DE19925280C2 - Device for monitoring a line carrying a medium - Google Patents

Description

The invention relates to a device for monitoring a a medium leading pipe, with a membrane passing through it the medium can be acted upon and directly or indirectly carries the first switching element with a second Switching element forms a first spacer.

In the case of known solutions for detection desired or undesired flowing medium z. B. pressure differences, Flow rates, time differences or flow rates into Relation to flow time set and evaluated. Of further solutions are known in which membranes in Channels, bypass or ring lines are provided, which in combination with reed contacts an electronic evaluable signal for the actual state (whether medium flows or not seen. Here was also with z. B. Flow time or flow rates compared. On Detection of small quantities escaping in an uncontrolled manner Medium is in such a way in all known solutions and solved way.

However, if pressure differences, flow rates, Time differences or flow rates not in relation to Flow time is set, but the solution is only through  e.g. B. a membrane with reed contact as switching signal generator realized, then the detection of very small quantities uncontrolled flowing medium only from a certain Flow rate or flow rate possible, namely only when the distance covered (e.g. a membrane, coupled with a mechanism), is sufficient to e.g. B. one Operate reed contact and thus a switching signal trigger. This path may be short, but it is sufficient to let medium flow. That means it's possible this condition, if applicable, at a later point in time or not recognizable at all.

In a known device for monitoring the pressure and / or the velocity of liquid or gaseous Media in piping systems, especially the pressure in Lubricant lines (DE 32 02 571 A1) carries one in one Branch (the line carrying the medium) spanned Membrane a body, which during media-influenced movement changes the field line course of a fixed magnet, so that a magnetically controllable component responds.

The invention has for its object a generic To create a device that controls the smallest quantities or uncontrolled escaping medium quickly and safely recognizes.

According to the invention, this object is achieved through the features of Claim 1 solved. Advantageous further training result from the subclaims.  

A special feature of the device is that it Small amounts of flowing medium are immediately recognized and integrated electronically evaluable switching signal without converting Pressure differences, flow rates, time differences or Flow quantities in relation to flow time or the like compare or evaluate.

To determine and evaluate whether in a medium line or a medium line system medium controlled or escapes uncontrollably, and around an uncontrolled To prevent one from escaping, a system from the serves Arrangement of several devices, the respective Switch signals for a comparison evaluation to a corresponding circuit (e.g. comparison-and-or circuit) hand off. In this circuit the switching signals evaluated. Are there any irregularities in the evaluation? before, i.e. medium flows uncontrolled, causes the Circuit appropriate measures via a switching signal, for. B. the closure of the medium line by a shut-off device, e.g. B. a solenoid valve.

The invention is based on a Embodiment explained in more detail. In the associated Show drawings

Fig. 1 is a two spacer encoder having probe according to the invention, in which a diaphragm sealingly engaging a line,

Element that triggers an electrical switching signal when it comes into contact with the flowing medium. The membrane 1 is arched against the flow direction by an energy-storing element 4 (for example a compression spring) mounted on the guide 2 . Here, z. B. the membrane 1 itself act as a compression lock for the energy storage element 4 . A permanent magnet is e.g. B. attached to the membrane 1 or to the guide 2 so that it travels a path when moving the membrane 1 in connection with the guide 2 . On the guide 6 z. B. membrane side mounted a magnetic switch 11 so that this triggers a switching signal in the direction of flow when moving the membrane 1 with the guide 2 and the permanent magnet 10 mounted thereon. Here, the energy absorption element 15 attached to the membrane-side end of the guide 6 serves as a compression lock for the energy-storing elements 4 and 7 . If the membrane 1 with the guide 2 and the permanent magnet 10 is in the starting position, that is to say the membrane is curved counter to the direction of flow, the magnetic switch 11 does not emit a switching signal. In order to be able to evaluate the switching signal accordingly, the switching signal must be led out of the housing 8 by means of information carrier 14 (e.g. electrical cable). The membrane 1 seals with the sealing surface 3 on the sealing surface 5 of the housing 8 by the force of the energy-storing element 7 (e.g. compression spring), mounted in connection with the guide 6 movable in the flow direction and counter to the flow direction, on the energy absorption element 15 . The energy absorption element 15 transmits the force of FIG. 2, a corresponding sensor, in which a body receiving the membrane lies sealingly against the line, and

Fig. 3 is a block diagram with two sensors arranged in line ends.

Characterized by the special design of the sensor, mechanical movements are converted into electronically evaluable switching signals and forwarded for evaluation. The sensor detects even the smallest amounts of flowing medium. This is done by converting a mechanical movement into an electronic switch signal that can be evaluated. For this, e.g. For example, a reed contact or a magnetic switch can be used. The construction is designed in such a way that both controlled and uncontrolled escaping medium can be recognized and evaluated in the smallest quantities. The sensor separates (by means of a specially designed membrane, for example), like a backflow preventer, the medium line when the medium is not flowing. The fluidically specially designed membrane 1 is mounted on a guide 2 which is movable in the direction of flow and counter to the direction of flow. It is multi-walled, e.g. B. double-walled. An element for detecting irregularities is attached in the dense space which cannot be touched by the medium in such a way that an irregularity, e.g. B. recognizes a crack in the membrane wall and emits a switching signal. An element for detection is e.g. B. a moisture detector or other energy-storing elements 7 and 4 on the membrane. The movable guide 6 is supported in the fixed to the housing 8, the guide 9 so that sliding is possible in the direction of flow and against the flow direction in this guide. 9 Seen from the membrane 1 z. B. at the end of the guide 6 , ie on the guide side 9, another, the path of the guide 6 corresponding permanent magnet 12 is attached so that it moves in connection with the movement of the guide 6 in the direction of flow. On the guide 9 is z. B. another magnetic switch 13 is mounted so that movements of the guide 6 with the permanent magnet 12 lead in the flow direction to trigger a switching signal. In the starting position of the guide 6 , that is to say when the energy-storing element 7 is not compressed, the magnetic switch 13 does not emit a switching signal. In order to be able to evaluate the switching signal accordingly, the switching signal must be guided out of the housing 8 by means of information carrier 14 (e.g. electrical cable). The energy-storing elements 4 and 7 act counter to the flow direction, but the energy-storing element 7 is more resistant than the energy-storing element 4 . The two energy-storing elements 4 and 7 are arranged such that the force of the energy-storing element 4 and then the force of the energy-storing element 7 must first be overcome by the flowing medium in order to be able to flow unhindered.

Fig. 2 shows an embodiment of the invention, in which the sealing surface 3 on the body 15 and the permanent magnet 10 is arranged on a fixed bracket 16 adjacent to the membrane 1 , the permanent magnet 10 cooperating with a fixed magnetic switch 11 , which is designed here as a Hall sensor and is seated in a sleeve screwed onto the housing 8 .

The mode of action is as follows:

If medium flows in the direction of flow, pressure is exerted on the membrane 1 by the flowing medium and thus against the force of the energy-storing elements 4 and 7 . Consequently, the shape of the membrane 1 is first changed by yielding the energy-storing element 4 and moved in the direction of flow. Now the magnetic switch 11 is actuated by the permanent magnet 10 and a switching signal is emitted. At this time, the sealing surface 3 of the membrane 1, held by the more resistant energy-storing element 7 , is still in contact with the sealing surface 5 of the housing 8 and keeps the medium line tightly closed. Since the curvature of the membrane 1 and the compression path of the energy-storing element 4 is limited by the guide 2 , the force of the energy-storing element 7 is now overcome by the medium, the entire membrane 1 and the body 15 move in the direction of flow and allow the flow of the Medium. A further switching signal is thus emitted by the magnetic switch 13 in parallel to the switching signal from the magnetic switch 11 . Due to the special shape of the membrane 1 in terms of flow technology and the force of the energy-storing element 4 acting against the direction of flow, while the medium is flowing and the energy-storing element 7 is compressed, the membrane 1 is arched again against the direction of flow. The magnetic switch 11 therefore no longer emits a switching signal. However, since the magnetic switch 11 and the magnetic switch 13 are connected in parallel, a switching signal is still provided by the magnetic switch 13 for evaluation. If the flow of the medium ends, the energy-storing element 7 also returns to its original shape and presses the energy-absorbing element 15 and consequently the membrane 1 with the sealing surfaces 3 against the sealing surfaces 5 of the housing 8 . The medium line is tightly closed again, and the magnetic switch 13 also no longer emits a switching signal.

For the electronic evaluation and further processing of the data from the Electronic switching signals supplied to the sensors is a electronic element, e.g. B. a comparison - and - or Circuit, hereinafter referred to as circuit, necessary. The evaluation provides for at least two results. The Circuit can e.g. B. the result "no irregularity" or evaluate the result "irregularity". "No Irregularity "arises only when all deliver the same switching signal to the compared sensor. Different from the compared sensors delivered switching signals, the result is obtained "Irregularity". If the result is "irregularity" leads the circuit has a corresponding switching signal on Shut-off device, e.g. B. a solenoid valve, which then  The medium line is blocked and therefore damage is uncontrolled flowing medium prevented. Is the double-walled membrane leaking, is caused by the inside Humidity sensor triggered a signal indicating the error displays.

To monitor a medium line, an arrangement of at least two sensors is required. The switching signals supplied by the individual sensors by means of the downstream circuits S1 are compared by the circuit S2. The switching signals are hereinafter referred to as 1 for the switching signal "medium flowing" and as 0 for the switching signal "medium not flowing". For this purpose, a sensor, hereinafter referred to as M1, is installed as far as possible at the beginning of the medium line to be monitored and a further sensor, hereinafter referred to as M2, as far as possible at the end of the medium line to be monitored. If medium is removed from this medium line, this is recognized by both the M1 and the M2. M1 and M2 accordingly give the switching signal 1 to the circuit S2. If no medium is removed from this medium line, this is recognized by both the M1 and the M2. M1 and M2 accordingly give the circuit S2 the switching signal 0. However, a sensor, z. Bp. M1, the switching signal 1 and another sensor, z. B. M2, the switching signal 0 further, the circuit S2 detects an "irregularity" and gives the shut-off device A the switching signal to shut off the medium line.

The sensor is used to detect whether medium is flowing or Not. It recognizes even the smallest amounts of flowing medium immediately and, in the event of an accident, a corresponding Issue switching signal. Its particularly high sensitivity results from its sealing the pipe system Arrangement. This information can also be evaluated and processed accordingly. With one out several sensors existing system can be determined and evaluate whether in a medium line or a Medium pipe system medium controlled or uncontrolled escapes. Furthermore, an uncontrolled escape is said to occur of a medium can be determined and prevented.

Claims (18)

1. A device for monitoring a medium-carrying pipe, with a membrane (1) which can be acted upon by the medium and, directly or indirectly, a first switching element (10), constituting a first distance sensor with a second switching element (11), characterized characterized in that the membrane ( 1 ) is stretched transversely to the direction of flow and, with its central region arched against the direction of flow, is supported in the direction of flow on a first spring ( 4 ) with a smaller first spring force (F1) which in turn is supported by a guided body ( 15 ) is held, which is supported in the flow direction on a fixed second spring ( 7 ) with a larger second spring force (F2 <F1), and that the membrane ( 1 ) and / or the body ( 15 ) a the pressure-free line ( 8 ) have sealing sealing surface ( 3 ). 2. Device according to claim 1, characterized in that the body ( 15 ) directly or indirectly carries a third switching element ( 12 ) which forms a second spacer with a fixed fourth switching element ( 13 ). 3. Device according to claim 1 or 2, characterized characterized in that the distance sensors a first Circuit arrangement (S1) is associated with a signal provides when the first and / or second spacer a predetermined shortfall between the associated switching elements reports. 4. The device according to claim 3, characterized in that the second spacer reports a predetermined shortfall, while the sealing surfaces ( 3 ) of the membrane ( 1 ) or the body ( 15 ) seal the line ( 8 ). 5. A device according to claim 3 or 4, characterized in that the first spacer reports a predetermined shortfall after the sealing surfaces ( 3 ) of the membrane ( 1 ) or the body ( 15 ) from the inner jacket of the line ( 8 ) have detached. 6. Device according to one of claims 2 to 4, characterized in that at least two of them spaced line positions provided are, the first circuit arrangements (S1) second circuit arrangement (S2) is associated with a Operating signal delivers when the first  Circuit arrangements (S1) provide the same signals, and deliver a breakdown signal when the first Circuit arrangements (S1) different signals provide. 7. Device according to one of claims 1 to 6, characterized in that the body ( 15 ) is designed as a disc. 8. Device according to one of claims 1 to 7, characterized in that the body ( 15 ) on a in the line ( 8 ) guided guide rod ( 6 ) is fixed. 9. The device according to claim 8, characterized in that the guide rod ( 6 ) is guided in spaced rings, which are each held by arms ( 9 ) which are supported on the inner jacket of the line ( 8 ). 10. The device according to claim 8 or 9, characterized in that the third switching element ( 12 ) is arranged on the guide rod ( 6 ). 11. The device according to claim 9 or 10, characterized in that the fourth switching element ( 13 ) is arranged on one of the arms ( 9 ). 12. The device according to one of claims 1 to 11, characterized in that the membrane ( 1 ) is supported with its edge region on the body ( 15 ). 13. The device according to one of claims 1 to 12, characterized in that the membrane ( 1 ) is at least double-walled and accommodates a moisture detector in its interior. 14. Device according to one of claims 1 to 13, characterized in that the membrane ( 1 ) is connected to a guide ( 2 ) guiding the first spring ( 4 ). 15. The apparatus according to claim 14, characterized in that the first switching element ( 10 ) is arranged on the guide. 16. The apparatus according to claim 14 or 15, characterized in that the guide ( 2 ) forms a stop acting in the flow direction. 17. Device according to one of claims 1 to 16, characterized in that the second switching element ( 11 ) is arranged fixed in space or directly or indirectly on the body ( 15 ). 18. Device according to one of claims 1 to 17, characterized in that the spacer as Switching elements each have a permanent magnet and one Have magnetic switches.