13 Attachment(s)
Forming .257 Roberts Ackley Improved cases from 8x57 brass
Forming .257 Roberts Ackley Improved cases from 8x57 brass
Background
Recently I found that I was down to my last ten or so loaded rounds for the hunting rifle chambered in .257 Improved, not enough for over the summer, so it would soon be time for a reloading session. I also recalled that in amongst the spent cases there was now the odd split neck, and hoped that when I came to look through them I would only lose maybe half-a-dozen and the rest I could run through the annealer and all would be well.
Instead, on inspection, the attrition rate from splitting was over one-half – I’d clearly left things too long – but worse; many of the remaining cases were showing signs of thinning in the brass above the head, identified by feel for the indent in the interior wall. I sectioned a case to have a closer look, and sure enough, the walls were down by a quarter from normal thickness in the usual place. They’d last another loading, but now was the time to start looking for replacement brass.
Attachment 158728
That said, I had used this set of cases for a long time. Originally fire formed from five boxes of .257 Roberts Winchester +P 117gr RN factory ammo purchased for a sharp price from Viv Collings as slow moving stock; all these years later and I wasn’t hopeful of easily finding more of the same – or unloaded brass for that matter. After calls to the usual places and then a look through some U.S. forum threads on the availability problems over there, this concern turned out to be realised.
Selecting a starting case
So while .257 Roberts brass now appears to be quite difficult to find, those that reload for this round will know that it can be made by necking up or down from the other cases that also derive from the 57mm Mauser case. This would most commonly be done by expanding 6mm Remington brass – a cartridge that has retained only marginally better availability here in NZ – or by necking down 7x57. There shouldn’t be much of a problem finding 7mm Mauser brass.
This approach comes up from time-to-time on most of the forums where reloading discussions have a place, but seldom do I see any specifics on how to go about it. For reloaders here who are well versed in turning one type of brass into another, such a conversion must seem trivial. But there will also be owners of rifles chambered from amongst this group of hard-to-find cartridges – 6mm Remington, .257 Roberts, .257AI – who are occasional reloaders, and who might appreciate more of a step-by-step description of how to go about making some fresh cases from brass that is still readily available.
Another reason for not dismissing the fine detail as unnecessary is that there is the potential for things to go wrong when firing home-modified brass that should not be underestimated. Here is a recent article from NZ Guns that emphasises this:
https://nzguns.co.nz/guns/converting-brass/
When possible I have a preference for brass from the blue boxes. Looking through the Lapua range for possible donor cases, the closest candidate was the 8x57is (the rimless Mauser round) since Lapua don’t make 7x57 brass. In these times of shortage, Belmont Ammunition still held stock of 8x57 Lapua brass.
What follows then is a detailed description of the steps I used to form this particular brass down to something approximating .257 Roberts, at which point it was loaded and fire formed to the finished shape in the improved chamber. Most of these steps could also be used to make standard .257 Roberts or 6mm Remington. Even if necking down from 7x57 there might be something useful to be found here – perhaps on setting the headspace for fire forming.
Attachment 158729
Step 1. Reduce the neck diameter to .284” via .308”
The 8mm cases cannot just be run through the .257 Improved FL (full length) die though – otherwise this post would be a lot shorter than it is! With the improved design being wider across the shoulder, the case walls are not supported in such a die. The force required to compress the neck diameter down by so much in one go will collapse the case walls. It may however be possible to run the 8mm cases directly through a standard .257 Roberts die where the case walls are supported, but I haven’t tried this, nor do I recommend this as a shortcut. The reason being is – and as was seen in the cases here – that the thickening of the brass in the necks from reducing the diameter will be distributed more evenly if the necking-down is carried out in steps.
Conventional dies for any cartridges with the appropriate intermediate neck diameters may be used as long as these can be set up in the press to size the whole neck without also reducing the dimensions of the case body or shoulder angle. So dies for shorter cases and with at least the same shoulder angle become likely candidates as they can simply be backed off in the press. In selecting these intermediate dies it also helps to avoid using dies for cases with particularly steep shoulder angles; a shallower shoulder understandably seems to better centre the necks to commence the sizing process and retain concentricity. The idea was also to use common dies that were either already on hand or could perhaps be borrowed, rather than buying in a specialty forming die from overseas that might only be used once or twice.
It just so happens that dies for two of our most common cartridges are perfect. I started out then by running the cases through .308 Winchester and 7mm-08 Remington full-length dies (both kindly loaned to me by @Brian), and with the expander buttons removed. The bottoms of the dies were backed off the shell holder to fully size the necks while only just running down onto the existing shoulders. For this the outsides of the cases were lubed with Imperial Sizing Wax.
Below is a diagram of the 8mm Mauser CIP case dimensions in both metric (left) and imperial units (right), along with the neck and shoulder dimensions for the .308 and 7mm-08.
Attachment 158730
The starting outside neck diameter on the 8mm Lapua brass as received – being sized ready to load – was somewhat smaller than that given above at 8.87mm (0.349”). The neck thickness started out at 0.36mm (0.014”). Measured case length was 56.7mm.
The full-length .308 and 7mm-08 dies without the expanders fitted took the neck ODs down to a measured 8.36mm (0.329”) and 7.67mm (0.302”) respectively.
With reference to the above drawing, dies based off the .308 case do not support the case walls either, however the walls had sufficient strength to support the smaller step-wise reductions in neck diameter. The aim was that the existing shoulder should be moved back only slightly if at all, while the neck-shoulder junction moves forward as the base of the neck is converted into new shoulder from reducing the neck diameter. It would only be in the next sizing step that the shoulder would be pushed back to precisely set the separation between the case head and the neck-shoulder junction, giving the headspace for fire forming.
At this point I had something approximating a 7x57 case but with the shoulder pushed forward.
Attachment 158731
Step 2. Final sizing of cases for fire forming to .257AI
Ideally the cases would now be sized down further to .257 Roberts dimensions and that could then be fire formed. If a conventional full-length die is used for this – that contacts the cases right into the neck-shoulder junction – then the cases will also be ready for neck turning.
I had a small technical difficulty at this point, as I don’t own a standard .257 Roberts die set. I also don’t have an expander or neck turning mandrel in 25-cal, but I do have these for 6.5mm. So instead I took the cases down to what was effectively 6.5x57 by running them through a backed-off 6.5x55 Scandinavian FL die (kindly loaned to me by @2post).
In setting up an appropriate headspace for fire forming, the shoulders were pushed back by close on 2mm (0.080”).
Attachment 158732
The expander button was left in place and sizing wax was used on the inside of the necks for this. The overall case length was now 57.2mm.
Below is a comparison of the CIP dimensions for the 6.5x55 and those of my .257 Improved reamer.
Attachment 158733
Notes on headspacing for fire forming
While I have added a headspacing dimension of 1.910” above to indicate a 0.010” crush-fit at the neck-shoulder junction when chambering cases for fire forming, in practice I just experimented with this figure by feel. My personal preference is to set up the headspace for fire forming so that I almost have to hammer the bolts closed on the parent cases in my ’98 Mausers. This degree of crush-fit is set by incrementally lowering the die in the press, usually in 0.1mm (0.004”) steps, and testing a sized case or two in the chamber. I want to avoid any stretching in the brass on firing that thins the case walls, and that at the extremity would mean the cases blowing apart. There is no downside that I am aware of to this degree of interference fit on the cases other than the difficulty in closing the bolt. I can also be certain then that the resistance felt is caused by compression between the chamber on the case shoulder or the case-shoulder junction and the bolt face on the case head, and not by some lesser unintended contact, either between the case walls and the chamber, or the jamming of a thickened neck into a chamber that is slightly too tight. Detouring via 6.5mm created this latter issue by the way that deserves mention.
When firing factory ammunition in an improved chamber there is no immediate control of this and you take what comes. Barrels are chambered to be 0.004” under-length on the parent round, or at least I seem to recall reading somewhere that this was the figure Parker Ackley recommended.
Making standard cases
Just as an aside, if wanting to make regular .257 Roberts cases then the brass would now be run through a .257 Roberts full-length die. If 6mm Remington cases were being made, I would be inclined to put the brass through something like a 6.5x55 FL die before the 6mm, to again split the necking-down process with an intermediate step. The 6.5x55 is actually a good choice as it meets the requirements of both reducing the case neck diameter while not compressing the body at any point to less than the final 6mm Remington specification, and is also common enough that many reloaders will already have a set of dies.
For both these cartridges I would propose that the dies for this final sizing could be adjusted height-wise in the press as one would for bumping shoulders back; lowered just enough so that the bolt can close with little or no feel on sized cases that have been chambered in the rifle. Alternatively a degree of crush fit could be left and the cases formed to the exact chamber dimensions with the first firing.
Step 3. Turning the Necks
At this point the outside diameter of the necks left by the 6.5mm expander were measured at 7.48-7.50mm (0.294-0.295” with an ID of 0.261-0.262”) since the neck walls had thickened to 0.0165”. If the necks were being taken down further to make 6mm Remington brass then a thickness over 0.017” could be expected. These would now need to be turned down for two reasons; to uniform the thickness of the brass around the necks, and to give the desired bullet release clearance for the chamber. If a reamer drawing is not available then the chamber neck dimension may be estimated by adding 0.0005-0.001” to the neck OD of previously fired cases.
The cases were then all trimmed back to a uniform 56.7mm in preparation for turning. Necks were chamfered, and then run through a 6.5mm expansion mandrel to achieve a snug fit to the turning spindle. I then took the neck thickness down to 0.0150” with the turning tool.
While this neck turning was performed at 6.5mm through necessity, no additional thickening of the necks was expected or was measured from the further small reduction from .264” to the final .257” neck diameter. Obviously adjust the neck turning setting to suit your particular needs and chamber dimensions if making cases in this way. Neck turning at the end-use calibre would always be preferable if the tools were available.
Attachment 158734
At the same time as thinning out the necks, a cutter with an appropriately angled chamfer could also be run into the shoulders to thin these to something similar to the neck thickness and so perhaps reduce the likelihood of developing the dreaded “donut”. As it turned out, the finished shoulder thickness in early trial cases that I sectioned were already the same as the necks at a measured 0.015”, and so for the subsequent main batch of cases the cutter was adjusted to only thin the necks to the shoulder junction and no further.
If it was decided to run the cutter into the neck, it does need to be remembered that anything taken off the shoulders at this stage will impact the degree of crush-fit in the headspacing as set previously with the final FL sizing die. The set-up of that die and the neck turning tool need to be balanced to achieve both the desired shoulder thickness below the necks and the desired headspacing.
Attachment 158735
Step 4. Loading and fire forming the cases
The case necks were then sized to hold .25-cal bullets for fire forming. The .257AI full-length sizing die was used for this. I only sized three-quarters of the length of the necks as shown in the image below. This leaves the neck-shoulder junction untouched and so the headspace previously set up by the 6.5x55 die unchanged.
Attachment 158736
For fire forming I stuffed the cases full with Reloader-25 behind 85gr bullets, for no other reason than that I had this powder and the bullets going spare. I also lightly lube the cases with Imperial Sizing Wax. As I’ve mentioned before on this site, I don’t subscribe to the claim that doing so significantly increases rearward force on the bolt. Using QuickLOAD to estimate what the peak pressure might have been from the recorded muzzle velocity, I thought perhaps 40kPSI. The shoulders nevertheless ended up pretty sharp, certainly more than I’d seen from pictures where the cream-of-wheat method had been used. Put another way, I didn’t expect any capacity increase on subsequent firings – I would have happily use these cases as they were for any load development.
With reference to the earlier reamer drawing, a final loaded diameter of 0.287” (0.257 + 2x 0.015”) gave 0.004” firing clearance in my .257AI chamber. After fire forming this was re-measured and hadn’t changed. Also noted was that the case length had been reduced by 0.2mm to 56.5mm from the fire forming.
Step 5. Annealing the cases
I should mention that the cases were not annealed prior to fire forming. When I had trialled annealing before fire forming I ran into trouble, possibly because I had made the necks and shoulders a little too soft. Although the cases were still dimensioned to give what seemed to be an adequate crush fit when chambered, clearly the headspacing either wasn’t – or did not remain – intact, as the cases stretched on firing almost to the point of head separation, making them fit only for the scrap bin. Perhaps the impact of the firing pin was sufficient to deform the brass. The headspacing is after all, set only by the limited contact area at the head-shoulder junction.
Attachment 158737
As it turned out, un-annealed cases survived the additional process of fire forming quite happily, and with the close attention that had been given to the headspacing, there was no indication of any case wall thinning either. I do think it is probably best to then anneal before further use as the brass will have by this stage been worked somewhat from new in forming to the improved and smaller calibre shape.
After annealing the fired .257 improved cases all gave a little bit of “feel” on returning them to the chamber and closing the bolt, so they were run through the .257AI full-length (or body die) and this was adjusted down – as many of us do when setting up our dies – to just have the bolt drop easily on the sized cases.
Attachment 158738
Case capacity
The last thing to do before trying out the new cases was to measure and compare case capacities. The original cases being replaced made from the Winchester+P brass, when full-length sized and trimmed to 56.5mm, had accepted 61.5gr of water to level with the case mouths, 57.3gr to the top of the shoulders. The capacity of the new Lapua cases was less: 60.6gr and 56.4gr respectively under the same conditions. Range time subsequently found that the powder charge would need to be backed off by the 0.9gr difference to return my pet hunting load to the same muzzle velocity as before. QuickLOAD predicts that peak chamber pressure would have been 3000PSI greater had I stuck with my original charge weight. So really just a reminder to check the case capacity of any new brass. It would be annoying to unintentionally loosen the primer pockets for cases you’d just spent so much time carefully preparing.
Attachment 158739
Follow-up: A visit to the range
Accuracy-wise as rifle for hunting, I don’t really require much from the .257. I seldom take shots out beyond 200 metres, which is the distance at which I zero this rifle. The choice of Lapua brass was really around case longevity. I had hoped that if I tweaked the load for the same MV then the rifle would shoot much the same as it had before. I certainly didn’t have any intention of going back to working up loads or checking on how the consistency of the new cases – or lack of – would impact accuracy. I just loaded up some rounds for the bush, checked the zero with a single clean cold-bore shot, and then tucked the rifle and ammo back in the safes.
My Nephew though had mentioned that he and his partner would like the opportunity to fire a centrefire rifle – what would be a first-time experience for both of them. So yesterday evening we took the .257 up to the Kaitoke range. They fired off three shots each. While some of you know that I’m not an advocate of 3-shot groups (putting it mildly), they both did very well. You wouldn’t expect to be able to use the first 3 shots fired by anyone new to a rifle of any kind as a means of gauging the consistency of a load, and I’m not proposing we do that here, but I would say that from what I saw, the signs are promising that the new brass is up to scratch. A couple of readings were then taken using the Labradar as an after thought – 3fps apart.
Attachment 158740
Thanks also to forum member @.308 who gave me half a dozen 8mm cases for the initial testing.