DE7814391U1 - OXYGEN HOSE - Google Patents

Description

The invention relates to an oxygen hose between an oxygen source and the tubular body of an oxygen lance or a flame device.

When burning with an oxygen lance, especially a fresh lance in ironworks, there is a risk that the high pressure oxygen in the oxygen hose will come into contact with glowing slag or iron parts, so that there is a risk of explosions. Such explosions are caused, for example, by slag, which flows back into the oxygen hose after the end of or when the blowing process is interrupted by the oxygen lance. From DE-PS 24 47 723 the proposal is known to stop the slag flowing back by a fuse. This safety device closes a valve which is located in the tubular body that receives the oxygen lance. The previously known protection has reduced the existing dangers, but explosions cannot be ruled out, since a backflow of slag cannot be completely ruled out. The oxygen hose, which is under high pressure, can also be damaged from the outside, so that this also creates the risk of explosions.

The present invention has for its object to be a

Developing oxygen smart that reduces the risk of explosions as much as possible if the oxygen hose is damaged.

According to the invention, this object is achieved in that a conductor loop extending over the length of the hose acts as a current-carrying conductor in the wall of the oxygen hose
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for a release device with a quick-acting valve
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Oxygen source is embedded. The conductor loop can, for example, in the area of the printed fabric between the core and the
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of oxygen
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be incorporated and preferably extends in a spiral over the length of the hose. A thin copper wire, for example, is suitable as a conductor loop. The conductor loop, which is designed as a current-carrying measuring loop,
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Trigger member in connection, which is arranged at the oxygen source when the current is interrupted
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closes. This ensures with certainty that if the oxygen hose is damaged, no more oxygen can be delivered from the oxygen source. It has been shown to be beneficial if that
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is designed as a three-way valve, so that after
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the quick-closing valve, the high-pressure oxygen can escape to the outside through the quick-closing valve.

According to a particularly preferred embodiment, at least the hose end to be coupled to the quick-release valve is equipped with a combined plug-in coupling which enables the gas supply and the conductor loop to be coupled in a common plug part (plug or socket). The common plug part (plug or socket) is characterized by a first part (plug or socket), on the circumference of which a second part (plug or socket) is arranged, with a passage from the first part to the second part, around the implementation to enable the conductor loop. Preferably, the common plug part is attached to the hose end, while the common

Sleeve part is arranged on the pipe section leading to the quick-acting valve or on the pipe body. The common plug part with the combined plug-in coupling opens up the possibility of using a single one

Plug-in process to establish the gas supply and the connection of the conductor loop, so that no operating errors can occur. The trigger element is designed in such a way that the quick-release valve only holds the quick-release valve in the open position when the connection is plugged in and the measuring loop is live.

The conductor loop can extend to the coupling part with which the oxygen hose is coupled to the pipe body. However, there is also the possibility of leading the conductor loop into the pipe body and arranging a temperature sensor there at the end of the conductor loop, which extends into the free pipe cross-section and actuates the triggering element in the event of a slag return due to the temperature increase.

An example of the subject matter of the invention is explained in more detail below with reference to the figures. Show it:

1 shows a schematic representation of an overall overview; 2 shows a section of the oxygen hose in a longitudinal view (partially in section); 3 shows a cross section through the oxygen hose; and FIG. 4 shows a schematic representation of a coupling part of the oxygen hose.

The overview in Fig. 1 shows the oxygen source 1, the quick-closing valve 2 with trigger element 7, the oxygen hose 3, each with a coupling 4 at the end of the hose, the tubular body 5 and the oxygen lance 6, following the path of the oxygen.

As FIGS. 2 and 3 show, a conductor loop 8 consisting of two insulated copper wires is vulcanized into the wall of the oxygen tube 3. The conductor loop 8 is located in the area of the fabric 9 between the rubber liner 10 and the rubber outer jacket 11. As FIG the wires are breaking. The conductor loop 8 can extend into the vicinity of the coupling part 4, which forms the connection to the tubular body 5. However, there is also the possibility of leading the conductor loop through the coupling 4 into the tubular body 5, as is indicated in the schematic illustration in FIG. 1. In this embodiment, it is advantageous to arrange a measuring element, e.g. a measuring resistor, a thermocouple, a bimetal, at the end of the conductor loop 8 arranged in the tubular body 5, which protrudes into the free pipe cross-section and, when the slag returns, the triggering command is sent to the triggering element due to the temperature increase 7 there.

Fig. 4 shows a coupling part, designated as a whole by 4, which is located at each of the hose ends. It is a combined plug-in coupling 4 with a common plug part (plug or socket) for the gas supply and for the conductor loop 8. In the embodiment shown in FIG 2 leading pipe socket 19 is attached. The common connector part consists of a first connector part 15 surrounding the hose 3 and a second connector part 16 arranged on its circumference. A passage 17 leads from the first connector part 15 to the second connector part 16. The two wires of the conductor loop 8 are guided through this passage 17.

The oxygen hose 3 is pressed against the inner wall of the first plug part 15 through a screwed-in hose nozzle 20, so that a gas-tight seal is ensured. The part of the hose nozzle 20 protruding from the first plug part 15 represents the coupling plug. This coupling plug engages in the first socket part 14 and is held in position by two bolts 21 after it has been inserted. Two O-rings 22 serve to seal against the first socket part 14. The second socket part 18, which is used to accommodate the electrical connector parts required for the conductor loop 8, is arranged on the circumference of the first socket part. As the figure shows, the two parts of the conductor loop 8 are connected to one another by a conventional electrical plug connection. In the embodiment shown, it is essential that a common plug part and a common socket part enable the gas supply and the connection of the conductor loop 8 by means of a plugging process, with a gas-tight seal and, at the same time, a secure connection for the conductor loop 8 being provided. Analogously to the example shown in which the common plug part is attached to the hose end, the common socket part can just as well be attached to the hose end, while the plug part would then be arranged on the pipe socket 19 or on the pipe body 5. In this constructive alternative, the passage 17 would have to be provided in the common bushing part attached to the hose end.

In practical use, the conductor loop 8, designed as a current-carrying measuring loop, is under an explosion-proof measuring current. As soon as this measuring current is changed beyond a threshold value, the trigger element 7 closes the quick-closing valve 2. This can be done once by interrupting the conductor loop 8 and thus the current flow due to a violation of the oxygen hose 3, or by interrupting a measuring element arranged in the tubular body 5 An increase in temperature leads to a change in the measuring current. The trigger element 7 is constructed in such a way that the quick-closing valve 2 after a closing process is not reopened, so that after a malfunction in the hose, or possibly also in the tubular body, a new hose or a new tubular body must be used in any case. This construction ensures that even small damage that is not visible from the outside is reliably recorded and accidents during operation are avoided.

The construction for the hose and the quick-closing valve for a flame device would be analogous to the example described. The tubular body is then designed for the use of the flame device.

Claims (2)

1. Oxygen hose between an oxygen source and the tubular body of an oxygen lance or a flame device, characterized in that in the wall of the oxygen hose (3) a conductor loop (8) extending over the length of the hose as a current-carrying measuring loop for a triggering element (7) of the quick-release valve ( 2) provided oxygen source (1) is embedded. 2. Oxygen hose according to claim 1, characterized in that of the two hose ends at least the hose end to be coupled to the quick-closing valve (2) is equipped with a combined plug-in coupling (4) which has a first part (15 or 15) in a common plug part (plug or socket) . 14) and on the circumference of which has a second part (16 or 18) into which the conductor loop (8) passes through a passage (17) between the first part (15 or 14) and the second part (16 or 18 ) opens.