diffusion+method

метод сплавления

1) Electronics: fusion method

2) Microelectronics: alloy-diffusion technique, alloying technique

опробователь грунтовых вод на загрязнение

Makarov: diffusion sampler and method of use

घन

ghaná

mf (ā́)n. ( han) a striker, killer, destroyer RV. I, 4, 8; III, 49, 1; IV, 38, 1; VIII, 96, 18 ;

compact, solid, material, hard, firm, dense, I, 8, 3 ;
(ghanā́ for -námā́) Suṡr. etc.;
coarse, gross;
viscid, thick, inspissated Suṡr. Bhartṛ. Kathās. XXIV, 93 ;
full of (in comp.), densely filled with (in comp.) MBh. I, XIII Ragh. VIII, 90 Ratnâv. IV, 2 ;
uninterrupted Pañcat. III, 14, 11 ;
dark (cf. - ṡyāma) BhP. IV, 5, 3 ;
deep (as sound;
colour) MBh. I, 6680 VarBṛS. XlIII, 19 ;
complete, all Kathās. IV, 53 ;
auspicious, fortunate W. ;
m. (= φόνος) slaying RV. VI, 26, 8 ;
an iron club, mace, weapon shaped like a hammer
I, 33, 4; 36, 16; 63, 5; IX, 97, 16 AV. X, 4, 9 ;
any compact mass orﾠ substance (generally ifc.) ṠBr. XIV etc.. ;
(said of the foetus in the 2nd month Nir. XIV, 6 Laghuj. III, 4);
ifc. mere, nothing but (e.g.. vijñāna-ghaná,
« nothing but intuition» ṠBr. XIV)
MāṇḍUp. 5 PraṡnUp. V, 5 BhP. VIII ;
f. (cf. ambu-, ayo-);
a collection, multitude, mass, quantity W. ;
vulgar people Subh. ;
a cloud MBh. etc. (ifc. f. ā Hariv. 2660);
talc L. ;
the bulbous root of Cyperus Hexastachys communis Suṡr. VI ;
a peculiar form of a temple Hcat. II, 1, 389 ;
a particular method of reciting the RV. and Yajur-veda (cf. RTL. p. 409);
the cube (of a number), solid body (in geom.) Laghuj. Sūryas. ;
phlegm ( kapha) L. ;
the body L. ;
extension, diffusion W. ;
n. any brazen orﾠ metallic instrument orﾠ plate which is struck (cymbal, bell, gong, etc.) Hariv. 8688 ;
iron L. ;
tin L. ;
a mode of dancing (neither quick nor slow) L. ;
darkness L. ;
(am) ind. closely Ratnâv. III 9 ;
( dhvan, to sound) deep Rājat. V, 377 ;
very much W. ;
(ā) f. N. of a stringed instrument;
Glycine debilis L. ;
a kind of creeper L. ;
- घनकपीवत्
- घनकफ
- घनकाल
- घनक्षम
- घनगर्जित
- घनगोलक
- घनघन
- घनचय
- घनच्छद
- घनज
- घनजम्बाल
- घनज्वाला
- घनता
- घनताल
- घनतिमिर
- घनतोय
- घनतोल
- घनत्व
- घनत्वच्
- घनद्रुम
- घनधातु
- घनध्वनि
- घननाभि
- घननीहार
- घनपत्त्र
- घनपद
- घनपदवी
- घनपयोधर
- घनपल्लव
- घनपाषण्ड
- घनप्रिया
- घनफल
- घनभित्ति
- घनमुद्
- घनमूल
- घनरव
- घनरस
- घनरुच्
- घनरुचिरकलाप
- घनरूपा
- घनवर
- घनवर्त्मन्
- घनवल्लिका
- घनवल्ली
- घनवाच्
- घनवात
- घनवारि
- घनवास
- घनवाहन
- घनवीथि
- घनव्यपाय
- घनव्यूह
- घनशब्द
- घनशृङ्गी
- घनश्याम
- घनसंवृत्ति
- घनसमय
- घनसार
- घनसिक्थ
- घनस्कन्ध
- घनस्वन
- घनहस्तसंख्या

достигать

•

At room temperature the electron's average diffusion distance for the p-n junction after injection may be as much as several microns.

•

This type of potential ranges up to about 100 millivolts.

•

The cadmium content of zinc concentrates may run to 1-2 percent.

•

The amount of mercury here may run as high as two parts per billion.

•

The permeability of iron may be as great as 2000.

•

After the orbit has attained its desired altitude...

•

This amounts up to one third of the velocity of light.

•

The output reaches its peak.

•

The number of formulations ( составов) runs (or ranges) into the thousands.

•

In metazoans, this may amount to as much as 11% of the deoxycytidines.

•

The pressure can be raised to get to point 3.

•

When equilibrium is attained (or established),...

II

. многого можно достигнуть; осуществлять

•

Almost complete conversion can be obtained at ordinary pressure.

•

Maximum efficiency is accomplished when...

•

No improvement was brought about (or attained, or achieved) by applying this method.

•

A reduction in metal thickness can be realized.

•

This realignment of the molecules can be brought about in several ways.

III

. вне пределов досягаемости

•

These bodies of magma do not make it to the surface and solidify at depth...

•

Almost all the heat generated in the earth's mantle finds its way to the ocean floor.

* * *

Достигать -- to achieve, to attain, to accomplish, to reach, to measure up to; to amount (всегда с указанием значения величины); to meet, to realize (о цели); to make (об успехах)

 This was accomplished by extending the outer legs of the coils to a large radial distance.

 This is usually accomplished by proper installation practices as described in reference [...].

 While the resulting engine will not measure up to the full potential which today's technology could provide, the compromise is small.

 The total solids burden passing into the second chamber amounted to 4207 mg/SCM.

 Tighten the flange nuts alternately in small equal increments until one of the nuts reaches the minimum recommended torque.

— достигать... уровня развития

— достигать... экономии по

— достигать величины

— достигать двумя путями

— достигать значительных успехов в

— достигать компромисса между

— достигать максимального значения

— достигать максимума

— достигать наивысшего уровня

— достигать наинизшего уровня

— достигать некоторого успеха

— достигать, но не превышать

— достигать полных оборотов

— достигать предела своих возможностей

— достигать примерно

— достигать путем

— достигать равновесия

— достигать равновесного состояния

— достигать успехов в

— достигать цели

— достичь этого можно, лишь

— занижение достигает

— не достигать поставленной цели

— не достигать

— не достигать расчётного срока службы

— не достигать цели

— такой..., какого только можно достичь

— чтобы достичь этого

используемый

. мало использоваться; наиболее широко используемый

•

Another type of indicator in use (or used) is the diffusion type.

•

A single laser beam has many thousands of times the signal-carrying capacity of any other transmission medium in service.

•

The major design method employed is based on this principle.

* * *

— в значении, используемом

— используемый в настоящее время

— используемый для борьбы с

— используемый... представлял собой

— используемый при

— наиболее широко используемый

— обычно используемый

занимать принадлежащее ... по праву место

Занимать принадлежащее (ему) по праву место-- Ion diffusion is rapidly taking its place as a reliable method of implanting silicon semiconductor sensors.

Boxdiffusion

Boxdiffusion f ME box (method) diffusion

константа

ж. constant

акустическая константа — acoustical constant

константа анизотропии — anisotropy constant

константа взаимодействия — coupling constant; force constant

константа диссоциации — equilibrium constant for dissociation

константа диффузии — diffusion constant

зависимая константа — contiguous constant

константа ионизации — dissociation constant

константа кислотности — acidity constant

логическая константа — logical constant

материальная константа — material constant

независимая константа — independent constant

константа основности — basicity constant

константа равновесия — equilibrium constant

константа равновесия изотопного обмена — isotope exchange equilibrium constant

константа равновесия реакции — reaction equilibrium constant

константа распада — decay constant

константа скорости реакции — reaction rate constant

константа скорости суммарной реакции — overall rate constant

оператор определения константы — define constant statement

метод выравнивания констант — method of fitting constants

константа типа C; символьная константа — C-type constant

константа с фиксированной точкой — fixed-point constant

Goulding, John

SUBJECT AREA: Textiles

[br]

b. 1791 Massachusetts, USA d. 1877

[br]

American inventor of an early form of condenser carding machine.

[br]

The condenser method of spinning was developed chiefly by manufacturers and machine makers in eastern Massachusetts between 1824 and 1826. John Goulding, a machinist from Dedham in Massachusetts, combined the ring doffer, patented by Ezekiel Hale in 1825, and the revolving twist tube, patented by George Danforth in 1824; with the addition of twisting keys in the tubes, the carded woollen sliver could be divided and then completely and continuously twisted. He divided the carded web longitudinally with the ring doffer and twisted these strips to consolidate them into slubbings. The dividing was carried out by covering the periphery of the doffer cylinder with separate rings of card clothing and spacing these rings apart by rings of leather, so that instead of width-way detached strips leaving the card, the strips were continuous and did not require piecing. The strips were passed through rotating tubes and wound on bobbins, and although the twist was false it sufficed to compress the fibres together ready for spinning. Goulding patented his invention in both Britain and the USA in 1826, but while his condensers were very successful and within twenty years had been adopted by a high proportion of woollen mills in America, they were not adopted in Britain until much later. Goulding also worked on other improvements to woollen machinery: he developed friction drums, on which the spools of roving from the condenser cards were placed to help transform the woollen jenny into the woollen mule or jack.

[br]

Bibliography

1826, British patent no. 5,355 (condenser carding machine).

Further Reading

D.J.Jeremy, 1981, Transatlantic Industrial Revolution. The Diffusion of Textile Technologies Between Britain and America, 1790–1830s, Oxford (provides a good explanation of the development of the condenser card).

W.English, 1969, The Textile Industry, London (a brief account).

C.Singer (ed.), 1958, A History of Technology, Vol. IV, Oxford: Clarendon Press (a brief account).

RLH

Houldsworth, Henry

SUBJECT AREA: Textiles

[br]

b. 1797 Manchester (?), England

d. 1868 Manchester (?), England

[br]

English cotton spinner who introduced the differential gear to roving frames in Britain.

[br]

There are two claimants for the person who originated the differential gear as applied to roving frames: one is J.Green, a tinsmith of Mansfield, in his patent of 1823; the other is Arnold, who had applied it in America and patented it in early 1823. This latter was the source for Houldsworth's patent in 1826. It seems that Arnold's gearing was secretly communicated to Houldsworth by Charles Richmond, possibly when Houldsworth visited the United States in 1822–3, but more probably in 1825 when Richmond went to England. In return, Richmond received information about parts of a cylinder printing machine from Houldsworth. In the working of the roving frame, as the rovings were wound onto their bobbins and the diameter of the bobbins increased, the bobbin speed had to be reduced to keep the winding on at the same speed while the flyers and drawing rollers had to maintain their initial speed. Although this could be achieved by moving the driving belt along coned pulleys, this method did not provide enough power and slippage occurred. The differential gear combined the direct drive from the main shaft of the roving frame with that from the cone drive, so that only the latter provided the dif-ference between flyer and bobbin speeds, i.e. the winding speeds, thus taking away most of the power from that belt. Henry Houldsworth Senior (1774–1853) was living in Manchester when his son Henry was born, but by 1800 had moved to Glasgow. He built several mills, including a massive one at Anderston, Scotland, in which a Boulton \& Watt steam engine was installed. Henry Houldsworth Junior was probably back in Manchester by 1826, where he was to become an influential cotton spinner as chief partner in his mills, which he moved out to Reddish in 1863–5. He was also a prominent landowner in Cheetham. When William Fairbairn was considering establishing the Association for the Prevention of Steam Boiler Explosions in 1854, he wanted to find an influential manufacturer and mill-owner and he made a happy choice when he turned to Henry Houldsworth for assistance.

[br]

Bibliography

1826, British patent no. 5,316 (differential gear for roving frames).

Further Reading

Details about Henry Houldsworth Junior are very sparse. The best account of his acquisition of the differential gear is given by D.J.Jeremy, 1981, Transatlantic Industrial Revolution. The Diffusion of Textile Technologies Between Britain and America, 1790–1830, Oxford.

W.English, 1969, The Textile Industry, London (an explanation of the mechanisms of the roving frame).

W.Pole, 1877, The Life of Sir William Fairbairn, Bart., London (provides an account of the beginning of the Manchester Steam Users' Association for the Prevention of Steam-boiler Explosions).

RLH