FROM THE EARTH TO THE MOON & Its Sequel, Around the Moon. Жюль Верн

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FROM THE EARTH TO THE MOON & Its Sequel, Around the Moon - Жюль Верн


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quadruple that length, and to construct a cannon 900 feet long.”

      The general and the major made some objections, but, nevertheless, this proposition, strongly supported by the secretary, was definitely adopted.

      “Now,” said Elphinstone, “what thickness must we give its sides?”

      “A thickness of six feet,” answered Barbicane.

      “You do not think of raising such a mass upon a gun-carriage?” asked the major.

      “That would be superb, however! said J.T. Maston.

      “But impracticable,” answered Barbicane. “No, I think of casting this engine in the ground itself, binding it up with wrought-iron hoops, and then surrounding it with a thick mass of stone and cement masonry. When it is cast it must be bored with great precision so as to prevent windage, so there will be no loss of gas, and all the expansive force of the powder will be employed in the propulsion.”

      “Hurrah! hurrah!” said Maston, “we have our cannon.”

      “Not yet,” answered Barbicane, calming his impatient friend with his hand.

      “Why not?”

      “Because we have not discussed its form. Shall it be a cannon, howitzer, or a mortar?”

      “A cannon,” replied Morgan.

      “A howitzer,” said the major.

      “A mortar,” exclaimed J.T. Maston.

      A fresh discussion was pending, each taking the part of his favourite weapon, when the president stopped it short.

      “My friends,” said he, “I will soon make you agree. Our Columbiad will be a mixture of all three. It will be a cannon, because the powder-magazine will have the same diameter as the chamber. It will be a howitzer, because it will hurl an obus. Lastly, it will be a mortar, because it will be pointed at an angle of 90°, and that without any chance of recoil; unalterably fixed to the ground, it will communicate to the projectile all the power of impulsion accumulated in its body.”

      “Adopted, adopted,” answered the members of the committee.

      “One question,” said Elphinstone, “and will this canobusomortar be rifled?”

      “No,” answered Barbicane. “No, we must have an enormous initial speed, and you know very well that a shot leaves a rifle less rapidly than a smooth-bore.”

      “True,” answered the major.

      “Well, we have it this time,” repeated J.T. Maston.

      “Not quite yet,” replied the president.

      “Why not?”

      “Because we do not yet know of what metal it will be made.”

      “Let us decide that without delay.”

      “I was going to propose it to you.”

      The four members of the committee each swallowed a dozen sandwiches, followed by a cup of tea, and the debate recommenced.

      “Our cannon,” said Barbicane, “must be possessed of great tenacity, great hardness; it must be infusible by heat, indissoluble, and inoxydable by the corrosive action of acids.”

      “There is no doubt about that,” answered the major, “and as we shall have to employ a considerable quantity of metal we shall not have much choice.”

      “Well, then,” said Morgan, “I propose for the fabrication of the Columbiad the best alloy hitherto known—that is to say, 100 parts of copper, 12 of tin, and 6 of brass.”

      “My friends,” answered the president, “I agree that this composition has given excellent results; but in bulk it would be too dear and very hard to work. I therefore think we must adopt an excellent material, but cheap, such as cast-iron. Is not that your opinion, major?”

      “Quite,” answered Elphinstone.

      “In fact,” resumed Barbicane, “cast-iron costs ten times less than bronze; it is easily melted, it is readily run into sand moulds, and is rapidly manipulated; it is, therefore, an economy of money and time. Besides, that material is excellent, and I remember that during the war at the siege of Atlanta cast-iron cannon fired a thousand shots each every twenty minutes without being damaged by it.”

      “Yet cast-iron is very brittle,” answered Morgan.

      “Yes, but it possesses resistance too. Besides, we shall not let it explode, I can answer for that.”

      “It is possible to explode and yet be honest,” replied J.T. Maston sententiously.

      “Evidently,” answered Barbicane. “I am, therefore, going to beg our worthy secretary to calculate the weight of a cast-iron cannon 900 feet long, with an inner diameter of nine feet, and sides six feet thick.”

      “At once,” answered J.T. Maston, and, as he had done the day before, he made his calculations with marvellous facility, and said at the end of a minute—

      “This cannon will weigh 68,040 tons.”

      “And how much will that cost at two cents a pound?”

      “Two million five hundred and ten thousand seven hundred and one dollars.”

      J.T. Maston, the major, and the general looked at Barbicane anxiously.

      “Well, gentlemen,” said the president, “I can only repeat what I said to you yesterday, don’t be uneasy; we shall not want for money.”

      Upon this assurance of its president the committee broke up, after having fixed a third meeting for the next evening.

      THE QUESTION OF POWDERS.

      Table of Contents

      The question of powder still remained to be settled. The public awaited this last decision with anxiety. The size of the projectile and length of the cannon being given, what would be the quantity of powder necessary to produce the impulsion? This terrible agent, of which, however, man has made himself master, was destined to play a part in unusual proportions.

      It is generally known and often asserted that gunpowder was invented in the fourteenth century by the monk Schwartz, who paid for his great discovery with his life. But it is nearly proved now that this story must be ranked among the legends of the Middle Ages. Gunpowder was invented by no one; it is a direct product of Greek fire, composed, like it, of sulphur and saltpetre; only since that epoch these mixtures; which were only dissolving, have been transformed into detonating mixtures.

      But if learned men know perfectly the false history of gunpowder, few people are aware of its mechanical power. Now this is necessary to be known in order to understand the importance of the question submitted to the committee.

      Thus a litre of gunpowder weighs about 2 lbs.; it produces, by burning, about 400 litres of gas; this gas, liberated, and under the action of a temperature of 2,400°, occupies the space of 4,000 litres. Therefore the volume of powder is to the volume of gas produced by its deflagration as 1 to 400. The frightful force of this gas, when it is compressed into a space 4,000 times too small, may be imagined.

      This is what the members of the committee knew perfectly when, the next day, they began their sitting. Major Elphinstone opened the debate.

      “My dear comrades,” said the distinguished chemist, “I am going to begin with some unexceptionable figures, which will serve as a basis for our calculation. The 24-lb. cannonball, of which the Hon. J.T. Maston spoke the day before yesterday, is driven out of the cannon by 16 lbs. of powder only.”

      “You are certain of your figures?”


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