DE10010913C1 - Device for monitoring gas density in high-voltage transmission lines filled with insulating gas has a high-voltage transmission line filled with insulating gas split into several line sections by bulkhead locations. - Google Patents

Abstract

A high-voltage transmission line (1) filled with insulating gas is split into several line sections by bulkhead locations (7) and has several measurement components (2) next to these locations to measure gas density and transmit measurement results to be analyzed by a signal processing device (3) and transmitted by a single light wave conductor (5,6). A source of light acting as a source of energy (4) feeds the measurement components.

Description

TECHNICAL AREA

The invention is based on a device for monitoring the Gas density of a high-voltage transmission line filled with insulating gas according to Preamble of claim 1.

The invention further relates to a method for monitoring the gas density of a insulating gas-filled high-voltage transmission line.

STATE OF THE ART

Devices for monitoring the gas density of are in the high voltage range known gas-insulated systems, for example, a central Signal processing unit and several electrical measuring components included. The Measurement components are powered by a central energy source. The one from the Measurement values supplied to measurement components are optically displayed, for example Optical fiber transmission.

In the area of high-voltage transmission lines, the supply of Measuring components not possible using electrical cables. The measuring components are arranged and monitored along the line over several kilometers line sections sealed off from one another. Several kilometers of energy with the low supply voltages, supply lines would be too large Have damping and consequently the losses would be too great. Therefore, the Measuring components fed by batteries, for example, but one need regular maintenance and also have a limited lifespan.

An optical signal transmission device is known from DE 195 12 771 A1, at which is a light source of an AC and a DC component emits superimposed light, which contains a signal and a power component. The light is transmitted from the light source to a field station via an optical fiber transfer. The field station includes an optoelectric converter, which in turn a light receiver for converting the signal component of the light into  an electrical signal and a light receiving arrangement for converting the Power component of light includes electrical power. The field station further comprises an electro-optical converter, which in turn is a light source for sending data.

SUMMARY OF THE INVENTION

An object of the invention is to provide an inexpensive device to create the type mentioned above, which even over larger distances maintenance-free and largely loss-free operation guaranteed. In addition, in one Process the gas density of a high-voltage transmission line filled with insulating gas be monitored by means of the device according to the invention.

The object is achieved according to claim 1. The are in the range of Partitions arranged measuring components for recording light waves trained, and several measurement components via a single as an optical fiber trained power supply line with a centrally located one Light source comprehensive energy source connected. Thanks to the low damping of the It is thus possible for optical fibers to achieve low power even over large distances some 10 km to transmit. A single, up to several km long optical fiber for the energy supply of several measuring components is cheaper to manufacture and to be maintained as separate optical fibers for each measuring component with one much larger total length.

The measuring components are either to be monitored at each bulkhead of a line section, or at every second bulkhead for monitoring in each case two adjacent line sections arranged. In the second embodiment the number of light sources and power supply lines can be significant be reduced.

In an advantageous embodiment of the device according to the invention, the Measuring component a capacitor. This buffers the energy source delivered energy and transfers it to the measuring component as required. This enables the measuring component to consume larger services at short notice constant low power.  

In a further advantageous embodiment of the device according to the invention are signal processing lines between the light diodes Measuring components and the signal processing unit containing light sensors as Optical fiber trained. A combination of the is particularly advantageous Power supply line with the signal processing line. So that is pro Measuring component only one optical fiber available.

In the inventive method of the type mentioned above, the Measuring component fed by the energy source with constant power Gas density is measured, the measured values are sent to the signal processing unit transmitted, and the measuring component is converted to a next active state Waiting state returned. Because the measuring component is in this waiting state consumes very little energy, the capacitor charges to the active state to be able to meet the increased energy requirements of the measuring component. The The process is characterized in that the one to be delivered by the energy source Performance can be kept constantly low.

The ratio is in an advantageous embodiment of the method according to the invention the duration of the active state to the duration of the waiting state of the measuring component less than 0.1, in particular less than 0.01. This allows in particular the several measuring components connected in series over a single one Feed the power supply line from an energy source.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred embodiments of the invention and the others achievable therewith Advantages are explained below with reference to drawings. Here shows:

Fig. 1 shows a part of a high voltage insulating gas transmission line having an apparatus for monitoring the gas density in the prior art,

Fig. 2 and 3 show two embodiments shown enlarged the present invention extended device of FIG. 1, with a measurement component, and

FIG. 4 shows a diagram with the supply and load current curve of the measuring component according to FIG. 2.

divided. A measuring component 2 for monitoring the gas density of the line 1 is arranged in each line section. The measurement components 2 are connected to a signal processing unit 3 via signal transmission lines 6 . The measurement components 2 are supplied, for example, by batteries which are mounted in each measurement component 2 .

Fig. 2 shows an embodiment of the inventive apparatus for monitoring the gas density of the insulating gas in line 1. A measuring component 2 is arranged in the area of at least every second bulkhead location 7 , which essentially consists of an energy processing unit 21 , a computing unit 22 and a sensor unit 23 . If a measurement component 2 is arranged only at every second bulkhead location 7 , it comprises two sensor units 23 for monitoring both adjacent line sections.

The energy processing unit 21 is supplied with energy by an energy source 4 containing a light source 41 via an energy supply line 5 in the form of an optical waveguide and an optoelectric energy converter 24 . Depending on the configuration of the monitoring device, the light source 41 contains one or more laser diode modules, each with an output of up to 500 mW. The energy processing unit 21 contains a capacitor, for example a low leakage current ELKO or an array of tantalum or ceramic capacitors, which stores the energy emitted by the energy source 4 and delivers it to the computing unit 22 if required.

The computing unit 22 , which essentially comprises a microprocessor, is used to control the sensor unit 23 , to record and process the values measured by the sensor unit 23 and to transmit the processed measured values via a light diode 25 , a signal transmission line 6 designed as an optical waveguide and a light sensor 31 to the signal processing unit 3rd

The sensor unit 23 is designed as a density sensor which directly measures the density of the gas in the pipeline and forwards corresponding values to the computing unit 22 . If the composition of the gas is known, the density could also be determined using a pressure and temperature measurement using appropriate sensors.

In a further embodiment of the device according to the invention as shown in FIG. 3, the light source 41 and the light sensor 31 on the one hand, the opto-electrical converter 24 and the light diode 25 on the other hand are one

The sensor unit 23 is designed as a density sensor which directly measures the density of the gas in the pipeline and forwards corresponding values to the computing unit 22 . If the composition of the gas is known, the density could also be determined using a pressure and temperature measurement using appropriate sensors.

In a further embodiment of the device according to the invention as shown in FIG. 3, the light source 41 and the light sensor 31 are arranged on one side, the opto-electrical converter 24 and the light diode 25 on the other side of a single optical waveguide 56 . Both energy and the measured values are thus transmitted through this one optical waveguide 56 .

As can be seen from FIG. 2 and FIG. 3, a plurality of measurement components 2 connected in series are arranged on an energy supply line 5 or 56 , which are fed from a single light source 41 .

In the method according to the invention for monitoring the gas density of the high-voltage transmission line 1 filled with insulating gas, the density of the insulating gas is measured at regular or irregular intervals from the measuring components 2 distributed along the line 1 and the measured values are transmitted to the signal processing unit 3 .

During a measuring process, the value of the density of the insulating gas measured by the sensor unit 23 is received by the computing unit 22 of the measuring component 2 and transmitted to the signal processing unit 3 in a correspondingly processed manner. After the completion of the transfer of the measured values, the measuring component 2 is led into a waiting state in which it remains until either a certain time has passed or until a corresponding signal is transmitted from the signal processing unit 3 for the purpose of measuring again. Then the measuring component 2 is brought into an active state again and the next measurement of the gas density is carried out.

The capacitor contained in the energy processing unit 21 of the measuring component 2 is continuously supplied with constant power by the energy source 4 . In the wait-state of the measured component 2, the capacitor is charged to cover for the needed in the active state of the measured component 2 increased energy demand of the measured component. 2 Is shown in FIG. 3, a common light waveguide 56 for power supply and signal transmission in the active state a of the Lasttrom I _L increases rapidly and is during this short time a much larger than the supply current I _SP. The additional current (I _L - I _SP ) is withdrawn from the capacitor, which quickly discharges itself as a result.

The power to be delivered by the energy source for a given energy requirement The measuring component is therefore dependent on the ratio of the duration of the active state a to Duration of the waiting state p.

The ratio is in an advantageous embodiment of the method according to the invention the duration of the active state a to the duration of the wait state p less than 0.1, in particular less than 0.01.

Thanks to the low average power requirement and the possibility of Intermediate storage of energy, several can be arranged in series Measuring components from one energy source over a single one Power supply line are fed.

Of course, the high-voltage transmission line, the gas density with the method according to the invention by means of the device according to the invention is monitored, only be formed from two line sections, which by a only bulkhead are divided.  

REFERENCE SIGN LIST

1

gas-filled pipeline

2

Measuring component

3rd

Signal processing unit

4

Energy source

5

Power supply line

6

Signal transmission line

7

Bulkhead

21

Energy processing unit

22

Arithmetic unit

23

Sensor unit

24th

opto-electrical energy converter

25th

Light emitting diode

31

Light sensor

41

Light source, laser diode module

56

optical fiber
I _L

Load current
I _SP

Supply current
a Duration of the active state (measuring and transferring)
p Duration of the wait state

Claims (10)

1. Device for monitoring the gas density of an insulating gas-filled, by bulkheads ( 7 ) divided into several line sections high-voltage transmission line ( 1 ), containing

• components ( 2 ) arranged in the area of the bulkheads ( 7 ) for measuring the gas density in the line sections and for sending measurement results,
• a signal processing unit ( 3 ) for receiving and evaluating the measurement results,

characterized in that

• the measurement components ( 2 ) are fed by a centrally arranged energy source ( 4 ) containing a light source ( 41 ) via at least one energy supply line ( 5 ) designed as an optical waveguide,
• - The measuring components ( 2 ) contain opto-electrical energy converters ( 24 ) for converting light into electrical energy, and
• - Several measuring components ( 2 ) are connected in series via a common power supply line ( 5 ) to the light source ( 41 ).

2. Device according to claim 1, characterized in that

• - A measurement component ( 2 ) is arranged at each bulkhead ( 7 ) for each line section.

3. Device according to claim 1, characterized in that

• - A measuring component ( 2 ) is arranged at every second bulkhead point ( 7 ) for every two adjacent line sections.

4. Device according to one of claims 1 to 3, characterized in that

• - The light source ( 41 ) comprises at least one laser module.

5. Device according to one of claims 1 to 4, characterized in that

• - The measuring component ( 2 ) contains a capacitor, in particular a low leakage current ELKO or an array of tantalum or ceramic capacitors for storing energy.

6. Device according to one of claims 1 to 5, characterized in that

• - The measuring components ( 2 ) contain light diodes ( 25 ),
• - The signal processing unit ( 3 ) contain light sensors ( 31 ), and
• - Signal transmission lines ( 6 ) configured as optical fibers are arranged between the measuring components ( 2 ) and the signal processing unit ( 3 ).

7. The device according to claim 6, characterized in that

• - The power supply line and the signal transmission line are combined in the form of a simple optical fiber ( 56 ).

8. A method for monitoring the gas density of an insulating gas-filled high-voltage transmission line ( 1 ) by means of a device according to one of claims 1 to 6, in which

• - The measuring component ( 2 ) from the energy source ( 4 ) is continuously supplied with constant power, and

repeating

• - the gas density is measured by the measuring component ( 2 ),
• - The measured value is transmitted to the signal processing unit ( 3 ), and then
• - The measurement component ( 2 ) is kept in a waiting state until the next measurement.

9. A method for monitoring the gas density of an insulating gas-filled high-voltage transmission line ( 1 ) by means of a device according to claim 7, wherein the repeating

• - The measurement component ( 2 ) is supplied with constant power from the energy source ( 4 ) during a wait state, then
• - the gas density is measured by the measuring component ( 2 ),
• - The measured value is transmitted to the signal processing unit ( 3 ), and then
• - The measuring component ( 2 ) is returned to the waiting state until the next measurement.

10. The method according to any one of claims 8 or 9, in which

• - The ratio of the duration of the measurement and the transmission of the measured value (a) to the duration of the waiting state (p) is less than 0.1, in particular less than 0.01.