The Gutta Percha Company was an English company formed in 1845 to make a variety of products from the recently introduced natural rubber gutta-percha. Unlike other natural rubbers, this material was thermoplastic allowing it to be easily moulded. Nothing else like it was available to manufacturing until well into the twentieth century when synthetic plastics were developed. [1]
Gutta-percha proved to be an ideal insulator for submarine telegraph cables. The company started making this type of cable in 1848 and it rapidly became their main product, on which it had a near monopoly. The world's first international telegraph connection under the sea, a link from Dover to Calais in 1851, used a cable made by the company. Except for a few early ones, submarine cables were armoured with iron, then later steel, wires. [2] The Gutta Percha Company made only the insulated cores, not the complete cable, until 1864 when it merged in to the Telegraph Construction and Maintenance Company.
Gutta-percha is a natural rubber that has the unusual property (for 19th-century materials) of being thermoplastic. It can be moulded after placing in hot water and will reharden when cool. It was brought to attention in Europe by William Montgomerie, a Scottish surgeon of the East India Company in Singapore where the trees from which the material is obtained are native. Montgomerie sent samples to the Society of Arts in London in 1843 with the idea that the material could be used for medical apparatus. [3]
In 1844, Montgomerie left samples with Charles Mackintosh's raincoat company. A partner in the company, Thomas Hancock, passed samples to his brother Charles who was trying to invent a new bottle stopper made from cemented ground cork. Hancock then abandoned his original idea and took out a patent for bottle stoppers made from gutta-percha. [4]
The company was formed on 4 February 1845 by partners Charles Hancock and Henry Bewley, a Dublin chemist making soda water, initially to make Hancock's bottle stoppers. [5] Their premises were at Wharf Road, Islington, London. [6] The range of products was soon greatly expanded, and included machine belts, shoe soles, and toys. However, one of their most important products was gutta-percha insulated electrical cable. [7]
Bewley was also a lead pipe maker. He had designed a machine for extruding lead pipes and on the formation of the Gutta Percha Company, he used this machine for extruding gutta-percha tubing. The company did not at first use this machine for insulating electrical cable. The method initially used was to apply strips of gutta-percha to copper wire. The resulting seam in the insulation was to prove problematic for underwater cables as it provided a route for the ingress of water. [8]
Gutta-percha made possible practical submarine telegraph cables because it was both waterproof and resistant to seawater as well as being thermoplastic. Gutta-percha's use as an electrical insulator was first suggested by Michael Faraday after he tested a sample. [9] Many possible insulation schemes for a submarine cable, such as hemp impregnated with tar, were tested by Charles Wheatstone who had suggested a cable between England and France as early as 1840. None of these schemes were successful. Wheatstone had looked at gutta-percha but could not find a good way of applying it to the conductor. [10]
On hearing of this possible application for gutta-percha, Hancock designed a machine for applying it to a conductor seamlessly. Hancock's machine was an adaptation of Bewley's tube extruding machine. However, Hancock denied Bewley the right to use the machine. The dispute resulted in Hancock leaving and setting up the rival West Ham Gutta Percha Company. Hancock lost the dispute in court and his company went bankrupt. [11] The first order for gutta-percha electrical cable came in 1848 from the South Eastern Railway for a 2-mile (3.2 km) length for experiment. South Eastern Railway, in collaboration with the Submarine Telegraph Company, wished to extend their telegraph line through to France. The cable was successfully tested off Folkestone from the ship Princess Clementine with messages sent through the cable to London. The railway afterwards used the cable in a wet railway tunnel. [12]
This trial was followed in 1849 by an order for 25 nautical miles (46 km) of cable from the Submarine Telegraph Company to lay a cable from Dover to Calais. This cable, laid in 1850, soon failed, largely because the Submarine Telegraph Company failed to have it armoured. Undeterred, the company placed a new order in 1850, but this time the cable was to be sent to a wire rope manufacturer for armouring before laying. This order was four times [13] as large as the 1849 order since the new cable was to have four gutta-percha insulated cores. This cable was a success, and became the first working oceanic submarine cable. [14]
Although the Gutta Percha Company were the first to make a cable for crossing an ocean, they were not the first to make a gutta-percha insulated underwater cable. Faraday published his suggestion in 1848, but had previously privately recommended gutta-percha to William Siemens of Siemens Brothers who passed the information to his brother Werner von Siemens. [15] In 1847 Werner invented a machine, described as like a macaroni machine, for applying gutta-percha to a conductor seamlessly. [16] His company, Siemens & Halske, then laid underground gutta-percha cables extensively around Germany, including one that crossed the Rhine in 1849. [17] However, the Gutta Percha Company were the first to make a cable that crossed an ocean. [18] The Gutta Percha Company does not appear to have had any intellectual property issues with Siemens. This was because Siemens' work was largely for military purposes and consequently nothing was patented initially. Siemens even obtained the gutta-percha from the Gutta Percha Company. The cables were not just for military communications, one 1848 cable in Kiel harbour had the overtly military purpose of setting off mines. [19]
Gutta-percha insulated core rapidly became the chief product of the company. [20] In 1851–1852 they produced 1,300 nautical miles (2,400 km) of it. The company had a monopoly on this product, and the cores for nearly all submarine cables made before 1865 were made by them. The Gutta Percha Company never made finished cables; they supplied the cores and other companies, mostly wire rope manufacturers, laid them into the steel armouring to make complete cables. In April 1864, the Gutta Percha Company merged with Glass, Elliot and Company, one of these wire rope makers, to form the Telegraph Construction and Maintenance Company who could supply completed cables and provide maintenance for them. [21] The merger was at the instigation of John Pender who became chairman of the company. Pender's motivation in this was that the new company should make the first successful transatlantic telegraph cable for the Atlantic Telegraph Company. [22]
The quality of gutta-percha, as supplied by the Gutta Percha Company, [23] was extensively discussed by Charles Bright in his book Submarine Telegraphs. [24] Bright's father, Charles Tilston Bright, was the chief electrician (chief engineer) of the Magnetic Telegraph Company, a major customer of the Gutta Percha Company, [25] and later electrician-in-chief of the first transatlantic telegraph cable project of the Atlantic Telegraph Company, also using the Gutta Percha Company's product. [26]
Gutta-percha from different regions contains different amounts of resin, resulting in variations in quality. For electrical cables, the resin content needs to be minimal. The best gutta-percha came from Java and Makassar, the worst came from Borneo. [27] The factory purification process could also make a difference. A good commercial gutta-percha would have around 80% gutta and 15% or less of resin. [28] Water content has no appreciable effect on the electrical resistance of the material until the content reaches a threshold of around 2–3%. [29]
Highly purified gutta-percha is almost entirely resistant to chemical attack and ingress of water. However, obtaining this level of purity was not economical for submarine cables. Impure gutta-percha oxidises and becomes brittle. The rate of deterioration is very slow for cable permanently in the water, but cable crossing the landing zone is exposed to frequent changes in temperature and cycles of exposure and submerging. This environment could cause the insulation to crumble and expose the conductor. [30] For this reason, these sections of cable were protected with an additional layer of another material such as India rubber. [31]
Additives to the gutta-percha could greatly affect quality. The material supplied for the Siemens cables by the Gutta Percha Company had a high sulphur content. This, together with poor joints and poor manufacturing by Siemens, caused many of the early Siemens cables to quickly fail. [32]
An electrical telegraph was a point-to-point text messaging system, used from the 1840s until the mid 20th century when it was slowly replaced by other telecommunication systems. At the sending station switches connected a source of current to the telegraph wires. At the receiving station the current activated electromagnets which moved indicators, providing either a visual or audible indication of the text. It was the first electrical telecommunications system and the most widely used of a number of early messaging systems called telegraphs, that were devised to communicate text messages more rapidly than by physical transportation. Prior to the electric telegraph, semaphore systems were used, including beacons, smoke signals, flag semaphore, and optical telegraphs for visual signals to communicate over distances of land.
A submarine communications cable is a cable laid on the sea bed between land-based stations to carry telecommunication signals across stretches of ocean and sea, also lake or lagoon. The first submarine communications cables laid beginning in the 1850s carried telegraphy traffic, establishing the first instant telecommunications links between continents, such as the first transatlantic telegraph cable which became operational on 16 August 1858. Subsequent generations of cables carried telephone traffic, then data communications traffic. Modern cables use optical fibre technology to carry digital data, which includes telephone, Internet and private data traffic.
Transatlantic telegraph cables were undersea cables running under the Atlantic Ocean for telegraph communications. Telegraphy is now an obsolete form of communication and the cables have long since been decommissioned, but telephone and data are still carried on other transatlantic telecommunications cables. The first cable was laid in the 1850s from Valentia in western Ireland to Bay of Bulls, Trinity Bay, Newfoundland. The first communications occurred on 16 August 1858, but the line speed was poor and efforts to improve it caused the cable to fail after three weeks.
Gutta-percha is a tree of the genus Palaquium in the family Sapotaceae. The name also refers to the rigid, naturally biologically inert, resilient, electrically nonconductive, thermoplastic latex derived from the tree, particularly from Palaquium gutta; it is a polymer of isoprene which forms a rubber-like elastomer.
Chatterton’s compound is an adhesive waterproof insulating compound that was used in early submarine telegraph cables. It was patented in 1859 by John Chatterton and Willoughby Smith.
A stopper or cork is a cylindrical or conical closure used to seal a container, such as a bottle, tube or barrel. Unlike a lid or bottle cap, which encloses a container from the outside without displacing the inner volume, a bung is partially or wholly inserted inside the container to act as a seal.
The Electric Telegraph Company (ETC) was a British telegraph company founded in 1846 by William Fothergill Cooke and John Ricardo. It was the world's first public telegraph company. The equipment used was the Cooke and Wheatstone telegraph, an electrical telegraph developed a few years earlier in collaboration with Charles Wheatstone. The system had been taken up by several railway companies for signalling purposes, but in forming the company Cooke intended to open up the technology to the public at large.
Sir Charles Tilston Bright was a British electrical engineer who oversaw the laying of the first transatlantic telegraph cable in 1858, for which work he was knighted.
Siemens Brothers and Company Limited was an electrical engineering design and manufacturing business in London, England. It was first established as a branch in 1858 by a brother of the founder of the German electrical engineering firm Siemens & Halske. The principal works were at Woolwich where cables and light-current electrical apparatus were produced from 1863 until 1968. The site between the Thames Barrier and Woolwich Dockyard has retained several buildings of historic interest. New works were built at Stafford in 1903 and Dalston in 1908.
Johann Georg Halske was a German master mechanic.
Willoughby Smith was an English electrical engineer who discovered the photoconductivity of the element selenium. This discovery led to the invention of photoelectric cells, including those used in the earliest television systems.
William Thomas Henley (1814–1882) was a pioneer in the manufacture of telegraph cables. He was working as a porter in Cheapside in 1830, leaving after disputes with his employer, and working at the St Katherine Docks for six years. During those years he was determined to learn a trade and used money from an aunt to purchase a lathe, vice and lumber with which he made a work bench. With those tools he taught himself to turn wood and brass and began to experiment, including with electricity.
Charles Vincent Walker FRS was an English electrical engineer and publisher, a major influence on the development of railway telecommunications, he was also the first person to send a submarine telegraph signal.
Sir Richard Atwood Glass was an English telegraph cable manufacturer and a Conservative politician who sat in the House of Commons from 1868 to 1869.
William Montgomerie (1797–1856) was a Scottish military doctor with the East India Company, and later head of the medical department at Singapore. He is best known for promoting the use of gutta-percha in Europe. This material was an important natural rubber that made submarine telegraph cables possible. Montgomerie was involved in spice cultivation as head of the Singapore botanical experimental gardens and at his personal estate in Singapore. The latter never became economically viable, but he received a Society of Arts gold medal for nutmeg cultivation. He was also responsible for building the first lunatic asylum in Singapore. Montgomerie died at Barrackpore in India a few years after taking part in the Second Anglo-Burmese War as Superintendent Surgeon.
The Okonite Company is an American manufacturer of insulated wire and cable.
The India Rubber, Gutta Percha and Telegraph Works Company was a London-based company based in Silvertown, East London. It was founded by Stephen William Silver in March 1864 as Silver's Indiarubber Works and Telegraph Cable Company Ltd. However in July that year the name was changed to the India Rubber, Gutta Percha and Telegraph Works Company.
The Submarine Telegraph Company was a British company which laid and operated submarine telegraph cables.
The British and Irish Magnetic Telegraph Company was founded by John Brett in 1850. The Magnetic was the principal competitor to the largest telegraph company in the United Kingdom, the Electric Telegraph Company. The Magnetic was the leading company in Ireland, while the Electric was the leading company in mainland Britain. Between them, they dominated the market until the telegraph was nationalised in 1870.
In the nineteenth century, the United Kingdom had the world's first commercial telegraph company. British telegraphy dominated international telecommunications well into the twentieth. Telegraphy is the sending of textual messages by human operators using symbolic codes. Electrical telegraphy used conducting wires to send messages, often incorporating a telegram service to deliver the telegraphed communication from the telegraph office. This is distinct from optical telegraphy that preceded it and the radiotelegraphy that followed. Though Francis Ronalds first demonstrated a working telegraph over a substantial distance in 1816, he was unable to put it into practical use. Starting in 1836, William Fothergill Cooke, with the scientific assistance of Charles Wheatstone, developed the Cooke and Wheatstone telegraph. The needle telegraph instrument suggested by Wheatstone, the battery invented by John Frederic Daniell, and the relay invented by Edward Davy were important components of this system.