1911 Encyclopædia Britannica/Roofs
ROOFS. A roof is a construction placed as a covering over the upper portion of a building to exclude the weather and preserve the contents dry and uninjured. Roofs are designed to throw off rain and snow, and their slope or “pitch,” as it is generally termed, is governed to a great extent by the climate, as well as by the material used and manner of laying. The pitch may vary from an almost horizontal surface (as largely adopted in dry countries and also in temperate climates for roofs of metal or asphalt) to the steeply pitched roofs required for the ordinary flat tiles which to be weatherproof must be laid at an angle of from 45° to 80° with the horizon. Besides serving the useful purpose of protection against inclement weather the roof, both externally and internally, may be designed to form an architectural feature in keeping with the character of he building.
The simplest form is the “flat roof” consisting of horizontal wood joists laid from wall to wall as in floor construction. The roof must not be quite flat, for a slight fall is necessary in its upper surface to allow water to drain away into gutters placed at convenient points. The joists are covered with a waterproof material such as asphalt, Forms of roof. lead, zinc or copper, the three last materials being usually laid upon boarding, which stiffens the structure and formsagood surface to fix the weatherproof covering upon. Such roofs are not suitable for cold climates, for accumulations of snow might overburden the structure and would also cause the wet to penetrate through any small crevices and under flashing's. With flat roofs the pressure exerted upon the supports is directly vertical.
“Lean-to,” “shed,” or “pent” roofs are practically developments of the flat roof, one end of the joists (which are now called “ rafters ”) being tipped up to form a decided slope, which enables slates, tiles, corrugated iron and other materials to be employed which cannot be used upon a “flat” roof.
Half elevation; 25′ 0″ span. | Sectional elevation on AA. |
Figs. 1 and 2.—King-post Roof Truss. |
Simple roofs in general use with a double slope are the “ coupled rafter roofs, ” the rafters meeting at the highest point upon a horizontal ridge-piece which stiffens the framework and gives a level ridge-line. In some old roofs the rafters are connected without any intervening ridge-plate, with the result that after a time the ridge instead of remaining level takes on a wavy outline, due to the fact that some of the timbers have settled slightly owing to decay or other causes, whilst others have remained firm in their places. The lower ends of the rafters should pitch on a wood plate bedded on the top of the wall; this, as described under Carpentry, assists in spreading the weight over a large area of the wall, and provides good fixing for the timbers. The simple “ couple roof” consists merely of two sets of rafters pitched from plates on the walls on either side of the building and sloping upwards to rest against a common ridge-piece. There are no ties between the feet of the rafters, which therefore exert a considerable thrust against the supporting walls. On account of this and of the lack of rigidity of the framing this form of roof should only be used to cover small spans of ro to 12 ft. Generally the ends of the rafters are connected by ceiling joists which form a level ceiling and at the same time prevent any outward thrust on the supports. When used for spans between 12 ft. and 18 ft. a binder supported by 'an iron or wood “king” tiepevery 5 or 6 ft. should be run along across the centres of the ceiling joists and the latter spiked to it. Such roofs with the wood tie across the feet of the rafters are termed “ couple close roofs.” When the ties are fixed about half-way up the rafters it is called a “ collar roof, ” and may be used for spans up to 16 ft. These are the type of roof commonly used in ordinary dwelling-houses where the fixed on the principal rafters with intervals of about 8 ft., and
framing, usually of rough northern pine or spruce, is generally In such large spans the straining beam often becomes of such hidden from view by the ceilings. The spans usually are not a length as to require support and this is effected by congreat, and extra support is obtained at various points from partitions and cross walls. Where the span is large, that is, above zo ft. without intermediate support, it is necessary to employ roofs with “ principals” and “purlins, ” sometimes called “double tinuing the principal
° '2, mrafters up to the ridge
and introducing a
y
short king-post to
sustain the beam in
rafter roofs.” Principals are strong trusses of timber 4” the middle of its rigidly framed together and placed at intervals of about length. ro ft. to support the weight of the roof covering., ,/ - Open timber roofs Purlins-stout timbers running longitudinally-are of various types but " principally Qpgg
construction were used
in the middle ages
where stone vault-M,
ing was not em-
ployed. Many of
these old roofs still
exist in good pre-7/
serration and exhibit
the great skill of the Y medieval carpenters
who designed and erected them. Such forms are still used, chiefly for ecclesi-SM MPM » astical buildings and
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FIG. 3.-Queen-post Roof Truss; half elevation, 38' o” span. on these the common rafters are fastened. Principals, or “ roof trusses” as they are more often called, are framed together in various ways, and the members may be entirely of wood or reinforced by ties of iron rods or bars; the latter are called “ composite trusses.”
The “ king-post truss ” may be used for spans up to 30 ft. and is constructed as shown in figs. I and 2. It has a central post sustaining the “ tie-beam ” in the centre with struts projecting from its base to support the principal rafters at their centres at a point where the weight. of the purlins renders strutting necessary. The members are connected by wrought iron straps and bolts; the strap connects the king-post and tie-beam and is often fitted with a gib-and-cotter arrangement (really a pair of iron folding wedges) which allows the Whole truss to be tightened up should any settlement or shrinkage occur. “ Queen-post trusses ” have, in place of the king-post dividing the tie-beam into two, two queen-posts supporting it at two points (fig. 3). The joints the roofs over large
halls. In the best
periods of Gothic
architecture the pitch
sometimes as much
of these roofs was made very steep, as 60° with the horizon. In the hammer-beam type of roof the tie-beam at the foot of the rafters is omitted, a. collar being thrown across connecting the principal rafters at a point about half-way in their length, the lower portion of the principal consisting of a number of struts and braces rigidly connected in such a manner as to throw as little thrust as possible upon the walls serving as abutments. There are two kinds of-hammer beams, the arched and the bracketed; the chief examples are Westminster Hall and Middle Temple Hall (Plate I. figs. 24 and 25). The “hammer beam” projects from the top of the Wall and is bracketed from a corbel projecting from the Wall some distance below. This form of roof has a style and dignity of its own, and gives greater height in the upper part of the building as well as being more ornamental and lighter in effect than tie-beam trusses, which have a rather heavy effect.
between the members are made in a, m, ,, {{{Hm@, ,, (, similar manner to those of the king-;', , m;“.'w -»»W§ ii""" mls; post principal with wrought-iron straps. I Milf, The purlins are two in number on each 3 44 'E slope, one supported at the top of each, W an “ queen, ” the other half-way between that . 7| I u -point and the wall-plate and resting upon vw 5; 1%. '| . W, -". the principal rafter at a point where i ' ; / strutted from the base of the queen- 53, ;, ,.-», . s. VU post. A stout straining beam connects -t, L f rjmjl the heads of the queens. In fig. 4, a /f', 1 lqll "WM, ~l and b are details at the foot of the g /g.f;' I l' nw queen-post, and c at the head. Trusses § /, ., of this type are suitable for spans up to 45 ft. In roofs of a larger span than fl I, " 'this and up to 60 ft. the tie-beam requires "“h / W" 0 to be upheld at more than two points, - and additional posts called “ princesses ” are introduced for this purpose. This also entails extra struts and purlins. FIG. 4.-a. Detail of queen-post truss at b. b. Vertical section through queen-post. c. Detail of queen-post truss at head; purlin and wrought-iron straps are
omitted for the sake of clearness. The Mansard roof (fig. 5) is a useful form of construction which obtains its name from Francois Mansard, a distinguished Munn' French architect who lived in the 17th century. This not kind of roof has been largely used, especially in France and other European countries, as well as in America in the old colonial days. It adapts itself well to some styles of architecture, but should be very carefully applied, since it
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FIG. 5.-Mansard Roof Truss: detail of outline as A; other outlines at B, C, D and E. is apt to appear ungainly in some situations. By the use of a Mansard roof extra rooms can be obtained at a small expense without adding an additional storey to the building proper. The outward thrust upon the supporting wallsis not so great as with an ordinary pitched roof, the load coming practically vertically upon them. There is no recognized rule for the proportion or pitch of a roof of this description, which should be designed to suit the particular building it is intended to cover. Fig. 5, A, B, C, D and E show various forms. A similar type of curb roof is often used having a flat lead- or zinc-covered top in place of the pitched slate- or tile-covered top of the ordinary Mansard roof. Composite roof trusses of wood and iron are frequently used for all classes of buildings, and have proved very satisfactory. They are built upon the same principles as wooden types of roof trusses. The struts-that is, those members subjected to compressional stress-are of wood, and iron bars or rods are used for the ties, which have to withstand tensile forces. When any shrinkage occurs to loosen the joints of the framing, as usually happens in large trusses, the tie-rods are tightened up by the bolts attached to them. Figs. 6, 7 and 8 are the sections and plan of a simple method of constructing the roof for an ordinary domestic building with plaster ceilings to the top rooms. It is a simple construction of the couple close order with the addition of a collar and struts and king-rod to every fourth rafter. Trimming is necessary -for openings and where portions of the structure, such as chimney stacks, cut into the roof. The trimming rafters are made an inch thicker than the others. The dragon tie is framed in connexion with the wall-plate at the hipped corners to take the thrust of the hip rafters. Steel and iron trusses in many cases follow the wood models already described. The struts and Z principal rafters are usually of T section, the - - Iron tensional members being rods or Hat bars., 00, s Flat plates and bolts or rivets are used to form the connexions between the members, and a means is provided in the tie-rod for tightening up the truss should any of the members “ give ” slightly under their load. Large trusses for very wide spans are specially designed for their work and may be of many different types of design. Big roofs on the tie-rod principle are now being discarded as being more liable to failure, through deterioration or defect, than those built on the girder principle in one form or another. Fig. 9 is a queen-rod roof principal for a span of 50 ft., and shows the sizes of the different members, a line diagram of the truss and large details of the joints. Fig. IO in a similar manner shows the roof at Cardiff railway station, which has a span of 4 3 ft. The steel roof covering the great hall at Olympia, London, is an example of a carefully designed and well-built roof which combines with strength an extremely light and elegant appearance. This is due to the fact that every member of the roof is adapted to meet the particular stresses found by calculation to affect it. By careful study of conditions the sections of steelwork used for the various members have been reduced
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FIGS. 6 and 7.-Roof for Domestic Building. V to the smallest size compatible with safety. 'In this way any unnecessary surplus of material is avoided, and so is the heavy, overwhelming effect noticeable in many roofs of large span. There is an entire absence of long Wide plates and webs; the various members are composed wholly of flat bars and angle irons riveted together, and plates are introduced only where required
to cover joints. Some notes on its size and construction An image should appear at this position in the text. If you are able to provide it, see Wikisource:Image guidelines and Help:Adding images for guidance. |
FIG. 8,
will be interesting. The dimensions of the great hall are 440 ft. long by 250 ft. wide, the height to the crown of the roof being about 100 ft. The main ribs of the roof have a clear span of 170 ft. and are placed 34 ft. apart. They are of box girder form and measure 7 ft. deep and 2 ft. wide. The gallery around the hall is 40 ft. Wide on three sides and 26 ft. wide on the remaining side. It is covered by a lean-to roof which abuts against the curved ribs on the north and south sides, and is attached to horizontal members of the screens on the east and west sides. The bricks walls of the building are not called upon to resist any portion of the thrust from the roof, as the side frames through which the gallery floor passes form a self-contained system of steelwork in which the thrust is ultimately conveyed to the ground. The screens which close the semicircular ends of the roof are of vertical ridge and furrow construction, as can be clearly seen in the illustrations, this form offering great resistance to wind pressure while at the same time requiring a minimum amount of material. Of the two illustrations, fig. II is a detailed cross-section showing fully the method of construction of the foot of the main rib and column, and the arrangement of the side frames above referred to is shown in fig. 12, which is a complete cross-section view, and will convey to the reader some idea of the vast size of the building and its general proportions. The following five roofs are examples of large span: Crystal Palace (104 ft.); Olympia, London (170 ft.); St Enoch station, Glasgow (198 ft.); Central station, 'Manchester (210 ft.); St Pancras station, London (240 ft.).
Domes may be framed up with wood rafters cut to shape. For small spans this construction is satisfactory, but when the dome is of considerable size it is often 'framed Domlcal
ln steel as being stronger and more rigid than wood, mom and therefore not exerting so great a thrust upon the supporting walls. The outer dome of St Paul's cathedral in London is of lead-covered wood, framed upon and supported by a conical structure of brickwork which is raised above the inner dome of brick. Concrete is a very suitable material for use in the construction of domes, and may be employed simply or with iron or steel reinforcement in the shape of wires, bars or perforated plates. One of the best modern examples of concrete vaulting and domical roofing without metal reinforcement occurs in the Roman Catholic cathedral at Westminster, a remarkable building designed by Mr ]. F. Bentley. A few details of the roofs will be interesting. The circle developed by the pendentives of the nave domes is 60 ft. in diameter. The thickness of the domes at the springing is 3 ft. gradually reduced to 13 in. at the crown; the curve of equilibrium is therefore well within the material. The domes were turned on closely boarded centring in a series of superimposed rings of concrete averaging 4 ft. in width. The concrete is not reinforced in any way. The independent external covering of the domes is formed of 3 in. artificial stone slabs cast to the curve. They rest on radiating ribs 5 in. deep of similar material fixed on the concrete and rebated to receive the slabs; thus an air space of 2 in. is left between the inner shell and the outer covering, the object being to render the temperature Iof the interior more uniform. At the springing and at the Roofing felt is an inexpensive fabric of animal or vege-Al, table fibre treated Felt ~ ' ' 5 "ir with asphalt to make it capable of resisting the <."" g weather. It is largely used ///' l Q as a roofing material for tem// / I | porary buildings. When ex/ ! 1 posed to the weather it should f // l l be treated with an application 2; B- l: of a compound of tar and / 'l; slaked lime well boiled and ljjqf; I "['121 ]S$. J/ I applied h0t, the surface being I; ' 7, sprinkled with sand before it /1 ' (g E becomes hard. Feltbisldalso /' ' ¥'~» . Q? } 2361 °§ 00§ e”'§§§ i'§§ du§ l0r'”§ ! i , heat under slating and other | roof-covering materials. In ¢ "°= i ' th'Sd°§ Se EE fs § °t1i§§ 'i§ iii; | san e s s pp 1. ' I | containing from 25 to 35 yds. / ~~ ', r - ' ' - C-I 30111. wide. The sheets should < ' "'~~., ~ A- -4- be laid with a lap of 2 in. at ~ , - the joints and secured to the " ' 5 ' | N boarding beneath by large-1 WT" { L headed clout-nails driven in IiF!1§ -lf' - - - - - 4/ “b§ %E%;';;1§ 'é'a5$¢.3 is Sugpraid 7'1" """"' /ft eit er ac or ga vanize . t /jg E 'i' |¢| is especially suited can f?'jZ;f/1 41;/. Err B for the roofs of out- mgaied 7 ' ', , . buildings and build-, mn ”' A 'ji 'ij iii' ings of a mor; or less B “' "' temporary c aracter. eing 1 to a large extent self-support-O DE3'-r'q““ HT C' ing, it requires a specially de-2; Q signed roof framework of light 5 1 OO '- construction. If, as is usually f' ', K . - the case, the sheets are lard W ' with the corrugations runninfg HTA- (Q with the slope of the 100, they can be fixed directly on I purlins spaced 5 ft. to IO ft. FIG. 9.-Queen-rod Roof Truss. apart according to the stiffness and length of the sheets. In crown the spaces between the ribs are left open for ventilation. The sanctuary dome differs in several respects from those of the nave. Unlike the latter, which seem to rest on the fiat roofing of the church, the dome of the sanctuary emerges gradually out of the substructure, the supporting walls on the north and south being kept down so as to give greater elegance to the eastern turrets. The apsidal termination of the choir in the east is covered in with a concrete vault surmounted by a timber roof, in striking contrast to the domes covering the other portions of the structure. Fig. 13 is a section through the nave showing how the domes are buttressed, fig. 14 is a section through the sanctuary dome, and IIPIE, DI¢<1(il2.¢¢II*'l Of 5 "FFT X li asf ili ' 'l '“""" I
so
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ex ' ep // f -1 .ai | 1-8. f H1 V5 9 / A yas; s i'&"@"° 'I *' "'°" ¢ l -L 1| " ” w- ngs. IS and 16 a section and part plan of the vaulting of the choir with / », ., -its wood span roof above the con- Crete vault. ' » Covering Materials for Roqfs.-There .6 ." are a large number of different roof- (-l'-'QF covering materials in common use, of, " / which short descriptions, giving the ¢f" '@;:¢~, ' '¢* principal characteristics, may be useful. - ”, M/Q, The nature of the material employed T /' QW" as the outer covering afiects the details i ' gf, / @"'Q¢', of roof construction very considerably. l l i ' 'rr 6. A light covering such as felt or corru- I gated iron can be safely laid u pon a much OF 5Fl0E5° ighter timber framing than is necessary tor a heavy covering of tiles or slates.
FIG. Io.-Roof at Cardiff Station. An image should appear at this position in the text. If you are able to provide it, see Wikisource:Image guidelines and Help:Adding images for guidance. |
Fig. 11.-Detail of Main Rib and Column, Olympia. pure air zinc coating of the galvanized sheets is durable for many years, but in large cities and manufacturing towns its life is short unless protected by painting. In such districts it has often been found that plain ungalvanized sheets well coated with paint will last longer than those galvanized, for the latter are attacked by corrosive influences through minute flaws in the zinc coating developed in the process of corrugation or resulting from some defect in the coating. The stock sizes of corrugated sheets vary from 5 ft. to 10 ft. long, and from 2 ft. to 2 ft. 9 in. wide with corrugations measuring 3 in. to 5 in. from centre to centre. For roofing purposes the sheets are supplied in several thicknesses ranging from No. I6 to No. 22 Standard Wire Gauge. No. 16 is for exceptionally strong work, No. 18 and No. 20 are used for good class work, and No. 22 for the roofs of temporary buildings. The sheets when laid should lap about 3 in. at their sides and from 3 in. to 6 in. at the ends. Riveting is the best method of connecting the sheets, although galvanized bolts, whic are not so satisfactory, are frequently employed. The Joints should be made along the raised corrugations to lessen the risk of leakage. Holes can be punched during the erection of the roof; their positions should first be determined by placing the sheets in position and marking the necessary point of fixing. Sheets are usually attached to
timber ramework with galvanized screws, or nails with domed
washers placed under their heads. Fixing to a steel framework is effected by means of galvanized hooked' bolts clipping the purlins passed through the sheet and held tight by nuts 4, Q. I -2. 94” 2 /'A g f /, af, =', ,¢ 7 9 ' 5 ., f Z 'ff' f ¢ rc”/if, 'V N)/QYQ, 1 .; . 4/<7 ,
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/ /» 22 fi; : '~ " in ~'.';:= - -.-F IG. 13.-Westminster Cathedral: section through nave. on the outside. 'Sheets corrugated in the Italian pattern have raised half-rounds every 15 in. or so, the portions between being flat. Such sheets have a very neat appearance and give a better effect in some positions than the ordinary corrugatlons-
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liable to easy breakage as are
slate, tile and glass. It is usuall
supplied in Hat sheets, although
it can also be had in the corrugated
form similar to corrugated
sheet-iron. When exposed,
a thin coating of oxide is
formed on the surface which
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FIG. 14.~ Westminster Cathedral:
diagonal section through
sanctuary dome.
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FIGS. 15 and 16.'W€StmiH5t€f
Cathedral: choir-vaulting.
protects the metal beneath from any further chan e, and obviates the necessity' of painting. In laying the sheets, tie use of solder and nails s ould be avoided entirely except for fixing clips and tacks which do not interfere with the free expansion and contraction of the sheets. The reason for this is that zinc expands freely, and sheets laid with soldered seams or fixed with nails are liable to buckle and probably break away owing to movements set up by changes of temperature. The usual sizes of zinc sheets are 7 ft. or 8 ft. long by 3 ft. wide. The thickness and weights of zinc are shown in the following table, which compares the Vieille Montagne Gauge with the Old Belgian Gauge and the British Imperial Standard Wire Gauge.
O.B.G. S.W.G.
V.M.G. approximately. approximately. Weight per sq. ft. IO 9 25 II? oz.
II 10 24 13;, ,
I2 II 23 15, ,
I3 12 22 17, ,
I4 13 2I 18%, ,
I5 14 20 2I%, ,
16 15 19 24%, ,
The best method of laying a zinc flat roof is with the aid of wood " rolls " of about 2 in.><2 in. in section, splayed at sides and spaced 2 lt. 8 in. apart and fixed to the roof boarding with zinc nails. Iron nails should not be used as this metal affects the zinc. The sheets of zinc are laid between the rolls with their sides bent up 1% in. or 2 in. against them, and held firmly in position by clips of zinc attached to the rolls. A cap of the same metal is then slipped over each roll and fastened down by tacks about 3 in. long soldered inside it so as to hook under the same clips that hold the sheet down. Drips of about 2% in. are made in the slope at intervals of 6 ft. or 7 ft.-that is, the length of a sheet-and special care must be taken at these points to keep the work waterproof. The lower sheet is bent up the face of the drip and under the projecting portion of the upper sheet, which is Enished with a roll edge to turn off the water. The end of the roll has a specially folded cap which also finishes with a curved or beaded water check, and this in conjunction with the saddle piece of the roll beneath forms a weather-proof joint (figs. I7 and 18). The fall between the drips is usually made about 1% in., T' S”
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18
Fics. 17 and 18.-Details of Zinc Flats. but where necessary it may be less, the least permissible fall being about I in 80. Felt laid beneath zinc has the effect of lengthening the life of the roof and should always be used, as the edges of the boarding upon which it is laid are, when the latter warps, apt to cut the sheets. It also forms a cushion protecting the zinc if there is traffic across the roof. V
Sheet-lead forms a much heavier roof covering than zinc, but it lasts a great eal longer and more easily withstands the attacks of impure air. Lead must be laid on a close boarding, for Lead its great ductility prevents it from spanning even the smallest spaces without bending and giving way. This characteristic of the metal, however, conduces largely to its usefulness, and enables it to be dressed and bossed into awkward corners without the necessity of jointing. The coefficient of expansion for lead is nearly as great as that for zinc and much h1gher than in the case of iron, and this fact requires precautions similar to those affecting zinc to be taken when laying the roofing. The manner of laying is with rolls and drips as in the case of zinc, the details of the work differing somewhat to suit the character of the material (see figs. 19, 20 and 21). Allowances must be made for expansion f'° . . 5 iff.
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F IGS. 19, zo and 21.-Details of Lead Flats. and contraction, and the use of nails and'solder avoided as far as possible. Contact with iron sets up corrosion in lead, and when nails are necessary they should be of copper; screws should be of brass. Lead is supplied in rolls of 25 to 35 ft. lon and 6 ft. to 7 ft. 6 in. wide. That in general use varies from one-fourteenth to one seventh of an inch in thickness. The weights most suitable for employment in roofing work are 7 or 8 lb per square foot for flats and gutters, 6 lb for ridges and hips, and 5 lb for flashing's. As a roof covering copper is lighter, stronger and more durable than either zinc or lead. It expands and contracts much less than these metals, and although not so strong as Wrought-iron co and steel it is much more durable. From a structural pper point of view these qualities enable it to be classed as the best available metal for roof covering, although its heat-conducting properties require it to be well insulated by layers of felt and other non-conducting material placed beneath the metal. On exposure to the air copper develops a feature of great beauty in the coating of green carbonate which forms upon its surface protecting it from further decomposition. Perhaps the chief disadvantage in the use of copper lies in its first cost, but against this must be set the almost imperishable nature of the metal and the fact that by reason of its light weight less substantial framework is required for its support. Copper roofing should be laid in a similar manner to zinc, with wood rolls at intervals of about 2 ft. 4 in. It is, however, often laid with welted seams. The general stock sizes of sheets are from 4 ft. to 5 ft. 3 in. long and 2 ft. to 3 ft. 6 in. wide. The thickness almost invariably used is known as 24 S.W.G. and weighs 16 oz. per square foot. Thinner metal would suffice, but owing to the increased cost of rolling very little would be gained by adopting the thinner gauges.
In the United States of America “ tin ” roofs are quite commonly useg. fSheets of vsifought-irojn coated eliitherhwifh tin or zinc are use o a size usua y 14 in. y 20 in., t oug t ey may be had double this size. Preparation for laying is made America by fixing an insulating foundation of somewhat stout paper U" mats or felt; this must be dry, else it is apt to spoil the impermeable covering laid upon it by causing it to rust. junctions between the sheets are made by welted seams in which the four edges of the sheets are turned over so as to lock together, thus forming one large sheet of tin covering the roof. In high-class work of la permanent nature the seams in addition are soldered, rosin only being used as a Hux. Each sheet also is secured to the roof with two or three tin cleats. The life of such roofs may be practically doubled by the application of a good coat of paint, which, however, adds considerably to the cost.
Slate is a strong and very impermeable material, and these qualities and the fact that it is easily split into thin plates suitable for laying, as well as its low cost, cause it to be by far the Slate most generally used of all materials for roof covering. Some of the best known varieties of slates, classed according to their colour, are as follows:-
Blue . . North Wales (Penrhyn, Festiniog, Dinorwic, &c.), France, Norway, Germany.
Blue-grey Cornwall (Delabole).
Grey . . North Wales (Penrhyn, Dinorwic). Purple . North Wales (Bangor, Penrhyn, Dinorwic), Newfoundland, Germany.
Green . South Wales (Precelly), Cumberland, Westmorland, Lancashire, Ireland, Newfoundland, Norway, United States and Germany.
Slates are cut to many different sizes varying in length from I0 in. to 36 in. and in width from 5 in. to 24 in. There are perhaps thirty or more recognized sizes, each distinguished by a different name. In common practice those generally used are “large ladies, " 16 in. by 8 in.; "courltesses, " 20 in. by IO in.; and “ duchesses, " 24 in. by 12 in. Generally speaking, the rule governing the use of the different sorts is that the steeper the pitch the smaller the slate, and vice versa. Buildings in very exposed positions naturally require steeply pitched roofs. Some of the technical terms used by the slater are as follows:- Bed, the under surface of a slab when laid. Buck, the upper surface of the slate. Gauge, the distance between the lines of nailing. This depends on the length of the slate and equals half the length of the slate after the lap plus an inch for the nail-hole has been deducted. This is for slates nailed near the top edge; for those fixed near the middle the gauge would be half an inch more, as no allowance for nail-holes is required.
Margin, the width of the exposed portion of each course which equals the width apart of the nailing. Head and tail, the top and bottom edges of the slate. Lap, the lap of the tail of one course of slates over the head of the second course below it. The lap is made from 2% in. to 4 in. (usually 3 in.), and for this distance there are three thicknesses of slate, namely, the tail of the top course, the middle of the next and the head of the third course.
Slates may be fixed by nailing at the head (see fig. 22) or at about the middle. The latter method is the stronger, as the levering effect of the wind cannot attain so great a strength. There is a small economy effected by centre nailing, as the margin is slightly larger and fewer slates are required to cover a given space; longer nails, however, are required, for as slates are laid at an angle with the pitch of the roof their centres cannot be made to approach so near ””* sh
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to the slating battens or boarding as the head, which lies close on the surface to which it is fixed. Another point worth noticing is that the nail-holes in the centre nailed slating are only covered by 3 in. of the tail (the amount of the “lap ”) of the course of slates above, and rain is very liable to be forced under by the wind and cause the wood battens or other woodwork to rot. Head-nailed slates, on the other hand, have their holes covered by two layers of slate, and are removed from exposure by the length of the gauge plus the lap, which in the case of “ Countess ” slating equals II in. “ Openslating " is an economical method of laying slates that is often adopted for the roofs of sheds and temporary buildings. The slates in the same course are not laid edge to edge as in closing slating, but at a distance of two or more inches apart. This forms a roof covering light in weight and inexpensive, which, although not strictly geather-proof, is sufficiently so for the buildings upon which it is use .
Slates are laid upon open battens fixed upon the rafters or upon close boarding or upon battens fixed upon boarding. The battens are % in. or I in. thick and 1% in. to 3 in. wide, and are spaced to suit the gauge of the slates. When close boarding is used it is often covered with in odorous asphalted felt. Nhile taking these precautions to make the roof sound and tight it should be borne in mind that slate is liable to decay if not ventilated, and to effect this the battens are sometimes fixed vertically, ridge ventilators introduced and air inlets arranged at the eaves. The bed of slates laid without provision for the admission of air will be found on removal after some time to have rotted so as to scale off and easily crumble into powder.
The nails used in slating are a very importantvitem, and the durability of the Work depends to a large extent upon them. They should have large fiat heads. The most satisfactory are those made of a composition of copper and zinc, but others of copper, zinc, galvanized iron and plain iron are used. Those of copper are most durable, but are soft and expensive. Zinc nails are soft and not very durable; they will last about twenty years. Iron nails even if galvanized are objectionable in permanent work, though they may be used for temporary roofs. When the plain-iron nails are employed they should be heated and plunged in boiled linseed oil. The pitch of a roof intended for slating should not incline less than 25° with the horizontal, while 30° is a safer angle to adopt. Tiles for roofing purposes are made from clay and burned in a manner similar to bricks. The clay from which they are made is, however, of a specially tenacious nature and prepared T” with great care so as to obtain a result as strong and as es nearly non-porous as possible. Tiles are obtainable in many different colours, and some of these have a very beautiful effect when fixed and improve with age. They comprise a large number of tints from yellowish red, red and brown to dark blue. As with bricks the quality depends to a large extent upon the burning; under burnt tiles are weak and porous, liable to early decay, while over burning, though improving the tiles as regards durability, will cause them to warp and will spoil colour. The usual shape is the “plain tile, ” but they are made in various other shapes with a view both to easier fixing and lighter weight, and to ornamental effect. There are also several patented forms on the market for which the makers claim special advantages. The ordinary tiles are slightly curved in shape to enable them to lie close one upon the other. Some of them have small “ nibs ” moulded on at the head by which they may be hung upon the battens and nailing avoided (see fig. 23). Nail-holes are provided, and upon
steep slopes it is advisable
to make useof
them. Others are
made without the
nibs, and are fixed ' »
either by nailing to
the battens or boarding or
hung by means
of oaken pegs wedged
in the holes to the battens,
the pegs in the
latter case acting in
the same way as the
above-mentioned nibs.
Plain tiles are of rectangular
form, the
standard dimensions
are 10% in. long by
6% in. wide. They are
usually % in. thick and
weigh about 2% lb each.
There are many forms of ornamental tiles, which are plain tiles having their tails cut to various shapes instead of moulded square. A number of patented forms of tiles also are on the market, some of which possess considerable merit. Pantiles are suitable for temporary and inferior buildings such as sheds and outhouses. They are laid on a different principle from plain tiles, merely overlapping each other at the edges, and this necessitates bedding in mortar and pointing inside and sometimes outside with mortar or cement. This pointin plays an important part in keeping the interior of the building free from the penetration of wind and water. Pantiles are generally made to measure 13% in. long by 9% in. wide, and weigh from 5 lb to 5% lb each. Moulded on at the head of each tile is a small projecting nib which serves for the purpose of hanging the tile to the lath or batten. They are laid with a lap of 3% in., 2% in. or 1% in., giving a gauge (and margin) of 10 in., II in. and 12 in.. respectively. The side lap is generally 1% in., leaving a width of 8 in. ex osed face. There are many other forms based upon the shape ofp the pantile, some of which are patented and claim to have advantages which the original form does not possess. Among such are “corrugated tiles, " of the ordinary shape or with angular flutes, and also the Italian pattern “ double roll tiles, " “ Foster's lock-wing tiles.” Poole's bonding roll tiles are a development of the Italian pattern tile.
Glass as a roof covering and the different methods of fixing it are dealt with in the article GLAZING.
There are many other materials used for roof covering besides those already described, many of them of considerable value. Some have in the past enjoyed considerable vogue, but have Ml practically died out of use owing to the development and 5 cheapening of other forms of roofing. Among these may 2 '::;:J';s be included thatch and wood shingles, the use of which in " these .days is practically reduced to special cases. Other, little used roofing materials are those of recent invention. some of 'shit h perhaps milf ty
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F IG. 23.-Detail of a Tiled Roof. have a great future before them. Plates of asbestos used as slates or tiles make a light, strong and fireproof covering. Large terracotta tiles or slabs are much used in the United States of America. A good form of flat roof is that in which concrete is used as a foundation for a waterproof layer of asphalt, laid to slight falls to allow the water to run off easily. This is the usual method adopted when a roof garden is required. Shingles or thatch look extremely well on a roof, but their use is debarred in a great many districts owing to the danger of fire. Galvanized iron tiles, zinc tiles and copper tiles may be employed on small areas with good effect. “ Willesden paper," often used as an insulating layer beneath slates and tiles, is also at times used as a roof covering. It is cardboard chemically treated to render it tough, waterproof and fire-resisting.
The weights of some of the various materials used in the construction and covering of roofs are given in the following table. The weights which are approximate are for a square foot of Weight. roofing. The roof trusses are taken to be spaced 10 ft. apart and include the necessary purlins.
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King-post wood truss 20 ft. to 30 ft. span . . 2 to 2% lb Queen-post, , 30 ft. to 50 ft. . . . 3 to 3%, , Wood rafters ...... . 2%, ,
Ceiling joists and ceiling . . . II, ,
%-in. boarding for roof covering . . 2%, ,
1-in., ,, , .... . 3%, ,
1%-in., ,, , ...., 4%, ,
2%-in. XI in. slate battens for 8%-in. gauge . 1, ,, Felt ......... . =}, ,
Thatch ........ 6%, ,
Slates (ordinary laid with 3-in. lap) . 9, , Tiles, plain Hat ........ 18, ,
Pantiles .......... II, ,
Zinc 12 to 16 gauge laid complete including rolls 1% to 1%, , Copper 25 to 19 gauge laid complete including rolls 1% to 2% Lead weighing 6 Ib per square foot laid complete including rolls ........ 6%
Corrugated iron 20 S.W. gauge ..... 2
Wind pressure is usually calculated at 22 to 25 lb on a roof with pitch of 30°, and 27 to 30 lb on a roof of 45° pitch. From these particulars it is easy to calculate the weight of a square (IO0 superficial ft.) of roofing material, this being the usual standard of measurement for many roofing materials.
The London Building Act of 1894 and its amendments set forth
with regard to roofs erected in the London district
Regula-
tions. that every
structure on a roof is to be covered wit slate, tile, metal
or other incombustible material, except wooden cornices
ms' and barge boards to dormers not exceeding 12 in. in depth,
and doors and windows and their frames. Every dwelling-house
or factory above 30 ft. in height and having a parapet must have
means of access to the roof. The pitch of the roofs of warehouse
buildings must not exceed 47°, and those of other buildings must
not exceed 75°, but towers, turrets and spires are exce ted. In
domestic buildings not more than two storeys are to be formed in
the roof, and if the floor is more than 60 ft. above the street level
fireproof materials must be used throughout and a sufficient means
of escape provided. The building by-laws of the municipality of
Johannesburg contain several clauses affecting the designing of
roofs and their method of construction. In the designing of buildings
roof-slopes must be within a line drawn and produced from the
ground level at the opposite side of the street to the top of the eaves,
gutter or parapet. No roof in the municipal fire limit may be
constructed of thatch, reed or other inflammable material. Without
the fire area they may be so constructed if the building stands
at least 20 ft. from the boundary of its site. Roofs having a pitch
of less than 22%° must be constructed to bear safely a load of at least
28 lb per square foot of surface. Roofs of steeper pitch must be
able to support a live load of 21 lb per square foot. The framing
of Mansard or other roofs of more than 60° pitch on a building
exceeding 45 ft. high must be constructed of approved fireproof
material at least 2 in. thick. N0 roofs exce t those of towers,
turrets or spires shall exceed 70° pitch for a R/Iansard or 60° for
an ordinary roof. Every fireproof roof, in addition to a door or
scuttle for access from below, must have a skylight or skylights with
metallic framing, having an area equal to at least one-sixtieth the
area of the roof. Skylights placed over rooms or areas to which
the public have access must be protected by wire netting below or
be glazed with wire-wove glass.
The Building and Health Laws and Regulations and Amendments of 1905 affecting the city of New York are based, so far as the construction of roofs goes, upon the same lines as those of London, the principal exceptions bein that they give very full working details, under part 2, as to the strengths of materials required to be used and the wind pressure to be provided against. In part I7 they provide that where a building exceeds three storeys or 40 ft. in height and the roof has a pitch of over 60°, it shall be constructed of iron rafters and be lathed with iron or steel on the inside and plastered or be filled in with fireproof material not less than 3 in. thick and covered with metal, slate or tile. The rovision as to access to roof and fire escapes therefrom adopted by the London County Council in 1907 under the London Building Act Amendment Act 1905 were in operation in New York in 1899.
Literature.—The principal reference books on this subject are the following:—Thomas Tredgold, Elementary Principles of Carpentry; J. Newland, Carpenter and Joiner's Assistant; G. L. Sutcliffe, The Modern Carpenter, Joiner and Cabinet Maker; J. Griffiths, Trusses in Wood and Iron; F. Bond, Gothic Architecture; J. Gwilt, Encyclopaedia of Architecture; F. E. Kidder, Trussed Roofs and Roof Trusses; J. Brandon, Analysis of Gothic Architecture; A. Pugin, Ornamental Gables; M. Emy, L'Art de la charpenterie; Viollet le Duc, Dictionnaire; J. K. Colling, Details of Gothic Architecture. (J. Bt.)