DE655311C - Device for preventing excessive gas discharge from an oxygen cylinder or other high-pressure container - Google Patents

Description

The invention relates to a device for preventing excessive discharge velocity of the gas from an oxygen cylinder or other high pressure container and consists in that a closure member is provided which is held by a spring from its seat and closed by the outflowing gas against the action of this spring can be, but in the closed position still a narrow passage to compensate for the Press in front of and behind the closing organ. The closing body expediently possesses in its end face facing the inlet of the gas, a bore into which a tube can also protrude from which the gas is directed to the closure member.

A large part of the well-known overpressure

ao valves has a spring that presses the valve body against the valve seat. Furthermore are valves are also known in which a narrow passage is still free in the closed position is serene. However, none of these devices are designed to prevent excessive discharge rates suitable for the medium.

. It has also become known a safety device for oxygen bottles whose Effect should be based on the use of appropriately sized compensation spaces. However, this device may be sufficient to an imperfect influence on the first opening pressure surge, but it can no regulation of the outlet speed during the operating process in its entire duration bring about and prevent the effect of pressure surges. The desired operational reliability is with this known device so not given.

In the subject matter of the invention, the flow of the pressure medium into the apparatus, which is located behind the outlet of the pressure chamber, controlled to the extent that only a slow flow in small amounts can take place at the same time. So if you are using the Invention on an oxygen cylinder suddenly opens the bottle caps (and this almost always happens due to the jamming of these closures), then it does not come suddenly the full pressure in the reducing

apparatus, but the pressure gauge pointer indicates that the pressure rises only gradually.

Some embodiments of the invention are shown in the drawing. Fig. Ι is a longitudinal section of a device according to the invention, and ^ j

Figure 2 is a cross section of the same through line H-II.

Fig. 3 is a longitudinal section of a second embodiment.

Fig. 4 is a longitudinal section of a third embodiment.

In Fig. Ι is with ι the union nut, by means of which the device can be screwed onto the oxygen cylinder. The outlet of this bottle is then formed by the channel 2 which is mounted in the coupling piece 3, which coupling piece is screwed into the tubular body 4 will. On the other end of the latter is a screw thread 5 provided, on which the reducer with the same union nut as under 1 can be screwed.

In the tubular body 4 there is a valve body 6. This consists on the one hand from the actual valve part 7 and on the other hand from the guide part 8. The valve part 7 lies in a narrowing of the bore of the body 4 and connects to the seat 9 the other end of the same; from here is the hole through the channel 10 with the right outer end of the device in connection.

A weak spring 12 is supported against the collar 11, which with the other End rests against the guide part 8 of the valve. The guide part 8 has a triangular shape Average, as can be seen from FIG.

If there is a sudden influx of pressure medium through channel 2, this blows the valve body 6 to the right, whereby the valve part 7 is pressed onto the seat 9 will. Although the closure on this seat has been taken care of as best as possible is by inserting a small steel ball 13 in the part 7, so is this conclusion is not completely tight against the high pressure of, for example 150 atm. However, this is precisely what is intended because the valve necessarily leaks have to be. This again shows that the device according to the invention is cheap can be kept because there are no special measures to keep the Valve needs to take; on the contrary, the leakage that occurs is useful use. Of course, it is not absolutely necessary to have that leakage occurs in the real sense; just as well can a special groove in the Seat or in the valve part, or it can even be a small circulation channel around the valve.

_{s <} -, Oxygen passes through the just described remaining passage along the valve part 7 (for example through a special channel 14) in small amounts into the channel 10. The pressure behind the valve thus increases slowly, that is, the reducing device comes on to be under pressure, and as soon as this pressure comes close to that prevailing in front of the valve, the spring 12 will push the valve 6 to the left. The outlet of the high pressure reservoir is then fully open, but since this opening took some time, there is no longer any danger as a result of a sudden outflow of the pressure medium.

The valve body 6 can with a Boh. tion 15 be provided in the head surface facing channel 2, so that a sufficient impulse effect of the entering pressure medium occurs and thus some pressure supply is formed to the left of the valve body to be sure to slide the valve to the right. In Fig. 3 it is indicated how the channel 2 ends in a tube 16 which protrudes into said bore 15, whereby the effect is further improved.

It is clear that the interposition of such a safety device would only decrease allows a certain maximum amount of the print medium at the same time. This comes down to the fact that you do not have more than on an oxygen cylinder a certain number of burners of a certain size can work simultaneously. This is of course another benefit. Incidentally, this maximum amount can be passed through Set replacement of spring 12. A stronger spring becomes_ a greater decrease enable. But if a hose flies off the burner or the reducer or if there is a break in the oxygen line in some other way, then it hits the safety device automatically closes again. This will cause the oxygen loss very limited and danger avoided. Fig. 4 (also with the same reference numerals) shows an even shorter version. The valve body 6 here has a round diameter and a very wide bore 15, into which the tube 16 protrudes. The flow along the valve body 6 must therefore entirely through the narrow ring slot. This gives you a larger gas decrease (Flying the hose) even more the overpressure and piston effect that

moves the body 6 to the right, in that a fairly large pressure drop from the occurs left to right side of body 6; the impulse or blowing effect of the Gases then has a less significant influence.

The maximum gas permeability is determined by the width of the ring slot between Valve body β and jacket 4 determined. If necessary, you can still do this reduce that the round body 6 with a wire spiral o. The like. Surrounds or that it is provided with a kind of piston spring. If necessary, one can then pass through the body small narrow channel to be drilled to get the necessary 'gas passage. The surface of the valve body 6 can be made somewhat concave (see. Fig. 4) to avoid danger Avoid jamming.

It is clear that the device, as described, can of course be directly connected to reducers combined, d. H. can be designed as a lower part of such.

Claims (3)

Patent claims: 1. Device for preventing excessive discharge of the gas from an oxygen cylinder or other high-pressure container, characterized by a closure member which is held by a spring from its seat and from the outflow Gas can be closed against the action of this spring, but still a narrow passage in the closed position to equalize the pressures in front of and behind the closing organ leaves free. 2. Apparatus according to claim 1, characterized in that the closure member has a bore in its end face facing the inlet of the gas. 3. Apparatus according to claim 2, characterized by a tube of which the gas is directed to the closure member, which tube protrudes into the bore of the closure member. 1 sheet of drawings