Steam Locomotive Construction and Maintenance/Chapter IV

CHAPTER IV

FORGINGS, SPRINGS, ETC.

Forging and Smithing Departments.—Locomotive forgings include work done in three different departments, to which may be added a fourth, the spring shop. Strictly speaking, the forgings proper are large pieces such as crank and straight axles, connecting rods, etc., which are made under the steam hammers in the large forge. In many cases forged axles are purchased outside from the manufacturers.

A second department consists of the blacksmith’s shop, in which smaller parts of wrought iron or mild steel are made by welding. There is also the third or “stamping” department, in which a large number of parts, formerly made by the blacksmith, are now stamped to shape in dies under gravity or “drop” hammers.

All wrought iron and mild steel parts of a locomotive, such as axles, connecting and coupling rods, piston rods, the machinery or “motion,” and a large number of other details are made in one or other of these departments. The springs are made in the spring shop by the spring smiths, and their manufacture is an art requiring special knowledge. Frequently they are purchased outside.

Axles. As an example of a locomotive forging a simple straight axle may be taken to give an idea of the principles involved. Such axles are made from steel “blooms,” which may be described as long thick blocks of steel supplied from the steel works. An axle bloom is about 5 ft. long × 9½ ins. square, the corners being rounded or chamfered off. The end of the heated

Fig. 10.—Blocks for Forging Straight Axles.

bloom is placed under the steam hammer and hammered into a circular form. The next operation is to form the journal portion and the collar of the shape shown in Fig. 10. To this end special blocks or dies of steel are machined out to the shape of the forging required. The bottom die fits into the anvil of the steam hammer, the top one being held by the forgeman. The axle is placed on the bottom die, and the hammer brought down upon the back of the top die, and by gradually turning the axle round, it is brought to the required shape. The middle of the axle is circular and is simply hammered down to shape. After one end of the axle has been

finished, the other is treated similarly. As the axle has to be machined, about ¼ in. of metal is left all round for turning, and the proper length is tried over with a template.

This method of swaging or forming the shape in dies is characteristic of nearly all locomotive forgings, when any quantity has to be made. Naturally it does not pay to make expensive dies when only one or two similar forgings are required. In such cases the forgeman has to work out the shapes with such ordinary swages and tools as are usually to be found in a forge.

The most difficult forging, and the one requiring the greatest care is that for the crank axle.^[1] The ingot is heated in a large furnace, having at the same time a “porter” bar or staff welded to one end at p (Fig. 11a). The “porter” is a long taper bar, which serves for the handling of the work by the forgeman, and is supported by a crane chain. Frequently it is welded to the ingot whilst the latter is being made. The ingot is first hammered down under a heavy steam hammer to a rectangular shape with chamfered edges as shown in Fig. 11a. This slab will be about 24 or 25 ins. deep × 12 ins. wide, and nearly 6 ft. long, and weighs about 2¾ tons without the “porter.” Whilst still hot it is taken to a hot saw, close at hand, and four saw cuts are made as shown at a, which extend nearly half way through the depth. The part b₁ is then removed either by cutting with a hot saw along the dotted line, or by means of a special cutting tool, and then the remaining portion c (Fig. 11b) is roughly rounded in swage blocks

Fig. 11.—Stages in Forging a Crank Axle.

under the steam hammer. The portion d is also removed by means of special cutting tools, and the middle part e between the cranks is roughly swaged down to a circular form. To cut out the portion b₂ the forging is re-heated and the porter bar p is re-welded to the opposite end. After this operation is complete, the appearance of the axle is as in Fig. 11b.

As the two cranks have to be at right angles to each other, one of the two parts f₁f₂ has to be twisted through 90°. This is done by firmly holding the crank f₁ supposing this to be the one to remain in its original position, between the tup and the anvil of a steam hammer, and then by means of hydraulic or other pressure applied at the end of a very large spanner, to provide sufficient leverage, the other arm f₂ is gradually bent round at a right angle. Lastly the ends of the crank webs are rounded at g under the hammer, and the appearance of the axle is then as shown in Fig. 11c. The right angle must be tested with a square, and all the dimensions checked to gauges to see that enough material is left throughout to enable the machining to be done subsequently to proper finished sizes. The whole of the above operations require several heats, and the greatest care must be taken in this respect, so that no re-heating is done until after mechanical work, e.g., hammering, has been done on the axle, otherwise the internal physical structure of the steel will suffer injury. Finally all crank axles are re-heated and generally cooled in oil, the scientific considerations underlying “heat treatment” being, however, beyond the scope of this primer. Test pieces are taken from the parts machined off the webs of each axle, and subjected to rigorous tensile and cold bending tests. An oil treated crank axle should have an ultimate tensile strength of not less than 35 tons per sq. in. with an elongation of not less than 20 per cent, in a length of 2 ins.

There are other methods of making crank axles by building up the second crank web with slabs welded to the bloom in such a way that the twisting of this web through a right angle is avoided. In some foreign works the webs are swaged in dies in their proper positions at right angles.

Miscellaneous Forgings. Connecting and coupling rods are forged solid out of slabs of mild steel,

Fig. 12.—Buffer Forging

the middle portions being hammered down to a rectangular section, and the ends, which have to be of special shapes, being swaged

in blocks cut out to suit those shapes. The whole work is done under the steam hammer.

Buffer heads form a good example of forging in die blocks under a steam hammer. They are usually made of wrought iron scrap, piled and heated in the furnace and hammered into “blooms.” Each bloom is then re-heated and hammered in suitably shaped blocks into the form shown in Fig. 12a, with a shank about 2 ft. long having a ball about 7 in. in diameter at one end. The shank is then placed in other blocks of which a section is shown at B, for the steam hammer to flatten the ball and form the head of the buffer. The bottom of the three blocks is firmly secured to the anvil of the steam hammer. The middle block is loosely dropped into a recess machined in the bottom block, and has a cup shaped depression at the top to suit the shape of the buffer head when finished. The top block is secured by wedges to the tup of the steam hammer. The two bottom blocks are made with a central hole to take the shank of the buffer. After the buffer head has been hammered to shape the “fin” of metal round it is cut off, after which the finished piece appears as shown at C. The middle block being loose can be rotated by the forgeman during the hammering, by placing a bar in the recess a shown in the side. All such blocks are machined and fitted together, and the exact shape of the forging is cut out in them.

Hydraulic Forging. A considerable amount of forging is now done by hydraulic press, instead of under a steam hammer. In this case the white hot pieces are welded by squeezing them together under pressure, the process being done in blocks or dies as in the case of hammer forgings. At one large railway works some of the casings in which the buffer heads work are made in this way, more especially for wagons. Formerly these used to be of cast iron, but they are now much stronger forgings. Such a finished buffer casing is shown in Fig. 13, and the three portions from which it is forged in Fig. 14. These consist of a flat steel plate C, in which a hole is punched, a conical cylinder B which is bent round a vertical roll and has an open seam a, and a ring A having a diagonal seam which is welded. The ring A is pressed on to the cone B at a welding heat, and then the combination is again heated and pressed into the plate C. The whole of this work is done in suitably shaped dies, so that after the final weld the piece comes out as in Fig. 13.

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Fig. 13.—Forged Buffer Casing	Fig. 14.—Pieces for Forged Buffer Casing

The joint a is merely closed together and not welded. The whole of the work is done under a 100 ton hydraulic forging press with two rams horizontal and vertical. One ram holds the work and dies in place, and then the other ram is set in action and squeezes the parts together.

Blacksmith’s Shop. In this department the work consists principally in welding rods, bars, angles, etc., and in the manufacture of brake shafts and levers, hooks, links, couplings, etc. Although this shop is of great importance, it has of recent years lost much of its work because

Fig. 15.—Stamping Shop with Drop Hammers.
By Brett’s Patent Lifter, Co., Ltd. (Coventry).

important details of the motion work of locomotives are now made as solid stampings in the drop hammer department instead of being welded. All the smaller parts of the valve gear, etc., are now made as stampings without welds. Steel castings have also superseded much of the wrought iron work formerly done by the blacksmiths.

Stamping Shop. Stampings are made in dies under drop hammers. In these hammers the tup or weight is raised by ropes connected to a rotary steam cylinder placed at the top of the hammer girders, and falls by gravity on to the

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Fig. 16. Underhung Laminated Spring.

work, which is placed on the anvil. The pieces made under these hammers are generally much smaller than the forgings produced under steam hammers, and consist of various brackets, links, pistons, parts of valve motion, spring links and hangers, hooks, bell crank levers, hand wheels, spanners, etc. Drop hammer stampings are much cleaner and nearer to shape and size than blacksmiths’ forgings, and less work is required in machining and finishing them in the machine and fitters’ shops. Fig. 15 shows the stamping shop with drop hammers in a large locomotive works. A number of drop-forged pieces are shown in the foreground.

Spring Shop. In this department, the springs are made and tempered, the eyes or hooks being welded on to the top plates. Fig. 16 shows a locomotive spring. The plates are maintained in position by small projections or “nibs” on each plate which work in slots cut in the plate immediately below it. The plates have to be “set” to the required curvature, and are then tempered by oil treatment. Finally they are put together and held securely whilst the central hoop or “buckle” is shrunk on. The buckles are forged solid, and machined inside where they pass over the plates. A double eye to take the axlebox pin, is forged on for underhung springs.

1. An illustration of a crank axle is given in the primer on The Steam Railway Locomotive.