Information about Marine Chronometer
A marine chronometer is a timekeeper precise enough to be used as a portable time standard, used to determine longitude by means of celestial navigation.
The term chronometer is also used to describe watches tested and certified to meet certain precision standards. In Switzerland, only timepieces certified by the COSC may use the word 'Chronometer' on them.
Until the mid 1750s, navigation at sea was an unsolved problem due to the difficulty in calculating longitudinal position. Navigators could determine their latitude by measuring the sun's angle at noon. To find their longitude, however, they needed a portable time standard that would work aboard a ship. Observation of celestial, "clockwork" motions such as Galileo's method based on observing Jupiter's natural satellites was usually not possible aboard due to the ship's motion. The Lunar Distance Method was proposed by Johannes Werner in 1514, but the technique, even after the measurement methods were refined, involved tedious arithmetic calculations and was not particularly practical for routine navigation.
The purpose of a chronometer is to keep the time of a known fixed location, which can then serve as a reference point for determining the ship's position. By comparing local high noon to the chronometer's time, a navigator could use the time difference to determine the ship's present longitude. Since the Earth rotates 360 degrees every day (that is, 24 hours or 1,440 minutes), the time difference between the two points reveals how many degrees separate them. With the degrees of difference in hand, locating the position on a map was a relatively simple matter of spherical trigonometry. (In modern practice, a navigational almanac and trigonometric sight-reduction tables permit navigators to measure the Sun, Moon, visible planets, or any of 57 navigational stars at any time that the horizon is visible).
The creation of a seaworthy timepiece was difficult. Until the 20th century, the best timekeepers were pendulum clocks, but the rolling of a ship at sea rendered the ordinary, gravity-based pendulum useless. John Harrison, a Yorkshire carpenter, invented a clock based on a pair of counter-oscillating weighted beams connected by springs whose motion was not influenced by gravity or the motion of a ship. His first two sea timekeepers used this system, but he became rightly convinced that they had a fundamental sensitivity to centrifugal force, which meant that they could never be accurate enough at sea. Construction of his third machine, designated H3, included novel circular balances and the invention of the bi-metallic strip and caged roller bearings (both inventions are still widely used today). H3's circular balances proved too inaccurate and he eventually abandoned the large machines. Harrison solved the precision problems with his H4 chronometer design. H4 appeared much like a large five-inch (12 cm) diameter pocket watch. In 1761 Harrison submitted H4 for the £20,000 longitude prize that had been offered by the British government in 1714. His design used a fast-beating balance controlled by a temperature compensated spiral spring. This general layout remained in use until microchips reduced the cost of a quartz clock to the point that electronic chronometers became commonplace.
After Harrison's work proved the possibility of portable precision timekeepers, making them practical by perfecting simpler and more affordable designs was the next problem. Pierre Le Roy and Ferdinand Berthoud in France, and Thomas Mudge in England successfully produced marine timekeepers. Although none of these makers discovered a path to simplicity, they did encourage others by proving that Harrison's design was not the only answer to the problem. The greatest strides toward practicality came at the hands of Thomas Earnshaw and John Arnold, who developed simplified, detached, "spring detent" escapements, moved the temperature compensation to the balance, and improved the design and manufacturing of balance springs. This combination of innovations served as the basis of marine chronometers until the electronic era.
By 1825, the British Navy had begun routinely supplying its vessels with chronometers.[1]
Although industrial production methods began revolutionizing watchmaking in the middle of the 19th century, chronometer manufacture remained craft-based much longer. Around the turn of the 20th century, Swiss makers like Ulysse Nardin made great strides toward incorporating modern production methods, like fully interchangeable parts, but it was only with the onset of World War II that the Hamilton Watch Company in the US perfected the process of mass production, which enabled them to produce of thousands of their superb Hamilton Model 21 chronometers for the US Navy and other Allied navies. Despite Hamilton's success, chronometers made in the old way never disappeared from the marketplace during the era of mechanical timekeepers. Mercer, in St. Albans, England, for instance, continued to produce high-quality chronometers by traditional production methods well into the 1970s.
The most complete international collection of marine chronometers, including Harrison's H1 to H4, is at the National Maritime Museum, Greenwich, England.
The escapement serves two purposes. First, it allows the train to advance fractionally and record the balance's oscillations. At the same time, it supplies minute amounts of energy to counter tiny losses from friction, thus maintaining the equilibrium of the oscillating balance. The escapement is the part that ticks. Since the natural resonance of an oscillating balance serves as the heart of a chronometer, chronometer escapements are designed to interfere with the balance as little as possible. There are many constant force and detached escapement designs, but the most common are the spring detent and pivoted detent. In both of these, a small detent locks the escape wheel and allows the balance to swing completely free of interference except for a brief moment at the center of oscillation, when it is least susceptible to outside influences. At the center of oscillation, a roller on the balance staff momentarily displaces the detent, allowing one tooth of the escape wheel to pass. The escape wheel tooth then imparts its energy on a second roller on the balance staff. Since the escape wheel turns in only one direction, the balance receives impulse in only one direction. On the return oscillation, a passing spring on the tip of the detent allows the unlocking roller on the staff to move by without displacing the detent.
Chronometers often included other innovations to increase their efficiency and precision. Hard stones such as ruby and sapphire were often used as jewel bearings to decrease friction and wear of the pivots and escapement. Until the end of mechanical chronometer production in the third quarter of the 20th century, makers continued to experiment with things like ball bearings and chrome-plated pivots.
Marine chronometers always contain a maintaining power which keeps the chronometer going while it is being wound, and a power reserve to indicate how long the chronometer will continue to run without being wound. Marine chronometers are the most accurate portable mechanical clocks ever made, achieving a precision of around a tenth of a second per day. This is accurate enough to locate a ship's position within 4600 feet after a month's sea voyage.
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COSC a/k/a C.O.S.C. is the Official Swiss Chronometer Testing Institute.
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The term chronometer is also used to describe watches tested and certified to meet certain precision standards. In Switzerland, only timepieces certified by the COSC may use the word 'Chronometer' on them.
History
)
Bréguet twin barrel box chronometer.
The purpose of a chronometer is to keep the time of a known fixed location, which can then serve as a reference point for determining the ship's position. By comparing local high noon to the chronometer's time, a navigator could use the time difference to determine the ship's present longitude. Since the Earth rotates 360 degrees every day (that is, 24 hours or 1,440 minutes), the time difference between the two points reveals how many degrees separate them. With the degrees of difference in hand, locating the position on a map was a relatively simple matter of spherical trigonometry. (In modern practice, a navigational almanac and trigonometric sight-reduction tables permit navigators to measure the Sun, Moon, visible planets, or any of 57 navigational stars at any time that the horizon is visible).
The creation of a seaworthy timepiece was difficult. Until the 20th century, the best timekeepers were pendulum clocks, but the rolling of a ship at sea rendered the ordinary, gravity-based pendulum useless. John Harrison, a Yorkshire carpenter, invented a clock based on a pair of counter-oscillating weighted beams connected by springs whose motion was not influenced by gravity or the motion of a ship. His first two sea timekeepers used this system, but he became rightly convinced that they had a fundamental sensitivity to centrifugal force, which meant that they could never be accurate enough at sea. Construction of his third machine, designated H3, included novel circular balances and the invention of the bi-metallic strip and caged roller bearings (both inventions are still widely used today). H3's circular balances proved too inaccurate and he eventually abandoned the large machines. Harrison solved the precision problems with his H4 chronometer design. H4 appeared much like a large five-inch (12 cm) diameter pocket watch. In 1761 Harrison submitted H4 for the £20,000 longitude prize that had been offered by the British government in 1714. His design used a fast-beating balance controlled by a temperature compensated spiral spring. This general layout remained in use until microchips reduced the cost of a quartz clock to the point that electronic chronometers became commonplace.
After Harrison's work proved the possibility of portable precision timekeepers, making them practical by perfecting simpler and more affordable designs was the next problem. Pierre Le Roy and Ferdinand Berthoud in France, and Thomas Mudge in England successfully produced marine timekeepers. Although none of these makers discovered a path to simplicity, they did encourage others by proving that Harrison's design was not the only answer to the problem. The greatest strides toward practicality came at the hands of Thomas Earnshaw and John Arnold, who developed simplified, detached, "spring detent" escapements, moved the temperature compensation to the balance, and improved the design and manufacturing of balance springs. This combination of innovations served as the basis of marine chronometers until the electronic era.
By 1825, the British Navy had begun routinely supplying its vessels with chronometers.[1]
Although industrial production methods began revolutionizing watchmaking in the middle of the 19th century, chronometer manufacture remained craft-based much longer. Around the turn of the 20th century, Swiss makers like Ulysse Nardin made great strides toward incorporating modern production methods, like fully interchangeable parts, but it was only with the onset of World War II that the Hamilton Watch Company in the US perfected the process of mass production, which enabled them to produce of thousands of their superb Hamilton Model 21 chronometers for the US Navy and other Allied navies. Despite Hamilton's success, chronometers made in the old way never disappeared from the marketplace during the era of mechanical timekeepers. Mercer, in St. Albans, England, for instance, continued to produce high-quality chronometers by traditional production methods well into the 1970s.
The most complete international collection of marine chronometers, including Harrison's H1 to H4, is at the National Maritime Museum, Greenwich, England.
Mechanical chronometers
The crucial problem was to find a resonator that remained unaffected by the changing conditions met by a ship at sea. The balance wheel harnessed to a spring solved most of the problems associated with the ship's motion. Unfortunately, the elasticity of most balance spring materials changes relative to temperature. To compensate for ever-changing spring strength, the majority of chronometer balances used bi-metallic strips to move small weights toward and away from the center of oscillation, thus altering the period of the balance to match the changing force of the spring. The balance spring problem was solved with a nickel-steel named Elinvar for its invariable elasticity at normal temperatures. The inventor was Charles Edouard Guillaume, who won the Nobel Prize for physics in recognition for his metallurgical work (the only Nobel that has been granted for work related to horology).
)
The escapement serves two purposes. First, it allows the train to advance fractionally and record the balance's oscillations. At the same time, it supplies minute amounts of energy to counter tiny losses from friction, thus maintaining the equilibrium of the oscillating balance. The escapement is the part that ticks. Since the natural resonance of an oscillating balance serves as the heart of a chronometer, chronometer escapements are designed to interfere with the balance as little as possible. There are many constant force and detached escapement designs, but the most common are the spring detent and pivoted detent. In both of these, a small detent locks the escape wheel and allows the balance to swing completely free of interference except for a brief moment at the center of oscillation, when it is least susceptible to outside influences. At the center of oscillation, a roller on the balance staff momentarily displaces the detent, allowing one tooth of the escape wheel to pass. The escape wheel tooth then imparts its energy on a second roller on the balance staff. Since the escape wheel turns in only one direction, the balance receives impulse in only one direction. On the return oscillation, a passing spring on the tip of the detent allows the unlocking roller on the staff to move by without displacing the detent.
Chronometers often included other innovations to increase their efficiency and precision. Hard stones such as ruby and sapphire were often used as jewel bearings to decrease friction and wear of the pivots and escapement. Until the end of mechanical chronometer production in the third quarter of the 20th century, makers continued to experiment with things like ball bearings and chrome-plated pivots.
Marine chronometers always contain a maintaining power which keeps the chronometer going while it is being wound, and a power reserve to indicate how long the chronometer will continue to run without being wound. Marine chronometers are the most accurate portable mechanical clocks ever made, achieving a precision of around a tenth of a second per day. This is accurate enough to locate a ship's position within 4600 feet after a month's sea voyage.
Today
Ships and boats primarily utilize GPS signals for navigation at sea. However, celestial navigation is still a requirement for certain international mariner certifications such as Officer in Charge of Navigational Watch, and Master and Chief Mate deck officers. [2] [3] Celestial navigation is also used by offshore yachtmasters on long-distance private cruising yachts. [4] [5] Celestial navigation still requires the use of a precise chronometer. Many marine chronometers today are based on quartz clocks that are corrected periodically by GPS signals or radio time signals (see radio clock). These quartz chronometers are not always the most accurate quartz clocks when no signal is received, and their signals can be lost or blocked. However, there are quartz movements, even in wrist watches, that are accurate to within 10 or 20 seconds per year. [6] [7] At least one quartz chronometer made for advanced navigational use (Syntonics's Precise Intermediate-term Computer-controlled Oscillator (PICO) Advanced Clock) utilizes multiple quartz crystals which are corrected by a computer using an average value, in addition to making GPS time signal corrections. [8] [9]References
1. ^ Britten, Frederick James (1894). Former Clock & Watchmakers and Their Work. New York: Spon & Chamberlain, p230. Retrieved on 2007-08-08. “Chronometers were not regularly supplied to the Royal Navy till about 1825
2. ^ International Convention on Standards of Training, Certification and Watchkeeping for Seafarers, 1978. Admiralty and Maritime Law Guide, International Conventions. Retrieved on 2007-09-22.
3. ^ International Convention on Standards of Training, Certification and Watchkeeping for Seafarers (with ammendments). International Maritime Organization. Retrieved on 2007-09-22.
4. ^ International Yachtmasters at Maritime Institute, Yachtmasters Course. The Maritime Institute. Retrieved on 2007-09-22.
5. ^ Royal Yachting Association Yachtmaster Training. The Royal Yachting Association. Retrieved on 2007-09-22.
6. ^ The most accurate "analog" quartz watches (non digital/non radio controlled). Retrieved on 2007-09-22.
7. ^ Read, Alexander. High accuracy timepieces that could be used as marine chronometer. Retrieved on 2007-09-22.
8. ^ Montgomery, Bruce G.. Keeping Precision Time When GPS Signals Stop. Cotts Journal Online. Retrieved on 2007-09-22.
9. ^ Precise Time and Frequency for Navy Applications: The PICO Advanced Clock. DoD TechMatch, West Virginia High Technology Consortium Foundation.. Retrieved on 2007-09-22.
2. ^ International Convention on Standards of Training, Certification and Watchkeeping for Seafarers, 1978. Admiralty and Maritime Law Guide, International Conventions. Retrieved on 2007-09-22.
3. ^ International Convention on Standards of Training, Certification and Watchkeeping for Seafarers (with ammendments). International Maritime Organization. Retrieved on 2007-09-22.
4. ^ International Yachtmasters at Maritime Institute, Yachtmasters Course. The Maritime Institute. Retrieved on 2007-09-22.
5. ^ Royal Yachting Association Yachtmaster Training. The Royal Yachting Association. Retrieved on 2007-09-22.
6. ^ The most accurate "analog" quartz watches (non digital/non radio controlled). Retrieved on 2007-09-22.
7. ^ Read, Alexander. High accuracy timepieces that could be used as marine chronometer. Retrieved on 2007-09-22.
8. ^ Montgomery, Bruce G.. Keeping Precision Time When GPS Signals Stop. Cotts Journal Online. Retrieved on 2007-09-22.
9. ^ Precise Time and Frequency for Navy Applications: The PICO Advanced Clock. DoD TechMatch, West Virginia High Technology Consortium Foundation.. Retrieved on 2007-09-22.
See also
- H5
- Clockmaker
- Larcum Kendall
- Noon Gun
- Railroad chronometer
- Rupert Gould, who wrote the definitive history of the marine chronometer
- Radio-controlled watch
- Watchmaker
- Timeline of invention
External links
A time standard is any officially-recognized specification for measuring time: either the rate at which time passes; or points in time; or both. For example, the standard for civil time specifies both time intervals and time-of-day. A time scale specifies divisions of time.
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equator divides the planet into a Northern Hemisphere and a Southern Hemisphere, and has a latitude of 0. Longitude is the east-west geographic coordinate measurement most commonly utilized in cartography and global navigation.
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For the episode of The West Wing, see .
Celestial navigation, also known as astronavigation, is a position fixing technique that was devised to help sailors cross the featureless oceans without having to rely on dead reckoning to enable them to..... Read more.
A chronometer watch is a watch tested and certified to meet certain precision standards. In Switzerland, only timepieces certified by the COSC may use the word 'Chronometer' on them.
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Motto
Unus pro omnibus, omnes pro uno (Latin) (traditional)[1]
"One for all, all for one"
Anthem
"Swiss Psalm"
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Unus pro omnibus, omnes pro uno (Latin) (traditional)[1]
"One for all, all for one"
Anthem
"Swiss Psalm"
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Circadian Locomotor Output Cycles Kaput, or Clock is a gene which encodes proteins regulating circadian rhythm. The CLOCK protein seems to affect both the persistence and length of the circadian cycle. CLOCK forms part of a basic-helix-loop-helix transcription factor.
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- COSC. For the state college in Connecticut, see Charter Oak State College.
COSC a/k/a C.O.S.C. is the Official Swiss Chronometer Testing Institute.
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Navigation is the process of planning, recording, and controlling the movement of a craft or vehicle from one place to another.[1] The word navigate is derived from the Latin roots navis meaning "ship" and agere meaning "to move" or "to direct.
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The three-letter acronym SEA may refer to:
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- Scientists and Engineers for America, a pro-science political advocacy group.
- Schoof-Elkies-Atkin algorithm
- Seattle-Tacoma International Airport (IATA: SEA, ICAO: KSEA)
- Sea Education Association
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equator divides the planet into a Northern Hemisphere and a Southern Hemisphere, and has a latitude of 0. Latitude, usually denoted symbolically by the Greek letter phi, , gives the location of a place on Earth north or south of the equator.
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Jupiter has sixty-three known natural satellites.
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Discovery of the moons
Although claims are made for the observation of one of Jupiter's moons by Chinese astronomer Gan De in 364 BC, the first certain observations of Jupiter's satellites are those of Galileo..... Read more.
In celestial navigation, lunar distance is the angle between the Moon and another celestial body. A navigator can use a lunar distance (also called a lunar) and a nautical almanac to calculate Greenwich time. The navigator can then determine longitude without a chronometer.
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Johann(es) Werner (14 February 1468 in Nuremberg, Germany – May 1522) (also Ioannis Verneri) was a German parish priest in Nuremberg and a mathematician. His primary work was in astronomy, mathematics, and geography, although he was also considered a skilled
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Noon is 12:00 at midday. Contrary to popular belief, it is not the moment when the sun crosses the meridian. The sun does cross the meridian at noon, apparent solar time, but we live by civil time (which is either Standard Time or Daylight Saving Time depending on the time
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time.
One view is that time is part of the fundamental structure of the universe, a dimension in which events occur in sequence, and time itself is something that can be measured.
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One view is that time is part of the fundamental structure of the universe, a dimension in which events occur in sequence, and time itself is something that can be measured.
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The Sun
Observation data
Mean distance
from Earth 1.4961011 m
(8.31 min at light speed)
Visual brightness (V) −26.74m [1]
Absolute magnitude 4.
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Observation data
Mean distance
from Earth 1.4961011 m
(8.31 min at light speed)
Visual brightness (V) −26.74m [1]
Absolute magnitude 4.
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Moon
The Moon as seen by an observer on Earth
Orbital characteristics
Periapsis: 363,104 km
0.0024 AU
Apoapsis: 405,696 km
0.0027 AU
Semi-major axis: 384,399 km
0.
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The Moon as seen by an observer on Earth
Orbital characteristics
Periapsis: 363,104 km
0.0024 AU
Apoapsis: 405,696 km
0.0027 AU
Semi-major axis: 384,399 km
0.
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planet, as defined by the International Astronomical Union (IAU), is a celestial body orbiting a star or stellar remnant that is massive enough to be rounded by its own gravity, not massive enough to cause thermonuclear fusion in its core, and has cleared its neighbouring region of
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A pendulum clock uses a pendulum as its time base. From their invention, in 1656, until the 1930s, clocks using pendulum movements were the most accurate. Because of their need to be stationary and immovable while operating, pendulum clocks cannot operate in vehicles; the motion
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John Harrison (March 24 1693 – March 24 1776) was an English clockmaker who revolutionised and extended the possibility of safe long distance sea travel in the Age of Sail by inventing a long-sought and critically-needed key piece in the problem of accurately establishing the
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Centrifugal force (from Latin centrum "centre" and fugere "to flee") is a term which may refer to two different forces which are related to rotation.
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bi-metallic strip is used to convert a temperature change into mechanical displacement. The strip consists of two strips of different metals which expand at different rates as they are heated, usually steel and copper.
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rolling-element bearing is a bearing which carries a load by placing round elements between the two pieces. The relative motion of the pieces causes the round elements to roll (tumble) with little sliding.
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The longitude prize was a reward offered by the British government through an Act of Parliament in 1714 for a simple and practical method for the precise determination of a ship's longitude.
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die in the context of integrated circuits is a small block of semiconducting material, on which a given functional circuit is fabricated. Typically, integrated circuits are produced in large batches on a single wafer of electronic-grade silicon (EGS) through processes such as
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A quartz clock is a clock that uses an electronic oscillator that is made of a quartz crystal to keep precise time. This crystal oscillator creates a signal with very precise frequency.
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Ferdinand Berthoud (March 19, 1727 - June 20, 1807), Swiss chronometer-maker, was born at Plancemont, Neuchâtel.
Settling in Paris in 1745, he gained a great reputation for the excellence and accuracy of his marine chronometers.
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Settling in Paris in 1745, he gained a great reputation for the excellence and accuracy of his marine chronometers.
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Thomas Mudge may refer to:
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- Thomas H. Mudge - an American Methodist Episcopal clergyman
- Thomas Mudge - a British watchmaker and the inventor of the lever escapement.
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Thomas Earnshaw (born February 4, 1749 in Ashton-under-Lyne - died March 1, 1829 in London) was an English watchmaker who first simplified the process of marine chronometer production, making them available to the general public.
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John Arnold (born 1736 in Bodmin, Cornwall; died 1799 in London) was a watchmaker who developed and patented escapement and balance spring designs. He is known to have lived for a period at Well Hall House in Eltham, which was then a civil parish of Kent.
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