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Statement of Accounts of the Expedition on its Setting Out, 1893.
ОглавлениеIncome. | ||
Kroner | ore. | |
State Grant | 280,000 | 0 |
H.M. The King, and original private subscribers | 105,000 | 0 |
Private subscription of the Geographical Society | 12,781 | 23 |
National subscription | 2,287 | 23 |
Interest accrued | 9,729 | 78 |
Guaranteed by private individuals | 5,400 | 0 |
Deficit covered by A. Heiberg and A. Dick | 12,000 | 0 |
Ditto F. Nansen | 5,400 | 0 |
Geographical Society, London (£300) | … | |
H. Simon, Manchester (£100) | … | |
A Norwegian in Riga (1000 roubles) and others . | 9,278 | 62 |
Total | 444,339 | 361 |
Expenditure. | ||
Kroner | ore. | |
Wages account | 46,440 | 0 |
Life insurance premiums of married participators | 5,361 | 90 |
Instruments account | 12,978 | 68 |
Ship account | 271,927 | 8 |
Provisions account | 39,172 | 98 |
Expenses account | 10,612 | 38 |
Equipment account | 57,846 | 34 |
Total | 444,339 | 36 |
It will be evident from the plan above expounded that the most important point in the equipment of our expedition was the building of the ship that was to carry us through the dreaded ice regions. The construction of this vessel was accordingly carried out with greater care, probably, than has been devoted to any ship that has hitherto ploughed the Arctic waters. I found in the well-known shipbuilder, Colin Archer, a man who thoroughly understood the task I set him, and who concentrated all his skill, foresight, and rare thoroughness upon the work. We must gratefully recognize that the success of the expedition was in no small degree due to this man.
Colin Archer
If we turn our attention to the long list of former expeditions and to their equipments, it cannot but strike us that scarcely a single vessel had been built specially for the purpose—in fact, the majority of explorers have not even provided themselves with vessels which were originally intended for ice navigation. This is the more surprising when we remember the sums of money that have been lavished on the equipment of some of these expeditions. The fact is, they have generally been in such a hurry to set out that there has been no time to devote to a more careful equipment. In many cases, indeed, preparations were not begun until a few months before the expedition sailed. The present expedition, however, could not be equipped in so short a time, and if the voyage itself took three years, the preparations took no less time, while the scheme was conceived thrice three years earlier.
Plan after plan did Archer make of the projected ship; one model after another was prepared and abandoned.
Fresh improvements were constantly being suggested. The form were finally adhered to may seem to many people by no means beautiful; but that it is well adapted to the ends in view I think our expedition has fully proved. What was especially aimed at was, as mentioned on page 29, to give the ship such sides that it could readily be hoisted up during ice-pressure without being crushed between the floes. Greely, Nares, etc., etc., are certainly right in saying that this is nothing new. I relied here simply on the sad experiences of earlier expeditions. What, however, may be said to be new is the fact that we not only realized that the ship ought to have such a form, but that we gave it that form, as well as the necessary strength for resisting great ice-pressure, and that this was the guiding idea in the whole work of construction. Colin Archer is quite right in what he says in an article in the Norsk Tidsskrift for Sövæsen, 1892: “When one bears in mind what is, so to speak, the fundamental idea of Dr. Nansen’s plan in his North Pole Expedition … it will readily be seen that a ship which is to be built with exclusive regard to its suitability for this object must differ essentially from any other previously known vessel. …
“In the construction of the ship two points must be especially studied: (1) that the shape of the hull be such as to offer as small a vulnerable target as possible to the attacks of the ice; and (2) that it be built so solidly as to be able to withstand the greatest possible pressure from without in any direction whatsoever.”
And thus she was built, more attention being paid to making her a safe and warm stronghold while drifting in the ice than to endowing her with speed or good sailing qualities.
Designs for the “Fram”
Fig. 1. Longitudinal section.
Fig. 2. Plan.
Fig. 3. Transverse section amidships.
Fig. 4. Transverse section at the engine-room.
rb Rudder-well. sb Propeller-well. S Saloon. s Sofas in saloon. b Table in saloon. Svk Sverdrup’s cabin. Bk Blessing’s cabin. 4k Four-berth cabins. Hk Scott-Hansen’s cabin. nk Nansen’s cabin. c Way down to engine-room. R Engine-room. M Engine. kj Boiler. g Companions leading from saloon. K Cook’s galley. B Chart-room. h Work-room. dy Place for the dynamo. d Main-hatch. e Long boats. i Main-hold. l Under-hold. f Fore-hatch. n Fore-hold. o Under fore-hold. p Pawl-bit. 1 Foremast. 2 Mainmast. 3 Mizzenmast.
As above stated, our aim was to make the ship as small as possible. The reason of this was that a small ship is, of course, lighter than a large one, and can be made stronger in proportion to her weight. A small ship, too, is better adapted for navigation among the ice; it is easier to handle her in critical moments, and to find a safe berth for her between the packing ice-floes. I was of opinion that a vessel of 170 tons register would suffice, but the Fram is considerably larger, 402 tons gross and 307 tons net. It was also our aim to build a short vessel, which could thread her way easily among the floes, especially as great length would have been a source of weakness when ice-pressure set in. But in order that such a ship, which has, moreover, very sloping sides, shall possess the necessary carrying capacity, she must be broad; and her breadth is, in fact, about a third of her length. Another point of importance was to make the sides as smooth as possible, without projecting edges, while plane surfaces were as much as possible avoided in the neighborhood of the most vulnerable points, and the hull assumed a plump and rounded form. Bow, stern, and keel—all were rounded off so that the ice should not be able to get a grip of her anywhere. For this reason, too, the keel was sunk in the planking, so that barely three inches protruded, and its edges were rounded. The object was that “the whole craft should be able to slip like an eel out of the embraces of the ice.”
The hull was made pointed fore and aft, and somewhat resembles a pilot-boat, minus the keel and the sharp garboard strakes. Both ends were made specially strong. The stem consists of three stout oak beams, one inside the other, forming an aggregate thickness of 4 feet (1.25 m.) of solid oak; inside the stem are fitted solid breasthooks of oak and iron to bind the ship’s sides together, and from these breasthooks stays are placed against the pawl-bit. The bow is protected by an iron stem, and across it are fitted transverse bars which run some small distance backwards on either side, as is usual in sealers.
The stern is of a special and somewhat particular construction. On either side of the rudder and propeller posts—which are sided 24 inches (65 cm.)—is fitted a stout oak counter-timber following the curvature of the stern right up to the upper deck, and forming, so to speak, a double stern-post. The planking is carried outside these timbers, and the stern protected by heavy iron plates wrought outside the planking.
Between these two counter-timbers there is a well for the screw, and also one for the rudder, through which they can both be hoisted up on deck. It is usual in sealers to have the screw arranged in this way, so that it can easily be replaced by a spare screw should it be broken by the ice. But such an arrangement is not usual in the case of the rudder, and, while with our small crew, and with the help of the capstan, we could hoist the rudder on deck in a few minutes in case of any sudden ice-pressure or the like, I have known it take sealers with a crew of over 60 men several hours, or even a whole day, to ship a fresh rudder.
The stern is, on the whole, the Achilles’ heel of ships in the Polar Seas; here the ice can easily inflict great damage, for instance, by breaking the rudder. To guard against this danger, our rudder was placed so low down as not to be visible above water, so that if a floe should strike the vessel aft, it would break its force against the strong stern-part, and could hardly touch the rudder itself. As a matter of fact, notwithstanding the violent pressures we met with, we never suffered any injury in this respect.
Everything was of course done to make the sides of the ship as strong as possible. The frame timbers were of choice Italian oak that had originally been intended for the Norwegian navy, and had lain under cover at Horten for 30 years. They were all grown to shape, and 10–11 inches thick. The frames were built in two courses or tiers, closely wrought together, and connected by bolts, some of which were riveted. Over each joint flat iron bands were placed. The frames were about 21 inches (56 cm.) wide, and were placed close together, with only about an inch or an inch and a half between; and these interstices were filled with pitch and sawdust mixed, from the keel to a little distance above the water-line, in order to keep the ship moderately water-tight, even should the outer skin be chafed through.
The outside planking consists of three layers. The inner one is of oak, 3 inches thick, fastened with spikes and carefully calked; outside this another oak sheathing, 4 inches thick, fastened with through bolts and calked; and outside these comes the ice-skin of greenheart, which like the other planking runs right down to the keel. At the water-line it is 6 inches thick, gradually diminishing towards the bottom to 3 inches. It is fastened with nails and jagged bolts, and not with through bolts; so that if the ice had stripped off the whole of the ice sheathing the hull of the ship would not have suffered any great damage. The lining inside the frame timbers is of pitch-pine planks, some 4, some 8 inches thick; it was also carefully calked once or twice.
The total thickness of the ship’s sides is, therefore, from 24 to 28 inches of solid water-tight wood. It will readily be understood that such a ship’s side, with its rounded form, would of itself offer a very good resistance to the ice; but to make it still stronger the inside was shored up in every possible way, so that the hold looks like a cobweb of balks, stanchions, and braces. In the first place, there are two rows of beams, the upper deck and between decks, principally of solid oak, partly also of pitch pine; and all of these are further connected with each other, as well as with the sides of the ship, by numerous supports. The accompanying diagrams will show how they are arranged. The diagonal stays are, of course, placed as nearly as possible at right angles to the sides of the ship, so as to strengthen them against external pressure and to distribute its force. The vertical stanchions between both tiers of beams and between the lower beams and keelson are admirably adapted for this latter object. All are connected together with strong knees and iron fastenings, so that the whole becomes, as it were, a single coherent mass. It should be borne in mind that, while in former expeditions it was thought sufficient to give a couple of beams amidships some extra strengthening, every single cross beam in the Fram was stayed in the manner described and depicted.
In the engine-room there was, of course, no space for supports in the middle, but in their place two stay ends were fixed on either side. The beams of the lower deck were placed a little under the water-line, where the ice pressure would be severest. In the after-hold these beams had to be raised a little to give room for the engine. The upper deck aft, therefore, was somewhat higher than the main deck, and the ship had a poop or half-deck, under which were the cabins for all the members of the expedition, and also the cooking-galley. Strong iron riders were worked in for the whole length of the ship in the spaces between the beams, extending in one length from the clamp under the upper deck nearly to the keelson. The keelson was in two tiers and about 31 inches (80 cm.) high, save in the engine-room, where the height of the room only allows one tier. The keel consists of two heavy American elm logs 14 inches square; but, as has been mentioned, so built in that only 3 inches protrude below the outer planking. The sides of the hull are rounded downward to the keel, so that a transverse section at the midship frame reminds one forcibly of half a cocoanut cut in two. The higher the ship is lifted out of the water, the heavier does she, of course, become, and the greater her pressure on the ice, but for the above reason the easier also does it become for the ice to lift. To obviate much heeling, in case the hull should be lifted very high, the bottom was made flat, and this proved to be an excellent idea. I endeavored to determine experimentally the friction of ice against wood, and taking into account the strength of the ship, and the angle of her sides with the surface of the water, I came to the conclusion that her strength must be many times sufficient to withstand the pressure necessary to lift her. This calculation was amply borne out by experience.
The principal dimensions of the ship were as follows: Length of keel, 102 feet; length of water-line, 113 feet; length from stem to stern on deck, 128 feet; extreme breadth, 36 feet; breadth of water-line, exclusive of ice-skin, 34 feet; depth, 17 feet; draught of water with light cargo, 12½ feet; displacement with light cargo, 530 tons; with heavy cargo the draught is over 15 feet and the displacement is 800 tons; there is a freeboard of about 3 feet 6 inches. The hull, with boilers filled, was calculated to weigh about 420 tons, and with 800 tons displacement there should, therefore, be spare carrying power for coal and other cargo to the amount of 380 tons. Thus, in addition to the requisite provisions for dogs and men for more than five years, we could carry coal for four months’ steaming at full speed, which was more than sufficient for such an expedition as this.
As regards the rigging, the most important object was to have it as simple and as strong as possible, and at the same time so contrived as to offer the least possible resistance to the wind while the ship was under steam. With our small crew it was, moreover, of the last importance that it should be easy to work from deck. For this reason the Fram was rigged as a three-masted fore-and-aft schooner. Several of our old Arctic skippers disapproved of this arrangement. They had always been used to sail with square-rigged ships, and, with the conservatism peculiar to their class, were of opinion that what they had used was the only thing that could be used in the ice. However, the rig we chose was unquestionably the best for our purpose. In addition to the ordinary fore-and-aft sails we had two movable yards on the foremast for a square foresail and topsail. As the yards were attached to a sliding truss they could easily be hauled down when not in use. The ship’s lower masts were tolerably high and massive. The mainmast was about 80 feet high, the maintopmast was 50 feet high, and the crow’s-nest on the top was about 102 feet (32 m.) above the water. It was important to have this as high as possible, so as to have a more extended view when it came to picking our way through the ice. The aggregate sail area was about 6000 square feet.
The ship’s engine, a triple expansion, was made with particular care. The work was done at the Akers Mechanical Factory, and Engineer Norbeck deserves especial credit for its construction. With his quick insight he foresaw the various possibilities that might occur, and took precautions against them. The triple-expansion system was chosen as being the most economical in the consumption of coal; but as it might happen that one or other of the cylinders should get out of order, it was arranged, by means of separate pipes, that any of the cylinders could be cut off, and thus the other two, or, at a pinch, even one alone, could be used. In this way the engine, by the mere turning of a cock or two, could be changed at will into a compound high-pressure or low-pressure engine. Although nothing ever went wrong with any of the cylinders, this arrangement was frequently used with advantage. By using the engine as a compound one, we could, for instance, give the Fram greater speed for a short time, and when occasion demanded we often took this means of forcing our way through the ice. The engine was of 220 indicated horse-power, and we could in calm weather with a light cargo attain a speed of 6 or 7 knots.
The propellers, of which we had two in reserve, were two-bladed, and made of cast-iron; but we never used either the spare propellers or a spare rudder which we had with us.
Our quarters lay, as before mentioned, abaft under the half-deck, and were arranged so that the saloon, which formed our dining-room and drawing-room, was in the middle, surrounded on all sides by the sleeping-cabins. These consisted of four state-rooms with one berth apiece and two with four berths. The object of this arrangement was to protect the saloon from external cold; but, further, the ceiling, floors, and walls were covered with several thick coatings of non-conducting material, the surface layer, in touch with the heat of the cabin, consisting of air-tight linoleum, to prevent the warm, damp air from penetrating to the other side and depositing moisture, which would soon turn to ice. The sides of the ship were lined with tarred felt, then came a space with cork padding, next a deal panelling, then a thick layer of felt, next air-tight linoleum, and last of all an inner panelling. The ceiling of the saloon and cabins consisted of many different layers: air, felt, deal panelling, reindeer-hair stuffing, deal panelling, linoleum, air and deal panelling, which, with the 4-inch deck planks, gave a total thickness of about 15 inches. To form the floor of the saloon, cork padding, 6 or 7 inches thick, was laid on the deck planks, on this a thick wooden floor, and above all linoleum. The skylight which was most exposed to the cold was protected by three panes of glass, one within the other, and in various other ways. One of the greatest difficulties of life on board ship which former Arctic expeditions had had to contend with was that moisture collecting on the cold outside walls either froze at once or ran down in streams into the berths and on to the floor. Thus it was not unusual to find the mattresses converted into more or less solid masses of ice. We, however, by these arrangements, entirely avoided such an unpleasant state of things, and when the fire was lighted in the saloon there was not a trace of moisture on the walls, even in the sleeping-cabins. In front of the saloon lay the cook’s galley, on either side of which was a companion leading to the deck.
As a protection against the cold, each of these companion-ways was fitted with four small solid doors consisting of several layers of wood with felt between, all of which had to be passed through on going out. And the more completely to exclude the cold air the thresholds of the doors were made more than ordinarily high. On the half-deck over the cook’s galley, between the mainmast and the funnel, was a chart-room facing the bow, and a smaller work-room abaft.
In order to secure the safety of the ship in case of a leak, the hold was divided into three compartments by water-tight bulkheads. Besides the usual pumps, we had a powerful centrifugal pump driven by the engine, which could be connected with each of the three compartments. It may be mentioned as an improvement on former expeditions that the Fram was furnished with an electric light installation. The dynamo was to be driven by the engine while we were under steam; while the intention was to drive it partly by means of the wind, partly by hand power, during our sojourn in the ice. For this purpose we took a windmill with us, and also a “horse-mill” to be worked by ourselves. I had anticipated that this latter might have been useful in giving us exercise in the long polar night. We found, however, that there were plenty of other things to do, and we never used it; on the other hand, the windmill proved extremely serviceable. For illumination when we might not have enough power to produce electric light, we took with us about 16 tons of petroleum, which was also intended for cooking purposes and for warming the cabins. This petroleum, as well as 20 tons of common kerosene,2 intended to be used along with coal in the boiler, was stored in massive iron tanks, eight of which were in the hold, and one on deck. In all, the ship had eight boats, two of which were especially large, 29 feet long and 9 feet wide. These were intended for use in case the ship should, after all, be lost, the idea being that we should live in them while drifting in the ice. They were large enough to accommodate the whole ship’s company with provisions for many months. Then there were four smaller boats of the form sealers generally use. They were exceedingly strong and lightly built, two of oak and two of elm. The seventh boat was a small pram, and the eighth a launch with a petroleum engine, which, however, was not very serviceable, and caused us a great deal of trouble.
As I shall have frequent occasion later on to speak of other details of our equipment, I shall content myself here with mentioning a few of the most important.
Special attention was, of course, devoted to our commissariat with a view to obviating the danger of scurvy and other ailments. The principle on which I acted in the choice of provisions was to combine variety with wholesomeness. Every single article of food was chemically analyzed before being adopted, and great care was taken that it should be properly packed. Such articles, even, as bread, dried vegetables, etc., etc., were soldered down in tins as a protection against damp.
A good library was of great importance to an expedition like ours, and thanks to publishers and friends, both in our own and in other countries, we were very well supplied in this respect.
The instruments for taking scientific observations of course formed an important part of our equipment, and special care was bestowed upon them. In addition to the collection of instruments I had used on my Greenland expedition, a great many new ones were provided, and no pains were spared to get them as good and complete as possible. For meteorological observations, in addition to the ordinary thermometers, barometers, aneroids, psychrometers, hygrometers, anemometers, etc., etc., self-registering instruments were also taken. Of special importance were a self-registering aneroid barometer (barograph) and a pair of self-registering thermometers (thermographs). For astronomical observations we had a large theodolite and two smaller ones, intended for use on sledge expeditions, together with several sextants of different sizes. We had, moreover, four ship’s chronometers and several pocket-chronometers. For magnetic observations, for taking the declination, inclination, and intensity (both horizontal and total intensity) we had a complete set of instruments. Among others may be mentioned a spectroscope especially adapted for the northern lights, an electroscope for determining the amount of electricity in the air, photographic apparatuses, of which we had seven, large and small, and a photographometer for making charts. I considered a pendulum apparatus with its adjuncts to be of special importance to enable us to make pendulum experiments in the far north. To do this, however, land was necessary, and, as we did not find any, this instrument unfortunately did not come into use. For hydrographic observations we took a full equipment of water-samplers, deep-water thermometers, etc. To ascertain the saltness of the water, we had, in addition to the ordinary areometers, an electric apparatus specially constructed by Mr. Thornöe. Altogether, our scientific equipment was especially excellent, thanks in great measure to the obliging assistance rendered me by many men of science. I would take this opportunity of tendering my special thanks to Professor Mohn, who, besides seeing to the meteorological instruments, helped me in many other ways with his valuable advice; to Professor Geelmuyden, who undertook the supervision of the astronomical instruments; to Dr. Neumeyer, of Hamburg, who took charge of the magnetic equipment; and to Professor Otto Petterson, of Stockholm, and Mr. Thornöe, of Christiania, both of whom superintended the hydrographic department. Of no less importance were the physiologico-medicinal preparations, to which Professor Torup devoted particular care.
As it might be of the utmost importance in several contingencies to have good sledge-dogs, I applied to my friend, Baron Edward von Toll, of St. Petersburg, and asked him whether it was possible to procure serviceable animals from Siberia.3 With great courtesy Von Toll replied that he thought he himself could arrange this for me, as he was just on the point of undertaking his second scientific expedition to Siberia and the New Siberian Islands. He proposed to send the dogs to Khabarova, on Yugor Strait. On his journey through Tiumen in January, 1893, by the help of an English merchant named Wardroper, who resided there, he engaged Alexander Ivanovitch Trontheim to undertake the purchase of thirty Ostiak dogs and their conveyance to Yugor Strait. But Von Toll was not content with this. Mr. Nikolai Kelch having offered to bear the expense, my friend procured the East Siberian dogs, which are acknowledged to be better draught dogs than those of West Siberia (Ostiak dogs), and Johan Torgersen, a Norwegian, undertook to deliver them at the mouth of the Olenek, where it was arranged that we should touch.
Von Toll, moreover, thought it would be important to establish some depots of provisions on the New Siberian Islands, in case the Fram should meet with disaster and the expedition should be obliged to return home that way. On Von Toll’s mentioning this, Kelch at once expressed himself willing to bear the cost, as he wished us in that event to meet with Siberian hospitality even on the New Siberian Islands. As it was difficult to find trustworthy agents to carry out a task involving so much responsibility, Von Toll determined to establish the depots himself, and in May, 1893, he set out on an adventurous and highly interesting journey from the mainland over the ice to the New Siberian Islands, where, besides laying down three depots for us,4 he made some very important geological researches.
Another important matter, I thought, was to have a cargo of coal sent out as far as possible on our route, so that when we broke off all connection with the rest of the world we should have on board the Fram as much coal as she could carry. I therefore joyfully accepted an offer from an Englishman, who was to accompany us with his steam-yacht to Novaya Zemlya or the Kara Sea and give us 100 tons of coal on parting company. As our departure was drawing nigh I learnt, however, that other arrangements had been made. It being now too late to take any other measures, I chartered the sloop Urania, of Brönösund, in Nordland, to bring a cargo of coals to Khabarova, on the Yugor Strait.
No sooner did the plan of my expedition become known than petitions poured in by the hundred from all quarters of the earth—from Europe, America, Australia—from persons who wished to take part in it, in spite of the many warning voices that had been raised. It was no easy thing to choose among all the brave men who applied. As a matter of course, it was absolutely essential that every man should be strong and healthy, and not one was finally accepted till he had been carefully examined by Professor Hialmar Heiberg, of Christiania.
The following is a list of the members of the expedition:
Otto Neumann Sverdrup, commander of the Fram, was born in Bindal, in Helgeland, 1855. At the age of seventeen he went to sea, passed his mate’s examination in 1878, and for some years was captain of a ship. In 1888–89 he took part in the Greenland expedition. As soon as he heard of the plan of the polar expedition he expressed his desire to accompany it, and I knew that I could not place the Fram in better hands. He is married, and has one child.
Sigurd Scott-Hansen, first lieutenant in the navy, undertook the management of the meteorological, astronomical, and magnetic observations. He was born in Christiania in 1868. After passing through the naval school at Horten, he became an officer in 1889, and first lieutenant in 1892. He is a son of Andreas Hansen, parish priest in Christiania.
Henrik Greve Blessing, doctor and botanist to the expedition, was born in Drammen in 1866, where his father was at that time a clergyman. He became a student in 1885, and graduated in medicine in the spring of 1893.
Theodore Claudius Jacobsen, mate of the Fram, was born at Tromsö in 1855, where his father was a ship’s captain, afterwards harbor-master and head pilot. At the age of fifteen he went to sea, and passed his mate’s examination four years later. He spent two years in New Zealand, and from 1886–90 he went on voyages to the Arctic Sea as skipper of a Tromsö sloop. He is married, and has one child.
Anton Amundsen, chief engineer of the Fram, was born at Horten in 1853. In 1884 he passed his technical examination, and soon afterwards his engineer’s examination. For twenty-five years he has been in the navy, where he attained the rank of chief engineer. He is married, and has six children.
Adolf Juell, steward and cook of the Fram, was born in the parish of Skåtö, near Kragerö, in 1860. His father, Claus Nielsen, was a farmer and ship-owner. In 1879 he passed his mate’s examination, and has been captain of a ship many years. He is married, and has four children.
Lars Pettersen, second engineer of the Fram, was born in 1860, at Borre, near Landskrona, in Sweden, of Norwegian parents. He is a fully qualified smith and machinist, in which capacity he has served in the Norwegian navy for several years. Is married, and has children.
Frederik Hjalmar Johansen, lieutenant in the Reserve, was born at Skien in 1867, and matriculated at the University in 1886. In 1891–92 he went to the Military School and became a supernumerary officer. He was so eager to take part in the expedition that, as no other post could be found for him, he accepted that of stoker.
Peter Leonard Henriksen, harpooner, was born in Balsfjord, near Tromsö, in 1859. From childhood he has been a sailor, and from fourteen years old has gone on voyages to the Arctic Sea as harpooner and skipper. In 1888 he was shipwrecked off Novaya Zemlya in the sloop Enigheden, from Christiansund. He is married, and has four children.
Bernhard Nordahl was born in Christiania in 1862. At the age of fourteen he entered the navy, and advanced to be a gunner. Subsequently he has done a little of everything, and, among other things, has worked as an electrical engineer. He had charge of the dynamo and electric installation on board, acted, moreover, as stoker, and for a time assisted in the meteorological observations. He is married, and has five children.
Ivar Otto Irgens Mogstad was born at Aure, in Nordmöre, in 1856. In 1877 passed his examination as first assistant, and from 1882 onward was one of the head keepers at the Gaustad Lunatic Asylum.
Bernt Bentzen, born in 1860, went to sea for several years. In 1890 he passed his mate’s examination, since which he has sailed as mate in several voyages to the Arctic Sea. We engaged him at Tromsö, just as we were starting. It was 8.30 when he came on board to speak to me, and at 10 o’clock the Fram set sail.
1. Nearly £25,000.
2. This oil, by means of a specially constructed steam-jet apparatus, was injected into the furnaces in the form of a fine spray, where it burned in a very economical and saving manner, giving forth a great amount of heat. The apparatus was one which has been applied to locomotives in England, whence it was procured. It appeared, however, that it tended to overheat the boiler at one particular point, where it made a dent, so that we soon abandoned this method of firing.
3. I had thought of procuring dogs from the Eskimo of Greenland and Hudson Bay, but there proved to be insuperable difficulties in the way of getting them conveyed from there.
4. These depots were arranged most carefully, and every precaution so well taken that we certainly should not have suffered from famine had we gone there. In the northernmost depot at Stan Durnova on the west coast of Kotelnoi, at 75° 37′ N. L., we should have found provisions for a week; with these we could easily have made our way 65 miles southward along the coast to the second depot at Urassalach, where, in a house built by Baron Von Toll in 1886, we should have found provisions for a whole month. Lastly, a third depot in a house on the south side of Little Liakhoff Island, with provisions for two months, would have enabled us to reach the mainland with ease.