DE155397C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

When removing liquefied gases such as liquid carbon dioxide and the like., From the Storage containers is known to easily freeze the valves BEZW. the Outflow openings and an obstructive formation of gas snow. In order to remedy this problem, one has to look for different, often quite simple means, which are all based on the basic idea,

ίο a heating of the liquefied gas from to bring about from the outside. The simplest remedy is to use the reducing valve wrapped in a warm cloth, another remedy is warming of the liquid gas contained in the storage container by passing through Steam or some other heating means, and a third known aid, for example in patent 106302 is that between carbon dioxide bomb and reducing valve a heatable water tank is provided through which the carbonic acid line is passed through.

These aids were sufficient for the previous needs. Totally inadequate but if large amounts of the liquid gas are withdrawn from the storage containers very quickly, for example when deleting

Ship fires or the like caused by carbonic acid. With such rapid consumption A heatable water tank such as patent 106302 would not be remotely capable of large amounts of carbonic acid enough, it would have to be the size of a steam boiler and still maybe not even enough. In addition, such a heatable container would between the carbon dioxide bomb and the reducing valve the practical needs for one such a case cannot be sufficient, because the heating would then be the same as with a steam boiler require several hours, during which time the fire would have long been must be deleted. On the other hand, in the application of such, lies between The carbon dioxide bomb and the reducing valve switched on an extraordinary heating source There is a danger that, if the consumption of carbonic acid stops as a result of some circumstance, a disadvantageous increase in the heating effect on the carbon dioxide contained in the container takes place and as a result an explosion can easily be caused.

According to the present invention is now intended, especially for those cases in which a rapid consumption of large amounts of carbonic acid takes place, a freezing of the

to prevent liquefied gas, but the whole device quickly usable and to make it self-regulating.

This is achieved by using a heat source, the principle one The difference, however, is that, as before, the gas is not in its liquid state is heated, but rather only after its exit in the state of the evaporator ^.

ίο Then the heating medium comes into contact with the gas in a finer distribution, as a result, it can work better and it is also not a dangerous retransmission to fear on the storage container, since only the gas particles are heated, that have already flowed out.

A device for performing this type of heating is shown in the drawing
in Fig. ι in longitudinal section,

in Fig. 2 in cross section
shown schematically.

The liquid gas comes out of the storage container through a pipe α. This tube a opens into a second further tube b, which is passed through a box or a housing c . The heating medium is introduced into the box at d; it flows over the ribs e attached to the tube b in such a way that it forms a serpentine «! Describes the way around the pipe b and finally flows off at f. The tube α is closed at the mouth and has an inclined or spiral slot g. As a result, the outflowing liquid gas is directed at an angle against the inner wall of the tube b , hits the wall under pressure, splits, evaporates as a result of the widening of the cross section of the tube b compared to the clear cross section of the slot g and flows through in a spiral path the tube b. The gas flow thus sweeps the entire inner pipe wall, so that the individual gas particles continuously heat up on the wall of the pipe b. A reliable, extensive effect is thus achieved, but a reaction through the tube α on the storage container is prevented.

The ribs in the vessel c not only serve to guide the flow of heat medium, but they also transfer the heat directly through their conductive capacity to the pipe b, which is also heated from the outside by the heat medium itself. As a heating medium, water is more conveniently used. Temperature is used so that a special heating source is not necessary.

The reason why with ordinary water, which is known to be cooler than the liquid Is carbonic acid, a vigorous warming can be achieved, lies precisely in the fact that not, as usual, the liquid carbonic acid, but the finely distributed vaporized bezvv. evaporating gases are washed by the water. The cold is only just starting to form in the evaporation and the freezing otherwise takes place through the return of the cold instead of.

The fact that in the new device shown, for example, the tube α still extends somewhat into the housing c has no effect on the effect, but rather only happened for practical reasons so that the tube α sits firmly and tightly in the device. The liquid carbon dioxide in the tube α does not heat up because the carbon dioxide flows through the tube α too quickly (approximately in ₁₀₀ seconds) and because (as already mentioned) the heating medium is colder than the liquid carbon dioxide.

The temperature conditions are roughly as follows:

The liquid carbon dioxide has a temperature of about ⁰ C -J-15, so can not be heated by the continuous current through the apparatus water of about +10 ⁰ C.. In the evaporation of carbon dioxide, however, a strong cold formation occurs because the snow formation occurs at about - 65 ⁰ C. These cold gases can thus substantial amounts of heat from the 10 ⁰ C. warm water absorb and are thus unable to snow formation.

Claims (3)

Patent claims: ι. Device to prevent freezing and snow formation during removal large quantities of liquefied gases (such as liquid carbon dioxide) from storage containers, characterized in that the gas is only heated after it has emerged from the outflow opening in the finely divided state During the evaporation takes place in that the jet of the same as the liquid gas flows out of the discharge opening is directed against a heatable wall, on which it is distributed in the event of a collision. 2. An embodiment of the device according to claim I, characterized in that the outflow tube (a) of the liquid gas with an inclined or spiral slot (g) opens into a tube (b) of larger diameter forming the heating wall, such that the gas flow with simultaneous expansion and evaporation Describes a spiral path and brushes the inner surface of the pipe (b) forming the heating wall. 3. Eine .Ausführungsform the device according to claim 2, characterized in that the tube (b) forming the heating wall is provided with ribs (e) and is enclosed by a box (c) in such a way that the heating medium is the outflow opening and the heating wall forming tube in a serpentine path, the ribs (e) simultaneously serving in a manner known per se for heat transfer. 1 sheet of drawings, Berlin, printed in the Reichsdruckerei.