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| Alphabetical [« »] watch 2 watch-chain 1 watch-tower 1 water 136 water-basin 1 water-column 4 water-columns 4 | Frequency [« »] 152 that 144 as 136 it 136 water 120 this 114 with 113 or | Mårten Triewald Short Description of the Fire- and Air-Machine at the Dannemora Mines Concordances water |
Part, §
1 Int | was having set up to pump water from a coal pit. It was 2 Int | to the problem of raising water from mines -- that is to 3 Int | injecting the condensing water into the cylinder is that 4 Int | cylinder wall, through which water rushed in from a water jacket 5 Int | which water rushed in from a water jacket formed by a lead 6 Int | generated by the boiling water in proportion to the quantity 7 Int | proportion to the quantity of water, whereas, as he asserts, 8 Int | thin membrane or coat of water, very much like a bladder.~ ~ 9 Int | would effectually draw the water out of all mines and collyeries 10 Pre, 1| study for many years to draw water by means of fire. When fourteen 11 Pre, 1| fire-machine for drawing water from the mines. He was induced 12 Pre, 1| the heavy costs of lifting water by means of horses which 13 Pre, 2| strange event. The cold water, which was allowed to flow 14 Pre, 2| opened a way for the cold water, which rushed into the cylinder 15 Pre, 2| represent the weight of the water in the pumps, proved to 16 Pre, 2| the small boiler. The hot water which flowed everywhere 17 Pre, 5| feet 1 inches high. The water in the boiler stood 4 feet 18 Pre, 5| minute 10 English gallons of water, and the mine was 51 yards 19 Pre, 7| any other way of drawing water from a mine that by means 20 Pre, 10| generated by the boiling water in proportion to the quantities 21 Pre, 10| proportion to the quantities of water. In consequence of these 22 Exp | widest part, 2/3 full of water, the steam, when boiling, 23 Exp | through the spurting of cold water, which creates a vacuum, 24 Exp | opened, can be seen how much water there is in the boiler, 25 Exp | coming from the upper one and water from the lower one this 26 Exp | there is a proper amount of water in the boiler.~ ~H. A pipe 27 Exp | boiler is fed with warm water coming from the cylinder. ~ ~ 28 Exp | which is always kept cold water to a height of 6 inches 29 Exp | which conducts the cold water to the cylinder, and which 30 Exp | the cylinder, by the cold water, spurting into the cylinder 31 Exp | injection-water and the water that may have been leaking 32 Exp | pipe for drawing off the water from the piston when it 33 Exp | W. A pipe conducting water to the puffing or snifting 34 Exp | placed under the level of the water in a box of wood for the 35 Exp | into the cylinder when the water spurts out of the valve 36 Exp | furnishes the piston with water from the reservoir or water-basin 37 Exp | constantly keeps filled with water, by means of a force-work 38 Exp | force-work or pump which forces water 45 feet from the water-level 39 Exp | launder which conveys the water, drawn by the machine from 40 Exp | reservoir, through which the water, which the force-work draws 41 I, 1| Florence, who noticed that the water in his pump did not rise 42 I, 2| lighter than a similar inch of water, (See Tractaten om Hydrostastika 43 I, 2| is 14 times heavier than water. From this it follows that 44 I, 2| covered all over by a layer of water 34 feet high. (A pillar 45 I, 2| feet high. (A pillar of water 34 feet high and of the 46 I, 9| a stone-floor or in cold water, it will be found that it 47 I, 9| thin membrane or coat of water, very much like a bladder.~ ~ 48 I, 11| useful to learn that all water contains an un-measurable 49 I, 11| easily be proved by allowing water to stand under the receiver 50 I, 11| piston, so that the cold water, which is turned on the 51 I, 11| opened, which causes a jet of water of one kanna or more -- 52 I, 11| the friction.~ ~The cold water which jets against the bottom 53 I, 12| powerful enough to draw water out of such a depth and 54 I, 12| Solwerbergs mines clear from water, only the pumps will have 55 II, 14| depth from which it draws water is 31 fathoms or 186 feet; 56 II, 14| which the fire-machine draws water, is 9 inches in diameter; 57 II, 14| it contains 6 kannor of water.~ ~ 58 II, 15| force-work, (the force-work draws water from the basin 45 feet up 59 II, 15| which contains 4 kannor water, and demonstrated how the 60 II, 15| hour~ ~ ~ 630 tunnor of water~ ~ 24 hours [an hour~ ~ ~ 61 II, 15| 1260~ ~ ~ 15120 tunnor of water~ ~ ~ ~in 24 hours.~ ~ 62 II, 16| 16.~ ~As one kanna of water wighs 6 skålpund, 8 lod, 63 II, 16| draw 189000 skålpund of water in an hour. The machine 64 II, 16| 472 skeppund, 10 lispund water~ ~ 65 II, 17| thus containing 4 kannor of water, -- as has already been 66 II, 17| every foot contains 4 kannor water~ ~ ~ 12 kannor~ ~ 14 lifts~ ~ ~ 67 II, 17| 420~ ~ ~ 5040 tunnor water in 24 hours~ ~The force-work 68 II, 17| 157 skeppund, 10 lispund water per hour.~ ~ 69 II, 18| the previous quantity of water, which the machine draws 70 II, 18| amount will be 20060 tunnor water per twenty-four hours which 71 II, 18| adds to the weight of the water which the machine draws 72 II, 18| an incredible weight of water which the machine is able 73 II, 20| the expenditure of drawing water from the mines can be made 74 II, 20| with the old way of drawing water by means of horses, which 75 II, 20| the machine has to draw water is 30 klafter or 180 feet;~ ~" 76 II, 20| to draw 117,600 skålpund water in an hour. (This machine, 77 II, 20| delivered 71,400 skålpund water less in an hour than the 78 II, 20| be able to draw all the water from the mine, they decided 79 II, 20| a machine for pumping-up water from the same depth as the 80 II, 20| artifice has drawn 25 feet water per minute by means of two 81 II, 20| subtracting the 25 feet of water which the horse-artifice 82 II, 20| been lifting 53 feet of water more than the horse-artifice.~ ~" 83 II, 21| machine delivers 78 feet water per minute, which makes -- 84 II, 21| contains four kannor of water, -- 312 kannor per minute.~ ~ ~ ~ 85 II, 21| delivering 504 kannor of water per minute.~ ~ ~ ~This machine 86 II, 22| draw the same quantity of water in 24 hours as 66 horse-whims, 87 II, 22| if I take the quantity of water which the machine is able 88 II, 23| more than 60 big tubs of water in 12 hours, even if the 89 II, 24| tubs, quite filled with water, are drawn in a day or 120 90 II, 24| in 24 hours~ ~ 120 kannor water in each tub~ ~ 120 tubs~ ~ ~ 91 II, 24| constitutes a larger quantity of water than any horse-whim is able 92 II, 24| to draw 20060 tunnor of water, and that 66 horse-whims 93 II, 24| draw each 300 tunnnor of water in 24 hours, or altogether 94 III, 26| machine is, when made to draw water from great depths, can partly 95 III, 28| saw 4 mills driven by the water which came out of a single 96 III, 28| which are so flooded with water, that they keep 1,2,3 or 97 III, 30| houses with a supply of water for daily use, and this 98 III, 30| several 1000 hogsheads of water, which from this reservoir 99 III, 30| One of the taps provides water for daily use, whilst the 100 III, 30| supplied with plenty of water. It thus seems impossible, 101 III, 30| which the machine supplies water by means of force-work, 102 III, 34| vicinity of Liége draws water from a coal mine; But the 103 III, 34| supplies the fountains with water, as Professor Weilderus 104 III, 35| small cost empty the dock of water in 8 or 12 hours, in case 105 III, 35| to draw about 9000 tunnor water per hour can be proved in 106 III, 35| machine, instead of drawing water out of a 9 inch pump, would 107 III, 35| pump, would be able to draw water of six 9 inch pumps, not 108 III, 35| it would be able to draw water out of the dock by more 109 III, 35| able to deliver 8820 tunnor water per hour.~ ~If such a machine 110 III, 38| drawing so many 1000 tunnor of water per hour, would quite well 111 III, 38| keep the locks clear from water, for as long a period as 112 III, 38| in the city itself with water every day in the same way 113 III, 38| toil they have in bring water home for daily use, could 114 III, 38| nor only be furnished with water daily but also saved from 115 III, 39| the machine would supply water and keep it always filled 116 III, 39| always filled and from which water could be supplied to any 117 III, 40| accidental fire sufficient water can be had high up under 118 III, 41| and conduits with running water in all the open places without 119 III, 41| market place, from which water would right high up in the 120 III, 41| to this be drenched with water in case of fire.~ ~How much 121 III, 41| supplying the town with running water from fountains and the houses 122 III, 41| with a sufficient supply of water in case of fire.~ ~We need 123 III, 41| if a sufficient supply of water had been accessible at all 124 III, 41| useless if the supply of water runs short and the fire 125 III, 41| upper-hand whilst waiting for water.) is supplying a fountain, 126 III, 41| Vienna is able to throw water perpendicularly 10 or 12 127 III, 43| derive their power from water and winds, as for instance 128 III, 43| and winds, as for instance water wheels and wind-mills which 129 III, 43| upon running or falling water and cannot thus be placed 130 III, 43| certain part of the power of water can be utilized, and this 131 III, 44| have a certain quantity of water enclosed in a dam and think 132 III, 44| requires a double amount of water, so that if the same quantity 133 III, 44| if the same quantity of water proved sufficient to keep 134 III, 44| the insufficiency of the water power or the means of transmitting 135 III, 44| any other way of drawing water out of a great depth than 136 III, 46| form of the weight of the water is brought to bear, pushing