pulp-press water

pulp-press water

пищ. жомопрессовая вода

pulp-press water

пищ. жомопрессовая вода

pulp press water

Нефть: жомопрессовая вода

pulp-press water

Пищевая промышленность: жомопрессовая вода

pulp press water

жомопрессовая вода

pulp-press water

жомопрессовая вода

pulp press water

küspe pres suyu

beet pulp-press water

Глоссарий компании Сахалин Энерджи: жомопрессовая вода

beet pulp-press water

жомопрессовая вода

beet pulp-press water

жомопрессовая вода

water

1) вода

2) объём воды; расход

3) минеральная вода

4) обводнять

5) увлажнять ( грунт)

6) мочить; замачивать; смачивать

7) разбавлять водой

8) водоём

9) мн. ч. паводок; разлив

•

to go to water — обводняться (о скважине, месторождении, добыча нефти в которых в результате этого становится нерентабельной)

-
absorbed water
-
acid waste water
-
acid water
-
activated water
-
adhesive water
-
adsorbed water
-
aerated water
-
aggressive water
-
ammonia water
-
apportioned water
-
artesian water
-
atmospheric water
-
available water
-
bleed water
-
boiler water
-
boiling water
-
borated water
-
bottom water
-
bound water
-
brackish water
-
capillary water
-
carbonate water
-
cavern water
-
char sweet water
-
chemically pure water
-
chlorinated water
-
circulating water
-
clarified water
-
cleaning purposes water
-
clear sweet water
-
clear water
-
colliery water
-
Cologne water
-
combined water
-
compensation water
-
condensate water
-
condenser water
-
condensing water
-
conductivity water
-
confined water
-
conservation water
-
constitution water
-
contaminated water
-
cooking water
-
cook water
-
cooling water
-
corrosive water
-
crystallization water
-
crystal water
-
day water
-
dead water
-
deaerated water
-
deep water
-
degassed water
-
deionized water
-
delivery water
-
demineralized water
-
dentifrice water
-
desalinized water
-
desiliconized water
-
desilting water
-
dirty sweet water
-
discharge water
-
distilled water
-
domestic water
-
downstream water
-
drain water
-
drilling water
-
drinking water
-
dystrophic water
-
effective snowmelt water
-
effluent water
-
electronic-grade water
-
electronic water
-
emergency core cooling water
-
entrained water
-
eutrophic water
-
excessive tail water
-
exchange water
-
exportable water
-
feed water
-
fixed water
-
floral water
-
flowing water
-
flushing water
-
flush water
-
formation water
-
foul water
-
free water
-
fruit soda water
-
glue water
-
gravitational water
-
gray water
-
gutter water
-
hard water
-
head water
-
heavy water
-
high water
-
hydrothermal water
-
hygroscopic water
-
ice-congested water
-
imported water
-
impounding water
-
industrial water
-
infected water
-
influent water
-
intercepted water
-
intermediate water
-
interstitial water
-
irreducible water
-
irregular temporary water
-
irrigation water
-
land water
-
leakage water
-
lenthic water
-
light water
-
lime water
-
lockage water
-
loose water
-
lothic water
-
low water
-
main water
-
makeup water
-
manufacturing water
-
mashing water
-
melt water
-
melting water
-
meteoric water
-
middle water
-
mine water
-
mineral water
-
mineralized water
-
mixing water
-
mud makeup water
-
muddy water
-
narrow water
-
navigable water
-
nonartesian water
-
noncirculating water
-
nonflashing water
-
nonmoving water
-
nonpotable water
-
nonradioactive water
-
offshore water
-
onsite water
-
open water
-
ordinary water
-
overflow water
-
overinhibited water
-
oversill water
-
oxygenated water
-
oxygenless water
-
peptone water
-
perched water
-
percolating water
-
phreatic water
-
piped water
-
polluted water
-
potable water
-
precipitation water
-
pressure water
-
pretreated water
-
process water
-
produced water
-
project water
-
pulp water
-
pulp-press water
-
pure water
-
quenching water
-
radioactive water
-
raw water
-
reactor water
-
recirculated water
-
recreation water
-
recycled water
-
regeneration water
-
residual water
-
residuary water
-
restricted water
-
return water
-
reuse water
-
rinse water
-
rose water
-
running water
-
saline water
-
salt water
-
sample water
-
sanitary water
-
saturated water
-
saturation-pressure water
-
scale-producing water
-
sediment-laden water
-
seepage water
-
service water
-
sewage water
-
shallow tail water
-
shielding water
-
shoaling water
-
silica-free water
-
silt-free water
-
silt-laden water
-
slope water
-
sludging water
-
sluice water
-
smooth water
-
snow water
-
soaking water
-
soft water
-
softened water
-
soil water
-
solid water
-
source water
-
spill water
-
spilling water
-
spray water
-
stagnant water
-
steeping water
-
steep water
-
still water
-
storage water
-
storm water
-
subcooled water
-
subsoil water
-
subsurface water
-
supercritical water
-
surface water
-
surplus water
-
suspended water
-
sweet water
-
table water
-
tail water
-
tank water
-
tap water
-
temporary water
-
thermally enriched water
-
thickened water
-
tie water
-
toilet water
-
top water
-
total precipitable water
-
town water
-
treated water
-
trypton water
-
turbid water
-
ultrapure water
-
underground water
-
underscreen water
-
upgrade water
-
upstream water
-
versatile hardness water
-
wash water
-
waste water
-
water of reaction
-
water of zero hardness
-
whirling water
-
white water

жомопрессовая вода

pulp-press water пищ.

жомопрессовая вода

пищ. pulp-press water

Cai Lun (Tsai Lun)

SUBJECT AREA: Paper and printing

[br]

b. c.57 AD China

d. c.121 AD China

[br]

Chinese Director of Imperial Workshops who is usually credited with the invention of paper.

[br]

He was a confidential secretary to the Emperor. He became Director of the Imperial Workshops and he is said to have invented, or sponsored the invention of, paper around the year 105 AD. Recent studies, however, suggest that paper was already known in China two centuries earlier. The method of making it has hardly varied in principle since that time. The raw materials, then usually old fishing nets and clothing rags, were boiled with water, to which alkali in the form of wood ash was sometimes added. The resulting pulp was then beaten in a stone mortar with a stone or a wooden mallet. The pulp was then mixed and stirred with a large amount of water, and a sieve or mould (formed on a wooden frame carrying a mat of thin reeds sewn together) was dipped into it and was shaken to help the fibres in the layer of pulp to interlock and thus form a sheet of paper. The rest of the process consisted, then as now, of getting rid of the water: the sheets of paper were dried and bleached by leaving them to lie in the sun.

Some of China's many inventions were achieved independently in Western Europe, but it seems that Europe's knowledge of papermaking stems from the Chinese. It was not until the eighth century that it passed into the Islamic world and so, first by contact with the Moors in Spain in the twelfth century, into Western Europe.

Cai Lun was later made a marquis. Further promotion followed when he was regarded as the god of papermaking.

[br]

Further Reading

J.Needham, 1985, Science and Civilisation in China, Cambridge: Cambridge University Press, Vol. V (1): Clerks and Craftsmen in China and the West, 1970.

LRD

Dickinson, John

SUBJECT AREA: Paper and printing

[br]

b. 29 March 1782

d. 11 January 1869 London, England

[br]

English papermaker and inventor of a papermaking machine.

[br]

After education at a private school, Dickinson was apprenticed to a London stationer. In 1806 he started in business as a stationer, in partnership with George Longman; they transferred to 65 Old Bailey, where the firm remained until their premises were destroyed during the Second World War. In order to secure the supply of paper and be less dependent on the papermakers, Dickinson turned to making paper on his own account. In 1809 he acquired Apsley Mill, near Hemel Hempstead on the river Gade in Hertfordshire. There, he produced a new kind of paper for cannon cartridges which, unlike the paper then in use, did not smoulder, thus reducing the risk of undesired explosions. The new paper proved very useful during the Napoleonic War.

Dickinson developed a continuous papermaking machine about the same time as the Fourdrinier brothers, but his worked on a different principle. Instead of a continuous flat wire screen, Dickinson used a wire-covered cylinder which dipped into the dilute pulp as it revolved. A felt-covered roller removed the layer of wet pulp, which was then subjected to drying, as in the Fourdrinier machine. The latter was first in use at Frogmore, just upstream from Apsley Mill on the river Gade. Dickinson patented his machine in 1809 and claimed that it was superior for some kinds of paper. In feet, both types of machine have survived, in much enlarged and modified form: the Fourdrinier for general papermaking, the Dickinson cylinder for the making of board. In 1810 Dickinson acquired the nearby Nash Mill, and over the years he extended the scope of his papermaking business, introducing many technical improvements. Among his inventions was a machine to paste together continuous webs of paper to form cardboard. Another, patented in 1829, was a process for incorporating threads of cotton, flax or silk into the body of the paper to make forgery more difficult. He became increasingly prosperous, overcoming labour disputes with unemployed hand-papermakers. and lawsuits against a canal company which threatened the water supply to his mills. Dickinson was the first to use percolation gauges to predict river flow, and his work on water supply brought him election to a Fellowship of the Royal Society in 1845.

[br]

Principal Honours and Distinctions

FRS 1845.

Further Reading

R.H.Clapperton, 1967, The Paper-making Machine, Oxford: Pergamon Press, pp. 331–5 (provides a biography and full details of Dickinson's inventions).

LRD

Fourdrinier, Henry

SUBJECT AREA: Paper and printing

[br]

b. 11 February 1766 London, England

d. 3 September 1854 Mavesyn Ridware, near Rugeley, Staffordshire, England

[br]

English pioneer of the papermaking machine.

[br]

Fourdrinier's father was a paper manufacturer and stationer of London, from a family of French Protestant origin. Henry took up the same trade and, with his brother Sealy (d. 1847), devoted many years to developing the papermaking machine. Their first patent was taken out in 1801, but success was still far off. A machine for making paper had been invented a few years previously by Nicolas Robert at the Didot's mill at Essonnes, south of Paris. Robert quarrelled with the Didots, who then contacted their brother-in-law in England, John Gamble, in an attempt to raise capital for a larger machine. Gamble and the Fourdriniers called in the engineer Bryan Donkin, and between them they patented a much improved machine in 1807. In the new machine, the paper pulp flowed on to a moving continuous woven wire screen and was then squeezed between rollers to remove much of the water. The paper thus formed was transferred to a felt blanket and passed through a second press to remove more water, before being wound while still wet on to a drum. For the first time, a continuous sheet of paper could be made. Other inventors soon made further improvements: in 1817 John Dickinson obtained a patent for sizing baths to improve the surface of the paper; while in 1820 Thomas Crompton patented a steam-heated drum round which the paper was passed to speed up the drying process. The development cost of £60,000 bankrupted the brothers. Although Parliament extended the patent for fourteen years, and the machine was widely adopted, they never reaped much profit from it. Tsar Alexander of Russia became interested in the papermaking machine while on a visit to England in 1814 and promised Henry Fourdrinier £700 per year for ten years for super-intending the erection of two machines in Russia; Henry carried out the work, but he received no payment. At the age of 72 he travelled to St Petersburg to seek recompense from the Tsar's successor Nicholas I, but to no avail. Eventually, on a motion in the House of Commons, the British Government awarded Fourdrinier a payment of £7,000. The paper trade, sensing the inadequacy of this sum, augmented it with a further sum which they subscribed so that an annuity could be purchased for Henry, then the only surviving brother, and his two daughters, to enable them to live in modest comfort. From its invention in ancient China (see Cai Lun), its appearance in the Middle Ages in Europe and through the first three and a half centuries of printing, every sheet of paper had to made by hand. The daily output of a hand-made paper mill was only 60–100 lb (27–45 kg), whereas the new machine increased that tenfold. Even higher speeds were achieved, with corresponding reductions in cost; the old mills could not possibly have kept pace with the new mechanical printing presses. The Fourdrinier machine was thus an essential element in the technological developments that brought about the revolution in the production of reading matter of all kinds during the nineteenth century. The high-speed, giant paper-making machines of the late twentieth century work on the same principle as the Fourdrinier of 1807.

[br]

Further Reading

R.H.Clapperton, 1967, The Paper-making Machine, Oxford: Pergamon Press. D.Hunter, 1947, Papermaking. The History and Technique of an Ancient Craft, London.

LRD

process

1) процесс

2) (технологический) процесс; (технологическая) обработка

3) технологический приём; способ

4) технология

5) режим; ход (процесса)

6) обрабатывать, подвергать обработке

7) подвергать анализу, анализировать

8) воспроизводить фотомеханическим способом

•

to design process — разрабатывать технологию

-
acetone-acetylene process
-
acetylene process
-
Acheson process
-
acid Bessemer process
-
acid process
-
acid reclaiming process
-
acyclic process
-
Adapti investment casting process
-
additive process
-
adiabatic process
-
Aero case process
-
aerobic process
-
age-dependent process
-
air blast process
-
air-sand process
-
Alcan process
-
Al-Dip process
-
alfin process
-
alkali reclaiming process
-
alkaline process
-
Allis-Chalmers agglomeration reduction process
-
ALT process
-
aluminothermic process
-
anaerobic process
-
anamorphotic process
-
annealing-in-line process
-
anode process
-
anodic electrode process
-
AOD process
-
aqua-cast process
-
ARBED-ladle-treatment process
-
arc-air process
-
arc-remelting process
-
argon-oxygen-decarburization process
-
ASEA-SKF process
-
autoregressive process
-
averaging process
-
Azincourt process
-
azo coupling process
-
background process
-
bag process
-
BAP process
-
Barrow process
-
Basett process
-
basic Bessemer process
-
basic oxygen process
-
basic process
-
basic-arc process
-
batch process
-
biofiltration process
-
bipolar process
-
bipolar-FET process
-
bipolar-MOS process
-
BISRA degassing process
-
black-heart process
-
Blackodising process
-
blast-furnace process
-
Blaw-Knox process
-
bleaching process
-
Bochumer-Verein process
-
boiling process
-
bonding process
-
bottom-argon-process process
-
broadband random process
-
bromoil transfer process
-
bromoil process
-
bubble-column process
-
bubble-hearth process
-
buffer-slag process
-
Calmes process
-
Canadizing process
-
carbon mold process
-
carbon process
-
carbon-arc process
-
carbon-in-leach process
-
carbon-in-pulp process
-
carbothermic process
-
carbro process
-
carrier-gas degassing process
-
cascade process
-
cast shell process
-
catalytic DENO process
-
cathodic process
-
CC-CR process
-
CC-DR process
-
CC-HCR process
-
cementation process
-
cementation-in-pulp process
-
cementing process
-
centrifugal spinning process
-
cermet process
-
CESM process
-
CEVAM process
-
charge transfer process
-
chemical vapor deposition process
-
chemical-bonding process
-
Chenot process
-
china process
-
cine exposure process
-
cine process
-
CLC process
-
clean burn process
-
cloudburst process
-
CLU process
-
CMOS process
-
CNC process
-
CO2 silicate process
-
coal reduction process
-
coal to gas process
-
coal-gas-sumitomo process
-
coal-oxygen-injection process
-
COIN process
-
cold box process
-
cold doping process
-
cold process
-
cold scrap process
-
cold type process
-
collodion process
-
color process
-
concurrent processes
-
consteel process
-
consumable electrode vacuum arc melting process
-
contact process
-
continuous annealing process
-
continuous casting-cleaning rolling process
-
continuous casting-direct rolling process
-
continuous casting-hot charging and rolling process
-
continuous electroslag melting process
-
continuous metal cast process
-
continuous-on-line control process
-
continuous-time process
-
controlled pressure pouring process
-
controlled process
-
converter process
-
cooking process
-
coppering process
-
copying process
-
coupled cathodic-anodic process
-
cracking process
-
Creusot Loire Uddenholm process
-
critical process
-
cumulative process
-
cuprammonium process
-
curing process
-
CVD process
-
cyclic process
-
Cyclosteel process
-
Czochralski process
-
daguerre photographic process
-
dense-media process
-
Desco process
-
deterministic process
-
developing process
-
DH degassing process
-
diabatic process
-
diazo process
-
diffused planar process
-
diffusion process
-
diffusion transfer process
-
dip-forming process
-
direct iron process
-
direct process
-
direct reduction process
-
direct-sintering process
-
discrete-time process
-
discrete process
-
DLM process
-
Domnarvet process
-
Dored process
-
double-crucible process
-
double-epi process
-
doubling process
-
D-process
-
DR process
-
drop-molding process
-
dry adiabatic process
-
dry process
-
dry-blanch-dry process
-
duplex process
-
easy drawing process
-
EBM process
-
EBR process
-
EF-AOD process
-
electric furnace-argon oxygen decarburization process
-
electroarc process
-
electrocatalytic process
-
electrocolor process
-
electrodialysis reversal process
-
electroflux-remelting process
-
electromembrane process
-
electron-beam-melting process
-
electron-beam-refining process
-
electrophotoadhesive process
-
electrophotographic process
-
electroslag refining process
-
electroslag remelting process
-
electroslag remelt process
-
electrostatographic process
-
electrostream process
-
Elo-Vac process
-
elquench process
-
endothermic process
-
energy efficient process
-
entropy process
-
enzymatic process
-
EPIC process
-
epidemic process
-
epitaxial growth process
-
epitaxy growth process
-
ergodic process
-
ESR process
-
Estel process
-
etching process
-
exoergic process
-
exothermic process
-
extrusion-molded neck process
-
ferroprussiate process
-
Ferrox process
-
filming process
-
filtration-chlorination process
-
Finkl-Mohr process
-
FIOR process
-
first process
-
fixed-bed MTG process
-
flash steel direct reduction process
-
float process
-
float-and-sink process
-
float-zone process
-
flow process
-
fluid iron ore reduction process
-
fluid-bed MTG process
-
fluidized roasting process
-
fluid-sand process
-
FMC coke process
-
foaming process
-
foehn process
-
food-machinery and chemical coke process
-
foreground process
-
Foren process
-
FOS process
-
freeze concentration process
-
fuel-oxygen-scrap process
-
full-mold process
-
fusion-casting process
-
Futacuchi process
-
Gaussian process
-
Gero mold degassing process
-
Gero vacuum casting process
-
GGS process
-
girbitol process
-
gradual reduction process
-
growing process
-
growth process
-
gypsum-sulfuric acid process
-
Hall electrolytic process
-
Harris process
-
hazardous process
-
H-coal process
-
heat-transfer process
-
heavy-media process
-
hibernating process
-
HI-GAS process
-
high-frequency induction process
-
HIP process
-
H-iron process
-
Hoope process
-
hot isostatic pressing process
-
hot process
-
hot-metal process
-
hot-metal-and-scrap process
-
hot-type process
-
hydrogasification process
-
hydrotype process
-
HyL process
-
IC-DR process
-
image process
-
imbibition process
-
immiscible displacement process
-
implantation process
-
impurity doping process
-
in-bulk process
-
inchrome process
-
in-draw process
-
inductoslag-melting process
-
ingot casting direct rolling process
-
injection molding process
-
in-line process
-
Inred process
-
interpolation process
-
investment process
-
ion-implantation process
-
irreversible process
-
isentropic process
-
ISM process
-
isobaric process
-
isochoric process
-
isoenthalpic process
-
isoentropic process
-
isometric process
-
isoplanar process
-
isothermal process
-
iterative process
-
jet-expanding process
-
Kaldo process
-
katadyn process
-
Kawasaki-bottom-oxygen-process process
-
Kawasaki-Gas-Lime-Injection process
-
K-BOP process
-
KEK process
-
KG-LI process
-
kiln-reduction process
-
KIVCET cyclone smelting process
-
KIVCET process
-
knit-deknit process
-
koetherizing process
-
KR process
-
kraft process
-
lance bubbling equilibrium process
-
LBE process
-
LD-AB process
-
LD-AC process
-
LD-AOD process
-
LD-argon bottom process
-
LD-argon oxygen decarburization process
-
LD-CB process
-
LD-circle lance process
-
LD-CL process
-
LD-combination blow process
-
LD-HC top and botton blowing process
-
LDK process
-
LD-Kawasaki-Gas process
-
LD-KG process
-
LD-OB process
-
LD-OTB process
-
LD-oxygen bottom process
-
LD-oxygen-top-bottom process
-
lift-off process
-
liquefaction process
-
liquid gas plug process
-
liquid-phase process
-
loop transfer process
-
lost core process
-
low-waste technological process
-
LSI process
-
LVR process
-
LVS process
-
Mannesmann powder process
-
mapping process
-
Markovian process
-
Markov process
-
masking process
-
matte fuming process
-
melting process
-
mercast process
-
Midland-Ross process
-
Midrex process
-
migration process
-
miscible displacement process
-
miscible plug process
-
mixed autoregressive-moving average process
-
moist adiabatic process
-
Molynutz process
-
monochrome process
-
monolithic process
-
MOS process
-
MOSFET process
-
motion-picture process
-
moving average process
-
narrowband random process
-
Neely process
-
negative-positive process
-
Nitemper process
-
no pickle process
-
nonflow process
-
non-Gaussian process
-
Nord-Fuvo process
-
Nu-iron process
-
OBM process
-
OG process
-
OLP converter process
-
one-way process
-
open-hearth process
-
orbitread process
-
ore process
-
Orthoflow cracking process
-
Orthoforming process
-
orthogonal increment process
-
oxidation process
-
oxide-isolated process
-
oxygen-blow process
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oxygen-gas process
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oxygen-lancing process
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oxygen-steelmaking process
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packaging process
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pad-batch dyeing process
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pad-dry dyeing process
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pad-jig dyeing process
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pad-roll dyeing process
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pad-steam dyeing process
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pad-steam vat-print process
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PAMCO-hot-alloy process
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parent process
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PCR process
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Perrin process
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PHA process
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phonon process
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photoelectric process
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photomechanical process
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photovoltaic process
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pig iron-scrap process
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pig-and-ore process
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pigment padding dying process
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pigment padding process
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pigment process
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pinatype process
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planar process
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plasma etching process
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plasma etch process
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plasma process
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plasma-arc process
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Plasmamelt process
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Plasmared process
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plaster mold process
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plastic wirecut process
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polytropic process
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powder silicon ribbon process
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power-press process
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prepolymer process
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prepress processes
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pressure-driven membrane process
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primuline process
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propane-acid process
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pulsating mixing process
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Purex process
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pushbench process
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Q-BOP process
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QDT process
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quality basic oxygen process process
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quasi-independent processes
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quick and direct tapping process
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ram process
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random process
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rapid solidification plasma deposition process
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rayon continuous process
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receiving process
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reclamator reclaiming process
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recurrent process
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redox process
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reducing process
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reduction-smelting process
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relaxation process
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repetitive process
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reproduction process
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reversal process
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reversible process
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RH process
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RH-OB process
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ribbon process
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R-N direct-reduction process
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roasting-sintering process
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roast-leaching process
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robot-controlled process
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rongalit-potash process
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rotor process
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rustless process
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sample process
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schoop process
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scrap-and-pig process
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scrap-conditioning process
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scrap-ore process
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screen printed process
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self-developing process
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self-healing process
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semibatch process
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semiconductor process
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sending process
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Sendzimir coating process
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sequential process
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silicon-gate MOS process
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silicon-gate process
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silk-screen process
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single-pumpdown process
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SIP process
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skein spinning process
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Skinner multiple-hearth process
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slag minimum process
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slip-casting process
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slow down process
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SLPM process
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SL-RN metallization process
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SL-RN reduction process
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solid source diffusion process
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solution regrowth process
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solvent extraction-electrowinning process
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solvent plug process
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SOS process
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spin-draw-texturizing process
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spinylock process
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sponge iron process
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spontaneous process
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Stanal process
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stationary random process
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STB process
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steady-flow process
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steam-blow process
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steelmaking process
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Stelmor process
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step and repeat process
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stochastic process
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stuffer box process
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submerged arc process
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subtractive process
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suck-and-blow process
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Sulf BT process
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Sulfinuz process
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Sumitomo-slag all recycling process
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Sumitomo-top-bottom process
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Sursulf process
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system process
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TBM process
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T-die process
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Technamation process
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thermal DeNOx process
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Therm-i-Vac process
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Thermo-Flow process
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thermoplastic process
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Thomas process
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Thorex process
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three-color process
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Thyssen-blast-metallurgy process
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Tifran process
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tightly coupled processes
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time-varying process
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trichromatic process
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triplex process
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Tropenas converter process
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Tufftride process
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Tufftride TF1 process
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uncertain process
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user process
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vacuum arc remelting process
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vacuum casting process
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vacuum deoxidation process
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vacuum induction refining process
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vacuum stream-droplet process
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vacuum-arc degassing process
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vacuum-carbodeoxidation process
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vacuum-carbonate process
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vacuum-induction melting process
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vacuum-melting process
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vacuum-metallothermic process
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vacuum-oxygen-decarburization process
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VAD process
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VAR process
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VAW process
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VHSIC process
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vigom process
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VIR process
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viscose process
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visual process
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VLSI process
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VOD process
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waiting process
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water gas process
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waterfall process
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wet process
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white-heart process
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Zinal process
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zinc distilling process