Reinfoircing motor bell to shaft on outrunners

ElectricGod

10 MW
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Nov 1, 2015
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It is common that outrunners won't have good and reliable power transfer from the bell to the shaft. I like running from the shaft for several reasons.

1. Easy access to a wide variety of motor sprockets that either directly fit or with a small adapter will fit just about any monitor shaft.
2. The top of the bell isn't supported very well. You have a narrow tunnel up the center of the motor that the top bearing sits in.
3. If the bell flexes side to side at all, it is putting a lot of lateral force on the tunnel and the skirt bearing if it exists.
4. Running the shaft out the bottom of the outrunner maximizes shaft support and minimizes lateral loading on the bearings and is the strongest point in the motor.

I've done this to 3 outrunners so far. An Alien Power C80100 and !2090 and a turnigy CA80-160KV as well. The C80100 and 12090 have a bolt on prop adapter so modding them separate from the bell was easy. The Turnigy motor has no separate adapter so I had to pull the bell top off the bell to work it for reinforcement. It is very common that the motor shaft extends up into the prop adapter from the factory. just loosen those 2 tiny set screws and drive the shaft down so it is flush with the top of your cut down prop adapter/reinforcement block. Now most of the shaft extends out the bottom of the motor. You will be pulling the shaft out several times until you get things lined up correctly. Don't bother trying to lock anything together until you are finished and test fitting everything.

I did this over the weekend on my 12090. Some time ago, I took it apart to add halls and wasn't going to put it back together until I had the shaft reinforced. I finally got around to it. The first step was to make a block that would bolt to the bell. The bell has these 6 screws through it that the prop adapter bolts to. I reused them to mount the block to the bell. It now has eight 10-32 set screws all sitting in shallow holes on the shaft to transfer torque from the bell to the shaft instead of the two 4mm set screws it had from the factory. The Factory prop adapter takes a lot of the work out this so reuse it!

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The prop adapter is the perfect part to start from for reinforcing the shaft to bell union. Mine is stainless steel, but the aluminum one that comes with the motor is perfect.

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The reinforcement block has 6 threaded holes around it's flat face that mate to those 6 bolt holes in the bell. It also has 6 threaded holes around the outside diameter for mating to the shaft.

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I neglected to take pictures of the shaft, but it has shallow holes around its end at the same positions as the 6 holes around the perimeter of the block. Set screws thread into the block and seat in the shallow holes in the shaft. One hole goes all the way through the shaft and 2 set screws touch in the middle of the shaft. Also the bell has 2 set screws that protrude into the shaft as well. Hopefully that many cross connect points will be enough to reliably transfer 18kw of power to the shaft. Now that it's all assembled, I'll cut off the extra length of the set screws so that they don't protrude beyond the block.

12090%20bell-shaft%20reinforcement%206_zpsck1mxcms.jpg

12090%20bell-shaft%20reinforcement%207_zpst39upsfk.jpg


Now my shaft extends out the bottom of the motor so that I can eventually run a sprocket off of it. I'm not going to bother adapting the shaft yet until I'm much closer to mounting it on something. The motor is ready to go for power. This is essentially the same thing that I did for my C80100.

12090%20bell-shaft%20reinforcement%208_zps6mqnjhfd.jpg

12090%20bell-shaft%20reinforcement%209_zps0cqzngdd.jpg


The set screws for the reinforcement block...one rolled away. Notice that 2 set screws have smooth ends on them. I put those screws in my drill press and spun it up. Then I ran a file on them to remove the threads to reduce their diameter to fit into the hole all the way through the shaft. The ends of the set screws bottom out into each other in that through hole in the shaft. The other set screws bottom out into shallow holes in the surface of the shaft.

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Turnigy CA80-160KV outrunner...

Push the shaft down flush with the top of the shaft adapter. The shaft has shallow holes drilled in it's surface so the set screws can seat in them. The bell has 2 set screws in it and then the prop adapter has 4 more. All 6 set screws are 5mm and seat in a shallow hole in the shaft. When I took this picture obviously the set screws were not in place yet. The allen head screw is what I refer to as one of the "bell set screws".

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Alien Power C80100 shaft to bell reinforcement...

I pushed the shaft down so that it was flush with the adapter top. I used those four 5mm threaded holes and the cut down factory shaft adapter to make this. Two set screws bottom out in the center of the shaft. The other two in the cut down shaft adapter bottom in shallow holes drilled in the surface of the shaft. Same for the bell set screws which were 4mm and are now 8-32. The 4 set screws in the cut down adapter are 10-32.

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Excellent work! and thanks for posting this. A few years ago, these large outrunners made a lot of ES members drool thinking about the possibilities, but many RC ESC's died when trying to power these on an ebike. I was told that these motors have a problem with inductance (either have too much inductance, or too little?).

This led to several posters showing how to add optical sensors, or hall sensors onto outrunners, so they could be driven by common ebike controllers. I have to admit, though...the tiny size of RC ESCs is intriguing when it comes to stand-up scooters and ebikes. Isn't there some way to increase the inductance, or reduce it, so RC ESCs are an option?
 
spinningmagnets said:
Excellent work! and thanks for posting this. A few years ago, these large outrunners made a lot of ES members drool thinking about the possibilities, but many RC ESC's died when trying to power these on an ebike. I was told that these motors have a problem with inductance (either have too much inductance, or too little?).

This led to several posters showing how to add optical sensors, or hall sensors onto outrunners, so they could be driven by common ebike controllers. I have to admit, though...the tiny size of RC ESCs is intriguing when it comes to stand-up scooters and ebikes. Isn't there some way to increase the inductance, or reduce it, so RC ESCs are an option?

I suppose they can be used. I know you like using those 160 amp castle controllers a good bit. Most RC controllers are very poor at dealing with cogging. Most RC controllers are way too light weight for EV use. They have tiny heat sinks and the mosfets are nearly impossible to replace if needed. I've destroyed a castle ESC trying to use it on an EV. Enough of that! I'll stick with something there's a hope I can actually repair! RC controllers never support FOC or throttle curves or ebrakes or regen or variable regen or ...list anything commonly found in an EV controller. RC controllers pretty much don't have any of those things. They may do batt voltage or current, but that's about it. And they tend to max out at 12S. I've built twice at 12S and both times I went to 16S or 20S after a very short time.

I'm getting a 24 fet controller to run this motor. That won't be enough since it's an 18kw motor. I plan to build a daughter board that is another 24 mosfets...still in the TO-220 package that will only get me to around 12kw. If the controller shell can hold a second daughter board internally, I may add another 24 mosfets to get to 20kw.

My experience with adding halls is that you do better if the hall cable does not pass next to the windings. If you put your halls on top of the motor, then try to run the wires down the central tube if possible. Otherwise, just add them to the bottom of the stators like I have done so it's not a problem. The EMF inside the motor creates a lot of noise on the hall signal wires. I think passing in between 2 sets of windings induces a lot of noise into the hall wires.

Anyway, this thread is about reinforcing motor shaft to bell unions so you can drive from the shaft.

My hall thread is here. Every hall add-on I have done is in this thread.
https://endless-sphere.com/forums/viewtopic.php?f=30&t=84112&p=1315587#p1315587

Outrunners have several advantages and disadvantages vs inrunners. I use both...just depends.

1. Inrunners tend to be closed up so dirt getting into them is not probable. Outrunners are almost always open to the environment.
2. Inrunners tend to weigh a good bit more for the same wattage as an equivalent outrunner. My 18kw outrunner is almost exactly the same size and weight as my 3000 watt HLD inrunner.
3. Inrunners are almost always much more expensive than an equivalent outrunner. just look at any 6000 watt inrunner and compare with any 6000 watt outrunner. The cost is commonly 3:1.
4. Inrunners tend to not need any work on them for EV use. Mount a sprocket and you are done. Outrunners seem to always need as a minimum some shaft work to make them stout enough to drive an EV.
5. Outrunners seem to always use shielded bearings which are open to getting dirt and water in them. It is fairly common for inrunners to have sealed bearings.
5a. Larger outrunners usually have 3 bearings. Two on the shaft and a skirt bearing. This means more friction and a third point of possible failure.
6. Inrunners trap more heat inside them which means a greater chance that the magnets will get too hot. Since outrunners have the magnets on the outside of the stator, they will tend to stay cooler and not fade from heating.
7. Think of a motor armature as a lever. A longer lever requires less force on the long arm to do a fixed amount of work on the short arm. A short arm requires much more force on it to do that same amount of work on the long arm. An inrunner is like a lever where you are applying force on the short arm to do work on the long arm. An outrunner is like applying force on the long arm to do work on the short arm. This essentially means that an outrunner for same amount of wattage applied to the motor should do more work than an equivalent inrunner....just because it is a longer lever.
8. Inrunners tuck up inside frames and other tight spaces with little concern for catching on wires or anything else. An outrunner needs to be clear of nearby objects since it has a spinning bell.
9. This one is up for debate IMHO. Inrunners, since the stators are on the motor can, should dump heat better than outrunners. Outrunners have the stators compactly fit in the middle of the motor. It's my opinion after having several inrunners that they get quite hot. I have to put a blower on them to force air through the motor if I intend to run them hard. Their ability to radiate heat even with added fins on the shell is not as good as an outrunner. Outrunners on the other hand have a built in fan and the stator doesn't seem to get anywhere near as warm.
 
I posted this in my halls thread found here...

https://endless-sphere.com/forums/viewtopic.php?f=30&t=84112

But since reinforcing the bell to shaft union requires taking your motor apart, I thought it would be good to post it here too. This is essentially a word for word duplicate of my other post.



OUTRUNNERS:

If your outrunner has a bell top and your shaft doesn't extend out the bottom of the motor, you will need to remove the bell top so you can pull the armature/bell from the top of the motor. If your outrunner has already been modded, like all of mine are, so the shaft extends out the bottom of the motor, then you can push the shaft and bell off from the bottom of the motor. My Alien Power C80100 is currently in parts on my bench so I can add new halls to the bottom of the stators. I'll post some pictures later of how I pushed off the armature when I do that actual post for adding halls to it.

Follow one of these 2 sets of steps to get the armature/bell off the stators on an outrunner.

Note about pulling motor bells:
The cylinder portion of the bell can be quite difficult to pull off the stator because the magnets are strongly attracted to the stator. They are N35 or stronger so they are going to pull quite hard on the stator. Just about any 80mm stator is going to be strong enough to get away from you and possibly cause magnet damage, but they can be pulled off with muscle strength alone. I strongly recommend NOT doing that. A 120mm stator and magnets is so strong that I recommend NOT using brute strength...NOT EVER. I always use a puller to remove the motor bell and to put it back on.

*** Using a 3 jawed puller to remove the motor bell keeps everything moving slowly and in 100% control. There is virtually no chance of losing control of the motor bell and accidentally damaging the magnets.

1. If your motor shaft does not stick out the bottom of the motor sufficiently to be used to push the bell off the stator, then do this.

a. Remove the bell top from the motor. Outrunners are made where the bell top is a separate part from the cylinder. They are usually held together via small screws and then the two parts of the bell need to be separated at the joint between them. I use an old kitchen knife and tap on the back edge of the knife to wedge it into the crack between the two parts of the bell. Usually it take 5 or 6 spots around the bell to get the top to start seperating from the bottom part that holds the magnets. I then move on to using a screw driver in the gap to widen it further. On my AP 12090, the top is inserted into the bottom by about 1/2", but by about 3/16" it will come off in my hand.

b. if the shaft is still in the motor, push it out down or remove it so it is out of the way of the top of the motor.

c. Remove any screws that hold the skirt bearing to the bell

d. You want to protect the top shaft bearing and the motor windings. The shaft bearings are not designed to take anything other than radial stresses so pushing laterally on the bearing is probably going to do damage. I use a thick washer on top of the bearing to take the load. A piece of plywood or a thick metal disk would work too. The bearing never sees any lateral loading and is protected from damage. A little tape over the tops of the windings keeps them safe from damage.

e. Pullers all have a center screw and 2 or 3 jaws typically. The screw can impact the magnets so I wrap a few layers of tape around it's diameter down by the end of the screw. This provides a cushion between the steel screw and the magnets to help prevent chipping or breaking a magnet.

f. Put the puller jaws around the motor bell. Most larger outrunners have vent holes above the skirt bearing. That's a good place to seat the jaws. The bottom of the bell works to.

g. Tighten the puller screw until it's snug and centered over the top bearing. If the puller jaws won't stay seated around the motor, wrap a few layers of tape tightly around them and the bell.

h. For a typical 80mm stator, I can turn the screw by hand and pull the bell off. For my 12090 and it's 120mm stator, I need light help from a wrench to get the bell moving. If you need more than light pressure on the screw then something is binding up or you forgot to undo something.

I. If your motor has a skirt bearing, it might want to stay in the bottom of the bell and possibly impact the bottoms of the windings. Pry at it as needed to keep it coming out of the bell.

j. Keep turning the puller screw until the magnets clear the stator teeth by about 1/4". At this point, you can probably pull the bell off with your hands easily. I say clear the magnets from the stator because it is possible you might slip or who knows what and if they are not 100% separated, you may impact a magnet on a stator tooth and chip the magnet.

k. Set the motor bell aside where it can't attract metal objects and get to adding halls to your motor. Leave the puller exactly where it is. You will want it there when you put the bell back on the motor.

l. Later reinstalling the bell is the exact opposite process of pulling it off. Use the puller to slowly lower the bell back onto the stators.


2. If your outrunner is like all of mine, then the first thing I do is modify the shaft. I add more support between the bell top and the shaft. I push the shaft down so it's flush with the top of the bell and is protruding out the bottom of the motor. This makes removing the bell later super easy. SO...do this if your outrunners have the shaft protruding out the bottom of the motor.

a. Undo any screws that hold the skirt bearing to the bell.

b. Place the jaws of the puller in the gap between the bell and the motor base.

c. Run the puller screw down until it's snug with the end of the motor shaft.

d. Start turning the screw. For 80mm or smaller motors, hand strength on the screw is probably enough to separate the bell from the stator. For larger motors, you may need light help from a wrench. At no time should you EVER need to crank on that screw with more than light force. If you do, something is binding up or isn't removed yet. That might be a circlip on the shaft or a screw in the skirt bearing.

e. The skirt bearing may want to stay in the bottom of the bell. It is possible it will ride up and impact the bottoms of the windings. Pry at it as needed so it comes out the bottom of the bell.

f. Turn the puller screw until the magnets clear the stators by about 1/4" and then pull it off the rest of the way by hand. You are pushing against the motor shaft which is attached to the bell and pushing the whole thing off as a single unit.

g. Set the bell aside where it can't attract metal objects.

h. Later reinstalling the bell is the exact opposite process of pulling it off. Use the puller to slowly lower the bell back onto the stators.

INRUNNERS:
I use a puller or possibly I put the motor shaft in a bench vice and then pull on the motor can to separate the armature from the stators. Both will work. Most inrunners have fairly large can diameters so you need really large pullers to get around the can and then to push on the motor shaft to slowly eject the armature. If your inrunner has vent holes, they can be used to attach to the motor shell so the puller screw can push on the shaft. Most inrunners have removable end plates that are held on with screws. Sometimes those screws can be partly loosened and the end plate is separated from the motor can enough to get the puller into the gap. Some end plates have threaded holes for mounting the motor. I've used them and made up an aluminum plate that matches those holes and then screwed the plate to the motor. This provided the purchase needed for the puller jaws. Sometimes there are no options like this and then I take the end plates off and put the motor shaft in my bench vice and just pull the armature out. I can't be as methodical with inrunners as I can be with outrunners, but also the chances of magnet damage are less too.

Regarding pullers...
1. 3 jaw pullers are more stable and less likely to fall off or shift than are 2 jaw pullers. I prefer 3 jaw pullers for this reason.
2. They can be found at most automotive parts stores, hardware stores, amazon, ebay, etc.
3. They come in different sizes. I have 3. The smallest one is perfect for 80mm motors. It's a 3" puller. The next one has only 2 jaws and if it had 3 jaws wouldn't fit on my 12090 outrunner. It is categorically a 4" puller. For 120mm motors, get a 5" 3 jaw puller. Anything smaller is going to be too small to get around the motor bell. My big one is 6" and I've only every used it when working on cars.


Other things to consider while you have the motor apart...

1. This is a perfect time to go find sealed ceramic balled bearings that fit your motor. Don't bother with fully ceramic bearings. They cost a fortune and have slightly less friction than bearings with ceramic balls only. All ceramic bearings have about half the internal friction of all steel bearings. Bearings with ceramic balls have a little more friction that all ceramics, but still much less than all steel ones. All steel bearings typically come on everything. They work and are cheap, but you pay for it in more friction. Motors commonly come with shielded instead of sealed bearings. Sealed bearings keep dirt and water out and grease in. Shielded bearings like your motor has do not and so they will fail prematurely from road grit, water and loss of lubrication. The seal creates a small amount of friction, but if you use ceramic balls, that still adds up to much less than shielded steel bearings and they will last 4X longer. I use sealed ceramic balled bearings everywhere I can.

2. Add a second set of halls.

3. Add a temperature sensor. They are super cheap and can be purchased on ebay, any electronics parts stores or scrounged from your kitchen digital thermometer. I get cheap Chinese digital temperature gauges that I put on my EV's. I get them on ebay for $2-3 each. They include a sensor. I cut off the wire that goes to the sensor long enough to be the same length as my hall wires coming out of the motor. The sensor gets mounted in the windings some place convenient. Use the cheap meter or something else.

4. If it's an outrunner, just about all of them have inadequate support between the bell and the shaft. If you intend running from the shaft and I recommend doing so, then reinforce the shaft to bell union. This is my thread on that subject. https://endless-sphere.com/forums/viewtopic.php?f=30&t=90264


A few notes about magnets...
1. All magnets including ceramic ones are brittle and chip easily.
2. Neodymium and samarium cobalt magnets are REALY UBER brittle. They chip super easily and break easily too.
3. A chipped magnet will still work, but is less effective than a whole magnet and your motor is a little out of balanced now too.
4. Neodymium is usually coated in nickle or copper. This coating is to protect the magnetic material from corrosion. Neodymium rusts and oxidizes very easily and quickly. I have a small neo I use for testing halls. Some time ago, I decided to peel off the chrome coating. Mys kin oils were enough to immediately corrode the neo material a little. In a motor exposed to weather, rain, whatever, this process would be more significant.
5. Neo magnets are the most commonly used magnet type in BLDC motors. There is a very high chance that 100% of your motors have neo magnets. They are strong and attract ferrous objects with lots of force. When a magnet starts pulling on something. The acceleration is very fast. There is little chance you will stop the metal object from impacting with a magnet. Most likely the magnet will get chipped or broken. Don't let this happen. Keep your motors magnets away from loose metal objects!
 
I have just purchased 3 Revolt outrunners (RV-100E, RV-100-Pro and RV-120-Regular) and already have an RV-100-Regular.

I was going to have Revolt do some shaft work for me, but they were such a PITA about even deciding what I wanted despite multiple drawings, pictures and descriptions, I finally just gave up trying. I'll just do it myself after I receive the motors. They are currently on a ship on their way to me.

All Revolt motors use keys on the shaft to bell union, but I doubt they are stout enough to last long term. For example I have an RV-100-Regular and it uses 3mm keys into aluminum in the bell. I have never loaded the motor heavily to know if those keyways will hold up or not, but I am skeptical. In this motor, there's about 6kw (8hp) of force on about 1.5mm x 13mm of aluminum in the bell. I expect the aluminum will deform and once it does, those key ways won't last. As a result I'll be reinforcing the bell to shaft union in a similar way that I have done with the Alien Power outrunners.

I found a motor coupling part used for coupling the output shaft of a motor to something that needs to be driven. This part is designed to allow some amount of movement and offset between the motor shaft and the driven shaft. I'm using the part that mounts on the motor shaft and adapting it for reinforcing the shaft to bell union. Here is a common part found on Amazon or ebay. I've found these hubs for around $6. There's other OD's besides 41mm. The 35mm size is too small for my uses and the larger ones (55mm) are too large for the typical outrunner I'll want to reinforce. There is a competitor to Ruland that makes hubs out of steel, but they are easily 3X more weight and I don't need the extra strength. The Ruland hubs are machined aluminum and come in a variety of ID's. You should have no problem finding an ID that matches your shaft diameter with a 41mm OD. I have purchased several in 10mm, 11mm, 12mm, 14mm and 15mm. I need 12mm and 15mm, but drilling out the smaller sizes is not a problem.

https://www.amazon.com/gp/product/B016APQ26Y/ref=ppx_yo_dt_b_asin_title_o05__o00_s00?ie=UTF8&psc=1

These 2 small keys and ways in the shaft and bell will be used still, but they are insufficient and too weak by themselves.

Dual%20keys.jpg


RV-100-regular%202.jpg



These Ruland hubs come with 2 set screws in them already. I'll be drilling those threaded holes out a bit larger and also adding at least 2 more positions for more set screws. This is the 12mm ID version which is perfect for the RV-100-Regular and RV-100-Pro which both have 12mm shafts.

Ruland%20MOST41-12-A%20hub%201.png


This is a close-up of the flange on the hub. I've historically screwed down the reinforcing disk to the top of the motor. AP includes a removable prop adapter with their motors so reusing the adapter and screw holes makes sense. Revolt does NOT include any extras with their motors and that includes no threaded holes in the bell top. I'll be using these flanges on the hub part to engage the bell. It will require I drill and file out 2 square holes in the bell top that fit those square flanges. I'll also run a couple of small screws through the underside of the bell and into the hub part just to make sure they hold together securely. Some M4 button head screws will do the job.

Ruland%20MOST41-12-A%20hub%202.png
 
In my last post, I showed the Ruland hubs. I never got around to reinforcing the bell and shaft on the 100-regular. I had to move to a new house and other life details kept me from it. I recently acquired a Revolt RV-120-regular and have completed reinforcing it.

The bell/shaft has 2 4mm x 8mm keys and that's lots better than any Alien Power outrunner with their super weak set screws. Still, this is insufficient for long term reliability. The key ways in the bell are 13mm long. Revolt could have easily used 12mm keys and didn't. In the Regular motors, Revolt misses lots of details. I noticed similar lack of attention to details in the RV-100-regular.

RV-120-reg%20armature%204.jpg


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I pulled the motor apart and the shaft has shoulders on it. I want to push the shaft downward and those shoulders on the shaft are in the way.

RV-120-reg%20shaft%202.jpg


I made this disk for reinforcing the bell to shaft union out of a Ruland hub. I've done something similar on several AP motors to strengthen them. I ground off the shoulders on the shaft. It's now 15mm it's whole length and can be shifted as needed.

RV-120-reg%20reworked%20shaft%20and%20reinforcing%20disk.jpg


I milled off the features from the bottom of the Ruland hub, then drilled and tapped it for 4 set screws into the shaft. There is a key way in the top of the shaft. A small portion of it was still accessible so I used a cut down key to lock the bell to the shaft for drilling the top of the bell.

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Sorry for the crappy images. I forgot to take stills of the shaft end so I had to do screen shots from a video I made. There's 4 shallow holes in the end of the shaft. The tips of 4 set screws will land in them for gripping onto the shaft. This is very reliable and easy to implement with nothing more than a drill press. The shaft is very hard steel. HSS drills tend to dull quickly in steel of this hardness. I drilled the shallow holes with a carbide drill.

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These reference marks on the bell top and disk are here to make sure assembly and disassembly are always the same.

RV-120-reg%20shaft%20to%20bell%20reinforcing%205.jpg


I think this turned out nicely and will hold up to whatever amount of torque this motor can generate. It's probably stout enough even without the 2 keys in it. Each screw threads into about 1/2" of bell material.

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This is the best work I've done so far. It still lacks a lot of precision that a mill could provide, but is very usable and doable on a drill press and few other tools.

This morning I transferred this 6 bolt pattern from the top of the RV-100E motor bell to paper.

RV-100E%20bolt%20pattern%202.jpg


RV-100E%20bolt%20pattern%201.jpg


I try to short cut this process by using something ready made. The 6 bolt pattern on the bell top is larger than a Ruland hub. I had to start 100% from scratch. I started with a square of 3/8" thick 6061 aluminum and stuck the paper bolt pattern down to it with double sided tape. I drilled and tapped the center for M6 so I'd have a center point to hold in my 3 jaw chuck. This allowed me to drill the bolt pattern on my rotary table. Perfect match!

Revolt%20RV-100E%20shaft%20reinforcing%20disk%201.jpg


I used the 6 holes and M5 screws to create a way to hold the 6061 so I could mill it round. The OD is not the final size.

Revolt%20RV-100E%20shaft%20reinforcing%20disk%202.jpg


Revolt%20RV-100E%20shaft%20reinforcing%20disk%203.jpg


I wanted to mill the ID to 14.5mm for an interference fit with the 15mm shaft. From time to time due to slop in the drill press, the mill will chatter and possibly grab the material being worked. Of course there I was at 14.5mm and this is exactly what happened! The ID had a pretty big gouge in it before I could get things under control again. GRRRR! I needed to mill out the ID to 17mm to get past the gouge. Fortunately the carbide end mill was undamaged. I have some aluminum tube with a 19mm OD and 14mm ID. I milled out the disk ID to 18.5mm so I''d have an interference fit with a section of the tube. Pressing the tube section into the ID was a tight fit! A little careful milling brought down the tube section to flush with the top and bottom of the disk. It won't ever come out again and fixed the chattering mill SNAFU. Fortunately I had no further issues with mill chatter and got the ID to 14.5mm the second time.

Revolt%20RV-100E%20shaft%20reinforcing%20disk%204.jpg


Revolt%20RV-100E%20shaft%20reinforcing%20disk%205.jpg


I bought 4 and 6 sided collet blocks and 12 and 15mm collets so I can securely hold shaft. I needed 6 flats on the shaft for the set screws in the reinforcing disk. The 6 sided collet block made milling 6 flats super easy and accurate.

Revolt%20RV-100E%20shaft%20reinforcing%20disk%206.jpg


Revolt%20RV-100E%20shaft%20reinforcing%20disk%207.jpg


The shaft inside the disk is a perfect fit.

Revolt%20RV-100E%20shaft%20reinforcing%20disk%208.jpg


Right now the OD is a bit over sized. I milled flats on the perimeter so when I drilled out the 6 set screw holes, the bit would not wander. Right now the disk looks a bit misshapen, but that gets fixed in a minute. I drilled out a single set screw hole more or less free hand. Once it was tapped, I could use a set screw in it to keep the disk from moving on the shaft. The collet block made the other 6 holes easy. This is all 6 set screw holes drilled and tapped and seated on the shaft flats.

Revolt%20RV-100E%20shaft%20reinforcing%20disk%209.jpg


I bit more milling of the OD got it down to size and back to round. I also drilled out the 6 screw holes so the bell screws are inset in the disk.

Revolt%20RV-100E%20shaft%20reinforcing%20disk%2010.jpg


Looking good!

Revolt%20RV-100E%20shaft%20reinforcing%20disk%2011.jpg


Revolt%20RV-100E%20shaft%20reinforcing%20disk%2013.jpg


Revolt%20RV-100E%20shaft%20reinforcing%20disk%2014.jpg


Revolt%20RV-100E%20shaft%20reinforcing%20disk%2015.jpg


I still need to mill out the mating keyway in the new shaft.

Revolt%20RV-100E%20shaft%20reinforcing%20disk%2016.jpg
 
I didn't really know where else to put this. A friend of mine is building a small scooter and I told him to put a C80100 outrunner on it. He was thinking of running the factory brushed motor at higher voltage, but I got him to go for a good bit more power. He sent me his old motor shell so I could modify it for mounting the outrunner inside.

First thing I needed was to create a shoulder inside the old motor can so that the C80100 motor base could securely seat in the motor can. Since the motor base is 1/4" thick, the shoulder is 1/4" deep. I did the motor can work a couple of weeks ago.

Reworked%20motor%20shell%201.jpg


Reworked%20motor%20shell%203.jpg


The back edge of the motor can had a sharp ledge on it so I milled it off.

Reworked%20motor%20shell%202.jpg


Today I finally got time to make the motor base. The circle of holes are for venting. The 4 countersunk holes mount the motor. The aluminum plate is an interference fit in the can ID. There's not much chance it will ever come loose.

Completed%20motor%20shell%204.jpg


Last step...drill holes around the perimeter to secure the plate to the can. And I messed up a hole.

Completed%20motor%20shell%203.jpg


Ah well...5 M4 screws is better than none. I doubt the plate will ever come loose without this, but now it's certain to never come loose.

Completed%20motor%20shell%201.jpg


Completed%20motor%20shell%202.jpg
 
Last time I did one of these, I didn't have an index block and my drill press wasn't set up for milling. Now it is, so I now can do things like you see above and below.

This is the motor shaft before modding. It has 2 flats on it for the set screws in the bell top. IMHO, they are insufficient for long term reliability. I don't need the threaded section so that got cut off and then the entire shaft got shifted down.

C80100%20motor%20shaft.png


I cut off the threaded end of the shaft and then milled it flat. Then I milled the end of the shaft with 4 flats. The 2 long ones catch the set screws in the bell top and the set screws in the reinforcing disk. The shorter flats are for the other 2 set screws in the disk.

C80100%20mod%20and%20base%204.jpg


C80100%20mod%20and%20base%205.jpg


The reinforcing disk used to be the prop adapter. I cut off the top section and then milled off the little bit of a shoulder. Then I used my index block to drill 4 holes around the perimeter for 4 set screws. This is it mounted to the motor bell.

C80100%20mod%20and%20base%206.jpg


C80100%20mod%20and%20base%203.jpg


C80100%20mod%20and%20base%208.jpg


This is the motor bottom screwed down inside the old motor shell.

C80100%20mod%20and%20base%209.jpg


The motor fits pretty nicely. I still need to take about 1" off the length and drill holes for pins to catch the sprocket adapter. The hole the wires come out needs to be a bit larger so the hall cable connector can fit.

C80100%20mod%20and%20base%2011.jpg


A decent amount of room around the outrunner. The irony is the C80100 is half as heavy, a lot smaller and about 8X more powerful than the factory brushed motor.

C80100%20mod%20and%20base%2012.jpg


C80100%20mod%20and%20base%2013.jpg


The factory shielded bearings get replaced with sealed ones. The skirt bearing is on order...be here in a day or 2.

C80100%20mod%20and%20base%202.jpg
 
This motor is a tight fit where it is mounted. There's no room for an external disk and any added length. I had to reinforce the motor to shaft union internally instead.

I added set screws to this sloped section of the motor bell.

Bell%20union.png


Set up is a bit complex. I needed to angle the drill press table at 40 degrees to match the angle on the bell section. I also needed to secure the shaft to the bell so at the same time I could drill the shaft. Since the shaft is hardened, I needed to use a carbide drill. The shaft is held in a 4 sided collet block in my cross vice. Getting the location right was a bit challenging. I wanted the set screws into as much aluminum as possible for good support and NOT extend out the top of the bell. Clearing the drill press so I could drill was a problem too.

Bell%20to%20shaft%20reinforcing%201.jpg


Bell%20to%20shaft%20reinforcing%203.jpg


Bell%20to%20shaft%20reinforcing%204.jpg


The holes are drilled at 4mm for M5 set screws.

Bell%20to%20shaft%20reinforcing%205.jpg


I pulled off the bell top and then using an end mill I milled out the angled hole with a flat bottom to more securely seat the set screws in the shaft.

Bell%20to%20shaft%20reinforcing%206.jpg


There are 3 M5 set screws in addition to the key way.

Bell%20to%20shaft%20reinforcing%207.jpg


Bell%20to%20shaft%20reinforcing%209.jpg


All reassembled and no added height to the motor.

Bell%20to%20shaft%20reinforcing%2010.jpg


RV-160-SH%20finished%202.jpg
 
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