Toy-Making at Home - Part 6
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Part 6

First of all make a number of little cardboard cubes, having sides varying from 3/4 in. to 3 in. Draw each one out on cardboard (Fig. 75); cut it out; and bind up with gummed tape--leaving one side ungummed. On one pan of the balance put this thing, and on the other pan put a proper weight (say 1/2 oz). Now pour in sand into the little cube until it exactly balances the correct weight. When it does, wet the binding, and stick down the remaining side. Finally print the correct weight on one face of the cube.

[Ill.u.s.tration: FIG. 75.]

In similar fashion you can proceed to make all the different weights that you are likely to require, from 1/2 oz. upwards. While not very substantial, these little weights will last quite a long time, if they are handled with care.

Engines of all sorts are always fascinating to boys and girls, and later on we shall describe some excellent ones. At this point we wish to describe what is possibly one of the simplest forms of engine known, and certainly one of the earliest. It is the engine driven by a f.l.a.n.g.ed wheel, which itself is made to turn by the weight of something falling on the f.l.a.n.g.es. The commonest form of this wheel is the water wheel, where the weight of the water falling on the wheel causes the revolution.

As water is generally a "messy" thing to operate with, especially on such a contrivance as this, we have subst.i.tuted something else.

For the working of very light toys, sand provides an alternative motive power. If a f.l.a.n.g.ed wheel be made after the fashion of a water wheel, and a steady stream of sand allowed to descend on to the f.l.a.n.g.es, then the wheel will rotate as long as the supply of sand lasts, and the power may be transmitted by pulley wheels for the working of some simple mechanism.

Fig. 76 shows

_A Sand-power Engine._--The large driving wheel consists of two circles of thick cardboard, each about 6 in. across, firmly glued together.

These two circles are bevelled, and fixed facing inwards, so that a groove is left in which the power band can run.

[Ill.u.s.tration: FIG. 76.]

Through the centre of the driving wheel thus fashioned a piece of dowelling or old lead pencil is fixed, projecting 1/4 in. on one side, and about 1-1/2 in. on the other. Nails are driven in the two ends of this axle, and the wheel is suspended between supports, glued and screwed firmly to a base board.

The f.l.a.n.g.ed sand wheel is next constructed. For this, four oblong pieces of cardboard, 1-1/4 in. wide and about 2 in. long, are cut out. A line is scratched along each of these about 1/2 in. from the end, and the cardboard bent so as to form a scoop to hold the sand for an instant.

These four f.l.a.n.g.es are then glued to the axle, and the side of the driving wheel. If the sand wheel so made is not sufficiently firm, then another small cardboard circle can be glued to the f.l.a.n.g.es, on the side remote from the driving wheel: this will strengthen the wheel and in no way interfere with the running.

All that is necessary now is to erect some sort of sand supply: for this a large canister will do. A tiny hole must be punched in the bottom of the tin, and a revolving trap made with another piece of tin. This is simple enough: all you need to do is cut a piece of tin about 3/4 in.

long and 1/2 in. wide, and punch a hole in one end. This pierced tin should then be placed so that the unbroken end of the slip covers the supply hole. A forked rivet should then be pa.s.sed through the hole in the slip and through the bottom of the canister and fixed in place (Fig.

77); the trap can then be made to revolve, and the sand supply started or stopped at will. The canister should be placed above the wheel so that a thin stream falls on the f.l.a.n.g.es and turns the wheel.

[Ill.u.s.tration: FIG. 77.]

If a string be now pa.s.sed round the outside edge of the driving wheel, the mechanism can be harnessed to any toy and the motive power supplied.

For instance, the contrivance can be erected on a flat hull similar to that shown in Fig. 83, page 70; and the power band, pa.s.sing through a hole in the centre of the hull, can be connected with the propeller by means of a rod (in place of the elastic). The resultant machine, though not highly efficient, is yet quite attractive.

Another material from which some delightful toys can be contrived is "tin," or, as it is more correctly called, "tinned iron." This is the stuff cocoa tins and mustard tins and many other articles are made of.

Perhaps the simplest toy we can commence with is

_A Rotating Snake._--For this secure a clean flat piece of thin tin--the piece which the little patent cutter removes from the top of a round cigarette tin will do admirably--and, using a soft lead pencil, draw on it a spiral snake, such as is shown in Fig. 78. Now cut along the lines with a stout pair of scissors, or else with a sharp-pointed knife. Pull out the resultant spiral till it is stretched as in Fig. 79, and mount it by means of the tail on an upright piece of pointed stout wire. The serpent will rotate on this for a considerable time.

[Ill.u.s.tration: FIG. 78.]

[Ill.u.s.tration: FIG. 79.]

If you are good at bent-wire work, you will be able to make a wire stand by which to fix it on a lamp chimney or gas globe: it will then revolve continuously, and with considerable speed.

_A Tin-can Steam Roller._--This is a nice piece of metal work, and, when finished well, provides a proper little toy. To construct it you need several tins--a round tin, such as a cocoa tin, about 2 in. across and 4 in. long; an oblong tin, about 3-1/2 in. by 3 in. by 2 in., such as the larger-sized mustard tins; a round cigarette tin, about 2-1/2 in. across and 3-1/4 in. deep; two equal-sized tin lids from canisters, each about 4 in. across; and a cotton reel. These, the main items, when put together, yield a model similar to that shown in Fig. 80.

[Ill.u.s.tration: FIG. 80.]

The fixing is quite a simple affair. With a pair of metal shears (or strong scissors) you cut away a portion of the top of the cocoa tin, so as to leave three tongues. Then on the side of the oblong mustard tin you mark three lines to correspond with the three tongues, and cut them through so as to form three slots into which the tongues may fit. Now, if the tongues be bent outwards or inwards, then the two tins will hold firmly together, and give the boiler and cab of the machine (Fig. 81).

Before bending these, however, it is necessary to bore a hole in the under side of the boiler for the fixing of the front roller. This is attached to the boiler by means of a narrow strip of tin bent twice at right angles, and kept in place by means of a forked bra.s.s rivet or a strong bra.s.s paper fastener so that it will revolve freely. This narrow strip of tin just fits over the cigarette tin--a piece of knitting needle being used as axle, pa.s.sing through holes bored in the centre of the bottom and lid of the tin, and through the ends of the slip.

For the larger rear wheels the lids of two canisters can be used, or, if something is required giving a more definite impression of solidity, two flat boot-polish tins can be subst.i.tuted. Another piece of knitting needle pa.s.ses through the centre of these, and through holes in the sides of the cab, and so acts as axle. This is kept in place by means of dabs of sealing wax.

For the stack you can use a long thin cotton reel, or, better still, you can fix on another small tin by the method shown in Fig. 81.

[Ill.u.s.tration: FIG. 81.]

The turning of the front wheel can be regulated by means of two strings pa.s.sing from the two right-angle strips through a hole into the cab. If you can fix the strings to a piece of wood as shown in Fig. 82, you will be able to steer properly. A hole in the bottom of the cab, and a piece of wood stretched tightly across the top, should enable you to set up the steering apparatus.

[Ill.u.s.tration: FIG. 82.]

_A Working Motor Boat._--To construct a motor boat that will travel a considerable distance is not really a difficult matter. All that is necessary is a piece of board for a hull, a wood or metal propeller, and a yard or two of strong elastic: these, carefully adjusted, will do all that is necessary.

For the hull, a piece of 5/8 in. or 3/4 in. board, about 18 in. long will do. This can be cut to the boat shape by means of a pocket knife or a spokeshave, and finished off with gla.s.s-paper. It should be sharp-pointed at the bows, about 3 in. to 4 in. at the centre, tapering down to a width of 2 in. at the stern. In the centre of the hull nail a block of wood, and to it glue two funnels (Fig. 83). For these, the odd lengths cut off from bamboo curtain poles will do admirably; or, if these be not obtainable, a couple of incandescent-mantle cases will suffice.

[Ill.u.s.tration: FIG. 83.]

The adjustment of the motive power is the difficult task. First, you will need to purchase a couple of yards of suitable elastic: this is sold at most large toy shops, and costs usually a penny a yard. To fix this into place beneath the hull you will need to construct two metal supports. If you can get an old tin box made from metal sufficiently stout, that will do; if not, then you had better buy a piece of sheet bra.s.s, No. 20 gauge: 6 in. by 4 in. will be ample. Draw out these supports as shown in Figs. 84 and 85, and bend them into shape as in Figs. 86 and 87--one for the bow and one for the stern. Screw on the bow one about 1-1/2 in. or 2 in. from the point, and the stern one in the middle of the end.

[Ill.u.s.tration: FIG. 84.]

[Ill.u.s.tration: FIG. 85.]

[Ill.u.s.tration: FIG. 86.]

[Ill.u.s.tration: FIG. 87.]

Now into the bow support fix a loop of stout wire to hold the rubber strands, making it sufficiently large to rest against the sides and so prevent turning. At the stern support adjust the propeller bearings. On the care with which these are adjusted depends largely the success of the model. Take a piece of wire (1/16-inch bra.s.s is best) and bend it as in Fig. 88, introducing a hard smooth gla.s.s bead. This "bead" runs more freely against the metal, and so facilitates the working. Now stretch the elastic between the two loops, arranging it so that there are six or eight strands. To work the model, turn the propeller round and round till the strands of elastic are very tightly twisted, place on the surface of the water, and then release the propeller. Fig. 83 shows the completed model.

[Ill.u.s.tration: FIG. 88.]

All boys love a toy that "goes"; and so a short account showing how to make

_A Steamboat_ that will actually travel on the water will be very welcome. Our boat, which in reality is not a "steam" boat, inasmuch as no steam is generated, is very simple in its construction and possesses neither wheels nor pistons nor cranks, nor any of the things that one a.s.sociates with a steamer.

The whole motive power is supplied by one or two candle ends, and a bent piece of strong metal tubing. This last can scarcely be called either "odds" or "ends"; and you will probably have to purchase it at a shop selling model-engine fittings, but a few pence will cover the cost. You must get an eight-inch piece of solid drawn copper or bra.s.s tubing, with an inside diameter of 1/8 in. (_N.B._--Do not let the man sell you soldered tubing, for it will certainly crack when you bend it.)

The next operation is the most difficult: it is bending the tube to the shape shown in Fig. 89. This must be done very gently, otherwise you will crack or dent it. The loop shown should have a diameter of about 5/8 to 3/4 of an inch.

[Ill.u.s.tration: FIG. 89.]

The actual boat itself can be of any shape. If you happen to have an old wooden hull suitable to the purpose, use that; if not, then a flat hull similar to that described on page 70 will do quite well. Fix the bent tubing at the stern of the boat, so that the two open ends project over the edge and dip beneath the surface of the water (Fig. 90). Two pieces of wire bent as in Fig. 90_a_ will hold the tubing in place.