DE67218C - Method of generating gases under pressure in order to obtain motive power - Google Patents

Description

IMPERIAL

PATENT OFFICE.

For the movement of torpedoes and other exploding projectiles, for Regulation of the movement of balloons and for various purposes is moving force required, the generation of which is of relatively little importance, if so only the same developing substance, as well as the necessary machines in proportion exceptionally light to the developed and practically usable strength. are. Previously, compressed air, liquid carbon dioxide and electric batteries were too. this Purposes used; but these have been found to be comparatively inadequate.

I replace this moving force with that which was caused by the previous reaction certain substances are developed which permit, with the aid of a simple and light apparatus to exploit that considerable force which they are able to develop.

These substances are metallic sodium or potassium, or alloys of these two metals, or finely powdered manganese, or one of those metals or those metal alloys which are used in Ordinary or slightly elevated temperature water or other, oxygen, Liquids containing chlorine, fluorine or sulfur decompose and thus gases or vapors develop whose expansion is able to generate moving force.

Sodium in connection with water breaks down the latter and combines with oxygen the same, evolving hydrogen gas; also in contact with fluorine, hydrogen acid, Hydrochloric acid and hydrogen sulfide gas are released from hydrogen, while in contact with sulfuric acid from the corresponding Concentration, sulfurous acid vapors can also develop.

The reaction of the metals or metal alloys referred to above with water causes this Development of high heat, which is also a source of moving force. When 23 g of sodium is brought into contact with 18 g of water, then develop 43.1 thermal units, which theoretically equates to a force of 182.30 kilograms or one get equal by 4 minutes of acting horse power; therefore theoretically produce 345 g Sodium 1 horse power for the duration of one hour or 10 horse power for those of 6 minutes.

In practice the results of the chemical reactions mentioned above will be obvious set significantly lower, but the loss is due to the small dimensions the necessary machine and the high pressure under which it can work by virtue of its construction, be low. The reaction of sodium or potassium with water and other liquids is an extraordinarily violent one and has almost the character of an explosion. This effect but can easily be mitigated by adding substances which have less affinity for Possess sodium or potassium. There are many such substances and are cited as such: Alcohol, glycerine, sugar, etc. But I prefer to use ammonia because of its chemical indifference to it the aforementioned metals and because of the large volume which it occupies,

when it is volatilized. Water of low temperature or under pressure absorbs one large amount of ammonia gas, which in the case of the reaction of sodium or potassium heat generated on water is released.

If 23 g of sodium act on a liquid consisting of 27 g of water and 85 g of ammonia (NH ₃ ) , the following results are obtained:

Of the 43.1 thermal units released, as stated earlier, 23 are required, to volatilize the 85 g of ammonia while the remaining 20.1 heat units serve to both the temperature of the 85 g of ammonia gas and the formed caustic soda solution (50 g) and the 1 g developed Increase hydrogen gas to approx. 2oo ° C.

The volume of ammonia and hydrogen thus produced and expanded at atmospheric pressure it would be about 210 edm.

Each cubic meter of gas to be generated would be about 109.5 g under the above conditions Sodium, 128.5 g water and 404 g ammonia or 642 g together.

The proportion to the water used must be regulated in such a way that it is through this the caustic soda produced dissolves the reaction, otherwise the reaction would be irregular and give rise to the formation of caustic soda crusts.

Any amount of water added above the above ratio causes the chemical reaction is accelerated.

From the data given above it can be seen that at the ratio of 85 parts Ammonia to 23 parts of sodium; the temperature of the evolved gas will be 200 ° C .; but if the reaction takes place under high pressure, this temperature can be reduced be considerably increased by reducing the ratio of ammonia and that of the water increased.

In practice these relationships must be regulated in such a way that they change according to the Set the pressure under which the ammonia gas is to be used.

This pressure is determined by the cross section of the inlet opening for the sodium or potassium or the alloy of these two metals, or regulated by a safety valve.

One must bear in mind here that the higher the pressure under which this signifies Gas is developed, the more benefits you get from its expansion and the more heat you get from this expansion is absorbed.

It is therefore desirable that the gas be evolved at a temperature which is high enough to replace, if possible, the heat absorbed by the expansion and to increase in this way to ensure the highest achievable efficiency.

Since the container in which the reaction takes place has very small dimensions can be so there is no reason not to push the pressure to a height of 50 to 100 atmospheres and even more to get; the supply of sodium or potassium too the water and ammonia mixture happens at a proportional speed.

The ammoniacal water is not the only liquid on which they named Metals or alloys exert a reaction and thereby develop gas, but it is the same most suitable for this purpose and ensures great regularity of effect, therefore, it is preferably used for the purpose described above.

For the practice of this invention I use a vessel which one withstands very high pressure and in which the materials to be reacted be brought into contact with each other.

This may in many ways ge ₇ Schehen, namely: a) Each of the two can each other acting substances individually and developed That the required amount of gas in a certain time are gradually injected in such an amount and in such Verhältnifs in the vessel,,, or b) the volume of the vessel is such that it already contains the whole quantity of ammonia and water which are necessary for developing the necessary force, in which case the sodium or potassium, or the respective alloy of both, alone is gradually introduced into the liquid to which it is supposed to exert the reaction.

Here the full mechanical effect is developed somewhat more slowly at the beginning because it It takes some time before the resultant reaction takes place in its entirety in the vessel Amount of water and ammonia can heat.

If sodium is used as an oxidizing agent, this metal must either be introduced into the vessel at a temperature at which it becomes liquid in which case it is then injected like any other liquid and distributed inside or when it is used in a solid state and at ordinary temperature it is pressed into the liquid through holes suitably made in the vessel been. This supply of sodium, potassium, or an alloy of both, can be done by hand to be effected; however, it is more advantageous to use a mechanical device for this purpose, which is arranged so that the supply according to the required force

and time during which it is to be applied.

If a very rapid supply is required, I mix it up, preferably with an ordinary one Metal reacting at temperature, like an alloy of sodium and potassium. By injecting the same in the finest Atomization easily gives a lively effect by which a a large amount of gas is evolved. This process offers due to the gradual supply no risk of explosion.

The higher the pressure is kept in the vessel, the less the liquid is in the Be able to squirt out (to mousse), in that the evolved gas then has a comparative effect takes up little space and therefore the liquid is less puffed up.

If sodium or potassium or an alloy of both on water or other Liquids should react, which mainly develop permanent gases, such as hydrogen, so is a machine or some other mechanical device for exploitation the developed force is not absolutely necessary because these gases when under a very high pressure against water or against air, an important one Develop forward or backward moving force.

As a rule, however, it will be cheaper and more practical to use the compressed gas produced in the same way as one now uses compressed air to power a machine or any other mechanical device that can develop moving force Food.

Fig. Ι the accompanying drawing shows a view in section of a suitable device for / generation of gas at high pressure for these and similar purposes.

Fig. 2 is a modification of the device shown in Fig. Ι.

A is a steel-made cylinder with rounded or dome-shaped ends that is strong enough to withstand even the highest pressure of the gas generated therein. A small hanging, cylindrical chamber B is attached to this cylinder or gas generator. This chamber serves to receive the sodium or potassium, or the alloy of both, which are necessary for the decomposition of the liquid in the cylinder A and are introduced into the same through a tube α. The cylinder A is either of such dimensions that it contains the whole amount of fluid which is necessary to produce the entire force required; or its dimensions are such that the supply of the liquid through the tube α occurs gradually and in proportion to the supply of the metal or the alloy.

In both cases it is indicated that the amount of water present is sufficient to to dissolve the metal oxide formed by the chemical action immediately after its formation and in this way to prevent it from covering the surface of the metal and thereby impairing the chemical reaction.

The cylindrical chamber B is closed at the top with a cover which is provided with a stuffing box cover through which a piston rod c passes.

The latter presses the metal in the solid, plastic state (if one is used) through the openings provided in the bottom of the cylindrical chamber B into the cylinder A. If the metal is not used in the above form, other means are used to carry it with it to bring the liquid into contact.

If you z. B. very porous manganese used in powder form, then is for the supply no higher pressure required and the same is done by means of a stirring or similar device. If the metal is used in a liquid state (as an alloy of Sodium and potassium), it is injected in a finely atomized form.

The valve housing D is connected to the housing A by means of a valve d regulated by a hand screw d or some other suitable arrangement, in order to determine the gas pressure to be maintained in the chamber A.

A pipe d ¹ is used to cool the compressed gas, which is to be used as a moving force with or without the aid of a machine.

The vessel A is provided with a manhole a ² for examining the inner space and in its bottom with an emptying pipe a ¹ . It also carries a manometer E so that the pressure of the gas inside the vessel can be seen at any moment; furthermore, a safety valve, such as those used in conventional boilers, can also be provided on the same.

If the metal is to be supplied by hand, the piston rod C is provided with a handle, by means of which the worker can easily depress the piston and, at the required moment, introduce the necessary quantity of fresh metal into the liquid.

In Fig. 2 a device is shown by means of which the supply of the metal takes place in an automatic manner. From the valve housing D , the inventor directs part of the gas into

Claims (1)

Another piston housing, which is attached to the outer end of the piston rod causing the supply of the metal, and by regulating the pressure by means of suitable differential valves F and G on both sides H and K of the piston, the same can be made to act in such a way that the supply of metal increases as the pressure in the chamber decreases as the reaction takes place. Godfather νt claims: i. A method of generating motive power by mixing materials such as metallic sodium, potassium, or alloys of these two metals, or finely powdered manganese, or corresponding metals or metal alloys with water or other liquids containing oxygen, chlorine, fluorine or sulfur Gradual and separate pressing or injection of the metal or metal alloy used and the respective liquid to be decomposed into a closed vessel or by pressing or injecting only the metal or the metal alloy onto the liquid already in the aforementioned vessel, thereby bringing hydrogen into contact , possibly also sulfurous acid gas, under a predetermined and controllable pressure and without the application of external heat. An embodiment of the by claim ι. characterized process in which, in order to moderate the effect of potassium, sodium or similar metal alloys on water or other liquids, alcohol, glycerine, sugar or ammonia is added to the water or the other liquids.
An apparatus for performing the by claim i. characterized process, consisting of the steel cylinder A with liquid inlet pipe a, valve housing D, valve d for regulating the gas pressure in cylinder A and the chamber B containing the metal or metal equipment used , with which the differential valves F and G are moved by hand or automatically by means of , the metal or the MetalUegirung in the liquid pressing piston C, and finally the outlet pipe d ¹ for the compressed gas. For this purpose ι sheet of drawings.