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Thanks for the reply. 
Wheel chocks on front wheels, strap the rear wheel to the ramps with compression straps.....who know what else....lower the tire pressure. All to avoid taking everything apart😁.

Let you know what happens. I have read about a gear driven torque multiplier. Maybe my Snap-On buddy can give me some insight.

Yea, this is a sucker to do. I didn't have access to a torque multiplier so I had to do it with a 4 foot pipe on a 1/2" breaker bar.

 

I made a 1/2" thick plate that went over the wheel studs and welded an arm to it, then did it on the car using the car lug studs to hold it in place, the bar turning against the floor.

That is so much leverage that you need to be careful you don't pick the car up off of the floor when you stand on the pipe.

 

I think I tried it on the workbench like in the above picture but I tore the vise loose from the top it being only 3/4" plywood.  I figured on the car was "safer". (Yea, that's the term...safer)

 

For the weld, you need to go back to your "strength of materials" class and calculate the size of the weld needed with an e60 electrode. It's pretty big and the "stick welder" was on like 150 amps.

I calculated that if I stood on the "arm" being 220 pounds that at 36" when the nut wouldn't turn anymore, it would be about right.

 

I'm not sure that you can do it accurately with an impact gun at 150 psi air pressure? I was more comfortable with my method, and I don't know if I was "fortunate" not to break a leg or arm, but I got it done.

You do need to be concerned with over stressing the gun, the air hoses AND the compressor itself.

Don't forget that the "impact gun" IS going to "kick" when you hit it with full tank and that you can shatter the gear in the gun. I didn't want to take that kind of a chance. I don't do this every day.

 

The issue is that there is little procedure for accurately measuring the applied torque without the multiplier.

To this day, I still don't think there are any local shops I could rent or borrow a torque multiplier from?

Maybe the "semi" shops have one but none of the big "semi" guys will even talk to me to this day. They suddenly become mute.

They get like $500 an hour with the "vehicle" on the lift in the shop and helping you takes "food out of their kids mouths".

 

Caution should prevail. Use the black impact wrench sockets, extensions and components. You don't want even a Craftsman forged socket suddenly shattering on you and throwing shrapnel in your direction. This ain't for "kids" to do. You can get killed doing this.

As I recall, I MIGHT have broken the pin on the 1/2" breaker bar on one, then bent the pipe too? I'm not sure? I prefer not to think about that. Gives me chills thinking about how freakin' crazy I really am? Next I'll be catching bullets in cotton padding? Well, maybe not?

 

You can twist yourself up really good with doing this too? My chiropractor wants to know exactly WTF I do, being so twisted? I think she means my back but I'm not completely sure that's what SHE meant? Maybe that's why people are afraid of me? Hum?

 

 

 

Last edited by panteradoug

I have found a multiplier that Snap-On makes. The small unit will do up to approx 650lbs. It has a 1/2 inch input with a 3/4 inch output. I should be able to use my standard 1/2 inch torque wrench set at max. Hopefully I can borrow one from my Snap-On buddy.

i also located a more heavy duty unit at my local rental shop that goes up to 1000lbs. - United Rentals.

Thanks for the replies and photos. Always leaning new things with the Pantera😊. 

That was not an issue for me. The clearance difference (.008") between the socket and the nut kind of locks it in place within reason.

COMMERCIAL tool rentals here do not have torque multipliers. Forget about chain parts stores.

The best bet is to watch ebay for a good used one. They come up occasionally as the big trucks need them just for the lug nuts alone.

marlinjack posted:

…A 4 Foot Bar with 100 Pounds on the End will give you 400 Ft/Lbs.

With the Assembly Mounted ON THE VEHICLE; I torqued the Nuts until they would Not Tighten Any Further.

Had a Helper hold the Brakes, and had the Tire on the Floor, with the Full Weight of the Car, to hold from turning. Tighten Beyond the Brake Slipping and the Tire Slips on the Floor, repeat as Necessary. As Tight as You can get it, will be More than 400 Ft/Lbs.

REMEMBER! The Drivers' (On American Cars) LEFT side Nut has the LEFT-Hand Thread!! 'Mass at Rest 'Tends' to Stay at Rest!'

...Last, You are NOT to Re-Use, the Original Nuts! They must be New.

Marlin 

Well sure, but it depends on where you stand on the bar. You need room for two feet and be positioned so you don't hit yourself in the private parts.

I said this isn't easy and it's a wonder I didn't kill or mame myself right?

 

Also, YOU CAN'T just hold the assembly on two lug studs, you will snap, shear those suckers right off. The studs, not your privates...but . Best to make a plate and use all 5.

panteradoug posted:

The torque number is to load the bearings, not necessarily to keep the nut tight. You can do that with Lok-tite.

If you aren't torking to 400 then the bearings aren't loaded correctly.

 

It's the factory's number, not something out of the blue or from outer space. Modify it at your own risk.

Preload is only justified with tapered roller or possibly angular contact bearings, not with simple ball or deep groove bearings.

At least, it was like that when I was studying in an engineering school in the early 70s, when the Pantera were produced.

 

Last edited by rene4406
rene4406 posted:
panteradoug posted:

The torque number is to load the bearings, not necessarily to keep the nut tight. You can do that with Lok-tite.

If you aren't torking to 400 then the bearings aren't loaded correctly.

 

It's the factory's number, not something out of the blue or from outer space. Modify it at your own risk.

Preload is only justified with tapered roller or possibly angular contact bearings, not with simple ball or deep groove bearings.

At least, it was like that when I was studying in an engineering school in the early 70s, when the Pantera were produced.

 

I agree, I would expect a torque rating like that to be used with tapered bearings. I don't know where 400lb-ft is required at all UNLESS the consideration (a paranoid one maybe) was that the designer wanted the bearings and the spacer for all intents and purposes to act as a single machined piece and he had previous experience maybe from Formula 1 that a torque like this was the safest bet?

I don't like that much torque particularly considering that the axle hardness to begin with is questionable (shown to be too soft and not hardened adequately by the original manufacturer) and worry that maybe I'm stressing out the threads and stretching the axle by going to that much torque?

 

Still, I am not Giancarlo Dilara. If he tells me to jump, my only question is how high?

I like your creative thinking on your modification but am concerned for 1) the crushability/durability of that lock washer and 2) something I'm missing that Dilara knows and I don't.

 

How much torque are you going to use with your modification? 400 I think is ridiculous to begin with? How can you calculate a preload with the modification? If I knew why it was 400 to begin with then maybe an educated guess would be in order?

Formula 1 cars of the era were only about 450hp and weighed around 600kg (1320lbs). Maybe the Pantera rear uprights are a common F1 design of the time?

 

A lot of experienced designers use an empirical method. They use what they know works. If it breaks, make it thicker/stronger, then if it doesn't break, they give it to a mathematician to write a predictable formula for it. Does that sound like Dilara? I don't know?

 

Oh...I give you high credit and kudos for the courage but I stand by my original comment of "modify at your own risk", because of all of the above. ^. No offense intended

Last edited by panteradoug

Do you really think that Dallara calculated all the assemblies, that would surprise me. At the time there were far fewer engineers than today and many sub-assemblies were designed by less qualified people, especially in a small company like De Tomaso. So I'm not sure it was an engineer who was responsible for the rear hubs.
Dallara has certainly calculated the chassis himself and we all know that it is not a model of rigidity, as what even the engineers of formula 1 may not always be skilful.

I think a torque of about 150 lb.ft is more than enough.

I have no idea how he would have worked.

I know as me being a "junior structural engineer", nothing I did got done without a two step oversight of approval.

In the '70s, "modelling" was being used. It was before computers and still the age of slide rules.

 

As I said, I don't know where 400lb-ft comes from or is necessary to begin with. I will add that the rear upright of the Pantera resembles that of the Ford GT. That one being cast in magnesium though.

Was that modelling? Why reinvent the wheel. Take one off the shelf and plug it in.

 

I think the issue with stiffness of the "chassis" is just an under estimate of horsepower and tire gripping capabilities using 1968 standards.

The Mustangs, Cobras and GT40s all show similar indications of lacking here and there. Race cars were stiffened with roll bars and cages AND NO manufacturer (including Ferrari ) provided for their cars to still be around over 7 years. That number is still used and proven by the actuaries the makers use.

 

150 sounds like a guess? Got the formula?

 

Last edited by panteradoug

I shouldn't, but I can't help myself at time.   Actually, I got lost in the exchange so don't know what to reply to

 

this assembly does not preload the bearing (like with front taper)

the nut is to make the inner two races  (10&15) one with the axle (7)

the threads are a 1 3/8" bolt thus a "normal" torque for a cheap bolt would be ver 400 ft-lbs. (almost 3X)

In my previous life (back when I knew how too) Verify bolt torques use to be one item I had to calc.   the reduce outer diameter of the locknut versus a normal bolt head will reduce to required torque somewhat.   (I just don't fell like calculating anymore)

the locking washer (installed between 17&18) would have no compression, thus a solid washer as the outer tabs are outside the nut face.

Tired now and going to take a knap!

edit. .  couldn't sleep

a quick run through a MathCad routine I used for land base turbine bolting

I played around with the Bolt Strenght value to see what the threads would be loaded to at 400 ft-lbs.   Note a cheap bolt would have a strenght of 60kpi.   

 

 

 

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Last edited by jfb05177

I doubt if any even cares, but I had an epiphany!

looking at the data sheet for the lock nut

https://www.skf.com/group/prod...way/productid-KM%207

It states an axial static loading, (but not specified as recomended nor maximum) of 50 KNextons (11,240 lbf)

using the known area of the threaded section, the Kpsi tension loading caused my tighten the nut is easily found

Then with that Kpsi, the torque can be calculated with the equation I used above.

I was surprised!   Not wanting to give this as a recomendation so I will let oneone interested find for theirself,  But I will say, use the nut ONCE!

 

 

panteradoug posted:

 

 

 

..........................

 

150 sounds like a guess? Got the formula?

 

I obviously did'nt do any calculation, it is just because 150 ft.lb is roughly the maximum capacity of my dynanometric key.

When I was a student in the early 70's, our teachers told us that about 80% of the parts were not calculated but estimated empirically! Among the 20% calculated, many were by hand because personal computers did not exist, there were only large computers which were expensive,  relatively slow and were used only for the calculations of the main and complicated parts.

rene4406 posted:
panteradoug posted:

 

 

 

..........................

 

150 sounds like a guess? Got the formula?

 

I obviously did'nt do any calculation, it is just because 150 ft.lb is roughly the maximum capacity of my dynanometric key.

When I was a student in the early 70's, our teachers told us that about 80% of the parts were not calculated but estimated empirically! Among the 20% calculated, many were by hand because personal computers did not exist, there were only large computers which were expensive,  relatively slow and were used only for the calculations of the main and complicated parts.

Yes. That's what I mean by "modelling".

For instance, if you were designing a building, every time you come to bath room as a component, you don't need to redesign it. You have a saved, already proven design that you can insert as a unit.

The front suspension of the Pantera, if you compare it to that of the '65 Mustang, you could clearly notice that the spindle size, bearing size, lug studs, all of these components have already been calculated for the Mustang and just need to be plugged in?

This is what I mean about the rear uprights. They resemble the Ford GT40. In that sense I think this is what Dillara did. He didn't reinvent the wheel. He selected components already of know and desirable quantities.

You can still do that today, not needing to recalculate the loads on a 1/2" grade 8 wheel stud. Just plug them in to the design. How many do you need, 4, 5, 6, 8?

 

As an aside, long ago here, I asked if race Panteras used the stock production front spindle diameter and wheel bearing. The reason was, that noticing that the Pantera front spindle was "modeled" after the '65 Mustang, when Ford introduced the "wide oval" tires for the '70 model year, they immediately started to have front spindle and bearing failures.

Their solution was to increase the diameter of the spindle and made running changes to put those into production. The main Mustang racing at the moment was Trans Am.

Shelby was no longer involved and the main racing engineering element of Ford became Kar Kraft. They immediately adopted those larger spindles into the Mustang front racing design.

When I asked that question here of the Pantera racers and if there was a Group 4 front spindle, (a larger diameter spindle then stock) the reaction here from the Pantera racers was, "what you talkin' about Willis?" ( yes, Rocky, that Willis)

I should be used to this lack of communication between one side of the "Ford Community" to the other but honestly, it never ceases to amaze me?

 

 

 The explanation of where the 400 comes from is interesting and comprehensive. It sort of illustrates to me, the strength of materials vs. the weakest link battle that most assemblies derive from.

I was just looking at the wrong component as the needy child for the loading but sort of had the idea.

Last edited by panteradoug

The basic idea behind tightening any threaded fastener is to stretch the bolt so the applied load in the assembly exceeds the expected force the system must retain. The axle is a 1-3/8" OD fine-thread fastener. 400 ft-lbs is the minimum torque to stretch the system sufficiently to withstand 350-400 horsepower the engine is sending thru to the tires. The SAE stated shearing force of a 1-3/8" fine thread fastener is around 1200 ft-lbs, so no worries about stripping a usable axle thread with a cleaned and lightly lubed nut. Note those nuts are supposed to be one-use-only, but I know the price of new nuts is high ($16 ea?) So we all reuse them. Mostly, this works.

There are two different axle nut sockets: the OEM factory tool is a face-pin spanner with four square protrusions. The late model socket now sold by the vendors is a socket with 4 protrusions inside so the socket completely encloses the nut. This is a much stronger, more slip-proof design, well worth the price. There are also two different axle nuts: one is fully threaded with 4 full height notches; the other has cut-down sides about half way resulting in half-height notches. The Factory face spanner socket will not reach far enough down to fully engage the cut-down nut's notches and may deform or strip the notches at 400 ft-lbs torque.

One last warning: if a previous owner was a little paranoid and used red Loc-tite 271 AND torqued the assembly to 400+ ft-lbs, it may be better to blow the nut off with a cutting torch or use a Dremel grinder rather than hurt yourself- or the assembly- trying to loosen the nut. If the nut simply won't move and you're turning the nut in the correct direction (dextro is right-hand-thread and sinistro is left hand-thread; the marked axles may have swapped sides), try a little heat: hot Loc-tite has an acrid odor instantly detected by your nose. If you smell something 'sharp' while heating, I suggest cutting the nut off. I have several such 'keepsakes'.

Tightening the nut creates an axial tensile stress in the axis to oppose the lateral force exerted by the tires when cornering.
This effort is completely independent of the power transmission (350-400 or 500 or 600 or .... PS), or rather of the corresponding torque, which creates a torsional stress in the axis.
These two stresses are independent, even if they combine to produce the total stress in the axis.


The axial force in turns is only supported by the outer bearing, this is why it is better to replace the outer bearing with a double row ball bearing rather than the inner bearing, but this requires to machine the hub:

The older I get, the more giant tools I buy.... 15 yrs ago I bought a used 0-750 ft-lb Snap-on torque wrench (3/4" drive) specifically for Pantera rear axle nuts. Also works for other very hi-torque car fasteners; original Mini flywheels, RX-7 rotary gland nuts, etc). Because such large torque wrenches are heavy, 3-1/2 ft long and bulky, they are often for sale used at ridiculously low prices on E-Bay. I paid $110 including shipping, in perfect condition. This model (and an even larger 0-1000 ft-lbs one) has a removable handle and a settable dial that lights up a small AA battery powered bulb when a preset torque is reached. So its a one-man wrench in spite of its size. Last time I looked, Snap-On still sells this model new.

Rene

You seem to be the go to guy with the axle nut questions.  I have the rear fully dissembled now. Two questions - with your locking nut idea using the SKF MB7 , I suspect you dispensed with the backing washer item 17 ? ( thanks for the sketch jfb!). Or did the locking not go on top ?

I hope so, because old 6997 was missing one on one side. One locking nut was pretty well loose - likely because the washer was missing and the nut was likely just run upon the inner hub lip.

Alternately any ideas where you can buy one of the chamfered washers  no 17 ? I have been looking everywhere with no luck.

I purchased two brand new axle nuts, with the locking cut  , lh and rh from Halls. Both don't seem to have a run in taper on the thread. Very difficult to thread on the axle because they look like a straight cut thread. The old nuts run on and off no problems.

Any one had this problem ??- very concerned about stripping the thread on the stub axle. Easy job made difficult.



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