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'Anti-magnetic (non-magnetic) watches' are those that are able to run with minimal deviation when exposed to a certain magnetic field.

Contents

Overview

History

Usage

Contributions

References

External links

Overview

According to DIN 8309 (Deutsche Industrie Norm - German Industry Norm) a watch must resist a magnetic field of 4,800 A/m (Ampere per meter) and have a maximum deviation of 30 seconds per day in order to be acknowledged as an anti-magnetic watch.
There are two ways of building an anti-magnetic watch:

★ The first way consists in using different alloys, capable to withstand magnetic fields. Such alloys as Invar (iron - nickel - carbon - chromium alloy), Glucydur (beryllium - bronze alloy), Nivarox (iron - nickel - chromium - titanium - beryllium alloy) and Elinvar - an alloy similar to Invar, though less resistant to magnetism and more resistant to thermal influence. Due to different components these alloys have different properties. They were differently used by various watch-making brands. However, since the 50's Nivarox and Glucydur were extensively used by the watchmakers. Starting with the 60's almost all Swiss watches had Glucydur balance and Nivarox hairsprings. The anchors, escape wheels and other parts of mechanism were also made of non-magnetic metals or alloys.

★ Another way of making a watch non-magnetic is to house the entire movement into a case made of a highly conductive (permeable) material. The movement is covered by an additional soft-iron clasp to prevent the forming of magnetic fields inside the watch itself.

History

First comments on experimenting with anti-magnetism in watch-making were reported in 1846. The watchmakers from Vacheron Constantin were among the first to experiment with anti-magnetic features of a watch. However, they succeeded in assembling the first antimagnetic watch only several decades later. That watch was able to withstand magnetic fields because some of its parts were made of non-magnetic metals: the palladium-made balance wheel, balance spring and the lever shaft.
In 1896 Charles Edouard Guillaume discovered the nickel based alloy 'Invar'. Afterwards, in 1920, when he received the Nobel Prize in Physics, he developed another alloy - 'Elinvar'. These events played an important role in assembling anti-magnetic watches. Invar is able to resist magnetic fields, thus protecting the watch from its influences.
The first anti-magnetic pocket watch was assembled by Vacheron Constantin in 1915. Later, in 1929, Tissot assembled the first ever non-magnetic wristwatch. In 1954 Vacheron Constantin has continued the innovative rush by producing the first anti-magnetic chronograph. In 1958 Jaeger-LeCoultre has improved the chronograph resistant to magnetic fields by doubling its anti-magnetic case.

Usage

Since their appearance anti-magnetic watches have found a wide application in different activities, especially where people deal with high magnetic fields. Such timepieces are wide-spread among engineers who deal with electronics and where magnetic fields are present but are not very intensive.
Today even divers' watches (according to ISO 6425) must correspond not only with such criteria as water resistance, luminosity, shock resistance and strap solidity, but also anti-magnetism.

Contributions

After discovering the alloys for assembling anti-magnetic watches many watch-making brands use the materials in production and try to improve the performance of such timepieces.
The most outstanding watches of this class were made by IWC: in 1989 IWC assembled the Ingeneur. It was able to withstand a huge magnetic field of 500,000 A/m. In 1993, when IWC celebrated its 125th birthday, the company substituted this model with a more conventional Ingeneur, resisting a magnetic field of 80,000 A/m. IWC Pilots' watches have the feature of showing accurate time under a moderate magnetic pressure too.
Almost all timepieces from Vacheron Constantin have this feature, especially those from the Overseas collection. These watches had an anti-magnetic screen in soft-iron for the protection of the movement.
The Olympic Games' timekeeper Omega also manufactures watches corresponding to ISO 764, which is based on the accidental exposure of the watch to a magnetic field of 4,800 A/m.
Patek Philippe has also introduced a few innovations into this field: the engineers developed a non-metallic, silicon-based material for building parts of a watch's mechanism, thus making them fully non-magnetic.
Breitling and Panerai also use such alloys as Glucydur to manufacture anti-magnetic watches.

References

★ High-end Materials for High-end Watches

External links

★ Vacheron Constantin and Nonmagnetic Watches