DE102011002876A1 - Controller for controlling density of gas e.g. sulfur hexafluoride used in e.g. high-voltage switching converter, generates malfunction signal and identification signal based on deviation of measured values from predetermined value - Google Patents

Abstract

The gas density controllers (1A-1C) comprise local data processing units (2A-2C) for detecting the functional test, and for monitoring the processing plant based on the measured values. The malfunction signal (3) and identification signal (4) are generated based on the deviation of the measured values from a predetermined value. The local data processing units are designed as microprocessors and are locally connected or integrated. The local data processing units are used to detect analog and digital signals. An independent claim is included for method for testing and/or monitoring gas density controllers.

Description

The invention relates to a gas density monitor with the features of claim 1, an apparatus for testing and / or monitoring a plurality of gas density monitors with the features of claim 7 and a method for testing and / or monitoring a plurality of gas density monitors with the features of claim 10.

In high or medium voltage systems, such. As high-voltage switchgear, converters, -tubleitern or transformers, a gas is often used as an insulator. Typically, gases such as SF ₆ , N ₂ , CF ₄ and / or compressed air (dried) are used as the insulator, and in principle other gases can also be used. The insulating gas prevents sparkover in high or medium voltage installations.

For the proper functioning of the high and medium voltage systems, it is necessary that the insulating gas remains safely in the system, otherwise the functionality of the high or medium voltage systems is no longer guaranteed. The pressure in the systems can z. B. through leaks over time decrease. The tolerable leaks are so low that accurate monitoring is necessary.

When monitoring the operation of high or medium voltage installations, gas density monitors are used which react to certain preset limit values. Basically, such gas density monitor z. B. from the DE 102 32 823 A1 known.

Since high demands are placed on the function of the gas density monitors in the monitoring of systems, an exact functional test is necessary in the production of the gas density monitor. As a rule, a large number of gas density monitors (eg 30 to 60) are each subjected to a functional test with a large number of electrical connections (eg 9 to 12), in particular the production of the numerous electrical connections of the gas density monitors becoming one central data processing device is complex.

It is therefore the object of the present invention to provide in the production efficiently to be tested and / or efficiently monitored in operation gas density monitor and devices and methods for efficient testing and / or monitoring of gas density monitors.

The object is achieved by a gas density monitor which has a local data processing device for detection during a functional test and / or a monitoring of the gas density monitor resulting measured values. The functional test can z. B. during the production of the gas density monitor. The monitoring of the gas density monitor can z. B. in use in the monitoring of a high or medium voltage system. The term measured value is to be understood here in general, d. H. also the detection of a digital (0-1) signal, such. B. a position signal of a contact of a microswitch (open, closed).

In the case of a deviation of the measured values from a predetermined limit value, a malfunction signal and an identification signal for the dysfunctional gas density monitor can be generated. The term limit value is also to be understood in general, since it also includes the detection of a predetermined digital switch position.

The malfunction signal and / or the identification signal can then be further processed in the course of a remote inquiry (eg by a central data processing device) during the testing and / or monitoring of the gas density monitors. This remote inquiry makes an analysis of contact positions possible.

It is advantageous if the data processing device is designed as a microprocessor and is locally connected to the gas density monitor or integrated with it.

Furthermore, it is advantageous if the local data processing device detects analog and / or electrical signals from terminals of the gas density monitor.

Advantageously, a comparison is made between the measured values detected by the local data processing device and the predetermined limit values by the local data processing device and / or by a central data processing device.

It is particularly advantageous if the measured values detected by the local data processing device result from volume changes of a reference volume, in particular deformations of a metal bellows, in the gas density monitor. This type of Gasdichtewächternn is widely used, which would be very complicated by the large number of electrical connections of the monitoring and / or examination effort without the inventive solution.

It is particularly efficient if the local data processing device emits the malfunction signal and / or the identification signal wirelessly.

The object is also achieved by a device having the features of claim 7. In this way, monitoring and / or functional testing can be carried out for a large number of gas density monitors, in particular in the form of a remote inquiry.

This makes it possible to record measured values during a functional test of the gas density monitors and / or monitoring a system with the gas density monitors at the gas density monitors, wherein a malfunction signal and an identification signal for a dysfunctional gas density monitor can be detected in the event of a deviation of the measured values from a predetermined limit.

Especially for a remote query, a central data processing device for detecting the malfunction signal and / or the identification signal of one of the gas density monitor is advantageous.

It is also advantageous if it is used to monitor a plurality of gas density monitors in a high or medium voltage system.

Likewise, the object is also achieved by a method having the features of claim 10, in which the plurality of gas density monitors is subjected to a monitoring program and / or monitoring.

In this case, measured values are registered by the plurality of gas density monitors during a functional test of the gas density monitor and / or monitoring of a system by gas density monitor, wherein in case of deviation of the measured values of a predetermined limit, a malfunction signal and a. Identification signal for a dysfunctional gas density monitor is registered and processed.

In the functional test, z. As in the context of the production of the gas density monitor, it is advantageous if the plurality of gas density monitors a test program, in particular an automatically run, subjected. From the large number of tested gas density monitors is so fast u. U. to identify incorrectly working.

Furthermore, it is advantageous if the malfunction signal and / or the identification signal of a gas density monitor from a central data processing device ( 5 ) is detected.

It is also advantageous if monitoring of a plurality of gas density monitors in a high or medium voltage system.

The invention will be explained in more detail below with reference to embodiments and figures. Show

1 a schematic representation of the electrical connections of a gas density monitor,

2 a schematic representation of an inspection or monitoring device for a variety of gas density monitors.

The invention will be described below with reference to gas density monitors 1 illustrated, which have a reference volume which is filled with the same gas as the gas space of the system to be monitored (eg., a high or medium voltage system, in 1 not shown for reasons of clarity). If at the same temperature in the gas space and in the reference space, a density difference occurs (ie by a leak), this is a trigger for the watchdog function.

The gas space and the reference space of the gas density monitor described here 1 are materially separated by a metal bellows. In case of a defect in the tightness, and a concomitant pressure change, the metal bellows is deformed or deflected. Due to this deformation or deflection, microswitches on the gas density monitor are connected via a selector rod 1 confirmed, which serve to provide information about certain functions of the gas density monitor 1 to signal.

In 1 are of an embodiment of the gas density monitor 1 the corresponding electrical connections 11 . 12 . 13 (first microswitch: alarm); 21 . 22 . 23 , (second microswitch: lock); 31 . 32 . 33 (third microswitch: lock, redundant to the second microswitch). In principle, it is also possible to occupy the microswitches differently or to use a different number of microswitches.

In the illustrated embodiment, the electrical connections 11 . 12 . 13 . 21 . 22 . 23 . 31 . 32 . 33 arranged concentrically. For other types of housing, the electrical connections 11 . 12 . 13 . 21 . 22 . 23 . 31 . 32 . 33 can also be arranged in a different form.

The connections 11 . 12 . 13 . 21 . 22 . 23 . 31 . 32 . 33 are assigned to three micro-switches, by means of which the state of the gas density monitor 1 is detectable.

The first microswitch can be two switch positions 12 . 13 taking. A first switch position 12 indicates that the standard density of the gas density monitor 1 is present. If the standard density falls below a predetermined limit value, the first microswitch switches to the second switch position 13 ; There is an alarm situation.

The second microswitch can also be two switch positions 22 . 23 assume, but here falls below another limit value, a blocking function is triggered, which prevents the monitored system can go back into operation.

The third microswitch is analogous to the second microswitch, the switch positions 32 . 33 are formed equal to the switch positions of the second microswitch. Here, redundancy is intentionally provided, since both microswitches must be switched to the same, so that the gas density monitor 1 monitored system is locked.

Furthermore, in 1 a microchip as a local data processing device 2 for data of the gas density monitor 1 shown. The connections of the local data processing device 2 with the electrical connections 11 . 12 . 13 . 21 . 22 . 23 . 31 . 32 . 33 is shown by dashed lines. The function of the local data processing device 2 is shown in more detail below.

Should a variety of gas density monitors 1 in the manufacture of the gas density monitor 1 be checked, so would a wiring of all connections 11 . 12 . 13 . 21 . 22 . 23 . 31 . 32 . 33 lead to a considerable amount of cabling. Assuming a review of 60 gas density monitors 1 each with 3 micro-switches with 3 contacts, so 540 wires must be laid. Typically, several kilometers of cables have to be laid.

This is a very large installation effort and cost factor. Also, it is not unlikely that there are so many wrong connections with so many wire connections, which further increases the examination effort. As will be described later, this plurality of wires can be replaced by two wires, which reduces the wiring effort involved in testing the gas density monitors 1 reduced.

The same advantage is in monitoring the gas density monitor 1 achievable during use in plant monitoring. In the monitoring of high or medium voltage systems, a variety of gas density monitors 1 used, which must be monitored during operation.

In any case, the cabling effort can be reduced if the individual gas density monitors 1A . 1B . 1C (Be it in the functional test during manufacture and / or when checking a system in operation), each with a local data processing device 2A . 2 B . 2C for detecting the switching state of the gas density monitor 1A . 1B . 1C are equipped. The detection of the switching states (or more generally the measurement of relevant measured values) can thus during the verification of the gas density monitor 1 during production or during real use in plant monitoring.

The local data processing device 2A . 2 B . 2C is designed as a microprocessor, the circuit state of the respective terminals 11 . 12 . 13 . 21 . 22 . 23 . 31 . 32 . 33 can capture. Examples of such microprocessors are PIC 16F84 or PIC 16F690.

When testing the gas density as part of a test program at different temperatures, the switching reactions of the gas density monitor 1 measured. The following table indicates, by way of example for one exemplary embodiment, which nominal values (limit values) apply to the switching points of the first switch at some temperatures. Test temperature [° C] Target range switching point first switch [bar overpressure] -30 3.77 to 3.93 -25 3.89 to 4.05 20 5.02 to 5.18 50 5.77 to 5.93

In this embodiment, the target range is linear, d. H. there are no breakpoints. In other embodiments, other temperatures may be used. It is also possible that the desired range may have break points.

If now during the test at a gas density monitor 1A a deviation from the setpoints is detected, switches the first switch of the relevant gas density monitor 1A um, what of the corresponding local computing device 2A of the gas density monitor 1A is detected. This triggers a malfunction signal 3 and an identification signal 4 out. The malfunction signal 3 indicates that the first switch of the gas density monitor 1A changed his switch position. The identification signal 4 indicates which gas density monitor 1A from the large number of tested gas density monitors 1A . 1B . 1C is responsible for triggering the change of contact position.

In an analogous manner, a use of the gas density monitor 1A . 1B . 1C with data processing devices 2A . 2 B . 2C during use in monitoring installations. The basic structure in 2 is shown applies to both cases.

The identification of the gas density monitor 1A can z. B. by individual address (digital) at the test positions in the switchgear or test cabinet done their information from the local data processing device 2A is read out. The malfunction signal 3 (Also referred to as contact monitoring signal) and the identification signal 4 can as a record to the central data processing device 5 be transmitted, for. B. also wireless.

It is also possible that the identification signal 4 additionally or alternatively generates an optical signal (eg by a light-emitting diode) to the faulty gas density monitor 1A among the multitude of verified gas density monitors 1A . 1B . 1C easier to recognize.

If the data transmission is by cable, only two cables are required for this type of data transmission, the switchgear or the test chamber with the large number of gas density monitors 1A . 1B . 1C with the central data processing device 5 connect with each other. By the central data processing device 5 is thus a constant function check of the large number of gas density monitors 1A . 1B . 1C possible.

In the test program or the monitoring of the variety of gas density monitors 1A . 1B . 1C But not only the switching position of the first switch is monitored, but also the other two switches.

The second and third switches switch at a pressure lower than the lower limit for the first switch, e.g. B. at a pressure difference of 0.22 to 0.33 bar. When these switch positions are triggered, this is also done by the local data processing device 2 determined and registered. In a similar way, a malfunction signal 3 and an identification signal 4 generated and sent to the central data processing device 5 transmitted.

In principle, it is possible that inexpensive microchips for the local data processing device 2A . 2 B . 2C permanently on the gas density monitors 1A . 1B . 1C remain.

Alternatively, it is also possible that the local data processing device 2A . 2 B . 2C not just the data of the electrical connections 11 . 12 . 13 . 21 . 22 . 23 . 31 . 32 . 33 recorded and the contact position, malfunction and identification signals 3 . 4 but also makes the comparison of the actual and the desired values. This would require the local data processing device 2A . 2 B . 2C save corresponding information.

LIST OF REFERENCE NUMBERS

1, 1A, 1B, 1C

Gas-tight guard

2, 2A, 2B, 2C

local data processing device on gas density monitor

3

Malfunction signal

4

identification signal

5

central data processing device

11, 12, 13, 21, 22, 23, 31, 32, 33

z. B. electrical connections to the gas density monitor

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10232823 A1 [0004]

Claims (13)

Gas density monitor ( 1A . 1B . 1C ) with a local data processing device ( 2A . 2 B . 2C ) for detection in a functional test of the gas density monitor ( 1A . 1B . 1C ) and / or monitoring a system with a gas density monitor ( 1A . 1B . 1C ) at the gas density monitor ( 1A . 1B . 1C ) in the case of a deviation of the measured values from a predetermined limit value, a malfunction signal ( 3 ) and an identification signal ( 4 ) for a dysfunctional gas density monitor ( 1A . 1B . 1C ) is producible. Gas density monitor according to claim 1, characterized in that the local data processing device ( 2A . 2 B . 2C ) is designed as a microprocessor and locally with the gas density monitor ( 1A . 1B . 1C ) or integrated with it. Gas density monitor according to claim 1 or 2, characterized in that the local data processing device ( 2A . 2 B . 2C ) analog and / or digital electrical signals from terminals ( 11 . 12 . 13 . 21 . 22 . 23 . 31 . 32 . 33 ) of the gas density monitor ( 1A . 1B . 1C ) detected. Gas density monitor according to at least one of the preceding claims, characterized in that a comparison between those of the local data processing device ( 2A . 2 B . 2C ) measured values and the predetermined limit values by the local data processing device ( 2A . 2 B . 2C ) and / or by a central data processing device ( 5 ) he follows. Gas density monitor according to at least one of the preceding claims, characterized in that the data from the local data processing device ( 2A . 2 B . 2C ) measured values from volume changes of a reference volume, in particular deformations of a metal bellows, in the gas density monitor ( 1A . 1B . 1C ) result. Gas density monitor according to at least one of the preceding claims, characterized in that the local data processing device ( 2A . 2 B . 2C ) the malfunction signal ( 3 ) and / or the identification signal ( 4 ) wirelessly. Apparatus for testing and / or monitoring a plurality of gas density monitors according to at least one of claims 1 to 6, characterized by a data processing device ( 5 ) for recording during a functional test of the gas density monitor ( 1A . 1B . 1C ) and / or monitoring a system with the gas density monitors ( 1A . 1B . 1C ) at the gas density monitors ( 1A . 1B . 1C ) in the case of a deviation of the measured values from a predetermined limit value, a malfunction signal ( 3 ) and an identification signal ( 4 ) for a dysfunctional gas density monitor ( 1A . 1B . 1C ) is detectable. Device according to claim 7, characterized by a central data processing device ( 5 ) for detecting the malfunction signal ( 3 ) and / or the identification signal ( 4 ) one of the gas density monitors ( 1A . 1B . 1C ). Apparatus according to claim 7 or 8, characterized in that thus a monitoring of a plurality of gas density monitors ( 1A . 1B . 1C ) takes place in a high or medium voltage system. Method for testing and / or monitoring a plurality of gas density monitors according to at least one of claims 1 to 6, characterized in that measured values of the plurality of gas density monitors ( 1A . 1B . 1C ) during a functional test of the gas density monitors ( 1A . 1B . 1C ) and / or when a system is monitored by a gas density monitor ( 1A . 1B . 1C ), wherein in the case of a deviation of the measured values from a predetermined limit value, a malfunction signal ( 3 ) and an identification signal ( 4 ) for a dysfunctional gas density monitor ( 1A . 1B . 1C ) is registered and processed. A method according to claim 9, characterized in that in the case of a functional test the plurality of gas density monitors ( 1A . 1B . 1C ) undergo a test program. Method according to claim 9 or 10, characterized in that the malfunction signal ( 3 ) and / or the identification signal ( 4 ) of a gas density monitor ( 1A . 1B . 1C ) from a central data processing device ( 5 ) is detected. Method according to at least one of claims 10 to 12, characterized in that a monitoring of a plurality of gas density monitors ( 1A . 1B . 1C ) takes place in a high or medium voltage system.

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