Bolt thrust

Bolt thrust or breech pressure is a term used in internal ballistics and firearms (whether small arms or artillery) that describes the amount of rearward force exerted by the propellant gases on the bolt or breech of a firearm action or breech when a projectile is fired. The applied force has both magnitude and direction, making it a vector quantity.

Bolt thrust is an important factor in weapons design. The greater the bolt thrust, the stronger the locking mechanism has to be to withstand it. Assuming equal engineering solutions and material, adding strength to a locking mechanism causes an increase in weight and size of locking mechanism components.

Bolt thrust is not a measure to determine the amount of recoil or free recoil.

Calculating bolt thrust

With a basic calculation the bolt thrust produced by a particular firearms cartridge can be calculated fairly accurately.

=Formula=

: $\vec{F}_{bolt} = P_{max} \cdot A_{internal}.$ [http://www.riflebarrels.com/articles/custom_actions/bolt_lug_strength.htm A Look at Bolt Lug Strength By Dan Lilja] {{webarchive |url=https://web.archive.org/web/20100303024616/http://www.riflebarrels.com/articles/custom_actions/bolt_lug_strength.htm |date=March 3, 2010 }}

where:

F_bolt = the amount of bolt thrust
P_max = the maximum (peak) chamber pressure of the firearms cartridge
A_internal = the inside area (of the cartridge case head) that the propellant deflagration gas pressure acts against

Cartridge case heads and chambers are generally circular. The area enclosed by a circle is:

: $Area = \pi r^2 \approx 3{.}1416 \cdot r^2.$

where:

π ≈ 3.1416
r = the radius of the circle

Equivalently, denoting the diameter of the circle by d.

: $Area = \frac{\pi d^2}{4} \approx 0{.}7854 \cdot d^2.$

File:Bolt thrust.JPG

A practical problem regarding this method is that the internal case head diameter of a particular production lot of cartridge cases (different brands and lots normally differ dimensionally) can not be easily measured without damaging them.

=Friction effects=

A complicating matter regarding bolt thrust is that a cartridge case expands and deforms under high pressure and starts to "stick" to the chamber. This "friction-effect" can be accounted for with finite elements calculations on a computer, but it is a lot of specialized work and generally not worth the trouble.[http://www.varmintal.net/abolt.htm Stolle Panda Bolt Stress and Deflection Analysis]

By oiling proof rounds during NATO EPVAT testing procedures, NATO test centers intentionally lower case friction to promote high bolt thrust levels.

Practical method to estimate bolt thrust

Instead of using the internal case head diameter, the external case head base diameter can also be measured with a caliper or micrometer or taken from the appropriate C.I.P. or SAAMI cartridge or chamber data tables and used for bolt thrust estimation calculations.

The basic calculation method is almost the same, but now the larger outside area of the cartridge case head is used instead of the smaller inside area.

: $\vec{F_{bolt}} = P_{max} \cdot A_{external}.$

where:

F_bolt = the amount of bolt thrust
P_max = the maximum (peak) chamber pressure of the firearms cartridge
A_external = the outside area of the cartridge case head

This method is fine for getting a good estimate regarding bolt thrust and assumes an overly large area that the gas pressure acts against yielding pessimistic estimations, generating a safety margin in the process for worse case scenarios which can result in increased maximum (peak) chamber pressure of the firearms cartridge, like a round that is chambered in an already very warm chamber that can result in cooking off (i.e. a thermally induced unintended firing).

=Bolt thrust estimations for various pistol/revolver cartridges=

\| Chambering \|\| P1 diameter (mm) \|\| A_external (cm²) \|\| P_max (bar) \|\| F_bolt (kgf) \|\| F_bolt
class="wikitable sortable"
s \| .22 Long Rifle	5.74	0.2587	1,650	427	{{convert\|4268\|N\|lb-f\|abbr=on}}
FN 5.7×28 mm	7.95	0.4964	3,450	1,713	{{convert\|16794\|N\|lb-f\|lk=on\|abbr=on}}
9×19 mm Parabellum	9.93	0.7744	2,350	1,820	{{convert\|17847\|N\|lb-f\|lk=on\|abbr=on}}
HK 4.6×30 mm	8.02	0.5051	4,000	2,021	{{convert\|19816\|N\|lb-f\|lk=on\|abbr=on}}
.357 Magnum	9.63	0.7284	3,000	2,185	{{convert\|21428\|N\|lb-f\|abbr=on}}
.357 SIG	10.77	0.9110	3,050	2,779	{{convert\|27248\|N\|lb-f\|abbr=on}}
.380 ACP	9.70	0.7390	1,500	1,130	{{convert\|11085\|N\|lb-f\|abbr=on}}
.40 S&W	10.77	0.9110	2,250	2,050	{{convert\|20101\|N\|lb-f\|abbr=on}}
10 mm Auto	10.81	0.9178	2,300	2,111	{{convert\|20701\|N\|lb-f\|abbr=on}}
.41 Remington Magnum	11.05	0.9590	3,000	2,877	{{convert\|28213\|N\|lb-f\|abbr=on}}
.44 Remington Magnum	11.61	1.0587	2,800	2,964	{{convert\|29069\|N\|lb-f\|abbr=on}}
.45 ACP	12.09	1.1671	1,300	1,517	{{convert\|14879\|N\|lb-f\|abbr=on}}
.454 Casull	12.13	1.1556	3,900	4,507	{{convert\|44197\|N\|lb-f\|abbr=on}}
.500 S&W Magnum	13.46	1.4229	4,270	6,076	{{convert\|59584\|N\|lb-f\|abbr=on}}

The P1 (cartridge case base) diameters and P_max used in the calculations were taken from the appropriate C.I.P. data sheets.

=Bolt thrust estimations for various rifle cartridges=

\| Chambering \|\| P1 diameter (mm) \|\| A_external (cm²) \|\| P_max (bar) \|\| F_bolt (kgf) \|\| F_bolt
class="wikitable sortable"
s \| 5.45×39mm	10.00	0.7854	3,800	2,985	{{convert\|29268\|N\|lb-f\|lk=on\|abbr=on}}
.223 Remington	9.58	0.7208	4,300	3,099	{{convert\|30396\|N\|lb-f\|abbr=on}}
7.62×39mm	11.35	1.0118	3,550	3,592	{{convert\|35223\|N\|lb-f\|abbr=on}}
6mm ARC	11.20	0.9852	3,800	3,744	{{convert\|36714\|N\|lb-f\|abbr=on}}
.303 British	11.68	1.0715	3,650	3,911	{{convert\|38352\|N\|lb-f\|abbr=on}}
7.92×57mm Mauser	11.97	1.1197	3,900	4,367	{{convert\|42824\|N\|lb-f\|abbr=on}}
7.65×53mm Mauser / 7×57mm	12.01	1.1329	3,900	4,418	{{convert\|43327\|N\|lb-f\|abbr=on}}
6.5×55mm	12.20	1.1690	3,800	4,442	{{convert\|43563\|N\|lb-f\|abbr=on}}
.30-06 Springfield / .308 Winchester	11.96	1.1234	4,150	4,662	{{convert\|45722\|N\|lb-f\|abbr=on}}
7.62×54mmR	12.37	1.2018	3,900	4,687	{{convert\|45964\|N\|lb-f\|abbr=on}}
8mm Lebel	13.77	1.4892	3,200	4,765	{{convert\|46734\|N\|lb-f\|abbr=on}}
7.5×55mm Swiss GP 11	12.64	1.2548	3,800	4,768	{{convert\|46761\|N\|lb-f\|abbr=on}}
.375 Holland & Holland Magnum / .300 Winchester Magnum	13.03	1.3335	4,300	5,734	{{convert\|56230\|N\|lb-f\|abbr=on}}
6.5×68mm / 8×68mm S	13.30	1.3893	4,400	6,113	{{convert\|59947\|N\|lb-f\|abbr=on}}
.375 Ruger / .416 Ruger	13.52	1.4356	4,300	6,173	{{convert\|60539\|N\|lb-f\|abbr=on}}
.277 FURY (SAAMI specifications)	11.95	1.1216	5,516	6,187	{{convert\|60670\|N\|lb-f\|abbr=on}}
.300 Remington Ultra Magnum	13.97	1.5328	4,400	6,744	{{convert\|66139\|N\|lb-f\|abbr=on}}
.300 Winchester Short Magnum	14.12	1.5659	4,400	6,890	{{convert\|67567\|N\|lb-f\|abbr=on}}
.338 Lapua Magnum	14.91	1.7460	4,200	7,333	{{convert\|71914\|N\|lb-f\|abbr=on}}
.300 Norma Magnum / .338 Norma Magnum	14.87	1.7366	4,400	7,641	{{convert\|74935\|N\|lb-f\|abbr=on}}
.300 Lapua Magnum / 7.62 UKM	14.91	1.7460	4,400	7,807	{{convert\|76556\|N\|lb-f\|abbr=on}}
.375 CheyTac / .408 CheyTac	16.18	2.0561	4,400	8,224	{{convert\|80654\|N\|lb-f\|abbr=on}}
.50 BMG	20.42	3.2749	3,700	12,117	{{convert\|118829\|N\|lb-f\|abbr=on}}
14.5×114mm	26.95	5.7044	3,600	20,536	{{convert\|201387\|N\|lb-f\|abbr=on}}

The P1 (cartridge case base) diameters and P_max used in the calculations were taken from the appropriate C.I.P. data sheets.

References

External links

[https://web.archive.org/web/20130505030534/http://lutz-moeller-jagd.de/Waffen/Blaser/R93/Blaser-R93.html Blaser R93 Unfälle - zur Verschlußbelastung {{in lang|de}}]
[https://web.archive.org/web/20130603114006/http://lutz-moeller-jagd.de/Waffen/Technik/Zylinderverschluss/Zylinderverschluesse.htm Zylinderverschluß - Verschlußkräfte {{in lang|de}}]

Category:Firearms

Category:Firearm actions

Category:Firearm terminology

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