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Tools · 27 March 2014, 10:06 AM

The new Oyster Perpetual
Sea-Dweller 4000
In 2014, Rolex is bringing a legend of professional diving back to life with a brand new, updated Oyster Perpetual Sea-Dweller 4000. This 40‑mm‑diameter technical model, waterproof to a depth of 1,220 metres (4,000 feet), features all the latest Rolex standards of innovation: Cerachrom bezel insert in a ceramic virtually impervious to scratches and ultraviolet rays; Chromalight display with long-lasting luminescence; paramagnetic blue Parachrom hairspring; Oysterlock safety clasp; and the Rolex Glidelock extension system. Not forgetting, of course, the groundbreaking function for which the Sea-Dweller is renowned, the helium escape valve.

2014 SD4000.jpg

2014 SD4000 2.jpg

The Sea-Dweller 4000
The original Helium Escape Valve, the key to the Deep.

Developed in 1967, waterproof to a depth of 610 metres (2,000 feet) initially and then to 1,220 metres (4,000 feet) in 1978, the Sea-Dweller is the watch for the pioneers of the deep. Those who were once known as aquanauts, explorers of the hydrosphere – the waters which cover some 70 per cent of the Earth’s surface. Like them, the Sea-Dweller had to adapt to the artificial breathing mixes devised for great pressure environments and composed of light gases such as helium or hydrogen. The watch has to face the same long decompression process as the diver undertakes in order to safely eliminate those gases without injury and avoid potentially fatal decompression sickness, or ‘the bends’, before he returns to the surface. With this in mind, in 1967 an important innovation developed and patented by Rolex was introduced on the Sea‑Dweller: the helium escape valve. This ingenious safety valve, set in the watch case, played an all-important role in the development of deep‑sea diving, a field in which Comex was the most renowned player. The company’s late founder and president, Henri-Germain Delauze, a pioneer of deep diving, said of his favourite watch: “A diver breathing hydrogen can’t live without his Rolex,” adding; “In diving, time is a crucial piece of information. Be it operations, changing gas mixes, timing decompression stops, entering and exiting the diving bell, it’s all a matter of seconds. Having a precise, robust, reliable watch was of vital importance.”

2014 SD4000 3.jpg

Sea Dweller 4000 back.jpg

Under pressure
To understand the importance of the Sea-Dweller, we need to look back to the heyday of man’s attempts to conquer the deep, in the early 1960s. The depth limit for scuba diving with compressed air was some 60 metres, principally for physiological reasons as the pressure beyond such a depth causes the air to become toxic. Nitrogen, which makes up almost 80 per cent of ordinary air, can have a severe narcotic effect – commonly known as the ‘rapture of the deep’ – which alters the mind of even the most experienced divers. From 66 metres down, oxygen also becomes dangerous as hyperoxia affects the nervous system, leading to seizures and loss of consciousness.

Counteracting these gas build-ups is not simply a question of returning quickly to the surface, because the diver risks the bends: 40 minutes spent at 60 metres below sea level requires a slow ascent of two hours interspersed by several decompression stops, which must be scrupulously respected to allow the release of the inert gases that have built up in the body – with the accompanying problem of needing sufficient air to stay underwater as long as that takes. And decompression time increases exponentially with depth. To overcome the 60-metre barrier, other solutions were clearly needed.

These emerged in the early 1960s with two innovations: the development of alternative breathing gas mixtures to avoid the toxic effect of air, and the concept of saturation diving which would reduce decompression time and the attendant risks.

Synthetic air
If ordinary air becomes toxic for the human body under the effect of pressure, why not breathe something else? The development of synthetic breathing mixes unlocked the gates to the deep sea. Ordinary air is composed of approximately 80 per cent nitrogen and 20 per cent oxygen, but only oxygen is metabolized by the body and is therefore essential. However, nitrogen becomes toxic and divers fall victim to nitrogen narcosis at depths of 40 to 60 metres, depending on the individual. Scientific research has shown that the proportion of nitrogen in the air may be replaced by helium, and that an artificial helium-oxygen mix (heliox) can be breathed by human beings without any physiological effects. It does not cause narcosis at pressure either. Oxygen toxicity could furthermore be avoided by increasing the proportion of helium in the mix. As a result, the 60-metre barrier could be crossed.

Later, other limitations – such as high-pressure nervous syndrome caused by prolonged diving at more than 150 metres using heliox – were circumvented by using gas cocktails with differing quantities of hydrogen, oxygen, helium and nitrogen. With a combination of gas mixes – using different mixes at different stages of the dive – diving limits were pushed even deeper from the early 1960s onwards and decompression times reduced. In 1961, a dive in open water was made to 222 metres in Lake Maggiore in Switzerland. The following year, a diver reached a depth of 313 metres in the Pacific Ocean, off the coast of California. A record that surprised the whole diving community at the time and paved the way for new marine exploration.

Living underwater:
To dive ever deeper is not the sole ambition of the conquest of the underwater world. The idea of being able to remain underwater for extended periods, or even live there, has long captured the human imagination. In the 1960s, experiments with underwater dwellings in France and in the United States freed mankind from the second constraint of marine exploration: decompression. The very name Sea‑Dweller, chosen for the highly resistant divers' watch conceived by Rolex at the time, reflects those experimental programmes. A major problem in diving is that decompression exponentially curtails useful diving time, with an impact on the depth deep-sea divers can reach as well as on the length of their stay underwater.

For example, after some 15 minutes at a depth of 90 metres below the surface, a diver must spend almost two hours in decompression stages before it is safe to return to the surface. Ten minutes at 300 metres would theoretically require more than 20 hours of decompression. A dive lasting a mere few minutes longer or just a few metres deeper leads to a considerable extension in decompression time.

The problem here is also physiological: decompression sickness, a condition which can lead to paralysis or even death. When at pressure under water, the human body can be likened to a bottle of sparkling water. Gases under pressure dissolve in water, and, since the body is composed of almost 65 per cent water, part of the gas that is breathed dissolves in the blood and body tissue. An ascent without decompression is equivalent to shaking the bottle of water hard and opening it suddenly: the gas is released in an explosion of bubbles. In the human tissue, the bubbles of gas can cause serious lesions. To release the gas safely, the bottle must be opened gradually and very gently. The purpose of decompression stops is similar, allowing the body to eliminate the accumulated gas in a controlled manner.

Saturation diving
In the mid-1950s, a scientific discovery proved crucial for the development of deep diving for extended periods. Experiments demonstrated that human tissue has a given capacity for gas absorption when the gas is under pressure. It implies that once the human body has reached its point of saturation with the breathing mix, decompression time remains the same whether a diver stays underwater a few hours, a few days, for weeks or even for months. Only the depth and the type of gas breathed are of consequence for decompression. The discovery led to the development of saturation diving, a technique that literally involves saturating the divers with breathing gases and keeping them in a pressurized environment for long periods of time. As a result, they can carry out a number of deep dives and only need to undergo a single decompression procedure at the very end of the mission. Between dives, they live in an underwater habitat or chamber, a kind of sea house on the seabed, in which the air pressure is maintained at a pressure equal to that of the water at this depth. The divers breathe a synthetic gas mix containing helium, both during the dives and in the chamber. In 1965, an American aquanaut stayed 30 days under the sea, living in a dwelling installed at a depth of 62 metres.

During their stay under water, divers saturated in the gas they breathe become completely acclimatized to the pressure at great depth. They can no longer return to surface atmospheric pressure without spending a long period of decompression – dozens of hours – in a hyperbaric chamber. This inescapable process, inherent to the life of a sea dweller, prompted Rolex to develop a special function for its highly resistant new-generation divers’ watch at the time: the helium valve, which provides an escape route for the gas and allows the helium-saturated watch to safely undergo decompression, not unlike the divers who wear it.

Highly resistant to external and internal pressure
In 1953, during the early days of scuba diving, Rolex created the archetypal divers’ watch: the Oyster Perpetual Submariner, waterproof to a depth of 100 metres. The Submariner’s waterproofness was doubled to 200 metres in 1954, offering a comfortable safety margin for those diving with air, who rarely descended beyond the 60-metre limit. The watch’s performance and reliability soon put it on the wrists of elite divers, with whom Rolex worked closely to continually improve its watches. In 1962, after the record-breaking dive to a depth of 313 metres in California, it became obvious that a new generation of divers’ watches was required, one that would be able to resist the pressure at depths below 200 metres. Rolex – having fixed an experimental watch to the bathyscaphe Trieste and successfully sent it almost 11,000 metres down to the deepest part of the ocean in 1960 – had the technology at its disposal to increase the Submariner’s performance.

In 1966, Comex made the first industrial dive to a depth of 160 metres. The French company developed a technique for saturation diving comparable to the idea behind the underwater housing projects, with the difference that the hyperbaric chambers were installed on ships that could sail on missions anywhere around the world. Saturation divers are taken down to working depth in the sea in pressurized diving bells and they return to the warm and dry pressurized chamber on board the support boat by the same method after their dive. Final decompression takes place only at the very end of their tour of duty. Comex, which came to be considered the leader in the field of commercial deep-sea diving, aimed to send its divers to 300 metros by the end of the decade. Rolex decided to make its next divers’ watch waterproof to a depth of 2,000 feet (610 metres). But in addition to increasing its resistance to external water pressure, thereby allowing the watch to descend deeper, feedback from saturation divers had uncovered a hitherto unsuspected requirement: the need to enhance the watch’s ability to withstand excess internal pressure.

The Rolex-patented
HELIUM ESCAPE VALVE
In habitats at overpressure, which are filled with breathing mixes composed largely of helium, the watches behave in a similar manner to the divers’ bodies. The inner part of the watch case becomes saturated with helium as the pressure inside the watch case equalizes with that inside the chamber. Due to the extreme volatility of this light gas, which has the smallest molecules on Earth, the helium gradually penetrates the watch through the gaskets. During the decompression phase, helium is eliminated from human tissue at a faster rate than it can escape from a waterproof watch, with the result that pressure effectively builds up inside the watch case. Divers often observed during decompression that the watch crystal could pop out like a champagne cork from a bottle, due to this internal pressure. The watch must also be able to eliminate the excess helium inside the case.

Instead of attempting to make the watch impervious to helium, a practically impossible task, Rolex developed a unidirectional valve on the side of the watch case. It is activated automatically above a certain level of internal pressure to allow the gas to escape from the case, without affecting the waterproofness of the watch. Patented in 1967 by Rolex for its new professional divers’ model, the Oyster Perpetual Sea‑Dweller, the helium valve proved invaluable to the rise of deep-sea saturation diving. Comex swiftly adopted the Sea-Dweller as its official watch, as its divers continued to push ever further the limits for manned deep dives. The open-sea record of 534 metres set in 1988 was followed by another record in 1992 at an experimental depth of 701 metros in a hyperbaric chamber, with a 24-day decompression period – a record which still stands today.

2014 SD4000 4.jpg

SPECIFICATIONS
Sea-Dweller 4000
Reference: 116600
MODEL CASE
Oyster (monobloc middle case, screw-down case back and winding crown), 40 mm
MOVEMENT
3135, Manufacture Rolex Mechanical movement with bidirectional self-winding via Perpetual rotor
DIAL
Black, satin finish
BRACELET
Oyster three-piece solid links

MODEL CASE
Oyster (monobloc middle case, screw-down case back and winding crown), 40 mm
DIAMETER
40 mm
MATERIAL
904L stainless steel superalloy, satin finish
SAFETY
Helium escape valve
CASE BACK
Screw-down with Rolex fluting
BEZEL
Unidirectional rotatable 60-minute graduated bezel with black Cerachrom insert in ceramic, engraved numerals and graduations coated with platinum via magnetron sputtering (PVD)
WINDING CROWN
Screw-down, Triplock triple waterproofness system
CROWN GUARD
Integral part of the middle case
CRYSTAL
Scratch-resistant sapphire
WATERPROOFNESS
1,220 metres (4,000 feet)

MOVEMENT
3135, Manufacture Rolex Mechanical movement with bidirectional self-winding via Perpetual rotor
CALIBRE
3135, Manufacture Rolex Mechanical movement with bidirectional self-winding via Perpetual rotor
PRECISION
Officially certified Swiss chronometer (COSC)
FUNCTIONS
Centre hour, minute and seconds hands Instantaneous date at 3 o’clock Stop-seconds for precise time setting
OSCILLATOR
Frequency: 28,800 beats/hour (4Hz)
Paramagnetic blue Parachrom hairspring
Breguet overcoil
Large balance wheel with variable inertia
High-precision regulating via four gold Microstella nuts
Traversing balance bridge
JEWELLING
31 rubies
POWER RESERVE
Approximately 48 hours

DIAL
Black, satin finish
COLOUR
Black, satin finish
HOUR MARKERS
Highly legible Chromalight appliques (long-lasting luminescence) in 18 ct white gold
HANDS
Chromalight hands in 18 ct white gold

BRACELET
Oyster three-piece solid links
MATERIAL
904L stainless steel superalloy, satin finished, polished edges
CLASP
Oysterlock folding safety clasp Rolex Glidelock extension system (20 mm in increments of 2 mm) Fliplock extension link (26 mm)

27 March 2014, 10:06 AM	#1
Tools TRF Moderator & 2024 DATE-JUST41 Patron Join Date: May 2007 Real Name: Larry Location: Mojave Desert Watch: GMT's Posts: 43,044	2014 Sea-Dweller 4000 The new Oyster Perpetual Sea-Dweller 4000 In 2014, Rolex is bringing a legend of professional diving back to life with a brand new, updated Oyster Perpetual Sea-Dweller 4000. This 40‑mm‑diameter technical model, waterproof to a depth of 1,220 metres (4,000 feet), features all the latest Rolex standards of innovation: Cerachrom bezel insert in a ceramic virtually impervious to scratches and ultraviolet rays; Chromalight display with long-lasting luminescence; paramagnetic blue Parachrom hairspring; Oysterlock safety clasp; and the Rolex Glidelock extension system. Not forgetting, of course, the groundbreaking function for which the Sea-Dweller is renowned, the helium escape valve. 2014 SD4000.jpg 2014 SD4000 2.jpg The Sea-Dweller 4000 The original Helium Escape Valve, the key to the Deep. Developed in 1967, waterproof to a depth of 610 metres (2,000 feet) initially and then to 1,220 metres (4,000 feet) in 1978, the Sea-Dweller is the watch for the pioneers of the deep. Those who were once known as aquanauts, explorers of the hydrosphere – the waters which cover some 70 per cent of the Earth’s surface. Like them, the Sea-Dweller had to adapt to the artificial breathing mixes devised for great pressure environments and composed of light gases such as helium or hydrogen. The watch has to face the same long decompression process as the diver undertakes in order to safely eliminate those gases without injury and avoid potentially fatal decompression sickness, or ‘the bends’, before he returns to the surface. With this in mind, in 1967 an important innovation developed and patented by Rolex was introduced on the Sea‑Dweller: the helium escape valve. This ingenious safety valve, set in the watch case, played an all-important role in the development of deep‑sea diving, a field in which Comex was the most renowned player. The company’s late founder and president, Henri-Germain Delauze, a pioneer of deep diving, said of his favourite watch: “A diver breathing hydrogen can’t live without his Rolex,” adding; “In diving, time is a crucial piece of information. Be it operations, changing gas mixes, timing decompression stops, entering and exiting the diving bell, it’s all a matter of seconds. Having a precise, robust, reliable watch was of vital importance.” 2014 SD4000 3.jpg Sea Dweller 4000 back.jpg Under pressure To understand the importance of the Sea-Dweller, we need to look back to the heyday of man’s attempts to conquer the deep, in the early 1960s. The depth limit for scuba diving with compressed air was some 60 metres, principally for physiological reasons as the pressure beyond such a depth causes the air to become toxic. Nitrogen, which makes up almost 80 per cent of ordinary air, can have a severe narcotic effect – commonly known as the ‘rapture of the deep’ – which alters the mind of even the most experienced divers. From 66 metres down, oxygen also becomes dangerous as hyperoxia affects the nervous system, leading to seizures and loss of consciousness. Counteracting these gas build-ups is not simply a question of returning quickly to the surface, because the diver risks the bends: 40 minutes spent at 60 metres below sea level requires a slow ascent of two hours interspersed by several decompression stops, which must be scrupulously respected to allow the release of the inert gases that have built up in the body – with the accompanying problem of needing sufficient air to stay underwater as long as that takes. And decompression time increases exponentially with depth. To overcome the 60-metre barrier, other solutions were clearly needed. These emerged in the early 1960s with two innovations: the development of alternative breathing gas mixtures to avoid the toxic effect of air, and the concept of saturation diving which would reduce decompression time and the attendant risks. Synthetic air If ordinary air becomes toxic for the human body under the effect of pressure, why not breathe something else? The development of synthetic breathing mixes unlocked the gates to the deep sea. Ordinary air is composed of approximately 80 per cent nitrogen and 20 per cent oxygen, but only oxygen is metabolized by the body and is therefore essential. However, nitrogen becomes toxic and divers fall victim to nitrogen narcosis at depths of 40 to 60 metres, depending on the individual. Scientific research has shown that the proportion of nitrogen in the air may be replaced by helium, and that an artificial helium-oxygen mix (heliox) can be breathed by human beings without any physiological effects. It does not cause narcosis at pressure either. Oxygen toxicity could furthermore be avoided by increasing the proportion of helium in the mix. As a result, the 60-metre barrier could be crossed. Later, other limitations – such as high-pressure nervous syndrome caused by prolonged diving at more than 150 metres using heliox – were circumvented by using gas cocktails with differing quantities of hydrogen, oxygen, helium and nitrogen. With a combination of gas mixes – using different mixes at different stages of the dive – diving limits were pushed even deeper from the early 1960s onwards and decompression times reduced. In 1961, a dive in open water was made to 222 metres in Lake Maggiore in Switzerland. The following year, a diver reached a depth of 313 metres in the Pacific Ocean, off the coast of California. A record that surprised the whole diving community at the time and paved the way for new marine exploration. Living underwater: To dive ever deeper is not the sole ambition of the conquest of the underwater world. The idea of being able to remain underwater for extended periods, or even live there, has long captured the human imagination. In the 1960s, experiments with underwater dwellings in France and in the United States freed mankind from the second constraint of marine exploration: decompression. The very name Sea‑Dweller, chosen for the highly resistant divers' watch conceived by Rolex at the time, reflects those experimental programmes. A major problem in diving is that decompression exponentially curtails useful diving time, with an impact on the depth deep-sea divers can reach as well as on the length of their stay underwater. For example, after some 15 minutes at a depth of 90 metres below the surface, a diver must spend almost two hours in decompression stages before it is safe to return to the surface. Ten minutes at 300 metres would theoretically require more than 20 hours of decompression. A dive lasting a mere few minutes longer or just a few metres deeper leads to a considerable extension in decompression time. The problem here is also physiological: decompression sickness, a condition which can lead to paralysis or even death. When at pressure under water, the human body can be likened to a bottle of sparkling water. Gases under pressure dissolve in water, and, since the body is composed of almost 65 per cent water, part of the gas that is breathed dissolves in the blood and body tissue. An ascent without decompression is equivalent to shaking the bottle of water hard and opening it suddenly: the gas is released in an explosion of bubbles. In the human tissue, the bubbles of gas can cause serious lesions. To release the gas safely, the bottle must be opened gradually and very gently. The purpose of decompression stops is similar, allowing the body to eliminate the accumulated gas in a controlled manner. Saturation diving In the mid-1950s, a scientific discovery proved crucial for the development of deep diving for extended periods. Experiments demonstrated that human tissue has a given capacity for gas absorption when the gas is under pressure. It implies that once the human body has reached its point of saturation with the breathing mix, decompression time remains the same whether a diver stays underwater a few hours, a few days, for weeks or even for months. Only the depth and the type of gas breathed are of consequence for decompression. The discovery led to the development of saturation diving, a technique that literally involves saturating the divers with breathing gases and keeping them in a pressurized environment for long periods of time. As a result, they can carry out a number of deep dives and only need to undergo a single decompression procedure at the very end of the mission. Between dives, they live in an underwater habitat or chamber, a kind of sea house on the seabed, in which the air pressure is maintained at a pressure equal to that of the water at this depth. The divers breathe a synthetic gas mix containing helium, both during the dives and in the chamber. In 1965, an American aquanaut stayed 30 days under the sea, living in a dwelling installed at a depth of 62 metres. During their stay under water, divers saturated in the gas they breathe become completely acclimatized to the pressure at great depth. They can no longer return to surface atmospheric pressure without spending a long period of decompression – dozens of hours – in a hyperbaric chamber. This inescapable process, inherent to the life of a sea dweller, prompted Rolex to develop a special function for its highly resistant new-generation divers’ watch at the time: the helium valve, which provides an escape route for the gas and allows the helium-saturated watch to safely undergo decompression, not unlike the divers who wear it. Highly resistant to external and internal pressure In 1953, during the early days of scuba diving, Rolex created the archetypal divers’ watch: the Oyster Perpetual Submariner, waterproof to a depth of 100 metres. The Submariner’s waterproofness was doubled to 200 metres in 1954, offering a comfortable safety margin for those diving with air, who rarely descended beyond the 60-metre limit. The watch’s performance and reliability soon put it on the wrists of elite divers, with whom Rolex worked closely to continually improve its watches. In 1962, after the record-breaking dive to a depth of 313 metres in California, it became obvious that a new generation of divers’ watches was required, one that would be able to resist the pressure at depths below 200 metres. Rolex – having fixed an experimental watch to the bathyscaphe Trieste and successfully sent it almost 11,000 metres down to the deepest part of the ocean in 1960 – had the technology at its disposal to increase the Submariner’s performance. In 1966, Comex made the first industrial dive to a depth of 160 metres. The French company developed a technique for saturation diving comparable to the idea behind the underwater housing projects, with the difference that the hyperbaric chambers were installed on ships that could sail on missions anywhere around the world. Saturation divers are taken down to working depth in the sea in pressurized diving bells and they return to the warm and dry pressurized chamber on board the support boat by the same method after their dive. Final decompression takes place only at the very end of their tour of duty. Comex, which came to be considered the leader in the field of commercial deep-sea diving, aimed to send its divers to 300 metros by the end of the decade. Rolex decided to make its next divers’ watch waterproof to a depth of 2,000 feet (610 metres). But in addition to increasing its resistance to external water pressure, thereby allowing the watch to descend deeper, feedback from saturation divers had uncovered a hitherto unsuspected requirement: the need to enhance the watch’s ability to withstand excess internal pressure. The Rolex-patented HELIUM ESCAPE VALVE In habitats at overpressure, which are filled with breathing mixes composed largely of helium, the watches behave in a similar manner to the divers’ bodies. The inner part of the watch case becomes saturated with helium as the pressure inside the watch case equalizes with that inside the chamber. Due to the extreme volatility of this light gas, which has the smallest molecules on Earth, the helium gradually penetrates the watch through the gaskets. During the decompression phase, helium is eliminated from human tissue at a faster rate than it can escape from a waterproof watch, with the result that pressure effectively builds up inside the watch case. Divers often observed during decompression that the watch crystal could pop out like a champagne cork from a bottle, due to this internal pressure. The watch must also be able to eliminate the excess helium inside the case. Instead of attempting to make the watch impervious to helium, a practically impossible task, Rolex developed a unidirectional valve on the side of the watch case. It is activated automatically above a certain level of internal pressure to allow the gas to escape from the case, without affecting the waterproofness of the watch. Patented in 1967 by Rolex for its new professional divers’ model, the Oyster Perpetual Sea‑Dweller, the helium valve proved invaluable to the rise of deep-sea saturation diving. Comex swiftly adopted the Sea-Dweller as its official watch, as its divers continued to push ever further the limits for manned deep dives. The open-sea record of 534 metres set in 1988 was followed by another record in 1992 at an experimental depth of 701 metros in a hyperbaric chamber, with a 24-day decompression period – a record which still stands today. 2014 SD4000 4.jpg SPECIFICATIONS Sea-Dweller 4000 Reference: 116600 MODEL CASE Oyster (monobloc middle case, screw-down case back and winding crown), 40 mm MOVEMENT 3135, Manufacture Rolex Mechanical movement with bidirectional self-winding via Perpetual rotor DIAL Black, satin finish BRACELET Oyster three-piece solid links MODEL CASE Oyster (monobloc middle case, screw-down case back and winding crown), 40 mm DIAMETER 40 mm MATERIAL 904L stainless steel superalloy, satin finish SAFETY Helium escape valve CASE BACK Screw-down with Rolex fluting BEZEL Unidirectional rotatable 60-minute graduated bezel with black Cerachrom insert in ceramic, engraved numerals and graduations coated with platinum via magnetron sputtering (PVD) WINDING CROWN Screw-down, Triplock triple waterproofness system CROWN GUARD Integral part of the middle case CRYSTAL Scratch-resistant sapphire WATERPROOFNESS 1,220 metres (4,000 feet) MOVEMENT 3135, Manufacture Rolex Mechanical movement with bidirectional self-winding via Perpetual rotor CALIBRE 3135, Manufacture Rolex Mechanical movement with bidirectional self-winding via Perpetual rotor PRECISION Officially certified Swiss chronometer (COSC) FUNCTIONS Centre hour, minute and seconds hands Instantaneous date at 3 o’clock Stop-seconds for precise time setting OSCILLATOR Frequency: 28,800 beats/hour (4Hz) Paramagnetic blue Parachrom hairspring Breguet overcoil Large balance wheel with variable inertia High-precision regulating via four gold Microstella nuts Traversing balance bridge JEWELLING 31 rubies POWER RESERVE Approximately 48 hours DIAL Black, satin finish COLOUR Black, satin finish HOUR MARKERS Highly legible Chromalight appliques (long-lasting luminescence) in 18 ct white gold HANDS Chromalight hands in 18 ct white gold BRACELET Oyster three-piece solid links MATERIAL 904L stainless steel superalloy, satin finished, polished edges CLASP Oysterlock folding safety clasp Rolex Glidelock extension system (20 mm in increments of 2 mm) Fliplock extension link (26 mm) __________________ (Chill ... It's just a watch Forum.....) NAWCC Member Last edited by Tools; 30 March 2014 at 06:19 AM..