Bullet trap

A bullet trap is a device to stop bullets fired at a shooting range. The bullet trap may also provide means to recycle bullet materials and/or prevent release of toxic metals from the shooting range. Bullet traps typically use friction, impact, or deceleration to stop bullets. Some bullet traps include a vacuum system to filter dust from air within the impact and/or capture area.[1]

Conceptual schematic cross-section of a deceleration bullet trap with black lines representing steel plates: Bullets entering from the left are deflected into the top of the deceleration chamber. Bullets are then deflected clockwise around the deceleration chamber until they lose kinetic energy and fall out the bottom of the deceleration chamber.

Deceleration traps

Deceleration bullet traps direct bullets into a helical or circular chamber in which the bullet may circle until it loses velocity and drops to the bottom of the chamber for collection. For use with multiple firing positions, the helical chamber often resembles a horizontal pipe, into which bullets are directed by upper and lower steel plates. The upper plate slopes downward and the lower plate slopes upward to a horizontal slot in the side of the helical chamber. Alternatively, some narrow deceleration traps for single firing positions employ vertical plates to direct bullets into a helical deceleration chamber resembling a vertical pipe from which spent bullets drop out the lower end.[1] Lightweight versions suitable for capturing airgun pellets are often used behind electronic scoring systems on ranges configured for ISSF 10 metre airgun events. The plate slopes are shallow (about 18° ) so bullets may be deflected relatively intact rather than disintegrated upon impact. Some deceleration traps use an oil and/or water coating to reduce friction and capture dust.[2]

Impact traps

Impact bullet trap into sand.

Impact bullet traps typically use vertical or angled 500 Brinell hardness steel plate at least 0.375 inches (9.5 mm) thick for centrefire cartridges.[3] Plate thickness of 4-6mm may be adequate for rimfire ammunition. Sloping plates deflect bullets downward into sand, water or some other capture material; but the plate angle is often steep enough to largely disintegrate the bullet upon initial impact, and bullets are expected to disintegrate upon impacting vertical plates. Shooter protection for firing positions within 25 metres (82 ft) of the impact plate may require an anti-splash curtain of Linatex or similar self-healing material hung in front of the plate to contain any fragments of “back splash” as well as dust. Rifle bullets may be partially melted by the energy of bullet impact. The spray of molten metal may solidify as dust, and lead bullets often leave a smear of lead upon impacting the steel plate. Smeared metal may be converted to additional dust by subsequent bullet impact.[2]

The popularity of vertical plate installations for indoor ranges is largely down to their minimal footprint compared with sand, granular or helical bullet traps and can consume less than 1 foot (30 cm) of a room’s available length - comprising the thickness of the steel plate, the thickness of the anti-splash curtain and 10 to 11 inches of air gap between.[4] However, sloping steel plates will tend to wear less quickly - particularly on precision target ranges where fixed targets result in fire being concentrated into small areas. In such cases, small sloping plates or sacrificial vertical wear plates may be placed behind the targets as the primary bullet trap, whilst a large vertical plate covers the remainder of the wall as the defence zone to catch errant shots. The small plates can be easily changed as frequently as necessary whilst the main back wall will need little maintenance from occasional scattered fire.

Friction traps

Earthen berm friction bullet trap

Friction bullet traps slow and capture the bullet more gently than steel plates. This allows more effective capture of contaminants and reduces the production of dust as well as allowing for the capture of higher energy projectiles which would wear an impact trap too quickly and necessitate uneconomical levels of maintenance. The most common form of friction trap is a berm of granular material such as sand; earth or granulated rubber. In some circumstances a wall of railway ties, intact vehicle tires, or blocks of shock attenuating concrete (SACON) or other proprietary materials may be used.[1] SACON is a fiber-reinforced concrete substituting expanded polystyrene beads for gravel aggregate.[5] For ISSF 50Metre rifle events, individual bullet traps comprising a metal box filled with plastic beads are often used behind the electronic scoring systems used for such events. Such systems require less space than earthen berms whilst being quieter than steel impact or deceleration traps, which can be a significant consideration for urban outdoor range complexes. Individual bullet traps of this nature would typically be backed by a concrete wall to protect from negligent discharges or mechanical failures causing a bullet to miss the target entirely but which is not expected to be struck during the course of normal firing. Intact vehicle tyres are generally only suitable for higher energy projectiles which will easily penetrate their surface. Handgun bullets and shotgun pellets may ricochet back. Granulated rubber (often from shredded tires) is a convenient capture material from which bullets may be separated by gravity during agitation by subsequent bullet impact.[1]

Sources

  1. 1 2 3 4 Evans, D.D.; Young, R.S. "Bullet Trap Feasibility Assessment and Implementation Plan" (PDF). United States Army Environmental Center. Retrieved 3 March 2017.
  2. 1 2 Boyles, Carolee Anita. "Backing and Trapping" (PDF). The Range Report. Retrieved 4 March 2017.
  3. Wilcher, Larry D. "Use of Bullets Traps and Steel Targets" (PDF). United States Department of Energy. Retrieved 3 March 2017.
  4. "Defence ranges safety (JSP 403 Volume 2, Chapter 3: Indoor Ranges)" (PDF). gov.uk. Ministry of Defence. 20 May 2015. pp. 6–8. Archived from the original (PDF) on 8 October 2015. Retrieved 3 May 2017.
  5. Hathaway, Mike K. "Shock-Absorbing Concrete Bullet Traps for Small Arms Ranges". United States Environmental Protection Agency. Retrieved 3 March 2017.
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