Accession No
2883
Brief Description
mercury mountain barometer, Fortin-type, with tripod, by Troughton and Simms, English, 1840 (c)
Origin
England; London
Maker
Troughton and Simms
Class
meteorology
Earliest Date
1840
Latest Date
1840
Inscription Date
Material
metal (brass; mercury); glass; wood (mahogany)
Dimensions
height 1030mm; maximum diameter 55mm tripod height 1090mm; maximum diameter 73mm
Special Collection
Provenance
Purchased from Sotherby’s, England; lot 159, 25/05/1982. Purchased with assistance from Preservation fund administered by Science Museum London.
Inscription
Troughton & Simms London
Description Notes
Mercury mountain barometer and thermometer, Fortin-type, with tripod, by Troughton & Simms, English, c. 1840.
Fortin-type brass case low-range mountain barometer by Troughton and Simms, London, c.1840. Graduated on brass 16-32½ inches, divided to 0.05 with vernier scale on brass cursor. Glass viewing pane backed by translucent white panel. Boxwood cistern with portable screw, tube drained.
Thermometer on stem, mercury round bulb, -15o-50oC, 0o-120oF. Steel lugs on brass case for mounting in gimbal on tripod.
Gimbal mount in mahogany tripod stand which, upside down, becomes the carrying case. Tripod with brass shod feet and brass mounting for barometer.
Condition good, slight corrosion on cistern and thermometer scale. Mercury drained in March 2009.
References
Joshua Nall; ‘Instrument Breakage and Repair’; Explore Whipple Collections online article; Whipple Museum of the History of Science; University of Cambridge; 2020: https://www.whipplemuseum.cam.ac.uk/explore-whipple-collections/astronomy-and-empire/instrument-breakage-and-repair
Events
Description
A barometer measures the pressure of this air upon us and our surroundings. The precise pressure of the air depends upon the weather, so a barometer is useful for weather forecasting. It can also be used as an altimeter (see "how to use" a hypsometer).
Torricelli, a pupil of Galileo, invented the traditional mercury barometer in 1644. Torricelli took a long glass tube closed at one end and completely filled it with mercury. He chose mercury because of its heaviness. Without letting air into the tube, it was then turned upside down and the open end placed in a bowl of mercury. Suprisingly perhaps, the mercury does not run out of the tube into the bowl (unless the tube is more than 760mm long). In fact, the column of mercury in the tube will always settle at the height of about 760mm above the level of the mercury in the bowl, even if the tube is tilted. This height is where the weight (or pressure) of the column of the mercury is equal to the pressure of air above the bowl, and so the height of the column of mercury measures the pressure of the surrounding air.
It was soon found that the height of the column of mercury was not absolutely fixed, but could rise and fall between 700 and 775 mm, even at sea level. The precise height seemed to depend upon the weather. From the late 17th century, therefore, the barometer rapidly became popular in the home for weather forecasting and later as an aid to the preparation of shipping forecasts. From 1840 onwards, other forms of barometer were devised that did not require cumbersome columns of mercury. Best known is the aneroid barometer, which depends upon the expansion and contraction of a partially-evacuated metal chamber to register changes in external air pressure. In the late 19th century, small pocket barometers of this type, which could also function as altimeters, were fashionable for mountaineers, balloonists, and explorers.
01/03/2001
Created by: Chris Lewis on 01/03/2001
FM:39636
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