slide the pedals forward so my young sons can reach them.

I also bought a race seat from Ebay. It is a Motordrive seat ( NOS (new old stock)) which is made in the UK and though not as well know as Sparco, Cobra, Corbeau etc is an excellent seat. It fits me well.

Next jobs:
Get my gas refilled for my TIG - now lockdown is easing I can get out and get it filled.
Weld up the pedals
Buy the electronics
Mount the pedals to the seat sliders with isolators and mounts for the transducers.
 
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The pedals are finally finished. Sorry about the lack of updates but I thought I would do one large one at the end.

After reading nearly all of the Tactile thread I started on the SFX100 one (always dangerous) and read all the pages and decided if I was going to build a rig I may as well do it right first time. This made me want to reduce weight. I know the actuators will lift a lot of mass but the lighter the rig the faster the response so i started lightening my pedal set up which created more work!

I worked on easy gains and that was the clutch. I bolted it to the face plate and bored out the centre.

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Also bored out the block that held the brake load cell.

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The box section holding everything together had lots cut out.

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The top and bottom had sections cut out. I drilled a hole in each corner and then cut the metal out using an angle grinder with a 1mm wide cutting disc, finishing off with a file to smooth things off.

Isolation

As I intended to add tactile at some stage I isolated the pedals. each pedal is individually isolated.

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I have 4 vertically mounted ones for each pedal plus the option to have 2 horizontal. Only one is fitted in the this picture.
 
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Heel Plate.

Even though all the pedals are individually isolated for now i will have a single heel plate. This can easily be split in future.

To get all the holes in the correct place on the plate I made a little screw in centre punch.

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The aluminium plate was placed on top and tapped. This left a nice mark which could be drilled. This was repeated for every hole.

The plate fitted perfectly. 5mm dia holes for M5 bolts.

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This picture shows bolts but I later countersunk the holes so I could fit countersunk bolts for a flush surface.
 

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More Pics.

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I dislike wiring and try to keep it as neat as possible.

This is the Bodnar LC board on isolated mounts.

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I worry about wiring. Most faults are not actually electrical but mechanical. I have tried to reduce cable bending in critical areas by adding supports.

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The picture below shows the support for the throttle potentiometer.

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Pot rod mount on clutch pedal

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(Whats that in the background??)

Clutch pot with radio controlled servo arm
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More Pictures

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The parts were cleaned with thinners, rubbed down with scotchbrite and then sprayed with etch primer and satin black all from tins.

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Pedal bearings were held in with Loctite bearing fit. This is amazing stuff and was also used to hold the accelerator pushrod together.

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I was worried about getting the signals to the PC. I used a Bodnar LC board with inputs for 2 pots and a load cell.

It was actually very easy. i updated the firmware, wired everything up and I was amazed it worked!

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On the Bodnar configuration software you can alter the gain. For the throttle pot because I was utilising nearly all the length of the 50mm pot the gain is practically 1.

For the clutch pot, which only utilises about 90 deg of the 300 or so degree I need more gain to get a full sweep of the bar.

I cant tune the brake yet until the pedals are in a rig where I can press really hard. As the load cell is 12V and I am exciting it with 5V I think I may need a lower rated load cell. This one is 100kg but with pedal ratios should be about 50kg.

It is easy to buy new load cells if required or crack up the gain in the cofig tool. Though I am thinking it will also amplify noise so is better as low as possible.
 
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Whats next?

I have some 100mm aluminium profile on order from Kinetik for my actuators, bought a small Mige for an OSW and have £100 of steel on order to build a space frame rig to hold it all together.

I dont yet have a PC and will not build one until the rig is finished by which time hopefully the current GPU situation will have calmed down.
 
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I'm also build a set of pedals using real car parts (see above).

Its funny though....you went with a real pressure plate for "clutch feel"...which I'm not terribly fussed about. On the other hand, I've gone with a real throttle assembly for throttle feel: throttle pedal, throttle cable, and throttle body (all from an MX-5).
 
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I do wonder if all the effort for the clutch is actually worth it and how much it will get used. But it is built now so I will use it. It does feel like the paddle clutch I had in my car, very much on and off.

I did consider a throttle body with cable but I am not out to replicate a car, plus the package was larger and the cost higher (I didnt have any parts in stock). I just wanted the smoothest throttle pedal I could get with maximum travel of the linear pot.

My brake pedal is constructed from 25mm x 25mm x 1.6mm box section and weighs about 300g. I wouldnt have wanted to go any smaller with the potential forces.

There are places which in hindsight I could reduce sizes such as the brake pushrod. This is 16mm and could have easily been 8mm. Thinking back to what size the pushrods were on my AP racing master cylinders these were quite small.

Hopefully I will not over engineer my space frame rig but I will see.
 
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This provoked me to realize what is missing from throttle feel, namely inertia of linkage and throttle bodies. I added mass to free end of throttle pedal, for a subtle improvement.
 
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