development well drilling

бурение разработочных скважин

1) Oil&Gas technology development drilling

2) Makarov: development well drilling

разведочная скважина

1) General subject: pioneer well, prospecting borehole

2) Geology: prospecting bore, test pit, trial borehole

3) Engineering: exploratory borehole, exploratory hole, new field wildcat, post hole, probe hole, structural test hole, structure hole, trial hole, wildcut

4) Construction: exploratory shaft, prospecting shaft

5) Mining: (нефтяная) wild cat (заложенная наугад), (нефтяная) wildcat (проведённая наугад)

6) Oil: EW (exploratory well), NFW (открыватель нового месторождения, new field wildcat), WC (wildcut), cover hole (при бурении по сетке), curtain hole (при бурении по сетке), development test well, development well, evaluation well, prospecting hole, prospecting well, proving hole, reservoir evaluation well, scout hole, test, trial boring, wild cat, exploratory well, prospect hole, prospect well, test hole, test well, wildcat, wildcat well

7) Geophysics: exploration hole

8) Drilling: tst (test)

9) Sakhalin energy glossary: appraisal well

10) Oil&Gas technology probe well

11) oil&gas: exploration well

капитальный ремонт эксплуатационной скважины

1) Oil: development well workover

2) Drilling: DX (development well workover)

скважина, в продукции которой содержится углекислый газ

1) Oil: development well - carbon dioxide

2) Drilling: DC (development well-carbon dioxide)

опробование скважины

1) Oil: well testing

2) Drilling: wellbore testing

3) Sakhalin energy glossary: analyzing, assay( ing), sampling, test(ing)

4) Gold mining: drillhole sampling

5) oil&gas: well development, well tests, welltest

Produktionsbohrung

f < petr> (Vorgang) ■ production hole drilling

f < petr> ■ production well; exploitation well; development well stand

Lucas, Anthony Francis

SUBJECT AREA: Mining and extraction technology

[br]

b. 9 September 1855 Spalato, Dalmatia, Austria-Hungary (now Split, Croatia)

d. 2 September 1921 Washington, DC, USA

[br]

Austrian (naturalized American) mining engineer who successfully applied rotary drilling to oil extraction.

[br]

A former Second Lieutenant of the Austrian navy (hence his later nickname "Captain") and graduate of the Polytechnic Institute of Graz, Lucas decided to stay in Michigan when he visited his relatives in 1879. He changed his original name, Lucie, into the form his uncle had adopted and became a naturalized American citizen at the age of 30. He worked in the lumber industry for some years and then became a consulting mechanical and mining engineer in Washington, DC. He began working for a salt-mining company in Louisiana in 1893 and became interested in the geology of the Mexican Gulf region, with a view to prospecting for petroleum. In the course of this work he came to the conclusion that the hills in this elevated area, being geological structures distinct from the surrounding deposits, were natural reservoirs of petroleum. To prove his unusual theory he subsequently chose Spindle Top, near Beaumont, Texas, where in 1899 he began to bore a first oil-well. A second drill-hole, started in October 1900, was put through clay and quicksand. After many difficulties, a layer of rock containing marine shells was reached. When the "gusher" came out on 10 January 1901, it not only opened up a new era in the oil and gas business, but it also led to the future exploration of the terrestrial crust.

Lucas's boring was a breakthrough for the rotary drilling system, which was still in its early days although its principles had been established by the English engineer Robert Beart in his patent of 1884. It proved to have advantages over the pile-driving of pipes. A pipe with a simple cutter at the lower end was driven with a constantly revolving motion, grinding down on the bottom of the well, thus gouging and chipping its way downward. To deal with the quicksand he adopted the use of large and heavy casings successively telescoped one into the other. According to Fauvelle's method, water was forced through the pipe by means of a pump, so the well was kept full of circulating liquid during drilling, flushing up the mud. When the salt-rock was reached, a diamond drill was used to test the depth and the character of the deposit.

When the well blew out and flowed freely he developed a preventer in order to save the oil and, even more importantly at the time, to shut the well and to control the oil flow. This assembly, patented in 1903, consisted of a combined system of pipes, valves and casings diverting the stream into a horizontal direction.

Lucas's fame spread around the world, but as he had to relinquish the larger part of his interest to the oil company supporting the exploration, his financial reward was poor. One year after his success at Spindle Top he started oil exploration in Mexico, where he stayed until 1905, when he resumed his consulting practice in Washington, DC.

[br]

Bibliography

1899, "Rock-salt in Louisiana", Transactions of the American Institution of Mining Engineers 29:462–74.

1902, "The great oil-well near Beaumont, Texas", Transactions of the American

Institution of Mining Engineers 31:362–74.

Further Reading

R.S.McBeth, 1918, Pioneering the Gulf Coast, New York (a very detailed description of Lucas's important accomplishments in the development of the oil industry).

R.T.Hill, 1903, "The Beaumont oil-field, with notes on other oil-fields of the Texas region", Transactions of the American Institution of Mining Engineers 33:363–405;

Transactions of the American Institution of Mining Engineers 55:421–3 (contain shorter biographical notes).

WK

эксплуатационная газовая скважина

1) Oil: DG (development gas well), development gas well

2) Drilling: DO (development gas well)

Oeynhausen, Karl von

SUBJECT AREA: Mining and extraction technology

[br]

b. 4 February 1795 Grevenburg, near Höxter, Germany

d. 1 February 1865 Grevenburg, near Höxter, Germany

[br]

German mining officer who introduced fish joints to deep-drilling.

[br]

The son of a mining officer, Oeynhausen started his career in the Prussian administration of the mining industry in 1816, immediately after he had finished his studies in natural sciences and mathematics at the University of Göttingen. From 1847 until his retirement he was a most effective head of state mines inspectorates, first in Silesia (Breslau; now Wroclaw, Poland), later in Westphalia (Dortmund). During his working life he served in all the important mining districts of Prussia, and travelled to mining areas in other parts of Germany, Belgium, France and Britain. In the 1820s, after visiting Glenck's well-known saltworks near Wimpfen, he was commissioned to search for salt deposits in Prussian territory, where he discovered the thermal springs south of Minden which later became the renowned spa carrying his name.

With deeper drills, the increased weight of the rods made it difficult to disengage the drill on each stroke and made the apparatus self-destructive on impact of the drill. Oeynhausen, from 1834, used fish joints, flexible connections between the drill and the rods. Not only did they prevent destructive impact, but they also gave a jerk on the return stroke that facilitated disengagements. He never claimed to have invented the fish joints: in fact, they appeared almost simultaneously in Europe and in America at that time, and had been used since at least the seventeenth century in China, although they were unknown in the Western hemisphere.

Using fish joints meant the start of a new era in deep-drilling, allowing much deeper wells to be sunk than before. Five weeks after Oeynhausen, K.G. Kind operated with a different kind of fish joint, and in 1845 another Prussian mining officer, Karl Leopold Fabian (1782–1855), Director of the salt inspectorate at Schönebeck, Elbe, improved the fish joints by developing a special device between the rod and the drill to enable the chisel, strengthened by a sinker bar, to fall onto the bottom of the hole without hindrance with a higher effect. The free-fall system became another factor in the outstanding results of deep-drilling in Prussia in the nineteenth century.

[br]

Principal Honours and Distinctions

Honorary PhD, University of Berlin 1860.

Bibliography

1822, Versuch einer geognostischen Beschreibung von Oberschlesien, Essen.

1824, "Über die geologische Ähnlichkeit des steinsalzführenden Gebirges in Lothringen und im südlichen Deutschland mit einigen Gegenden auf beiden Ufern der Weser", Karstens Archiv für Bergbau und Hüttenwesen 8: 52–84.

1847, "Bemerkungen über die Anfertigung und den Effekt der aus Hohleisen zusammengesetzten Bohrgestänge", Archiv fur Mineralogie, Geognosie, Bergbau und Hüttenkunde 21:135–60.

1832–3, with H.von Dechen, Über den Steinkohlenbergbau in England, 2 parts, Berlin.

Further Reading

von Gümbel, "K.v.Oeynhausen", Allgemeine deutsche Biographie 25:31–3.

W.Serlo, 1927, "Bergmannsfamilien. Die Familien Fabian und Erdmann", Glückauf.

492–3.

D.Hoffmann, 1959, 150 Jahre Tiefbohrungen in Deutschland, Vienna and Hamburg (a careful elaboration of the single steps and their context with relation to the development of deep-drilling).

WK

опорная скважина

1) Geology: test hole, test pit

2) Mining: stable hole (при разметке серии скважин)

3) Oil: appraisal well, development test well, evaluation well, (геолого-разведочная) expendable well (бурится с целью получения геологической информации, а не с целью дальнейшей добычи углеводородов), key-well, record hole (проходимая с отбором керна от поверхности до конечной глубины), reservoir evaluation well, stratigraphic hole (для изучения геологического разреза), stratigraphic well, test well, key hole

4) Geophysics: stratigraphic test well, offset well (Наиболее часто употребляемое словосочетание в контексте межскважинной корелляции геофизических данных, геонавигации и пр. Иногда просто offset)

5) Drilling: key well

6) oil&gas: key borehole

Adamson, Daniel

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Metallurgy, Steam and internal combustion engines

[br]

b. 1818 Shildon, Co. Durham, England

d. January 1890 Didsbury, Manchester, England

[br]

English mechanical engineer, pioneer in the use of steel for boilers, which enabled higher pressures to be introduced; pioneer in the use of triple-and quadruple-expansion mill engines.

[br]

Adamson was apprenticed between 1835 and 1841 to Timothy Hackworth, then Locomotive Superintendent on the Stockton \& Darlington Railway. After this he was appointed Draughtsman, then Superintendent Engineer, at that railway's locomotive works until in 1847 he became Manager of Shildon Works. In 1850 he resigned and moved to act as General Manager of Heaton Foundry, Stockport. In the following year he commenced business on his own at Newton Moor Iron Works near Manchester, where he built up his business as an iron-founder and boilermaker. By 1872 this works had become too small and he moved to a 4 acre (1.6 hectare) site at Hyde Junction, Dukinfield. There he employed 600 men making steel boilers, heavy machinery including mill engines fitted with the American Wheelock valve gear, hydraulic plant and general millwrighting. His success was based on his early recognition of the importance of using high-pressure steam and steel instead of wrought iron. In 1852 he patented his type of flanged seam for the firetubes of Lancashire boilers, which prevented these tubes cracking through expansion. In 1862 he patented the fabrication of boilers by drilling rivet holes instead of punching them and also by drilling the holes through two plates held together in their assembly positions. He had started to use steel for some boilers he made for railway locomotives in 1857, and in 1860, only four years after Bessemer's patent, he built six mill engine boilers from steel for Platt Bros, Oldham. He solved the problems of using this new material, and by his death had made c.2,800 steel boilers with pressures up to 250 psi (17.6 kg/cm²).

He was a pioneer in the general introduction of steel and in 1863–4 was a partner in establishing the Yorkshire Iron and Steel Works at Penistone. This was the first works to depend entirely upon Bessemer steel for engineering purposes and was later sold at a large profit to Charles Cammell \& Co., Sheffield. When he started this works, he also patented improvements both to the Bessemer converters and to the engines which provided their blast. In 1870 he helped to turn Lincolnshire into an important ironmaking area by erecting the North Lincolnshire Ironworks. He was also a shareholder in ironworks in South Wales and Cumberland.

He contributed to the development of the stationary steam engine, for as early as 1855 he built one to run with a pressure of 150 psi (10.5 kg/cm) that worked quite satisfactorily. He reheated the steam between the cylinders of compound engines and then in 1861–2 patented a triple-expansion engine, followed in 1873 by a quadruple-expansion one to further economize steam. In 1858 he developed improved machinery for testing tensile strength and compressive resistance of materials, and in the same year patents for hydraulic lifting jacks and riveting machines were obtained.

He was a founding member of the Iron and Steel Institute and became its President in 1888 when it visited Manchester. The previous year he had been President of the Institution of Civil Engineers when he was presented with the Bessemer Gold Medal. He was a constant contributor at the meetings of these associations as well as those of the Institution of Mechanical Engineers. He did not live to see the opening of one of his final achievements, the Manchester Ship Canal. He was the one man who, by his indomitable energy and skill at public speaking, roused the enthusiasm of the people in Manchester for this project and he made it a really practical proposition in the face of strong opposition.

[br]

Principal Honours and Distinctions

President, Institution of Civil Engineers 1887.

President, Iron and Steel Institute 1888. Institution of Civil Engineers Bessemer Gold Medal 1887.

Further Reading

Obituary, Engineer 69:56.

Obituary, Engineering 49:66–8.

Obituary, Proceedings of the Institution of Civil Engineers 100:374–8.

H.W.Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press (provides an illustration of Adamson's flanged seam for boilers).

R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (covers the development of the triple-expansion engine).

RLH

буровые установки для эксплуатационного и глубокого разведочного бурения

General subject: drilling rigs for development and deep-well exploratory drilling

выемка

1) General subject: chamfer, channel, coulisse, cut, ditch, excavation, flute, gab, groove, hollow, housing, indent, indentation, notch (особ. на бирке), notching, removal, roach (у паруса), rut, sink, ward (в бородке ключа, в замке), ward (в бородке ключа и в замке), extraction

2) Geology: crank, dent, digging (глины), dint (от удара), extraction (руды), fault trace rift, getter, primary mining (камер), vault

3) Biology: excision

4) Aviation: hollow space

5) Naval: channel, tongue

6) Medicine: trough, vallecula, valley

7) American: gouge

8) Obsolete: dell

9) Military: hole (элемент окопа)

10) Engineering: crater, depression, digging, drawing, excavation (грунта), excavation work, fluting, gouge (полученная выдалбливанием), gutter, mining, pit, pocket, recess, sinker throat, sinking, x

11) Agriculture: channel (у седла)

12) Construction: earth cut, excavating (грунта), excavation (в грунте), flute (напр. на колонне), leat, dug-out

13) Mathematics: dimple, opening

14) Railway term: ditch cut, rabbet, removing

15) Law: caption, seizure (имущества, документов)

16) Automobile industry: channelling, cut-out, digging (грунта), scallop

17) Mining: broken working (столбов), champfer, kerve, kirve, mining extraction, recovery, robbing (столбов или целиков), stoping (очистная), taking, winning, withdrawal, withdrawing, working

18) Forestry: hilum, slit

19) Metallurgy: sprue (в штампе)

20) Polygraphy: gap

21) Information technology: collection (писем из почтового ящика)

22) Oil: cutout, gouge (дефект), removal (в периферийном зубе шарошки или между зубьями долота)

23) Special term: kerf

24) Fishery: emargination

25) Mechanic engineering: race (для маховика или кривошипа)

26) Drilling: cavity, furrow, pulling

27) Oilfield: cutting (процесс), digging-out (процесс), dugout (углубление в грунте, породе)

28) Polymers: slot

29) Labor protection: open sunken reservoir

30) Automation: cave, concave, concavity, impression, takeout, throat

31) Roll stock: scallops

32) Arms production: mortise

33) leg.N.P. seizure (criminal procedure), taking out (criminal procedure)

34) Mineral products: harvest (торфа( как единица добычи с определенной площади))

35) Makarov: a slight depression in the ground, actual mining (руды или угля), cannelure, depression (углубление), exavation, excavation (напр. дорожная), getting (угля), groove (углубление), hold-down groove (в боковой стенке пресс-формы), indention, indenture, kerf (между зубьями пилы), mucro (верхушки листа), pit (углубление), recess (углубление), removal (горной породы), removal from (извлечение одного из другого), scoop, slight depression in the ground, socket, ward (в бородке ключа и, соответственно, в замке), well, winning (угля)

36) Gold mining: development

37) General subject: channeling, cutoff trench

газовая скважина для эксплуатационного бурения

General subject: gas well for development drilling

amortization

Fin

1. a method of recovering (deducting or writing off) the capital costs of intangible assets over a fixed period of time.

EXAMPLE

For tax purposes, the distinction is not always made between amortization and depreciation, yet amortization remains a viable financial accounting concept in its own right.

     It is computed using the straight-line method of depreciation: divide the initial cost of the intangible asset by the estimated useful life of that asset.

Initial cost/useful life = amortization per year

For example, if it costs $10,000 to acquire a patent and it has an estimated useful life of 10 years, the amortized amount per year is $1,000.

$10,000/10 = $1,000 per year

     The amount of amortization accumulated since the asset was acquired appears on the organization’s balance sheet as a deduction under the amortized asset.

     While that formula is straightforward, amortization can also incorporate a variety of noncash charges to net earnings and/or asset values, such as depletion, write-offs, prepaid expenses, and deferred charges. Accordingly, there are many rules to regulate how these charges appear on financial statements. The rules are different in each country, and are occasionally changed, so it is necessary to stay abreast of them and rely on expert advice.

     For financial reporting purposes, an intangible asset is amortized over a period of years. The amortizable life—“useful life”—of an intangible asset is the period over which it gives economic benefit.

     Intangibles that can be amortized can include:

      Copyrights, based on the amount paid either to purchase them or to develop them internally, plus the costs incurred in producing the work (wages or materials, for example). At present, a copyright is granted to a corporation for 75 years, and to an individual for the life of the author plus 50 years. However, the estimated useful life of a copyright is usually far less than its legal life, and it is generally amortized over a fairly short period;

     Cost of a franchise, including any fees paid to the franchiser, as well legal costs or expenses incurred in the acquisition. A franchise granted for a limited period should be amortized over its life. If the franchise has an indefinite life, it should be amortized over a reasonable period not to exceed 40 years;

     Covenants not to compete: an agreement by the seller of a business not to engage in a competing business in a certain area for a specific period of time. The cost of the not-tocompete covenant should be amortized over the period covered by the covenant unless its estimated economic life is expected to be less;

     Easement costs that grant a right of way may be amortized if there is a limited and specified life; Organization costs incurred when forming a corporation or a partnership, including legal fees, accounting services, incorporation fees, and other related services.

     Organization costs are usually amortized over 60 months;

     Patents, both those developed internally and those purchased. If developed internally, a patent’s “amortizable basis” includes legal fees incurred during the application process. A patent should be amortized over its legal life or its economic life, whichever is the shorter;

     Trademarks, brands, and trade names, which should be written off over a period not to exceed 40 years;

     Other types of property that may be amortized include certain intangible drilling costs, circulation costs, mine development costs, pollution control facilities, and reforestation expenditures;

     Certain intangibles cannot be amortized, but may be depreciated using a straight-line approach if they have “determinable” useful life. Because the rules are different in each country and are subject to change, it is essential to rely on specialist advice.

2. the repayment of the principal and interest on a loan in equal amounts over a period of time