Battles with the Sea, Robert Michael Ballantyne [ebook reader macos txt] 📗
- Author: Robert Michael Ballantyne
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use by the Lifeboat Institution is absolutely perfect in this respect. What more could be desired in any boat than that, after being upset, it should right itself in a _few seconds_, and empty itself of water in less than one minute?
A boat which does not right itself when overturned is only a lifeboat so long as it maintains its proper position on the water.
Let its self-emptying and buoyant qualities be ever so good, you have only to upset it to render it no better than any other boat;--indeed, in a sense, it is worse than other boats, because it leads men to face danger which they would not dare to encounter in an ordinary boat.
Doubtless, lifeboats on the non-self-righting principle possess great stability, and are seldom overturned; nevertheless they occasionally are, and with fatal results. Here is one example. In the month of January, 1865, the Liverpool lifeboat, when out on service, was upset, and seven men of her crew were drowned. This was not a self-righting boat, and it did not belong to the Lifeboat Institution, most of whose boats are now built on the self-righting principle. Moreover, the unfortunate men had not put on lifebelts. It may be added that the men who work the boats of the Institution are not allowed to go off without their cork lifebelts on.
Take another case. On the 4th January, 1857, the Point of Ayr lifeboat, when under sail in a gale, upset at a distance from the land. The accident was seen from the shore, but no aid could be rendered, and the whole boat's crew--thirteen in number--were drowned. This boat was considered a good lifeboat, and doubtless it was so in many respects, but it was not a self-righting one. Two or three of the poor fellows were seen clinging to the keel for twenty minutes, by which time they became exhausted, were washed off, and, having no lifebelts on, perished.
Again in February, 1858, the Southwold lifeboat--a large sailing boat, esteemed one of the finest in the kingdom, but not on the self-righting principle--went out for exercise, and was running before a heavy surf with all sail set, when she suddenly ran on the top of a sea, turned broadside to the waves, and was upset. The crew in this case were fortunately near the shore, had on their lifebelts, and, although some of them could not swim, were all saved--no thanks, however, to their boat, which remained keel up--but three unfortunate gentlemen who had been permitted to go off in the boat without lifebelts, and one of whom was a good swimmer, lost their lives.
Let it be noted here that the above three instances of disaster occurred in the day time, and the contrast of the following case will appear all the stronger.
One very dark and stormy night in October, 1858, the small lifeboat of Dungeness put off through a heavy sea to a wreck three-quarters of a mile from the shore. Eight stout men of the coastguard composed her crew. She was a self-righting, self-emptying boat, belonging to the Lifeboat Institution. The wreck was reached soon after midnight, and found to have been abandoned. The boat, therefore, returned towards the shore. Now, there is a greater danger in rowing before a gale than in rowing against it. For the first half mile all went well, though the sea was heavy and broken, but, on crossing a deep channel between two shoals, the little lifeboat was caught up and struck by three heavy seas in succession. The coxswain lost command of the rudder, and she was carried away before a sea, broached to, and upset, throwing her crew out of her. _Immediately_ she righted herself, cleared herself of water, and was brought up by her anchor which had fallen out when she was overturned. The crew meanwhile having on lifebelts, floated and swam to the boat, caught hold of the life-lines festooned round her sides, clambered into her, cut the cable, and returned to the shore in safety! What more need be said in favour of the self-righting boats?
The self-emptying principle is quite equal to the self-righting in importance.
In _every_ case of putting off to a wreck in a gale, a lifeboat ships a great deal of water. In most cases she fills more than once. Frequently she is overwhelmed by tons of water by every sea. A boat full of water cannot advance, therefore baling becomes necessary; but baling, besides being very exhausting work, is so slow that it would be useless labour in most cases. Besides, when men have to bale they cannot give that undivided attention to the oars which is needful. To overcome this difficulty the self-emptying plan was devised.
As, I doubt not, the reader is now sufficiently interested to ask the questions, How are self-righting and self-emptying accomplished? I will try to throw some light on these subjects.
First, as to self-righting. You are aware, no doubt, that the buoyancy of our lifeboat is due chiefly to large air-cases at the ends, and all round the sides from stem to stern. The accompanying drawing and diagrams will aid us in the description. On the opposite page you have a portrait of, let us say, a thirty-three feet, ten-oared lifeboat, of the Royal National Lifeboat Institution, on its transporting carriage, ready for launching, and, on page 95, two diagrams representing respectively a section and a deck view of the same (Figures 1, 2, and 3).
The breadth of this boat is eight feet; its stowage-room sufficient for thirty passengers, besides its crew of twelve men--forty-two in all. It is double-banked; that is, each of its five banks, benches, or thwarts, accommodates two rowers sitting side by side. The lines festooned round the side dip into the water, so that anyone swimming alongside may easily grasp them, and in the middle part of the boat--just where the large wheels come in the engraving--two of the lines are longer than the others, so that a man might use them as stirrups, and thus be enabled to clamber into the boat even without assistance. The rudder descends considerably below the keel--to give it more power--and has to be raised when the boat is being launched.
The shaded parts of the diagrams show the position and form of the air-cases which prevent a lifeboat from sinking. The white oblong space in Figure 2 is the free space available for crew and passengers. In Figure 3 is seen the depth to which the air-chambers descend, and the height to which the bow and stern-chambers rise.
It is to these large air-chambers in bow and stern, coupled with great sheer--or rise fore and aft--of gunwale, and a very heavy keel, that the boat owes its self-righting power. The two air-chambers are rounded on the top. Now, it is obvious that if you were to take a model of such a boat, turn it upside down on a table, and try to make it rest on its two _rounded_ air-chambers, you would encounter as much difficulty as did the friends of Columbus when they sought to make an egg stand on its end. The boat would infallibly fall to one side or the other. In the water the tendency is precisely the same, and that tendency is increased by the heavy iron keel, which drags the boat violently round to its right position.
The self-righting principle was discovered--at all events for the first time exhibited--at the end of last century, by the Reverend James Bremner, of Orkney. He first suggested in the year 1792 that an ordinary boat might be made self-righting by placing two watertight casks in the head and sternsheets of it, and fastening three hundredweight of iron to the keel. Afterwards he tried the experiment at Leith, and with such success that in 1810 the Society of Arts voted him a silver medal and twenty guineas. But nothing further was done until half a century later, when twenty out of twenty-four pilots lost their lives by the upsetting of the non-self-righting Shields lifeboat.
Then (1850) the late Duke of Northumberland offered a prize of 100 guineas for the best lifeboat that could be produced. No fewer than 280 models and drawings were sent in, and the plans, specifications, and descriptions of these formed five folio manuscript volumes! The various models were in the shape of pontoons, catamarans or rafts, north-country cobles, and ordinary boats, slightly modified. The committee appointed to decide on their respective merits had a difficult task to perform. After six months' careful, patient investigation and experiment, they awarded the prize to Mr James Beeching, of Great Yarmouth. Beeching's boat, although the best, was not, however, deemed perfect.
The committee therefore set Mr James Peake, one of their number, and assistant master-shipwright at Woolwich Dockyard, to incorporate as many as possible of the good qualities of all the other models with Beeching's boat. From time to time various important improvements have been made, and the result is the present magnificent boat of the Institution, by means of which hundreds of lives are saved every year.
The self-discharge of water from a lifeboat is not so easy to explain. It will be the more readily comprehended if the reader understands, and will bear in remembrance, the physical fact that water will, and must, find its level. That is--no portion of water, small or great, in tub, pond, or sea, can for a moment remain above its flat and level surface, except when forced into motion, or commotion. Left to itself it infallibly flattens out, becomes calm, lies still in the lowest attainable position--in other words, finds its level. Bearing this in mind, let us look again at Figure 3.
The dotted double line about the middle of the boat, extending from stem to stern, represents the _floor_ of the boat, on which the men's feet rest when standing or sitting in it. It also represents, or very nearly so, the waterline outside, that is, the depth to which the boat will sink when afloat, manned and loaded. Therefore, the _boat's floor_ and the _ocean_ _surface_ are on the same level. Observe that! The space between the floor and the keel is filled up with cork or other ballast. Now, there are six large holes in the boat's floor--each hole six inches in diameter--into which are fitted six metal tubes, which pass down by the side of the cork ballast, and right through the bottom of the boat itself; thus making six large openings into the sea.
"But hallo!" you exclaim, "won't the water from below rush up through these holes and fill the boat?"
It will indeed rush up into these holes, but it will not fill the boat because it will have found its level--the level of ocean--on reaching the floor. Well, besides having reached its level, the water in the tubes has reached six valves, which will open downwards to let water out, but which won't open upwards to let it in. Now, suppose a huge billow topples into the boat and fills it quite full, is it not obvious that all the water in the boat stands _above_ the ocean's level--being above the boat's floor? Like a wise element, it immediately seeks its own level by the only mode of egress--the discharging tubes; and when it has found its level, it has also found the floor of the boat. In other words, it is all gone! moreover,
A boat which does not right itself when overturned is only a lifeboat so long as it maintains its proper position on the water.
Let its self-emptying and buoyant qualities be ever so good, you have only to upset it to render it no better than any other boat;--indeed, in a sense, it is worse than other boats, because it leads men to face danger which they would not dare to encounter in an ordinary boat.
Doubtless, lifeboats on the non-self-righting principle possess great stability, and are seldom overturned; nevertheless they occasionally are, and with fatal results. Here is one example. In the month of January, 1865, the Liverpool lifeboat, when out on service, was upset, and seven men of her crew were drowned. This was not a self-righting boat, and it did not belong to the Lifeboat Institution, most of whose boats are now built on the self-righting principle. Moreover, the unfortunate men had not put on lifebelts. It may be added that the men who work the boats of the Institution are not allowed to go off without their cork lifebelts on.
Take another case. On the 4th January, 1857, the Point of Ayr lifeboat, when under sail in a gale, upset at a distance from the land. The accident was seen from the shore, but no aid could be rendered, and the whole boat's crew--thirteen in number--were drowned. This boat was considered a good lifeboat, and doubtless it was so in many respects, but it was not a self-righting one. Two or three of the poor fellows were seen clinging to the keel for twenty minutes, by which time they became exhausted, were washed off, and, having no lifebelts on, perished.
Again in February, 1858, the Southwold lifeboat--a large sailing boat, esteemed one of the finest in the kingdom, but not on the self-righting principle--went out for exercise, and was running before a heavy surf with all sail set, when she suddenly ran on the top of a sea, turned broadside to the waves, and was upset. The crew in this case were fortunately near the shore, had on their lifebelts, and, although some of them could not swim, were all saved--no thanks, however, to their boat, which remained keel up--but three unfortunate gentlemen who had been permitted to go off in the boat without lifebelts, and one of whom was a good swimmer, lost their lives.
Let it be noted here that the above three instances of disaster occurred in the day time, and the contrast of the following case will appear all the stronger.
One very dark and stormy night in October, 1858, the small lifeboat of Dungeness put off through a heavy sea to a wreck three-quarters of a mile from the shore. Eight stout men of the coastguard composed her crew. She was a self-righting, self-emptying boat, belonging to the Lifeboat Institution. The wreck was reached soon after midnight, and found to have been abandoned. The boat, therefore, returned towards the shore. Now, there is a greater danger in rowing before a gale than in rowing against it. For the first half mile all went well, though the sea was heavy and broken, but, on crossing a deep channel between two shoals, the little lifeboat was caught up and struck by three heavy seas in succession. The coxswain lost command of the rudder, and she was carried away before a sea, broached to, and upset, throwing her crew out of her. _Immediately_ she righted herself, cleared herself of water, and was brought up by her anchor which had fallen out when she was overturned. The crew meanwhile having on lifebelts, floated and swam to the boat, caught hold of the life-lines festooned round her sides, clambered into her, cut the cable, and returned to the shore in safety! What more need be said in favour of the self-righting boats?
The self-emptying principle is quite equal to the self-righting in importance.
In _every_ case of putting off to a wreck in a gale, a lifeboat ships a great deal of water. In most cases she fills more than once. Frequently she is overwhelmed by tons of water by every sea. A boat full of water cannot advance, therefore baling becomes necessary; but baling, besides being very exhausting work, is so slow that it would be useless labour in most cases. Besides, when men have to bale they cannot give that undivided attention to the oars which is needful. To overcome this difficulty the self-emptying plan was devised.
As, I doubt not, the reader is now sufficiently interested to ask the questions, How are self-righting and self-emptying accomplished? I will try to throw some light on these subjects.
First, as to self-righting. You are aware, no doubt, that the buoyancy of our lifeboat is due chiefly to large air-cases at the ends, and all round the sides from stem to stern. The accompanying drawing and diagrams will aid us in the description. On the opposite page you have a portrait of, let us say, a thirty-three feet, ten-oared lifeboat, of the Royal National Lifeboat Institution, on its transporting carriage, ready for launching, and, on page 95, two diagrams representing respectively a section and a deck view of the same (Figures 1, 2, and 3).
The breadth of this boat is eight feet; its stowage-room sufficient for thirty passengers, besides its crew of twelve men--forty-two in all. It is double-banked; that is, each of its five banks, benches, or thwarts, accommodates two rowers sitting side by side. The lines festooned round the side dip into the water, so that anyone swimming alongside may easily grasp them, and in the middle part of the boat--just where the large wheels come in the engraving--two of the lines are longer than the others, so that a man might use them as stirrups, and thus be enabled to clamber into the boat even without assistance. The rudder descends considerably below the keel--to give it more power--and has to be raised when the boat is being launched.
The shaded parts of the diagrams show the position and form of the air-cases which prevent a lifeboat from sinking. The white oblong space in Figure 2 is the free space available for crew and passengers. In Figure 3 is seen the depth to which the air-chambers descend, and the height to which the bow and stern-chambers rise.
It is to these large air-chambers in bow and stern, coupled with great sheer--or rise fore and aft--of gunwale, and a very heavy keel, that the boat owes its self-righting power. The two air-chambers are rounded on the top. Now, it is obvious that if you were to take a model of such a boat, turn it upside down on a table, and try to make it rest on its two _rounded_ air-chambers, you would encounter as much difficulty as did the friends of Columbus when they sought to make an egg stand on its end. The boat would infallibly fall to one side or the other. In the water the tendency is precisely the same, and that tendency is increased by the heavy iron keel, which drags the boat violently round to its right position.
The self-righting principle was discovered--at all events for the first time exhibited--at the end of last century, by the Reverend James Bremner, of Orkney. He first suggested in the year 1792 that an ordinary boat might be made self-righting by placing two watertight casks in the head and sternsheets of it, and fastening three hundredweight of iron to the keel. Afterwards he tried the experiment at Leith, and with such success that in 1810 the Society of Arts voted him a silver medal and twenty guineas. But nothing further was done until half a century later, when twenty out of twenty-four pilots lost their lives by the upsetting of the non-self-righting Shields lifeboat.
Then (1850) the late Duke of Northumberland offered a prize of 100 guineas for the best lifeboat that could be produced. No fewer than 280 models and drawings were sent in, and the plans, specifications, and descriptions of these formed five folio manuscript volumes! The various models were in the shape of pontoons, catamarans or rafts, north-country cobles, and ordinary boats, slightly modified. The committee appointed to decide on their respective merits had a difficult task to perform. After six months' careful, patient investigation and experiment, they awarded the prize to Mr James Beeching, of Great Yarmouth. Beeching's boat, although the best, was not, however, deemed perfect.
The committee therefore set Mr James Peake, one of their number, and assistant master-shipwright at Woolwich Dockyard, to incorporate as many as possible of the good qualities of all the other models with Beeching's boat. From time to time various important improvements have been made, and the result is the present magnificent boat of the Institution, by means of which hundreds of lives are saved every year.
The self-discharge of water from a lifeboat is not so easy to explain. It will be the more readily comprehended if the reader understands, and will bear in remembrance, the physical fact that water will, and must, find its level. That is--no portion of water, small or great, in tub, pond, or sea, can for a moment remain above its flat and level surface, except when forced into motion, or commotion. Left to itself it infallibly flattens out, becomes calm, lies still in the lowest attainable position--in other words, finds its level. Bearing this in mind, let us look again at Figure 3.
The dotted double line about the middle of the boat, extending from stem to stern, represents the _floor_ of the boat, on which the men's feet rest when standing or sitting in it. It also represents, or very nearly so, the waterline outside, that is, the depth to which the boat will sink when afloat, manned and loaded. Therefore, the _boat's floor_ and the _ocean_ _surface_ are on the same level. Observe that! The space between the floor and the keel is filled up with cork or other ballast. Now, there are six large holes in the boat's floor--each hole six inches in diameter--into which are fitted six metal tubes, which pass down by the side of the cork ballast, and right through the bottom of the boat itself; thus making six large openings into the sea.
"But hallo!" you exclaim, "won't the water from below rush up through these holes and fill the boat?"
It will indeed rush up into these holes, but it will not fill the boat because it will have found its level--the level of ocean--on reaching the floor. Well, besides having reached its level, the water in the tubes has reached six valves, which will open downwards to let water out, but which won't open upwards to let it in. Now, suppose a huge billow topples into the boat and fills it quite full, is it not obvious that all the water in the boat stands _above_ the ocean's level--being above the boat's floor? Like a wise element, it immediately seeks its own level by the only mode of egress--the discharging tubes; and when it has found its level, it has also found the floor of the boat. In other words, it is all gone! moreover,
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