See also:

• BRICK (derived according to some etymologists from the Teutonic bricke, a disk or plate; but more authoritatively, through the French brique, originally a " broken piece," applied especially to bread, and so to clay, from the Teutonic brikan, to break)

BRICK (derived according to some etymologists from the See also:

• TEUTONIC
• TEUTONIC (GERMANIC) LANGUAGES

Teutonic bricke, a disk or See also:

• PLATE

plate; but more authoritatively, through the See also:

• FRENCH
• FRENCH, DANIEL CHESTER (1850– )
• FRENCH, NICHOLAS (1604-1678)

French brique, originally a " broken piece," applied especially to See also:

• BREAD

bread, and so to See also:

• CLAY (from O. Eng. claeg, a word common in various forms to Teutonic languages, cf. Ger. Klei)
• CLAY, CASSIUS MARCELLUS (1810-1903)
• CLAY, CHARLES (1801–1893)
• CLAY, FREDERIC (1838–1889)
• CLAY, HENRY (1777–1852)

clay, from the Teutonic brikan, to break)  , a See also:

• KIND (O. E. ge-cynde, from the same root as is seen in " kin," supra)

kind of artificial See also:

• STONE
• STONE (0. Eng. shin; the word is common to Teutonic languages, cf. Ger. Stein, Du. steen, Dan. and Swed. sten; the root is also seen in Gr. aria, pebble)
• STONE, CHARLES POMEROY (1824-1887)
• STONE, EDWARD JAMES (1831-1897)
• STONE, FRANK (1800-1859)
• STONE, GEORGE (1708—1764)
• STONE, LUCY [BLACKWELL] (1818-1893)
• STONE, MARCUS (184o— )
• STONE, NICHOLAS (1586-1647)

stone generally made of burnt See also:

• CLAY (from O. Eng. claeg, a word common in various forms to Teutonic languages, cf. Ger. Klei)
• CLAY, CASSIUS MARCELLUS (1810-1903)
• CLAY, CHARLES (1801–1893)
• CLAY, FREDERIC (1838–1889)
• CLAY, HENRY (1777–1852)

clay, and largely used as a See also:

• BUILDING

building material . See also:

• HISTORY

History.—The See also:

• ART

art of making bricks See also:

• DATES

dates from very See also:

• EARLY
• EARLY, JUBAL ANDERSON (1816-1894)

early times, and was practised by all the civilized nations of antiquity . The earliest burnt bricks known are those found on the sites of the See also:

• ANCIENT
• ANCIENT (also spelt ANTIENT; derived, through the Fr. ancien, old, from the late Lat. antianum, from ante, before)

ancient cities of Babylonia, and it seems probable that the method of making strong and durable bricks, by burning blocks of dried clay, was discovered in this corner of See also:

• ASIA

Asia . We know at least that well-burnt bricks were made by the Babylonians more than 6000 years ago, and that they were extensively used in the See also:

• TIME (0. Eng. Lima, cf. Icel. timi, Swed. timme, hour, Dan. time; from the root also seen in " tide," properly the time of between the flow and ebb of the sea, cf. O. Eng. getidan, to happen, " even-tide," &c.; it is not directly related to Lat. tempus)
• TIME, MEASUREMENT OF
• TIME, STANDARD

time of See also:

• SARGON

Sargon of See also:

• AKKAD (Gr. versions apxat and hXab)

Akkad (c . 3800 B.c.) . The site of the ancient See also:

• CITY (through Fr. cite, from Lat. civitas)

city of See also:

• BABYLON (mod. Hillah)

Babylon is still marked by huge mounds of bricks, the ruins of its See also:

• GREAT

great walls, towers and palaces, although it has been the See also:

• CUSTOM (from O. Fr. costume, costume or coustume; Low Lat. costuma, a shortened form of consuetudo)

custom for centuries to carry away from these heaps the bricks required for the building of the See also:

• MODERN

modern towns in the surrounding See also:

• COUNTRY (from the Mid. Eng. contre or contrie, and O. Fr. cuntree; Late Lat. contrata, showing the derivation from contra, opposite, over against, thus the tract of land which fronts the sight, cf. Ger. Gegend, neighbourhood)

country . The Babylonians and Assyrians attained to a high degree of proficiency in brickmaking, notably in the manufacture of bricks having a coating of coloured glaze or See also:

• ENAMEL (formerly " amel," derived through the Fr. amail, emmll, esmail, from a Latin word smaltum, first found in a 9th-century life of Leo IV.)

enamel, which they largely used for See also:

• WALL (O. Eng. weal, weall, Mid. Eng. wal, wane, adapted from Lat. vallum, rampart; the original O. Eng. word for a wall was wag or tenth)
• WALL, RICHARD (1694-1778)

wall decoration . The See also:

• CHINESE, JAPANESE AND

Chinese claim great antiquity for their clay See also:

• INDUSTRIES

industries, but it is not improbable that the knowledge of brickmaking travelled eastwards from Babylonia across the whole of Asia . It is believed that the art of making glazed bricks, so highly See also:

• DEVELOPED

developed afterwards by the Chinese, found its way across Asia from the See also:

• WEST
• WEST, BENJAMIN (1738-1820)
• WEST, NICHOLAS (1461-1533)

west, through See also:

• PERSIA

Persia and See also:

• NORTHERN

northern See also:

• INDIA
• INDIA, FRENCH

India, to See also:

• CHINA

China . The great wall of China was constructed partly of See also:

• BRICK (derived according to some etymologists from the Teutonic bricke, a disk or plate; but more authoritatively, through the French brique, originally a " broken piece," applied especially to bread, and so to clay, from the Teutonic brikan, to break)

brick, both burnt and unburnt; but this was built at a comparatively See also:

• LATE

late See also:

• PERIOD
• PERIOD (Gr. irepioSos, a going or way round, circuit, aepi, round, and &Sis, way, road)

period (c . 210 B.C.), and there is nothing to show that the Chinese had any knowledge of burnt bricks when the art flourished in Babylonia . Brickmaking formed the See also:

• CHIEF (from Fr. chef, head, Lat. caput)

chief occupation of the Israelites during their bondage in See also:

• EGYPT

Egypt, but in this See also:

• CASE
• CASE, JOHN (d. 1600)

case the bricks were probably See also:

• SUN
• SUN (0. Eng. sonne, Ger. sonne. Fr. soleil, Lat. sol, Gr. ijXior, from which comes helio- in various English compounds)

sun-dried only, and not burnt .

These bricks were made of a mixture of clay and chopped See also:

• STRAW

straw or reeds, worked into a stiff See also:

• PASTE (O. Fr. paste, modern pate, Late Lat. pasta, whence also in Span., Port. and Ital., from Gr. 1r&vrrl or 1raara, barley porridge, or salted pottage, ir&ao'ety, to sprinkle with salt)

paste with See also:

• WATER

water . The clay was the See also:

• RIVER

river mud from the See also:

• BANKS, GEORGE LINNAEUS (1821-1881)
• BANKS, NATHANIEL PRENTISS (1816–1894)
• BANKS, SIR JOSEPH
• BANKS, THOMAS (1735-1805)

banks of the See also:

• NILE
• NILE, BATTLE OF THE
• NILE, SOBAT

Nile, and as this had not sufficient cohesion in itself, the chopped straw (or reeds) was added as a binding material . The addition of such substances increases the plasticity of wet clay, especially if the mixture is allowed to stand for some days before use; so that the See also:

• ACTION

action of the chopped straw was twofold; a fact possibly known to the Egyptians . These sun-dried bricks, or " adobes," are still made, as of old, on the banks of the Nile by the following method:—A shallow See also:

• PIT (O. E. pytt, cognate with Du. put, Ger. Pfutze, &c., all ultimately adaptations of Lat. puteus, well, formed from root pu-, to cleanse, whence gurus, clean, pure)

pit or See also:

• BED
• BED (a common Teutonic word, cf. German Bett, probably connected with the Indo-European root bhodh, seen in the Lat. fodere, to dig; so " a dug-out place " for safe resting, or in the same sense as a garden " bed ")

bed is prepared, into which are thrown the mud, chopped straw and water in suitable proportions, and the whole See also:

• MASS (O.E. maesse; Fr. messe; Ger. Messe; Ital. messa; from eccl. Lat. missa)
• MASS, IN

mass is tramped on until it is thoroughly mixed and of the proper consistence . This mixture is removed in lumps and shaped into bricks, in moulds or by See also:

• HAND
• HAND (a word common to Teutonic languages; cf. Ger. Hand, Goth. handus)
• HAND, FERDINAND GOTTHELF (1786-185r)

hand, the bricks being simply sun-dried . See also:

• PLINY, THE ELDER
• PLINY, THE YOUNGER

Pliny mentions that three kinds of bricks were made by the Greeks, but there is no indication that they were used to any great extent, and probably the walls of See also:

• ATHENS
• ATHENS ['AN vat, Athenae, modem colloquial Greek `Ath va]

Athens on the See also:

• SIDE
• SIDE (mod. Eski Adalia)

side towards See also:

• MOUNT, WILLIAM SIDNEY (1807-1868)

Mount See also:

• HYMETTUS (Ital. Monte Matto, hence the modern name Trello Vouni)

Hymettus were the most important brick-structures in ancient See also:

• GREECE

Greece . The See also:

• ROMANS
• ROMANS, EPISTLE TO THE

Romans became masters of the brick-maker's art, though they probably acquired much of their know-ledge in the See also:

• EAST
• EAST, ALFRED (1849- )

East, during their occupation of Egypt and Greece . In any case they revived and extended the manufacture of bricks about the beginning of the See also:

• CHRISTIAN
• CHRISTIAN, WILLIAM (1608-1663)

Christian era; exercising great care in the selection and preparation of their clay, and introducing the method of burning bricks in kilns . They carried their knowledge and their methods throughout western See also:

• EUROPE

Europe, and there is abundant See also:

• EVIDENCE (Lat. evidentia, evideri, to appear clearly)

evidence that they made bricks extensively in See also:

• GERMANY
• GERMANY (Ger. Deutschland)

Germany and in See also:

• BRITAIN (Gr. Hperavuml vi7vot, Bperravia; Lat. Britannia, rarely Britannia)

Britain . Although brickmaking was thus introduced into Britain nearly 2000 years ago, the art seems to have been lost when the Romans withdrew from the country, and it is doubtful whether any burnt bricks were made in See also:

• ENGLAND
• ENGLAND, THE CHURCH OF

England from that time until the 13th See also:

• CENTURY (from Lat. centuria, a division of a hundred men)

century . Such bricks as were used during this See also:

• LONG, GEORGE (1800-1879)
• LONG, JOHN DAVIS (1838– )

long period were generally taken from the remains of See also:

• ROMAN

Roman buildings, as at See also:

• COLCHESTER
• COLCHESTER, CHARLES ABBOT, 1ST BARON (1757-1829)

Colchester and St Albans See also:

• ABBEY (Lat. abbatia; from Syr. abba, father)
• ABBEY, EDWIN AUSTIN (1852– )

Abbey . One of the earliest existing brick buildings, erected after the revival of brickmaking in England, is Little Wenham See also:

• HALL
• HALL (generally known as SCHWABISCH-HALL, tc distinguish it from the small town of Hall in Tirol and Bad-Hall, a health resort in Upper Austria)
• HALL (O.E. heall, a common Teutonic word, cf. Ger. Halle)
• HALL, BASIL (1788-1844)
• HALL, CARL CHRISTIAN (1812–1888)
• HALL, CHARLES FRANCIS (1821-1871)
• HALL, CHRISTOPHER NEWMAN (1816—19oz)
• HALL, EDWARD (c. 1498-1547)
• HALL, FITZEDWARD (1825-1901)
• HALL, ISAAC HOLLISTER (1837-1896)
• HALL, JAMES (1793–1868)
• HALL, JAMES (1811–1898)
• HALL, JOSEPH (1574-1656)
• HALL, MARSHALL (1790-1857)
• HALL, ROBERT (1764-1831)
• HALL, SAMUEL CARTER (5800-5889)
• HALL, SIR JAMES (1761-1832)
• HALL, WILLIAM EDWARD (1835-1894)

Hall, in See also:

• SUFFOLK
• SUFFOLK, CHARLES BRANDON, 1ST DUKE OF (c. 1484–'545)
• SUFFOLK, EARLS AND DUKES OF
• SUFFOLK, THOMAS HOWARD, 1ST EARL OF (1561-1626)
• SUFFOLK, WILLIAM DE LA POLE

Suffolk, built about A. n .

121o; but it was not until the 15th century that bricks came into See also:

• GENERAL
• GENERAL (Lat. generalis, of or relating to a genus, kind or class)

general use again, and then only for important edifices . During the reign of See also:

• HENRY
• HENRY (1129-1195)
• HENRY (c. 1108-1139)
• HENRY (c. 1174–1216)
• HENRY (Fr. Henri; Span. Enrique; Ger. Heinrich; Mid. H. Ger. Heinrich and Heimrich; O.H.G. Haimi- or Heimirih, i.e. " prince, or chief of the house," from O.H.G. heim, the Eng. home, and rih, Goth. reiks; compare Lat. rex " king "—" rich," therefore " mig
• HENRY, EDWARD LAMSON (1841– )
• HENRY, JAMES (1798-1876)
• HENRY, JOSEPH (1797-1878)
• HENRY, MATTHEW (1662-1714)
• HENRY, PATRICK (1736–1799)
• HENRY, PRINCE OF BATTENBERG (1858-1896)
• HENRY, ROBERT (1718-1790)
• HENRY, VICTOR (1850– )
• HENRY, WILLIAM (1795-1836)

Henry VIII. brickmaking was brought to great perfection, probably by workmen brought from See also:

• FLANDERS (Flem. Vlaanderen)

Flanders, and the older portions of St See also:

• JAMES
• JAMES (Gr. 'IlrKw,l3or, the Heb. Ya`akob or Jacob)
• JAMES (JAMES FRANCIS EDWARD STUART) (1688-1766)
• JAMES, 2ND EARL OF DOUGLAS AND MAR(c. 1358–1388)
• JAMES, DAVID (1839-1893)
• JAMES, EPISTLE OF
• JAMES, GEORGE PAYNE RAINSFOP
• JAMES, HENRY (1843— )
• JAMES, JOHN ANGELL (1785-1859)
• JAMES, THOMAS (c. 1573–1629)
• JAMES, WILLIAM (1842–1910)
• JAMES, WILLIAM (d. 1827)

James's See also:

• PALACE (Lat. Palatium, the name given by Augustus to his residence on the Palatine Hill)

Palace and See also:

• HAMPTON
• HAMPTON, WADE (1818-1902)

Hampton See also:

• COURT
• COURT (from the O. Fr. court, Late Lat. cortis, curtis, a popular form of class. Lat. cohors, gen. cohortis; the mod. Fr. form tour is due to the influence of the Lat. curia, the word used in medieval documents to translate " court " in the feudal sense)
• COURT, ANTOINE (1696-176o)

Court Palace remain to testify to the skill then attained . In the 16th century bricks were increasingly used, but down to the Great See also:

• FIRE (in O. Eng. f j'r; the word is common to West German languages, cf. Dutch vuur, Ger. Feuer; the pre-Teutonic form is seen in Sanskrit pu, pavaka, and Gr. irup; the ultimate origin is usually taken to be a root meaning to purify, cf. Lat. purus)

Fire of See also:

• LONDON

London, in 1666, the smaller buildings, shops and dwelling-houses, were constructed of See also:

• TIMBER

timber framework filled in with See also:

• LATH (0. Eng. laett, Mid. Eng. lappe, a form possibly due to the Welsh llath; the word appears in many Teutonic languages, cf. Dutch lat, Ger. Latte, and has passed into Romanic, cf. Ital. latta, Fr. latte)

lath and See also:

• PLASTER

plaster . In the rebuilding of London after the fire, bricks were largely used, and from the end of the 17th century to the See also:

• PRESENT

present See also:

• DAY (O. Eng. dreg, Ger. Tag; according to the New English Dictionary, " in no way related to the Lat. dies")
• DAY, JOHN (1574-1640?)
• DAY, THOMAS (1748-1789)

day they have been almost exclusively used in all See also:

• ORDINARY (med. Lat. ordinarius, Fr. ordinaire)

ordinary buildings throughout the country, except in those districts where building stone is plentiful and See also:

• GOOD, JOHN MASON (1764-1827)

good brick-clay is not readily procurable . The bricks made in England before 1625 were of many sizes, there being no recognized See also:

• STANDARD
• STANDARD, BATTLE OF THE

standard; but in that See also:

• YEAR

year the sizes were regulated by See also:

• STATUTE

statute, and the present standard See also:

• SIZE

size was adopted, viz . 9X42 X3 in . In 1784 a tax was levied on bricks, which was not repealed until 1850 . The tax averaged about 4S . 7d. per thousand on ordinary bricks, and See also:

• SPECIAL

special bricks were still more heavily taxed . The first brick buildings in See also:

• AMERICA

America were erected on Manhattan See also:

• ISLAND (O.E. ieg =isle, +land')

Island in the year 1633 by a See also:

• GOVERNOR (from the Fr. gouverneur, from gouverner, O. Fr. governer, Lat. gubernare, to steer a ship, to direct, guide)

governor of the Dutch West India See also:

• COMPANY

Company . These bricks were made in See also:

• HOLLAND
• HOLLAND, CHARLES (1733–1769)
• HOLLAND, COUNTY AND PROVINCE OF
• HOLLAND, HENRY FOX, 1ST BARON (1705–1774)
• HOLLAND, HENRY RICH, 1ST EARL OF (1S9o-,649)
• HOLLAND, HENRY RICHARD VASSALL FOX, 3RD
• HOLLAND, JOSIAH GILBERT (1819-1881)
• HOLLAND, PHILEMON (1552-1637)
• HOLLAND, RICHARD, or RICHARD DE HOLANDE (fl. 1450)
• HOLLAND, SIR HENRY, BART

Holland, where the See also:

• INDUSTRY (Lat. industria, from indu-, a form of the pre, position in, and either stare, to stand, or struere, to pile up)

industry had long reached great excellence; and for many years bricks were imported into America from Holland and from England . In America burnt bricks were first made at New Haven about 1650, and the manufacture slowly spread through the New England states; but for many years the See also:

• HOME
• HOME, DANIEL DUNGLAS (1833-1886)
• HOME, EARLS OF

home-made See also:

• ARTICLE (from Lat. articulus, a joint)

article was inferior to that imported from Europe .

The Dutch and the Germans were the great brickmakers of Europe during the See also:

• MIDDLE

middle ages, although the Italians, from the 14th to the 15th century, revived and developed the art of decorative brick-See also:

• WORK

work or terra-See also:

• COTTA
• COTTA, BERNHARD VON (1808—1879)
• COTTA, GAIUS AURELIUS (c. 124—73 B.c.)

cotta, and discovered the method of applying coloured enamels to these materials . Under the Della Robbias, in the 15th century, some of the finest work of this class that the See also:

• WORLD

world has seen was executed, but it can scarcely be included under See also:

• BRICKWORK

brickwork . Brick See also:

• CLAYS, PAUL JEAN (1819-1900)

Clays.—All clays are the result of the denudation and decomposition of felspathic and siliceous rocks, and consist of the See also:

• FINE

fine insoluble particles which have been carried in suspension in water and deposited in geologic basins according to their specific gravity and degree of fineness (see CLAY) . These deposits have been formed in all geologic epochs from the " See also:

• RECENT

Recent " to the " See also:

• CAMBRIAN

Cambrian," and they vary in hardness from the soft and plastic " alluvial " clays to the hard and See also:

• ROCK
• ROCK (O.Fr. rake, Sp. rota, Ital. rocca; possibly from a Lat. form rupica, from rupes, rock)
• ROCK, DANIEL (1799–187t)

rock-like shales and slates of the older formations . The alluvial and See also:

• DRIFT (from "drive ")

drift clays (which were alone used for brickmaking until modern times) are found near the See also:

• SURFACE

surface, are readily worked and require little preparation, whereas the older sedimentary deposits are often difficult to work and necessitate the use of heavy machinery . These older shales, or rocky clays, may be brought into plastic See also:

• CONDITION (Lat. condicio, from condicere, to agree upon, arrange; not connected with conditio, from condere, conditum, to put together)

condition by long weathering (i.e. by exposure to See also:

• RAIN (O.E. regn; the word is common to Teutonic languages, cf. Ger. Regen, Swed. and Dan. regn; it has been connected with Lat. rigare, to wet, Gr. 13pixeav)

rain, See also:

• FROST (a common Teutonic word, cf. Dutch, vorst, Ger. Frost, from the common Teutonic verb meaning " to freeze," Dutch, vriezcn, Ger. frieren; the Indo-European root is seen in Lat. pruina, hoar-frost, cf. prurire, to itch, burn, pruna, burning coal, Sans
• FROST, WILLIAM EDWARD (1810–1877)

frost and sun) or by crushing and grinding in water, and they then resemble ordinary alluvial clays in every respect . The clays or earths from which burnt bricks are made may be divided into two See also:

• PRINCIPAL

principal types, according to chemical See also:

• COMPOSITION
• COMPOSITION (Lat. compositio, from componere, to put together)

composition: (1) Clays or shales containing only a small percentage of carbonate of See also:

• LIME
• LIME (O. Eng. lim, Lat. limes, mud, from linere, to smear)

lime and consisting chiefly of hydrated See also:

• ALUMINIUM (symbol Al; atomic weight 27.0)

aluminium silicates (the " true clay substance ") with more or less See also:

• SAND
• SAND, GEORGE (1804-1876)

sand, undecomposed grains of See also:

• FELSPAR, or FELDSPAR

felspar, and See also:

• OXIDE

oxide or carbonate of See also:

• IRON [symbol Fe, atomic weight 55.85 (0=16)]

iron; these clays usually See also:

• BURN, RICHARD (1709-1785)

burn to a See also:

• BUFF (from Fr. bu.ffie, a buffalo)

buff, See also:

• SALMON
• SALMON, GEORGE (1819-1904)

salmon or red See also:

• COLOUR (Lat. color, connected with celare, to hide, the root meaning, therefore, being that of a covering)

colour; (2) Clays containing a considerable percentage of carbonate of lime in addition to the substances above mentioned . These latter clay deposits are known as " marls," 1 and may contain as much 1 The See also:

• TERM

term " See also:

• MARL (from O. Fr. marle, Late Lat. margila, dim. of marga; cf. Du. and Ger. Mergel)

marl " has been wrongly applied to many fire-clays . It should be restricted to natural mixtures of clay and See also:

• CHALK

chalk such as those of the See also:

• PARIS
• PARIS (also called ALEXANDROS)
• PARIS, ALEXIS PAULIN (1800-x881)
• PARIS, BRUNO PAULIN GASTON (1839-1903)
• PARIS, FRANCOIS DE (169o-1727)
• PARIS, LOUIS PHILIPPE ALBERT
• PARIS, TREATIES OF (1814-1815)

Paris and London basins.1 as 40% of chalk . They burn to a See also:

• SULPHUR

sulphur-yellow colour which is quite distinctive . Brick clays of class (1) are very widely distributed, and have a more extensive See also:

• GEOLOGICAL

geological range than the marls, which are found in connexion with chalk or See also:

• LIMESTONE

limestone formations only . These ordinary brick clays vary considerably in composition, and many clays, as they are found in nature, are unsuitable for brickmaking without the addition of some other kind of clay or sand .

The strongest brick clays, i.e. those possessing the greatest plasticity and tensile strength, are usually those which contain the highest percentage of the hydrated aluminium silicates, although the exact relation of plasticity to chemical composition has not yet been determined . This statement cannot be applied indiscriminately to all clays, but may be taken as fairly applicable to clays of one general type (see CLAY) . All clays contain more or less See also:

• FREE

free See also:

• SILICA

silica in the See also:

• FORM (Lat. forma)

form of sand, and usually a small percent-See also:

• AGE (Fr. age, through late Lat. aetaticum, from aetas)

age of undecomposed felspar . The most important ingredient, after the clay-substance and the sand, is oxide of iron; for the colour, and, to a less extent, the hardness and durability of the burnt bricks depend on its presence . The amount of oxide of iron in these clays varies from about 2 to so %, and the colour of the bricks varies accordingly from See also:

• LIGHT

light buff to See also:

• CHOCOLATE

chocolate; although the colour developed by a given percentage of oxide of iron is influenced by the other substances present and also by the method of firing . A clay containing from 5 to 8% of oxide of iron will, under ordinary conditions of firing, produce a red brick; but if the clay contains 3 to 4% of alkalis, or the brick is fired too hard, the colour will be darker and more See also:

• PURPLE

purple . The actions of the alkalis and of increased temperature are probably closely related, for in either case the clay is brought nearer to its See also:

• FUSION

fusion point, and ferruginous clays generally become darker in colour as they approach to fusion . Alumina acts in the opposite direction, an excess of this See also:

• COMPOUND
• COMPOUND (from Lat. componere, to combine or put together)

compound tending to make the colour lighter and brighter . It is impossible to give a typical composition for such clays, as the percentages of the different constituents vary through such wide ranges . The clay substance may vary from 15 to 8o %, the free silica or sand from 5 to 8o%, the oxide of iron from 1 to ro%, the See also:

• CARBONATES

carbonates of lime and See also:

• MAGNESIA

magnesia together, from 1 to 5 %, and the alkalis from 1 to 4% . Organic See also:

• MATTER

matter is always present, and other impurities which frequently occur are the sulphates of lime and magnesia, the chlorides and nitrates of soda and potash, and iron-See also:

• PYRITES

pyrites . The presence of organic matter gives the wet clay a greater plasticity, probably because it forms a kind of See also:

• MUCILAGE (from Late Lat. mucilago, a mouldy juice, from mucere, to be mouldy)

mucilage which adds a certain viscosity and adhesiveness to the natural plasticity of the clay .

In some of the See also:

• COAL

coal-measure shales the amount of organic matter is very considerable, and may render the clay useless for brickmaking . The other impurities, all of which, except the pyrites, are soluble in water, are undesirable, as they give rise to scum," which produces patchy colour and pitted faces on the bricks . The commonest soluble impurity is See also:

• CALCIUM [symbol Ca, atomic weight 40.0 (o= x6)]

calcium sulphate, which produces a whitish scum on the See also:

• FACE (from Lat. fades, derived either from facere, to make, or from a root fa-, meaning " appear "; cf. Gr. cbatvstv)

face of the brick in drying, and as the scum becomes permanently fixed in burning, such bricks are of little use except for See also:

• COMMON

common work . This question of "scumming" is very important to the maker of high-class facing and moulded bricks, and where a clay containing calcium sulphate must be used, a certain percentage of See also:

• BARIUM (symbol Ba, atomic weight 137'37 [0=16])

barium carbonate is nowadays added to the wet clay . By this means the calcium sulphate is converted into calcium carbonate which is insoluble in water, so that it remains distributed throughout the mass of the brick instead of being deposited on the surface . The presence of See also:

• MAGNESIUM [symbol Mg, atomic weight 24.32 (0 = 16)]

magnesium salts is also very objectionable, as these generally remain in the burnt brick - as magnesium sulphate, which gives rise to an efflorescence of fine See also:

• WHITE
• WHITE, ANDREW DICKSON (1832– )
• WHITE, GILBERT (1720–1793)
• WHITE, HENRY KIRKE (1785-1806)
• WHITE, HUGH LAWSON (1773-1840)
• WHITE, JOSEPH BLANCO (1775-1841)
• WHITE, RICHARD GRANT (1822-1885)
• WHITE, ROBERT (1645-1704)
• WHITE, SIR GEORGE STUART (1835– )
• WHITE, SIR THOMAS (1492-1567)
• WHITE, SIR WILLIAM ARTHUR (1824--1891)
• WHITE, SIR WILLIAM HENRY (1845– )
• WHITE, THOMAS (1628-1698)
• WHITE, THOMAS (c. 1550-1624)

white crystals after the bricks are built into position . Clays which are strong or plastic are known as " See also:

• FAT (O.E. fdett; the word is common to Teutonic languages, cf. Dutch vet, Ger. Fett, &c., and may be ultimately related to Greek Irian, and =apos, and Sanskrit pivan)

fat " clays, and they always contain a high percentage of true " clay substance, and, consequently, a See also:

• LOW, SETH (1850- )
• LOW, WILL HICOK (1853- )

low percentage of sand . Such clays take up a considerable amount of water in " tempering"; they dry slowly, shrink greatly, and so become liable to lose their shape and develop cracks in drying and firing . " Fat " clays are greatly improved by the addition of coarse See also:

• SHARP, GRANVILLE (1735-1813)
• SHARP, JAMES (1618-1679)
• SHARP, JOHN (1645-1714)
• SHARP, RICHARD (1759-1835)
• SHARP, WILLIAM (1749-1824)
• SHARP, WILLIAM (1856-1905)

sharp sand, which reduces the time of drying and the shrinkage, and makes the brick more rigid during the firing . Coarse sand, unlike clay-substance, is practically unaffected during the drying and firing, and is a desirable if not a necessary ingredient of all brick clays . The best brick-clays feel gritty between the fingers; they should, of course, be free from pebbles, sufficiently plastic to be moulded into shape and strong enough when dry to be safely handled . All clays are greatly improved by being turned over and exposed to the See also:

• WEATHER (O. Eng. weder; the word is common to Teutonic languages; cf. Du. weder, Dan. veir, Icel. ve8r, and Ger. Wetter and Gewitter, storm; the root is wa- to blow, from which is derived " wind ")

weather, or by See also:

• STANDING

standing for some months in a wet condition .

This "weathering" and "ageing" of clay is particularly important where bricks are made from tempered clay , i.e. clay in the wet or plastic See also:

• STATE
• STATE, GREAT OFFICERS OF

state; where bricks are made from shale, in the semi-plastic condition, weathering is still of importance . The lime clays or " marls " of class (2), which contain essentially a high percentage of chalk or limestone, are not so widely distributed as the ordinary brick-clays, and in England the natural deposits of these clays have been largely exhausted . A very fine chalk-clay, or "maim" as it was locally called, was formerly obtained from the See also:

• ALLUVIUM

alluvium in the vicinity of London; but the available See also:

• SUPPLY (through Fr. from Lat. supplere, to fill up)

supply of this has been used up, and at the present time an artificial " maim " is prepared by mixing an ordinary brick-clay with ground chalk . For the best London facing-bricks the clay and chalk are mixed in water . The chalk is ground on grinding-pans, and the clay is mixed with water and worked about until the mixture has the consistence of cream . The mixture of these " pulps " is run through a grating or coarse See also:

• SIEVE (O.E. sife, older sibi, cf. Dutch zeef, Ger. Sieb; from the subst. comes O.E. siftan, to sift)

sieve on to a drying-See also:

• KILN (0. E. cylene, from the Lat. culina, a kitchen, cooking-stove)

kiln or " bed," where it is allowed to stand until stiff enough to walk on . A layer of fine ashes is then spread over the clay, and the mass is turned over and mixed by See also:

• SPADE

spade, and tempered by the addition of water . In other districts, where clays containing limestone are used, the marl is mixed with water on a See also:

• WASH, THE

wash-See also:

• PAN (" pasturer ")
• PAN (common in various forms to many Teutonic languages, cf. Ger. Pfanne; it is generally taken to be an early adaptation in a shortened form of Lat. patina, shallow bowl or dish, from patere, to lie open)

pan and the resulting creamy fluid passed through coarse See also:

• SIEVES

sieves on to a drying-bed . If necessary, coarse sand is added to the clay in the wash-pan, and such addition is often advisable because the washed clays are generally very fine in See also:

• GRAIN (derived through the French from Lat. granum, seed, from an Aryan root meaning " to wear down," which also appears in the common Teutonic word " corn ")

grain . Another method of treating these marls, when they are in the plastic condition, is to squeeze them by machinery through iron gratings, which See also:

• ARREST (Fr. arrester, arreeter, to stop or stay)

arrest and remove the pebbles . In other cases the marl is passed through a grinding-See also:

• MILL
• MILL (O. Eng. mylen, later myln, or miln, adapted from the late Lat. molina, cf. Fr. moulin, from Lat. mola, a mill, molere, to grind; from the same root, mol, is derived " meal;" the word appears in other Teutonic languages, cf. Du. molen, Ger. muhle)
• MILL, JAMES (1773-1836)
• MILL, JOHN (c. 1645–1707)
• MILL, JOHN STUART (1806-1873)

mill having a solid bottom and heavy iron rollers, by which means the limestone pebbles are crushed sufficiently and mixed through the whole mass . The removal of limestone pebbles from the clay is of great importance, as during the firing they would be converted into quicklime, which has a tendency to shatter the brick on exposure to the weather .

As before stated, these marls (which usually contain from 15 to 30 % of calcium carbonate) burn to a yellow colour which is quite distinctive, although in some cases, where the percentage of Iimestone is very high, over 40%, the colour is See also:

• GREY, CHARLES GREY, 2ND EARL (1764-1845)
• GREY, HENRY GREY, 3RD EARL (1802-1894)
• GREY, LADY JANE (1537-1554)
• GREY, SIR EDWARD
• GREY, SIR GEORGE (1812–1898)

grey or a very See also:

• PALE (through Fr. pal, from Lat. palms, a stake, for paglus, from the stem pag- of pangere, to fix; " pole " is from the same original source)

pale buff . The action of lime in See also:

• BLEACHING

bleaching the ferric oxide and producing a yellow instead of a red brick, has not been thoroughly investigated, but it seems probable that some compound is produced, between the lime and the oxide of iron, or between these two oxides and the free silica, entirely different from that produced by oxide of iron in the See also:

• ABSENCE (Lat. absentia)

absence of lime . Such marls require a harder fire than the ordinary brick-clays in See also:

• ORDER
• ORDER (through Fr. ordre, for earlier ordene, from Lat. ordo, ordinis, rank, service, arrangement; the ultimate source is generally taken to be the root seen in Lat. oriri, rise, arise, begin; cf. " origin ")
• ORDER, HOLY

order to bring about the reaction between the lime and the other ingredients . Magnesia may replace lime to some extent in such marls, but the firing temperature must be higher when magnesia is present . Marls usually See also:

• CONTRACT
• CONTRACT (Lat. contract us, from contrahere, to draw together, to bind)

contract very little, if at all, in the burning, and generally produce a strong, square brick of fine texture and good colour . When under-fired, marl bricks are very liable to disintegrate under the action of the weather, and great care must be exercised in burning them at a sufficiently high temperature . Brickmaking.—Bricks made of tempered clay may be made by hand or by See also:

• MACHINE
• MACHINE (through Fr. from Lat. form machina of Gr. µnxavil)

machine, and the See also:

• MACHINES

machines may be worked by hand or by See also:

• MECHANICAL

mechanical See also:

• POWER [WILLIAM GRATTAN] TYRONE (1797-1841)

power . Bricks made of semi-plastic clay (i.e. ground clay or shale sufficiently See also:

• DAMP

damp to adhere under pressure) are generally machine-made throughout . The method of making bricks by hand is the same, with slight variation, the world over . The tempered clay is pressed by hand into a wooden or See also:

• METAL
• METAL (through Fr. from Lat. metallum, mine, quarry, adapted from Gr. µATaXAov, in the same sense, probably connected with ,ueraAAdv, to search after, explore, µeTa, after, aAAos, other)

metal See also:

• MOULD

mould or four-sided case (without See also:

• TOP (cf. Dan. top, Ger. Topf, also meaning pot)

top or519 bottom) which is of the desired shape and size, See also:

• ALLOWANCE (from "allow,' derived through 0. Fr. alouer from the two Lat. origins adlaudare, to praise, and allocare, to assign a place; so that the English word combined the general idea of "assigning with approval")

allowance being made for the shrinkage of the brick in drying and firing . The moulder stands at the See also:

• BENCH (an O.E. and Eng. form of a word common to Teutonic languages, cf. Ger. Bank, Dan. baenk and the Eng. doublet " bank ")

bench or table, dips the mould in water, or water and then sand, to prevent the clay from sticking, takes a rudely shaped piece of clay from an assistant, and dashes this into the mould which rests on the moulding bench . He then presses the clay into the corners of the mould with his fingers, scrapes off any surplus clay and levels the top by means of a See also:

• STRIP

strip of See also:

• WOOD, ANTHONY A2 (1632-1695)
• WOOD, JOHN GEORGE (1827—1889)
• WOOD, MRS HENRY [ELLEN] (1814—1887)
• WOOD, SEARLES VALENTINE (1798—188o)

wood called a " strike," and then turns the brick out of the mould on to a See also:

• BOARD (O. Eng. bord)

board, to be carried away by another assistant to the drying-ground .

The mould may be placed on a special pieceof wood, called the stock-board, provided with an elevated See also:

• TONGUE (O. Eng. lunge)

tongue of wood in the centre, which produces the hollow or " See also:

• FROG

frog " in the bottom of the brick . Machine-made bricks may be divided into two kinds, plastic and semi-plastic, although the same type of machine is often used for both kinds . The machine-made plastic bricks are made of tempered clay, but generally the. tempering and working of the clay are effected by the use of machinery, especially when the harder clays and shales are used . The machines used in the preparation of such clays are grinding-See also:

• MILLS, JOHN (d. 1736)
• MILLS, ROGER QUARLES (1832– )

mills and pug-mills . The grinding-mills are either a See also:

• SERIES (a Latin word from serere, to join)

series of rollers with graduated spaces between, through which the clay or shale is passed, or are of the ordinary " See also:

• MORTAR

mortar pan " type, having a solid or perforated iron bottom on which the clay or shale is crushed by heavy rollers . Shales are sometimes passed through a grinding-mill before they are exposed to the action of the weather, as the disintegration of the hard lumps of shale greatly accelerates the " weathering." In the case of ordinary brick-clay, in the plastic condition, grinding-mills are only used when pebbles more than a See also:

• QUARTER (through Fr. from Lat. quartarius, fourth part)

quarter of an See also:

• INCH (O. Eng. ynce from Lat. uncia, a twelfthpart; cf. " ounce," and see As)

inch in See also:

• DIAMETER (from the Cr. &a, through, µErpov, measure)

diameter are present, as otherwise the clay may be passed directly through the pug-mill, a See also:

• PROCESS

process which may be repeated if necessary . The pug-mill consists of a See also:

• BOX
• BOX (Gr. irl or, Lat. buxus, box-wood; cf. 2r6Eir, a pyx)

box or trough having a feed hole at one end and a delivery hole or See also:

• NOSE (O.Eng. nosu, cf. Dutch neus, Swed. nos, snout; the Aix in Provence. Both at Aix and at Lyons he acquired great connexion with O.Eng. nasu is obscure, cf. Ger. Nase, Lat. pares, distinction by his labours during outbreaks of the plague. In nostrils,

nose at the other end, and provided with a central See also:

• SHAFT
• SHAFT (O. Eng., sceaft, from scafan, to shave; the word is common to Teutonic languages)

shaft which carries knives and cutters so arranged that when the shaft revolves they cut and knead the clay, and at the same time force it towards and through the delivery nose . . The See also:

• CROSS

cross See also:

• SECTION
• SECTION (Lat. sectio, cutting, secare, to cut)

section of this nose of the pug-mill is approximately the same as that of the required brick (9 in . X 42 in. plus contraction, for ordinary bricks), so that the pug delivers a solid or continuous mass of clay from which bricks may be made by merely making a series of square cuts at the proper distances apart . In practice, the clay is pushed from the pug along a smooth iron See also:

• PLATE

plate, which is provided with a See also:

• WIRE (A.S. wir, a wire; cf. Swed. vire, to twist, M.H.G. wiere, a gold ornament, Lat. viriae, armlets, ultimately from the root wi, to twist, bind)

wire cutting See also:

• FRAME

frame having a number of tightly stretched wires placed at certain distances apart, arranged so that they can be brought down upon, and through, the clay, and so many bricks cut off at intervals . The frame is sometimes in the form of a See also:

• SKELETON

skeleton See also:

• CYLINDER (Gr. KvAwSpos, from KvXivaety, to roll)

cylinder, the wires being arranged radially (or the wires may be replaced by metal disks) ; but in all cases bricks thus made are known as " wire-cuts." In order to obtain a better-shaped and more compact brick, these wire-cuts may be placed under a brick See also:

• PRESS (through Fr. presse from Lat. pressare, frequentative of premere, to crush, squeeze, press)

press and there squeezed into iron moulds under great pressure . These two processes are now generally performed by one machine, consisting of pug-mill and brick press combined .

The pug delivers the clay, downwards, into the mould; the proper amount of clay is cutoff; and the mould is made to travel into position under the See also:

• RAM
• RAM, PIERRE FRANCOIS XAVIER DE (18o4-1865)

ram of the press, which squeezes the clay into a solid mass . There are many forms of brick press, a few for hand power, but the most adapted for See also:

• BELT (a word common to Teutonic languages, the Old Ger. form being bale, from which the Lat. balteus probably derived)
• BELT, THOMAS (1832-1878)

belt-See also:

• DRIVING (from " to drive," i.e. generally to propel, force along or in, a word common in various forms to the Teutonic languages)

driving; although in recent years See also:

• HYDRAULIC

hydraulic presses have come more and more into use, especially in Germany and America . The essential parts of a brick press are: (I) a box or frame in which the clay is moulded; (2) a plunger or See also:

• DIE
• DIE (Fr. de, from Lat. datum, given)

die carried on the end of a rain, which gives the necessary pressure; (3) an arrangement for pushing the pressed brick out of the moulding box . Such presses are generally made of iron throughout, although other metals are used, occasionally, for the moulds and See also:

• DIES, CHRISTOPH ALBERT (1755-1822)

dies . The greatest See also:

• VARIATIONS
• VARIATIONS, CALCULUS
• VARIATIONS, CALCULUS OF

variations found in brick presses are in the means adopted for actuating the ram; and many ingenious mechanical devices have been. applied to this end, each claiming some particular See also:

• ADVANTAGE

advantage over its predecessors . In many recent presses, especially where semi-plastic clay is used, the brick is pressed simultaneously from top and. bottom, a second ram, working upwards from beneath, giving the additional pressure . Although the best bricks are still pressed from tempered or plastic clay, there has recently been.a great development in the manufacture of semi-plastic or dust-made bricks, especially in those districts where shales are used for brickmaking . These semi-plastic bricks are stamped out of ground shale that has been sufficiently moistened with water to enable it to bind together . The hard-clay, or shale, is crushed under heavy rollers in an iron grinding-pan having a perforated bottom through which the crushed clay passes, when sufficiently fine, into a small compartment underneath . This clay See also:

• POWDER (through O. Fr. puldre, modern poudre, from Lat. pulvis, pulveris, dust)

powder is then delivered, by an elevator, into a sieve or See also:

• SCREEN (usually, but very doubtfully, connected with Lat. scrinium, a box for holding books, from scribere, to write; a connexion with Ger. Schranke, barrier, has been suggested)

screen, which retains the coarser particles for regrinding . Sets of rollers may also be used for crushing shales that are only moderately hard, the ground material being sifted as before . The material, as fed into the mould of the press, is a coarse, damp powder which becomes adhesive under pressure, producing a so-called semi-plastic " brick .

The presses used are similar to those employed for plastic clay, but they are generally more strongly and heavily built, and are capable of applying a greater pressure . The semi-plastic method has many advantages where shales are used, although the bricks are not as strong nor as perfect as the best " plastic " bricks . The method, however, enables the brickmaker to make use of certain kinds of clay-rock, or shale, that would be impracticable for plastic bricks; and the weathering, tempering and " ageing " may be largely or entirely dispensed with . The plant required is heavier and more costly, but the brickyard becomes more compact, and the processes are simpler than with the plastic " method . The drying of bricks, which was formerly done in the open, is now, in most cases, conducted in a special See also:

• SHED

shed heated by flues along which the heated gases from the kilns pass on their way to the See also:

• CHIMNEY (through the Fr. cheminee, from caminata, sc. camera, a Lat. derivative of caminus, an oven or furnace)

chimney . It is important that the See also:

• ATMOSPHERE (Gr. fir µ6r, vapour; orkaipa, a sphere)

atmosphere of the drying-shed should be fairly dry, to which end suitable means of See also:

• VENTILATION (Lat. ventilare, from ventus, wind)

ventilation must be arranged (by fans or otherwise) . If the atmosphere is too moist the surface of the brick remains damp for a considerable time, and the moisture from the interior passes to the surface as water, carrying with it the soluble salts, which are deposited on the surface as the water slowly evaporates . This See also:

• DEPOSIT (Lat. depositurn, from deponere, to lay down, to put in the care of)

deposit produces the " scum " already referred to . When the drying is done in a dry atmosphere the surface quickly dries and hardens, and the moisture from the interior passes to the surface as vapour, the soluble salts being See also:

• LEFT

left distributed through the whole mass, and consequently no " scum " is produced . Plastic bricks take much longer to dry than semi-plastic; they shrink more and have a greater tendency to warp or twist . The burning or firing of bricks is the most important See also:

• FACTOR (from Lat. facere, to make or do)

factor in their See also:

• PRODUCTION (Lat. productionem, from producere, to pro-duce)

production; for their strength and durability depend very largely on the See also:

• CHARACTER (Gr. xapareri7p, from xap&crew, to scratch)

character and degree of the firing towhich they have been subjected . The action of the See also:

• HEAT (0. E. haktu, which like " hot," Old Eng. hat, is from the Teutonic type haita, hit, to be hot; cf. Ger. hitze, heiss; Dutch, hitte, heet, &c.)

heat brings about certain chemical decompositions and re-combinations which entirely alter the See also:

• PHYSICAL

physical character of the dry clay .

It is important, therefore, that the firing should be carefully conducted and that it should be under proper See also:

• CONTROL (Fr. contrdle, older form contre rolle, from Med. Lat. contra-rotulus, a counter roll or copy of a document used to check the original; there is no instance in English of the use of " control " in this, its literal, meaning)

control . For ordinary bricks the firing atmosphere should be oxidizing, and the See also:

• FINISHING

finishing temperature should be adjusted to the nature of the clay, the See also:

• OBJECT

object being to produce a hard strong brick, of good shape, that will not be too porous and will withstand the action of frost . The finishing temperature ranges from 900 C. to 1250° C., the usual temperature being about Io5o° C. for ordinary bricks . As before mentioned, lime-clays require a higher firing temperature (usually about 1 1 go° C. to 1200° C.) in order to bring the lime into chemical See also:

• COMBINATION (Lat. combinare, to combine)

combination with the other substances present . It is evident that the best method of firing bricks is to See also:

• PLACE (through Fr. from Lat. platea, street; Gr. IrAar6s, wide)

place them in permanent kilns, but although such kilns were used by the Romans some 2000 years ago, the older method of firing in "clamps " is still employed in the smaller brickfields, in every country where bricks are made . These clamps are formed by arranging the unfired bricks in a series of rows or walls, placed fairly closely together, so as to form a rectangular stack . A certain number of channels, or fire-mouths, are formed in the bottom of the clamp; and fine coal is spread in See also:

• HORIZONTAL

horizontal layers between the bricks during the building up of the stack . Fires are kindled in the fire-mouths, and the clamp is allowed to go on burning until the See also:

• FUEL (O. Fr. feuaile, popular Lat. focalia, from focus, hearth, fire)

fuel is consumed throughout, The clamp is then allowed to cool, after which it is taken down, and the bricks sorted; those that are under-fired being built up again in the next clamp for refiring . Sometimes the clamp takes the form of a temporary kiln, the outside being built of burnt bricks which are plastered over with clay, and the fire-mouths being larger and more carefully formed . There are many other See also:

• LOCAL

local modifications in the manner of building up the clamps, all with the object of producing a large percentage of well-fired bricks . Clanip-firing is slow, and also uneconomical, because irregular and not sufficiently under control; and it is now only employed where bricks are made on a small See also:

• SCALE
• SCALE (1) A

scale . Brick-kilns are of many forms, but they can all be grouped under two See also:

• MAIN (from the Aryan root which appears in " may " and " might," and Lat. magnus, great)
• MAIN (Lat. Moenus)

main types—Intermittent kilns and Continuous kilns .

The intermittent kiln is usually circular in See also:

• PLAN
• PLAN (from Lat. planes, flat)

plan, being in the form of a See also:

• VERTICAL (from Lat. vertex, highest point)

vertical cylinder with a domed top . It consists of a single firing-chamber in which the unfired bricks are placed, and in the walls of which are contrived a number of fire-mouths where wood or coal is burned . In the older forms known as up-See also:

• DRAUGHT (from the common Teutonic word " to draw "; cf. Ger. 7'racht, load; the pronunciation led to the variant form " draft," now confined to certain specific meanings)

draught kilns, the products of See also:

• COMBUSTION (from the Lat. comburere, to burn up)

combustion pass from the fire-mouth, through flues, into the bottom of the firing-chamber, and thence directly upwards and out at the top . The modern plan is to introduce the products of combustion near the top, or See also:

• CROWN

crown, of the kiln, and to draw them down-wards through holes in the bottom which See also:

• LEAD
• LEAD (pronounced iced)

lead to flues connected with an See also:

• INDEPENDENT

independent chimney . These down-draught kilns have See also:

• SHORT, FRANCIS JOB (1857– )

short chimneys or " bags " built See also:

• ROUND (O. Fr. rond, Lat. rotundus, the Fr. is the source also of Du. rond; Ger., Swed., Dan. and Nor. rond)

round the inside wall in connexion with the fire-mouths, which conduct the flames to the upper See also:

• PART

part of the firing-chamber, where they are reverberated and passed down through the bricks in obedience to the pull of the chimney . The " bags" may be joined together, forming an inner circular wall entirely round the firing chamber, except at the See also:

• DOORWAY (corresponding to the Gr. Iran, Lat. porte)

doorway; and a number of kilns may be built in a See also:

• ROW, JOHN (c. 1525—1580)

row or See also:

• GROUP

group having their bottom flues connected with the same tall chimney . Down-draught kilns usually give a more See also:

• REGULAR

regular fire and a higher percentage of well-fired bricks;and they are more economical in fuel See also:

• CONSUMPTION (Lat. consumere)

consumption thanup-draught kilns, while the hot gases, as they pass from the kiln, may be utilized for drying purposes, being conducted through flues under the See also:

• FLOOR (from O. Eng. flor, a word common to many Teutonic languages, cf. Dutch vloer, and Ger. Flur, a field, in the feminine, and a floor, masculine)

floor of the drying-shed, on their way to the chimney . The method of using one tall chimney to work a group of down-draught kilns naturally led to the invention of the " continuous " kiln, which is really made up of a number of See also:

• SEPARATE

separate kilns or firing-See also:

• CHAMBERS (the Fr. chambre, from Lat. camera, a room)
• CHAMBERS, EPHRAIM (d. 1740)
• CHAMBERS, GEORGE (1803-1840)
• CHAMBERS, ROBERT (18oz-1871)
• CHAMBERS, SIR WILLIAM (1726-1796)

chambers, built in series and connected up to the main flue of the chimney in such a manner that the products of combustion from one kiln may be made to pass through a number of other kilns before entering the flue . The earliest formof continuous kiln was invented by See also:

• FRIEDRICH, JOHANN (1836— )

Friedrich Hoffman, and all kilns of this type are built on the Hoffman principle, although there are a great number of modifications of the See also:

• ORIGINAL

original Hoffman construction . The great principle of continuous " firing is the utilization of the See also:

• WASTE (O. Fr. wast, guast, gast, gaste; Lat. vastus, vast, desolate)

waste heat from one kiln or section of a kiln in See also:

• HEATING

heating up another kiln or section, See also:

• DIRECT

direct firing being applied only to finish the burning . In practice a number of kilns or firing-chambers, usually rectangular in plan, are built side by side in two parallel lines, which are connected at the ends by other kilns so as to make a See also:

• COMPLETE

complete See also:

• CIRCUIT (Lat. circuitus, from circum, round, and ire, to go)

circuit . The original form of the complete series was elliptical in plan, but the tendency in recent years has been to flatten the sides of the See also:

• ELLIPSE (adapted from Gr. EXkei 'tc, a deficiency, iXXeirely, to fall behind)

ellipse and bring them together, thus giving two parallel rows joined at the ends by a chamber or passage at right angles .

Coal or See also:

• GAS

gas is burnt in the chamber or section that is being fired-up, the See also:

• AIR (from an Indo-European root meaning " breathe," " blow ")
• AIR, or ASBEN

air necessary for the combustion being heated on its passage through the kilns that are cooling down, and the products of combustion, before entering the chimney flue, are See also:

• DRAWN

drawn through a number of other kilns or chambers containing unfired bricks, which are thus gradually heated up by the otherwise waste-heat from the sections being fired . Continuous kilns produce a more evenly fired product than the intermittent kilns usually do, and, of course, at much less cost for fuel . Gas firing is now being extensively applied to continuous kilns, natural gas in some instances being used in the See also:

• UNITED

United States of America; and the methods of construction and of firing are carried out with greater care and intelligence, the See also:

• PRIME, PRIMER AND PRIMING

prime See also:

• OBJECTS

objects being See also:

• ECONOMY

economy of fuel and perfect control of firing . Pyrometers are coming into use for the control of the firing temperature with the result that a See also:

• CONSTANT, BENJAMIN (1845-1902)

constant and trustworthy product is turned out . The introduction of machinery greatly helped the brickmaking industry in opening up new See also:

• SOURCES

sources of supply of raw material in the shales and hardened clays of the sedimentary deposits of the older geologic formations, and, with the extended use of continuous firing See also:

• PLANTS

plants, it has led to the See also:

• ESTABLISHMENT (0. Fr. establissement, Fr. etablissement, late Norm. Fr. establishement, from O. Fr. establir, Fr. etablir, Lat. stabilire, to make stable)

establishment of large concerns where every-thing is co-ordinated for the production of enormous quantities of bricks at a minimum cost . In the United See also:

• KINGDOM

Kingdom, and still more in Germany and the United States of America, great improvements have been made in machinery, firing-plant and organization, so that the whole manufacture is now being conducted on more scientific lines, to the great advantage of the industry . See also:

• BLUE (common in different forms to most European languages)

Blue Brick is a very strong vitreous brick of dark, slaty-blue colour, used in See also:

• ENGINEERING

engineering See also:

• WORKS

works where great strength or impermeability is desirable . These bricks are made of clay containing front 7 to Io% of oxide of iron, and their manufacture is carried out in the ordinary way until the later stages of the firing process, whets they are subjected to the strongly reducing action of a smoky atmosphere, which is produced by throwing small bituminous coal upon the fire-mouths and damping down the See also:

• ADMISSION

admission of air . The See also:

• SMOKE (from O. Eng. smeocan, to smoke, reek, cf. Dutch meek, Ger. Schmauch, probably allied to Gr. vol9caiv)

smoke thus produced reduces the red ferric oxide to blue-See also:

• GREEN, A
• GREEN, ALEXANDER HENRY (1832—1896)
• GREEN, DUFF (1791—1875)
• GREEN, JOHN RICHARD (1837—1883)
• GREEN, MATTHEW (1696-1737)
• GREEN, THOMAS HILL (1836-1882)
• GREEN, VALENTINE (1739–1813)
• GREEN, WILLIAM HENRY (.1825–1900)

green ferrous oxide, or to metallic iron, which combines with the silica present to form a fusible ferrous silicate . This fusible " slag "' partly combines with the other silicates present, and partly fills up the pores, and so produces a vitreous impermeable layer varying in thickness according to the duration and character of the smoking, the finishing temperature of the kiln and the texture of the brick . Particles of- See also:

• CARBON (symbol C, atomic weight 12)

carbon penetrate the surface during the early stages of the smoking, and a small quantity of carbon probably enters into combination, tending to produce a harder surface and darker colour . Floating Bricks were first mentioned by See also:

• STRABO (born c. 63 n.c.)

Strabo, the See also:

• GREEK
• GREEK, ETRUSCAN AND

Greek geo- vapher, and afterwards by Pliny as being made at Pitane in the road .

The See also:

• SECRET (Lat. secretum, hidden, concealed)

secret of their manufacture was lost for many centuries, but was rediscovered in 1791 by Fabroni, an See also:

• ITALIAN

Italian, who made them from the fossil See also:

• MEAL

meal (diatomaceous See also:

• EARTH
• EARTH (a word common to Teutonic languages, cf. Ger. Erde, Dutch aarde, Swed. and Dan. jord; outside Teutonic it appears only in the Gr. 'pq'e, on the ground; it has been connected by some etymologists with the Aryan root ar-, to plough, which is seen in
• EARTH, FIGURE OF
• EARTH, FIGURE OF THE

earth) found in See also:

• TUSCANY
• TUSCANY (Toscana)

Tuscany . These bricks are very light, fairly strong, and being poor conductors of heat, have been employed for the construction of powder-magazines on board See also:

• SHIP

ship, &c . Mortar Bricks belong to the class of unburnt bricks, and are, strictly speaking, blocks of artificial stone made in brick moulds . These bricks have been made for many years by moulding a mixture of sand and slaked lime and allowing the blocks thus made to harden in the air . This hardening is brought about partly by evaporation of the water, but chiefly by the See also:

• CONVERSION (Lat. conversio, from convertere, to turn or ,change)

conversion of the calcium See also:

• HYDRATE

hydrate, or slaked lime, into calcium carbonate by the action of the carbonic See also:

• ACID (from the Lat. root ac-, sharp; acere, to be sour)

acid in the atmosphere . A small proportion of the lime enters into combination with the silica and water present to form hydrated calcium silicate, and probably a little hydrated basic carbonate of lime is also formed, both of which substances are in the nature of See also:

• CEMENT (from Lat. caementum, rough pieces of stone, a shortened form of caedimentum, from caedere, to cut)

cement . This process of natural hardening by exposure to the air was a very long one, occupying from six to eighteen months, and many improvements were introduced during the latter See also:

• HALF

half of the 19th century to improve the strength of the bricks and to hasten the hardening . Mixtures of sand, lime and cement (and of certain ground blast-See also:

• FURNACE

furnace slags and lime) were introduced; the moulding was done under hydraulic presses and the bricks afterwards treated with carbon dioxide under pressure, with or without the application of mild heat . Some of these mixtures and methods are still in use, but a new type of mortar brick has come into use during recent years which has practically superseded the old mortar brick . Sand-lime Bricks.—In the early 'eighties of the 19th century, Dr See also:

• MICHAELIS, JOHANN DAVID (1717-1791)

Michaelis of See also:

• BERLIN
• BERLIN, CONGRESS AND TREATY OF
• BERLIN, ISAIAH (1725–1799)

Berlin patented a new process for hardening blocks made of a mixture of sand and lime by treating them with high-pressure See also:

• STEAM
• STEAM (0. Eng. steam, vapour, smoke, cf. Du. steam; the origin is unknown)

steam for a few See also:

• HOURS, CANONICAL

hours, and the so-called sand-lime bricks are now made on a very extensive scale in many countries . There are many See also:

• DIFFERENCES, CALCULUS OF (Theory of Finite Differences)

differences of detail in the manufacture, but the general method is in all cases the same . Dry sand is intimately mixed with about one-tenth of its See also:

• WEIGHT

weight of powdered slaked lime, the mixture is then slightly moistened with water and afterwards moulded into bricks under powerful presses, capable of exerting a pressure of about 6o tons per sq. in .

After removal from the press the bricks are immediately placed in huge See also:

• STEEL, FLORA ANNIE (1847– )

steel cylinders usually 6o to 8o ft. long and about 7 ft. in diameter, and are there subjected to the action of high-pressure steam (120 lb to 15o lb per sq. in.) for from ten to fifteen hours . The proportion of slaked lime to sand varies according to the nature of the lime and the purity and character of the sand, one of lime to ten of sand being a See also:

• FAIR

fair See also:

• AVERAGE

average . The following is an See also:

• ANALYSIS (Gr. avci and Meta, to break up into parts)

analysis of a typical See also:

• GERMAN
• GERMAN, DUTCH AND SCANDINAVIAN

German sand-lime brick: silica (SiO2), 84 %; lime (CaO), 7%; alumina and oxide of iron, 2 %; water, magnesia and alkalis, 7 % . Under the action of the high-pressure steam the lime attacks the particles of sand, and a chemical compound of water, lime and silica is produced which forms a strong See also:

• BOND
• BOND, SIR EDWARD AUGUSTUS (1815-1898)

bond between the larger particles of sand . This bond of hydrated calcium silicate is evidently different from, and of better type than, the filling of calcium carbonate produced in the mortar-brick, and the sand-lime brick is consequently much stronger than the ordinary mortar-brick, however the latter may be made . The sand-lime brick is See also:

• SIMPLE

simple in manufacture, and with reasonable care is of constant quality . It is usually of a light-grey colour, but may be stained by the addition of suitable colouring oxides or See also:

• PIGMENTS (Lat. pigmentum, from pingere, to paint)

pigments unaffected by lime and the conditions of manufacture . Strength of Brick.—The following figures indicate the crushing load for bricks of various types in tons per sq. in.: Common hand-made. from 0.4 to o•9 machine-made 0.9 „ 1.2 London stock . . „ 0.7 „ 1.3 See also:

• STAFFORDSHIRE

Staffordshire blue „ 2.8 „ 3.3 Sand-lime . . ++ 2.9 3.4 See also BRICKWORK . (J . B.*; W .