Bank vault explained

A bank vault is a secure space where money, valuables, records, and documents are stored. It is intended to protect their contents from theft, unauthorized use, fire, natural disasters, and other threats, much like a safe. Unlike safes, vaults are an integral part of the building within which they are built, using armored walls and a tightly fashioned door closed with a complex lock.

Historically, strongrooms were built in the basements of banks where the ceilings were vaulted, hence the name. Modern bank vaults typically contain many safe deposit boxes, as well as places for teller cash drawers and other valuable assets of the bank or its customers. They are also common in other buildings where valuables are kept such as post offices, grand hotels, rare book libraries and certain government ministries.

Vault technology developed in a type of arms race with bank robbers. As burglars came up with new ways to break into vaults, vault makers found new ways to foil them. Modern vaults may be armed with a wide array of alarms and anti-theft devices. Some 19th and early 20th century vaults were built so well that today they are difficult to destroy, even with specialized demolition equipment.[1] These older vaults were typically made with steel-reinforced concrete. The walls were usually at least 1 ft (0.3 m) thick, and the door itself was typically 3.5 ft (1.1 m) thick. Total weight ran into the hundreds of tons . Today vaults are made with thinner, lighter materials that, while still secure, are easier to dismantle than their earlier counterparts.

Design

Bank vaults are built as custom orders. The vault is usually the first aspect of a new bank building to be designed and built. The manufacturing process begins with the design of the vault, and the rest of the bank is built around it. The vault manufacturer consults with the customer to determine factors such as the total vault size, desired shape, controls, and location of the door. After the customer signs off on the design, the manufacturer configures the equipment to make the vault panels and door. The customer usually orders the vault to be delivered and installed. That is, the vault manufacturer not only makes the vault parts, but brings the parts to the construction site and puts them together.

Bank vaults are typically made with steel-reinforced concrete. This material was not substantially different from that used in construction work. It relies on its immense thickness for strength. An ordinary vault from the middle of the 20th century might have been 18 in (45.72 cm) thick and was quite heavy and difficult to remove or remodel around. Modern bank vaults are now typically made of modular concrete panels using a special proprietary blend of concrete and additives for extreme strength. The concrete has been engineered for maximum crush resistance. A panel of this material, though only 3 in (7.62 cm) thick, may be up to 10 times as strong as an 18 in-thick (45.72-cm) panel of regular formula concreted.

There are at least two public examples of vaults withstanding a nuclear blast. The most famous is the Teikoku Bank in Hiroshima whose two Mosler Safe Company vaults survived the atomic blast with all contents intact. The bank manager wrote a congratulatory note to Mosler.[2] [3] A second is a vault at the Nevada National Security Site (formerly the Nevada Test Site) in which an above ground Mosler vault was one of many structures specifically constructed to be exposed to an atomic blast in Operation Plumb Bob - Project 30.4:Response of Protective Vaults to Blast Loading.[4] [5]

Manufacturing process

Panels

The wall panels are molded first using a special reinforced concrete mix. In addition to the usual cement powder, stone, etc., additional materials such as metal shavings or abrasive materials may be added to resist drilling penetration of the slab. Unlike regular concrete used in construction, the concrete for bank vaults is so thick that it cannot be poured. The consistency of concrete is measured by its "slump". Vault concrete has zero slump. It also sets very quickly, curing in only six to 12 hours, instead of the three to four days needed for most concrete.[6] [7]

Door

The vault door is also molded of special concrete used to make the panels, but it can be made in several ways. The door mold differs from the panel molds because there is a hole for the lock and the door will be clad in stainless steel. Some manufacturers use the steel cladding as the mold and pour the concrete directly into it. Other manufacturers use a regular mold and screw the steel on after the panel is dry.

Round vault doors were popular in the early 20th century and are iconic images for a bank's high security. They fell out of favor due to manufacturing complexities, maintenance issues (door sag due to weight) and cost, but a few examples are still available.[8] [9]

A day gate is a second door inside the main vault door frame used for limited vault protection while the main door is open. It is often made of open metal mesh or glass and is intended to keep a casual visitor out rather than to provide true security.[10]

Lock

A vault door, much like the smaller burglary safe door, is secured with numerous massive metal bolts (cylinders) extending from the door into the surrounding frame. Holding those bolts in place is some sort of lock. The lock is invariably mounted on the inside (behind) of the difficult-to-penetrate door and is usually very modest in size and strength, but very difficult to gain access to from the outside. There are many types of lock mechanisms in use:

Installation

US resistance standards

Quality control for much of the world's vault industry is overseen by Underwriters Laboratories, Inc. (UL), in Northbrook, Illinois. Until 1991, the United States government also regulated the vault industry. The government set minimum standards for the thickness of vault walls, but advances in concrete technology made thickness an arbitrary measure of strength. Thin panels of new materials were far stronger than the thicker, poured concrete walls. Now the effectiveness of the vault is measured by how well it performs against a mock break-in. Manufacturers also do their own testing designing a new product to make sure it is likely to succeed in UL trials.[13] Key points include:

RatingTime to Breach Vault
Class M15 minutes
Class I30 minutes
Class II60 minutes
Class III120 minutes

European resistance standards

As with the US, Europe has agreed a series of test standards to assure a common view of penetrative resistance to forcible attack.[14] The testing regime is covered under the auspices of Euronorm 1143-1:2012 (also known as BS EN 1143-1: 2012),[15] which can be purchased from approved European standards agencies.[16] [17]

Key points include:

Resistance GradeResistance Value to Breach VaultLock QuantityExplosive Rating PossibleCore Drill Rating Possible
030OneNoNo
I50OneNoNo
II80OneYesNo
III120OneYesNo
IV180TwoYesNo
V270TwoYesNo
VI400TwoYesNo
VII600TwoYesNo
VIII825TwoYesYes
IX1050TwoYesYes
X1350TwoYesYes
XI2000Two or ThreeYesYes
XII3000Two or ThreeYesYes
XIII4500Two or ThreeYesYes

Future

Bank vault technology changed rapidly in the 1980s and 1990s with the development of improved concrete material. Bank burglaries are also no longer the substantial problem they were in the late 19th century up through the 1930s, but vault makers continue to alter their products to counter new break-in methods.

An issue in the 21st century is the thermal lance. Burning iron rods in pure oxygen ignited by an oxyacetylene torch, it can produce temperatures of 6,600–8,000 °F (3,650–4,430 °C). The thermal lance user bores a series of small holes that can eventually be linked to form a gap. Vault manufacturers work closely with the banking industry and law enforcement in order to keep up with such advances in burglary.

Further reading

Books

Periodicals

External links

Notes and References

  1. Web site: Demolition crew cracks the old U.S. Bank vault. 6 March 2015 . 10 August 2018. 16 April 2020. https://web.archive.org/web/20200416235528/https://www.mankatofreepress.com/news/local_news/demolition-crew-cracks-the-old-u-s-bank-vault/article_40b8808c-c42c-11e4-8929-a3b126a0fa7a.html. live.
  2. Web site: Letters of Note: Your Products are Stronger than the Atomic Bomb . 16 September 2010 . 16 September 2010. https://web.archive.org/web/20100919151038/http://www.lettersofnote.com/2010/09/safe.html. 19 September 2010 . live.
  3. Web site: Unbreakable: Hiroshima and the Mosler Safe Company . 26 August 2010 . CONELRAD Adjacent . 26 August 2010 . 13 August 2011 . https://web.archive.org/web/20110813222916/http://conelrad.blogspot.com/2010/08/unbreakable-hiroshima-and-mosler-safe.html . live .
  4. A Nuclear Family Vacation. Slate . 11 July 2005 . Slate Magazine . 11 July 2005. https://web.archive.org/web/20050713012637/http://www.slate.com/id/2122382/entry/2122387/. 13 July 2005 . live.
  5. News: Slate's Well-Traveled: A Nuclear Family Vacation. NPR.org. NPR. 15 July 2005. 6 August 2005. https://web.archive.org/web/20050806073311/http://www.npr.org/templates/story/story.php?storyId=4755708. live.
  6. Web site: Discovery Channel (UK) How Do They Do It? (Season 3 / Episode 7 / Part 2) Diebold Vault Construction (YouTube). YouTube. 28 December 2010.
  7. Web site: Hercvlite Vault Panels . 28 December 2010 . https://web.archive.org/web/20101217144147/http://www.vaultstructures.com/hercvlite.php . 17 December 2010 . dead .
  8. Web site: Vault Structure Inc. Round Vault Doors . 28 December 2010 . https://web.archive.org/web/20110411044420/http://www.vaultstructures.com/round.php . 11 April 2011 . dead .
  9. Web site: VSI 360 Round Vault Door . 28 December 2010 . https://web.archive.org/web/20110711045334/http://fspa1.com/pdf/Round_Vault_Door.pdf . 11 July 2011 . dead .
  10. Web site: Installation Instructions for Overly GSA Class 5 Vault Door. Overly Door Company. 28 December 2010. https://web.archive.org/web/20110715024825/http://www.overly.com/door/tech/docs/ins-gsaCL5.pdf. 15 July 2011. dead.
  11. Web site: Kaba-MAS X-09 and CDX-09 High Security Locks. 8. Dec 2010. 28 December 2010. 14 March 2005. https://web.archive.org/web/20050314012811/http://www.kaba-mas.com/pdf/brochures/x_09.pdf. live.
  12. Book: Scott Selby & Greg Campbell. Flawless: Inside the Largest Diamond Heist in History. Sterling. 2010. 148–149. 24 August 2021. 15 August 2021. https://web.archive.org/web/20210815161257/https://www.scottselby.com/flawless. live.
  13. Web site: UL 608 Burglary Resistant Vault Doors and Modular Panels . Underwriter's Laboratories . 30 October 2012 . https://web.archive.org/web/20120421182643/http://ulstandardsinfonet.ul.com/scopes/scopes.asp?fn=0608.html . 21 April 2012 . dead .
  14. Web site: Requirements on strongrooms in cast in-situ and/or pre-fabricated construction ECB-S R03. ECB-S. 4 September 2017. 16 April 2020. https://web.archive.org/web/20200416235529/https://www.ecb-s.com/_data/EN_ECBS_R03_Guideline.pdf. live.
  15. Web site: Red Book Live, Part 4, Section 2. LPCB. 4 September 2017. 4 September 2017. https://web.archive.org/web/20170904200245/https://www.redbooklive.com/pdfdocs/redbook-vol2part4.pdf. live.
  16. Web site: BS EN 1143-1:2012 - Secure storage units. Requirements, classification and methods of test for resistance to burglary. Safes, ATM safes, strongroom doors and strongrooms. shop.bsigroup.com. 4 September 2017. 4 September 2017. https://web.archive.org/web/20170904210030/https://shop.bsigroup.com/ProductDetail/?pid=000000000030249975. live.
  17. Web site: Standards. European. EN 1143-1. 4 September 2017. en. 4 September 2017. https://web.archive.org/web/20170904200203/https://www.en-standard.eu/csn-en-1143-1-secure-storage-units-reguirements-classification-and-methods-of-test-for-resistance-to-burglary-part-1-safes-atm-safes-strongroom-doors-and-strongrooms/?gclid=CjwKCAjw87PNBRBAEiwA0XAIryThemGNylzv3FWMy0tYHBB3sdTDkqhcsWZR07QygpMIgpSxp9CaoBoCcRoQAvD_BwE. live.
  18. Web site: EN 1300 Locks. www.ecb-s.com. 5 September 2017. 18 April 2018. https://web.archive.org/web/20180418124029/http://www.ecb-s.com/_rubric/index.php?rubric=ESSA+EN+Products+Categories+Locks. live.