Fig. 3258Fig. 3258.
Fig. 3258.
Fig. 3258represents a chain riveted joint, having the same thickness of plate, rivet diameter and pitch as the zigzag riveted joint inFig. 3257, and it will be seen that the plate sections at a and ataare the same in the two figures, and as there are four half rivets, which are equal to two rivets, in one pitch, therefore the strength of the two joints is equal.
Each joint can be as efficiently caulked as the other, as the rivet spacing is the same and the edge of the plate is the same distance from the rivets in both cases.
The pitch of the rivets is obtained by the same rule as for zigzag riveted joints, and all we have now to consider is the distance apart of the two rows of rivets or distancevin theFig. 3258, and for this there are two rules, the first being that it shall not be less than twice the diameter of the rivet, which would leave a dimension athin the figure equal to the diameter of the rivet. The second rule is that a better proportion than the above is to multiply the diameter of the rivet by 3. This makes the dimension athequal to twice the rivet diameter.
When the joints have double buttstraps, the rivets may be spaced as wide as the necessity for tight caulking will admit, because, on account of the rivets being in double shear, the rivet percentage exceeds the plate percentage.
The allowance for the rivets being in double shear is 75 per cent., or in other words, a rivet in double shear is allowed 1.75 times the area of the same size rivet in single shear.
The simplest form of horizontal boiler is the plain cylinder boiler, an example of which is given inFig. 3259, and which is largely used in iron works and coal mines.
Largeimage(106 kB).Fig. 3259Fig. 3259.
Fig. 3259.
Boilers of this class are easily cleaned, because the whole interior can be readily got at to clean.
As the bottom of this boiler gets thinned from wear, the boiler is turned upside down, thus prolonging its life.
Fig. 3260Fig. 3260.
Fig. 3260.
Fig. 3260represents an internally fired flue boiler, known as the Cornish or Lancashire boiler. The furnace is at one end of the flues, the fire passing through them to the chimney. There is here obviously more heating surface than in the plain cylinder boiler, but somewhat less facility for cleaning.
The Galloway boiler is of this class, but has vertical water tubes placed at intervals in the flues. These water tubes are wider at the top than at the bottom. They serve to break up the body of heat that passes through the flues, and increase the heating surface while extracting more of the heat and promoting the circulation of the water in the boiler.
A water tube is one in which the water is inside and the fire outside, as distinguished from a fire tube, in which the fire passes through the tube and the water is outside. A water tube is stronger than a fire tube, because the former is subject to bursting pressure and the latter to collapsing pressure.
Vertical boilers are internally fired, and in the ordinary forms have no return tubes or flues, examples of those used for small stationary engines being given as follows.
Fig. 3261Fig. 3261.
Fig. 3261.
Fig. 3261represents an ordinary form with vertical tubes. The upper ends of the tubes here pass through the steam space—a condition that under the moderate pressures and firing that this class of boiler is subjected to is of less importance than it is in boilers having higher chimneys and therefore a more rapid draught, and using higher pressures of steam. Furthermore, the small diameters and lengths or heights in which these boilers are made give them ample strength with shells and tubes of less thickness, while the condition of tube ends with steam on one side and fire on the other is permissible without the injurious effects that ensue under rapid combustion and high pressures.
The crown sheet of the fire boxes or furnaces of this class of boiler is very effective heating surface, first, because of the great depth(and therefore weight) of water resting upon it insuring constant contact between the water and the plate, while there is no danger of the crown sheet burning from shortness of water.
Fig. 3262Fig. 3262.
Fig. 3262.
A similar boiler, but with the upper ends of the tubes below the water level, is shown inFig. 3262.
From the small diameters of these boilers, the flat surfaces are not stayed except to the extent that the holding power of the tubes serves that end.
Fig. 3263Fig. 3263.
Fig. 3263.
Fig. 3264Fig. 3264.
Fig. 3264.
A return flue vertical boiler is shown inFigs. 3263and3264. The whole of the surfaces having contact with the fire also have contact with the water, and the height of the crown sheet removes it from the intense heat of the fire. It is stayed to the top of the boiler. The fire box or combustion chamber being taper increases the effectiveness of its sides as heating surface, since the heat in its vertical passage impinges against it.
The products of combustion pass from the top of the combustion chamber through short horizontal flues, which enter an annular space surrounding the lower section of the boiler, and from this space vertical flues pass to a corresponding space at the bottom of the boiler.
The passage of the steam generated at the sides of the combustion chamber is facilitated by the taper of the chamber, which gives increased room for the steam as it gathers in ascending.
Vertical boilers for high pressures, as from 60 to 120 lbs. per inch, are represented in the figures from 3265 to 3269.
In boilers of this class, a majority contain water tubes, which, when properly arranged, promote rapid evaporation and circulation.
Fig. 3265Fig. 3265.
Fig. 3265.
A boiler withFieldtubes is shown inFig. 3265. It consists of an outer shell and a cylindrical fire box, from the crown sheet of which a number of Field tubes are suspended in the fire box or combustion chamber.
Fig. 3266Fig. 3266.
Fig. 3266.
Fig. 3266is a sectional view of a Field tube, the construction being as follows:
The outer tube, which is expanded into the tube plate, is enclosed at its lower end, and has at its upper end in the water space of the boiler a perforated mouth piece, from which is suspended an inner tube that extends nearly to the bottom of the outer tube.
As the outer tube is bathed in the fire, steam is generated very rapidly, and a thorough and rapid circulation is kept up, the water passing down the inner and up the outer tubes, as denoted by the arrows.
The outer tube is spread out at the upper end to a slight cone, so that it cannot be forced out of the tube sheet by the pressure, and as it hangs free, there is no liability for it to loosen or get leaky from expansion and contraction.
From the great amount of heating surface obtained with these tubes, the fire box may be kept at a minimum diameter for the duty, while still leaving a wide space for the water leg, which facilitates the circulation.
The damper, which is suspended in the uptake, spreads the fire sideways.
Fig. 3267Fig. 3267.
Fig. 3267.
Fig. 3267represents the arrangement of Field tubes in a boiler.
A boiler of this form may for a given capacity be made lighter and smaller than in any other of the ordinary forms, while the rapid circulation acts to keep the tubes clean.
The inner tubes may be thin, because they are under pressure both inside and out, while the outer tubes may be thin, because they are under a bursting strain, whereas a fire tube is under collapsing pressure.
Fig. 3268Fig. 3268.
Fig. 3268.
A design of high rate boilers, in which the uptake does not come into contact with the water, and water tubes are employed, is shown inFig. 3268. In the fire box is an inclined tube which promotes the circulation, and is very effective heating surface, and in the combustion chamber are a number of vertical water tubes.
Two manholes give access for cleaning purposes.
Fig. 3269Fig. 3269.
Fig. 3269.
The efficiency of the heating surface in this class of boiler is increased from the fact that, as the heat does not pass direct through the boiler, it impinges against the surface. InFig. 3269, for example, the exit from the spherical fire box is on one side of the boiler, and the uptake on the other, the heat passing from the fire box into a combustion chamber, and thence through the horizontal fire tubes to the uptake.
Fig. 3270Fig. 3270.
Fig. 3270.
The crown sheet is here stayed by gusset stays, but if made spherical, as inFig. 3270, the stays may be omitted.
Largeimage(106 kB).Fig. 3272Fig. 3272.
Largeimage(106 kB).
Fig. 3272.
Largeimage(134 kB).Fig. 3273Fig. 3273.
Largeimage(134 kB).
Fig. 3273.
Figs. 3271,3272, and3273illustrate a 60-inch horizontal return tubular boiler constructed by the Hartford Steam Boiler Inspection and Insurance Company. This class of boiler has found much favor in the United States. It is an externally fired, return tube boiler, the fire passing beneath the boiler and returning throughthe tubes to the front end of the boiler, whence it passes through the drum to the chimney.
The boiler is supported on the bracketsb,b′, the front one,b, resting on an iron plate imbedded in the brickwork, and the back ones on rollers which rest on the platesp′imbedded in the brickwork. This allows the boiler to expandand contract endways under variations of temperature without racking the brickwork.
a,a, etc., are for holding the brickwork together. The blow-off pipecis for emptying or blowing down the boiler. The feed-pipefenters the front end of the boiler, passes along it, and then crosses over. A pipehfrom the steam space of the boiler supplies steam to the steam gaugeg, and to the upper end of the gauge glass, which is on the castingk. The lower end of the gauge glass receives water from a pipe which passes into the water space of the boiler; atjare the three gauge cocks for testing the height of the water in the boiler.
The manhole affords ingress into the boiler for inspecting and for scaling or cleaning it, the nozzles being for a safety valve. Ateis a hand-hole for washing out and cleaning the boiler.pis a damper in the fire door for admitting air above the fire bars, andris a damper for regulating the draught.
In the brick walls that support the boiler there are air spaces to prevent the conduction of the heat through and prevent cracking of the brickwork. The tubes are arranged in vertical and horizontal rows and are equally spaced throughout.
Fig. 3274Fig. 3274.
Fig. 3274.
Fig. 3275Fig. 3275.
Fig. 3275.
Fig. 3274represents the front end, andFig. 3275a longitudinal sectional view of the front end of a boiler of this class. In this case, however, the pipes for the water gauge pass direct into the boiler.
Fig. 3276Fig. 3276.
Fig. 3276.
In some practice the tubes are arranged as inFig. 3276, being wider pitched or spaced in the middle of the boiler to increase the circulation of the water in the boiler.
Fig. 3277Fig. 3277.
Fig. 3277.
Another arrangement is shown inFig. 3277, the tubes beingstaggeredor arranged zigzag. This permits of the employment of a greater number of tubes, but does not afford such free circulation of the water.
Fig. 3278Fig. 3278.
Fig. 3278.
Fig. 3278represents an arrangement where the tubes are in rows both vertically and horizontally.
Fig. 3279Fig. 3279.
Fig. 3279.
Fig. 3279represents a boiler by the Erie Iron Works, the details of the setting being as follows:
Fig. 3280-3281Fig. 3280.Fig. 3281.
Fig. 3280.Fig. 3281.
Fig. 3280is an end view of the setting with the brickwork in section.
Fig. 3281side view of the boiler and setting.
Fig. 3282Fig. 3282.
Fig. 3282.
Fig. 3283Fig. 3283.
Fig. 3283.
Fig. 3282a front end view of the boiler, andFig. 3283a ground plan of the brickwork. When the front plate of the boiler setting extends above the middle of the boiler, as inFig. 3279, it is said to have a “full arch front.” Whereas when this plate or casting extends to the middle only of the boiler, it is said to have a half arch front.
Fig. 3284-3287Figs. 3284, 3285, 3286, 3287.
Figs. 3284, 3285, 3286, 3287.
Figs. 3284,3285,3286, and3287show the setting for a half arch front boiler, the dimensions of the settings of both these boilers being given in the following tables:
[56]“Many tests have been undertaken to ascertain the evaporative power of different classes of boilers in actual work; but few of these are of any value, owing to the unreliable means usually employed to measure the quantity of water evaporated. The easiest method, and consequently the one most frequently adopted, is to measure the quantity by the difference of its height in the water-gauge glass at the beginning and end of the trial, and also at intermediate stages. This method is very rude and uncertain, since there can be little doubt that in many boilers at work the surface of the water is not level, but is usually higher over the furnace, or where the greatest ebullition occurs. The difference in height at any moment will greatly depend upon the intensity of the ebullition, which is ever varying during the intervals between firing. With mechanical firing the difference of height is probably reduced to a minimum.