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ANNEALING

I don't know the answer to that but I've often thought that given the imprecise temperature control with flame annealing, empirically (and with a little science sprinkled in) over time it may have just worked out to be a safe Tempilaq indicator temp that yields some softening without the risk of going overboard. Realistically, even using Tempilaq, with flame annealing I'd bet the true case temps well over shoot 750 because of how quickly temps are rising and instantaneous temp reading isn't really how Tempilaq is designed to be used. When I use it inside the case neck it pretty much seems to go immediately from nothing to charred which tells me it's likely well over 750.

Basically, this begs someone to perform flame annealing with proper hardness and microstructure measurements just as AMP did for induction and salt bath annealing. I don't think AMP owes a study of flame-annealing to anyone - they already tested salt bath annealing, which had a reputation for being a highly controllable at-home process.

Has anyone in the flame annealing sphere done the metallography to back up their product/process? (I ask, openly because I'm not seeing any sources that go back to hardness in the cross-section)

David
 
Probably based on the Melting point of Zinc (787F). This was likely from a person who had ZERO understanding of alloys and how they function. Perhaps a denizen of a “hide” somewhere?

As we have discussed in the past, 750F gets not much but a stress relief.

There are temperature versus HV plots for cartridge brass in college level metallurgical text books. The main problem with a glance at those is that they always tend to show a 50% cold work starting point on a sample that is way too large and then soak times on the order of 30 minutes at the plotted temperature. We can't use those beautiful phase boundary plots or those annealing plots for our interests.

One then has to account for the time factor and heat transfer relationship in terms of the difference between those plots for analysis pucks which are on the order of a quarter inch thick and a 12.5 mil case neck.

There is also some contention as to the target HV. For example, is a HV of 110 good, or should the value be more like 95.

Without a doubt, the cartridge manufacturers have had to tune their processes to achieve their goals. Those goals tend to show a similar target value in the micro-Vickers range of about 95 - 105 in the necks. Military rounds tend to have sealants in the case neck that eliminate the topic of how that science helps reloaders.

So, we are typically on our own for precision reloading when it comes to the general science of what happens to multiple use brass and is there any such thing as "one right" answer for everybody. Short of laboratory access and a government sized budget, it is easy to see why there are not more folks publishing on the topic. I have to commend AMP for at least trying to set up the measurements that directly and indirectly show the relationship between brass processing and accuracy. It will take much more work to arrive at all those answers.
 
Basically, this begs someone to perform flame annealing with proper hardness and microstructure measurements just as AMP did for induction and salt bath annealing. I don't think AMP owes a study of flame-annealing to anyone - they already tested salt bath annealing, which had a reputation for being a highly controllable at-home process.

Has anyone in the flame annealing sphere done the metallography to back up their product/process? (I ask, openly because I'm not seeing any sources that go back to hardness in the cross-section)

David

I agree. When I retired, I lost all access to the labs or it would have been a good study to run. I did manage to check my own Giraud work on (.30-06) Lapua and Remington brass when I first picked up the machine. I was able to see my necks were good, right about HV 95, and the body near the middle was unchanged. I don't know if that was luck or repeatable. I will admit, I agonize over the flame position and the timing, every time I set up the machine.

I was also heartbroken to see the AMP report on salt bath annealing because I really liked the method. I have not run that salt since seeing the report.

If I can go back and have the work run in the labs, it would be good to learn how sensitive or forgiving the flame method is compared to the Tempilaq and visual indicators we use,
 
There are temperature versus HV plots for cartridge brass in college level metallurgical text books. The main problem with a glance at those is that they always tend to show a 50% cold work starting point on a sample that is way too large and then soak times on the order of 30 minutes at the plotted temperature. We can't use those beautiful phase boundary plots or those annealing plots for our interests.

One then has to account for the time factor and heat transfer relationship in terms of the difference between those plots for analysis pucks which are on the order of a quarter inch thick and a 12.5 mil case neck.

There is also some contention as to the target HV. For example, is a HV of 110 good, or should the value be more like 95.

Without a doubt, the cartridge manufacturers have had to tune their processes to achieve their goals. Those goals tend to show a similar target value in the micro-Vickers range of about 95 - 105 in the necks. Military rounds tend to have sealants in the case neck that eliminate the topic of how that science helps reloaders.

So, we are typically on our own for precision reloading when it comes to the general science of what happens to multiple use brass and is there any such thing as "one right" answer for everybody. Short of laboratory access and a government sized budget, it is easy to see why there are not more folks publishing on the topic. I have to commend AMP for at least trying to set up the measurements that directly and indirectly show the relationship between brass processing and accuracy. It will take much more work to arrive at all those answers.

These charts are set up to show the function and these are easily repeatable by sophomore students. When you get low amounts of cold work and thin sections, the achievement of good results take a little more finesse. AMP found they had to get to higher temperatures to initiate recrystallization. That gave them the repeatable results they were looking for. I’ve always maintained that heating to the initiation of a very dull dark red heat on the neck in a very dark room will give good results. Strangely it’s the same advise Townsend Whelen and EH Harrison gave 40 years ago. But I digress.
 
These charts are set up to show the function and these are easily repeatable by sophomore students. When you get low amounts of cold work and thin sections, the achievement of good results take a little more finesse. AMP found they had to get to higher temperatures to initiate recrystallization. That gave them the repeatable results they were looking for. I’ve always maintained that heating to the initiation of a very dull dark red heat on the neck in a very dark room will give good results. Strangely it’s the same advise Townsend Whelen and EH Harrison gave 40 years ago. But I digress.

^^^This. Although having the metallurgical data would be a bonus, it's not essential. Heating cases in my Giraud [torch] annealer until the neck turns dull red in a darkened room provides the results I want in the reloading room and on the target, firing after firing. Knowing the exact grain structure of the brass isn't going to change any of that. However, it IS very important for manufacturers of induction-based annealers to know that information, so they can provide users with appropriate guidelines for annealing their cases.
 
The 750 degree temperature corresponds in the majority of cases to be the point where the actual colour of the case after the temperature has been applied has changed to that frosted slightly blueish. I am colour blind but you all know what I mean.

I have a 1500W power supply in my unit so if the piece of metal to be heated has the right resistance about 31A is able to flow. With a 308 case in my coil the maximum current is about 14A

@SGK how much needs to be heated like you said is a very good point for discussion. When you look at say new Lapua cases that case colour change is a long way down the case perhaps 1/2 inch. My thinking is that annealing is only needed where we are reshaping / sizing the brass. So in most cases that would be the neck only and even shoulder bumping is often only really the slope of the shoulder. Not really changing the point where the shoulder starts.

However I have noticed that with even the round work coil the anneal is not perfectly the same distance from the base. There is a slight wave to it. Therefore I heat to about 1/4 inch down the case so the case shoulder point is consistent all the way around the case. I try to keep that distance to a minimum.
 
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When cartridge manufacturers anneal their brass they calibrate their annealer, whether it is flame or induction, to anneal to a certain HV. When starting up a line they will anneal a cartridge and then go test the HV until it is right. I’ve had a discussion with Peterson Brass about this and their ideal HV on the neck is around 95-100.

Also, everyone knows flame annealing will anneal and drop the HV, no one doubts that. AMP did a study on Salt Bathing, at least in my opinion, because it looked too good to be true and it was. For bottle-necked cases it looks to only start the recovery phase, barely dropping in HV which hints at stress relieving. With flame and induction you hit recovery, and can see recrystallization and grain growth under a x200 microscope.
 
Here is a brochure of case brass with annealing time 2 minutes. Half the time and you need to add 10° C. Think this gives quite the right annealing time and temperature.
 

Attachments

Cycle time for annealing case necks is in seconds. That’s why the temperatures are as high as they are. Also, as previously documented, there is a time at temperature requirement. So if your time is limited to reduce damage at the base of the case, the temperature has to be high.
 
If any case manufacturing engineers/metallurgists are following these annealing threads, they are no doubt laughing! They obviously understand their final anneal process and its effect. However, there is no reason for them to share the information with their customers and/or competitors!

I've read the various tests describing how through some fairly serious metallurgical experiments certain methods of "annealing" are better than others. I put annealing in parentheses because we are stress relieving, not returning the metal to it's soft state.

The common omission in every test I've read is the very reason we "anneal", that is to reduce and make more consistent the cartridge neck tension. Where are the graphs of seating force applied?

Neck tension can be described as the resistance to deformation the cartridge brass experiences as a bullet is forced into the neck. The more neck tension, the more force required to seat a bullet, and the more likely there will be variances in bullet seating depth (BTO).

I use the salt bath method with the media heated to 1000 F and I can say without any doubt whatsoever that his method has the desired effect on neck tension. Seating forces are greatly diminished after a 3-5 second soak. Bullets seat easier using less force, and more consistently. Isn't that what we're after?

I've seen brass crack in the neck area during long term storage of loaded rounds. I believe that Military requirements for annealing are there to address that issue more than to produce supremely accurate ammo.

I don't know what HV has to do with ductileness of brass. Is it even related?
 
I've read the various tests describing how through some fairly serious metallurgical experiments certain methods of "annealing" are better than others. I put annealing in parentheses because we are stress relieving, not returning the metal to it's soft state.

The common omission in every test I've read is the very reason we "anneal", that is to reduce and make more consistent the cartridge neck tension. Where are the graphs of seating force applied?

Neck tension can be described as the resistance to deformation the cartridge brass experiences as a bullet is forced into the neck. The more neck tension, the more force required to seat a bullet, and the more likely there will be variances in bullet seating depth (BTO).

I use the salt bath method with the media heated to 1000 F and I can say without any doubt whatsoever that his method has the desired effect on neck tension. Seating forces are greatly diminished after a 3-5 second soak. Bullets seat easier using less force, and more consistently. Isn't that what we're after?

I've seen brass crack in the neck area during long term storage of loaded rounds. I believe that Military requirements for annealing are there to address that issue more than to produce supremely accurate ammo.

I don't know what HV has to do with ductileness of brass. Is it even related?
HV is a microhardness and is relatable to Brinnel Hardness.

while the military leaves the oxide when it anneals for corrosion inhibition (they even test for it), even they have bullet pull requirements. The values are minuscule in comparison to the pressures. Shot start is the term used by ballisticians and that pressure is on the order of 1500-3000 psi.
One thing to consider, there is NO data to support the notion that seating force has any effect on shot start.
 
When cartridge manufacturers anneal their brass they calibrate their annealer, whether it is flame or induction, to anneal to a certain HV. When starting up a line they will anneal a cartridge and then go test the HV until it is right. I’ve had a discussion with Peterson Brass about this and their ideal HV on the neck is around 95-100.

Also, everyone knows flame annealing will anneal and drop the HV, no one doubts that. AMP did a study on Salt Bathing, at least in my opinion, because it looked too good to be true and it was. For bottle-necked cases it looks to only start the recovery phase, barely dropping in HV which hints at stress relieving. With flame and induction you hit recovery, and can see recrystallization and grain growth under a x200 microscope.
I have tried open flame, salt bath and an Amp. Anyone that says that salt bath does not achieve the desired affect is full of it. I am not sure about what salt bathing does to the brass molecules, but the end result in the cartridge is similar to the Amp. The Amp is faster, safer and a little more consistent, but all three methods work.

With that said, if you can afford it get the Amp.
 
Again many want to get into the science of.annealing

It is what works for you

For me i found annealing improved consistent neck tension and consistent shoulder bump.

I don't think it matters much if you are just stress releaving or fully annealing as.long as it works for you. The trick is consistency. Can you set up a torch annealer where it does each piece of brass the same every time you set up the annealer. If you don't see it as an improvement in your reloading process and.or on your target then why bother with it.

Most.consistent annealer is.the AMP by far
 
Cycle time for annealing case necks is in seconds. That’s why the temperatures are as high as they are. Also, as previously documented, there is a time at temperature requirement. So if your time is limited to reduce damage at the base of the case, the temperature has to be high.
Here we can halve the time and add 10°C. First time to 1 min. second half 30 sec. third half 15 sec. and so on. After 7 halves, we are at approx. 1 sec. which is approximately the time we have the case above recrystalaition temp. At 100HV we see that we have approx. 460° + 70° = 530°C (986°F). This agrees well with the temperature of the AMP.
 

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