WO2022037971A1

WO2022037971A1 - Switchgear for medium and/or high voltages, and method for data exchange in the switchgear using an optical waveguide

Info

Publication number: WO2022037971A1
Application number: PCT/EP2021/071991
Authority: WO
Inventors: Lutz-Rüdiger JÄNICKE; Christoph Armschat
Original assignee: Siemens Energy Global GmbH & Co. KG
Priority date: 2020-08-21
Filing date: 2021-08-06
Publication date: 2022-02-24
Also published as: DE102020210646A1

Abstract

The invention relates to a switchgear (1) for medium and/or high voltages as well as to a method for data exchange in the switchgear, the switchgear comprising at least two switching units (2) and at least one data acquisition unit (3). The at least two switching units (2) are connected to the at least one data acquisition unit (3) via a collective optical waveguide (4).

Description

description

SWITCHGEAR FOR MEDIUM AND/OR HIGH VOLTAGE AND METHOD OF DATA EXCHANGE IN THE SWITCHGEAR USING FIBER OPTICS

The invention relates to a switchgear for medium and/or high voltages and a method for data exchange in the switchgear, with at least two switching units and at least one data acquisition unit.

Switchgear for medium voltages are designed to switch voltages in the range from one kilovolt to a two-digit kilovolt number, in particular 52 kV, and in the range of up to a few kiloamperes, in particular 15 kA operating current. Switchgear for high voltages are designed to switch voltages in the range of up to a few hundred kilovolts, in particular 1200 kV, and in the range of up to a few hundred kiloamperes. Switchgear are e.g. B. Outdoor switchgear and/or gas-I insulated switchgear, which in particular include circuit breakers, disconnectors, instrument transformers and/or control units and data transmission units.

Step into switchgear, e .g . B. in the event of overstress or weakened insulation, breakdown and/or flashover to . These lead z. B. to arcing, which can lead to malfunctions, permanent damage and/or destruction as well as failures of individual units and/or the entire switchgear and elements in the network . Damage is particularly dependent on the amperage and the duration of the arcs. Therefore, the impact time of the arcs is to be limited, in particular by switching off the affected units or to limit plant sections. In addition to conventional methods for detecting fault currents, in particular current and/or voltage measurements, optical detection systems that react to the light emitted by the arc are used. At each system component to be monitored, i .e . H . an arc detection system with a light sensor is installed on each switching unit. H . a data acquisition unit, is connected. Thus, a direct assignment of a message or a signal generated by the arc to the affected system component or to the corresponding switching unit possible . When an arc fault occurs in particular in a system module or a switching unit, the light of the arc is guided to the detection system, and from the detection system or The data acquisition unit reports the event to a control and protection system, which triggers the appropriate switching actions.

The connection of each light sensor via its own optical waveguide to its own receiver input of a particularly multi-channel detection system, i. H . a data acquisition unit is time-consuming, complex and cost-intensive. If designed accordingly, each fiber optic cable must be equipped with its own protective device in order to prevent or prevent the risk of personal injury and/or flashovers when voltage is applied to the switching units. to minimize . This entails additional costs and effort.

The object of the present invention is to specify a switchgear for medium and/or high voltages and a method for data exchange in a switchgear for medium and/or high voltages, in particular in a switchgear described above, which solve the problems described above. In particular, it is the task of specifying a switchgear and a method which are simple and inexpensive and enable safe, permanent, non-destructive operation of the switchgear. The specified object is achieved according to the invention by a switchgear for medium and/or high voltages with the features according to patent claim 1 and/or by a method for data exchange in a switchgear for medium and/or high voltages, in particular in a previously described switchgear, according to patent claim 12 solved . Advantageous refinements of the switchgear according to the invention for medium and/or high voltages and/or the method according to the invention for data exchange in a switchgear for medium and/or high voltages, in particular in a switchgear described above, are specified in the dependent claims. Subjects of the main claims can be combined with one another and with features of the subclaims and features of the subclaims with one another.

A switching system according to the invention for medium and/or high voltages comprises at least two switching units and at least one data acquisition unit. The at least two switching units are connected to the at least one data acquisition unit via a collecting optical waveguide.

By using a collecting optical waveguide for the connection of the at least two switching units with the at least one data acquisition unit instead of a separate optical waveguide for each switching unit for the connection in each case with the at least one data acquisition unit, the construction of the switchgear becomes simpler, more economical and only one optical waveguide, i.e. H . in particular, the collecting fiber optic cable must be equipped with its own protective device.

The at least two switching units can each be connected to a connecting optical waveguide. The connection optical waveguides can be connected to the collecting optical waveguide, in particular by means of a splice. The at least two switching units can each be connected to a connection optical waveguide, which is connected by means of a Nes splice can be connected to the collecting optical waveguide, which can be connected to the at least one data acquisition unit. In this way, each switching unit is connected to the data acquisition unit via the collecting optical waveguide in a cost-effective and simple manner, with the advantages described above.

Exactly one collecting optical waveguide can be included. The switchgear can be set up in a particularly simple and cost-effective manner with precisely one collecting fiber-optic cable. Only one protective device is e.g. B. necessary in order to prevent or to minimize .

Alternatively, exactly one collecting optical waveguide per phase can be included in order to protect each phase individually and, in particular, to be able to completely switch off the phase when an arc occurs at a switching device of the phase.

The optical waveguides can be designed to transmit optical signals, in particular light from arcs of the at least two switching units to the at least one data acquisition unit.

The at least two switching units can each include a light sensor, in particular connected to a connecting optical waveguide and/or designed as a connecting optical waveguide. This enables arcs to be detected easily and cost-effectively at each switching unit. In particular, a connection optical waveguide as a light sensor saves additional facilities such. B. Photodiodes whose electrical signals have to be converted into optical signals for transmission via optical waveguides, which involves additional effort and costs. The at least two switching units can each include specific units for coloring, in particular color filters, in particular for the clear assignment of light signals from a switching unit on the at least one data acquisition unit to the respective switching unit. By coloring, in particular using color filters, which are inexpensive and simple in construction, the signals can be clearly assigned to a switching unit, despite the transmission of the light signals via a common collecting optical waveguide, and this switching unit can be specifically assigned if an arc occurs in the respective switching unit turned off . Certain colors can also be assigned to switching units of a switching unit block, so that when an arc occurs in at least one switching unit of the switching unit block, the entire block can be specifically switched off, with switching units of other blocks z. B. not be turned off.

The optical waveguides can be designed to transmit optical control signals from the at least one data acquisition unit to the at least two switching units. The at least one data acquisition unit can include specific units for coloring, in particular color filters, and each switching unit can each have a unit for acquiring light signals of a specific color and/or predetermined colors, in particular for controlling the switching units by the data acquisition unit . The advantages are analogous to the advantages described above for the signal transmission from the switching units to the at least one data acquisition unit.

A method according to the invention for data exchange in a switchgear for medium and/or high voltages, in particular in a previously described switchgear, includes that at least two switching units are connected to at least one data acquisition unit via precisely one collecting optical waveguide. The at least two switching units, in particular two switching units of a phase, can each be connected to a connection optical waveguide, which can be connected by means of a splice to the collecting optical waveguide, which can be connected to the at least one data acquisition unit.

Optical control signals, in particular specifically through color filters for switching units, of the at least one data acquisition unit can be transmitted to the at least two switching units via the optical waveguide, in particular for the specific switching of individual switching units and/or switching unit blocks, in particular for switching off in the event of arcing.

Light signals, in particular from arcs in the switching unit, can be fed into a collecting fiber optic cable by means of a respective connection fiber optic cable via light sensors in each switching unit, in particular with color filters for the specific identification of a switching unit and/or a switching unit block , and the collecting optical waveguide can transmit the light signals to a data acquisition unit, which can assign the light signals to a switching unit and/or a switching unit block via color coding, and/or switching units and/or switching unit blocks specifically depending on the light signals can switch, in particular depending on the occurrence of arcing in switching units.

The advantages of the method according to the invention for data exchange in a switchgear for medium and/or high voltages, in particular in a previously described switchgear, according to claim 12 are analogous to the previously described advantages of the switchgear according to the invention for medium and/or high voltages according to claim 1 and vice versa. In the following, an exemplary embodiment of the invention is shown schematically in the single figure and described in more detail below.

The

Figure schematically shows a ski z ze of the structure of a switchgear 1 according to the invention for medium and / or high voltages, with switching units 2 and a data acquisition unit 3, which are connected via a collecting optical waveguide 4.

FIG. 1 shows a schematic sketch of the structural principle of a switching system 1 according to the invention for medium and/or high voltages, with three switching units 2 and one data acquisition unit 3 . The points ... indicate that two, three or more switching units 2 can be included in the switchgear 1 . The switching units 2 are connected to the data acquisition unit 3 via a common collecting optical waveguide 4 . Each switching unit 2 has a light sensor, which is connected via a connection optical fiber 5 to the collecting optical fiber 4, z. B. coupled by a splice 6 . Alternatively, each connection optical waveguide 5 serves as a light sensor and/or includes a light sensor, e.g. B. in the form of a lens and/or a colored optical filter.

The switching units 2 are connected to the data acquisition unit 3 via exactly one collecting optical waveguide 4, since all connection optical waveguides 5 converge on the collecting optical waveguide 4 and z. B. are coupled via the splice 6 to the collecting optical waveguide 4 . light or . Optical signals of an arc, in particular in or on a switching unit 2, are received or received via the light sensor in the respective connection optical waveguide 5. fed, forwarded in this and in particular fed via the splice 6 into the collecting optical waveguide 4 . in collecting Optical fiber 4 is the light or. Optical signal forwarded to the data acquisition unit 3 and processed in the data acquisition unit 3 . The processed signal can e.g. B. are stored, are displayed on an output unit such. B. an alarm light or on a monitor, and/or forwarded e.g. B. to a remote control room, in particular by radio, mobile radio, cable, or z. B. Internet Facilities .

The processed signal is z. B. used to trigger a control signal, which is fed in particular via the data acquisition unit 3 in the collecting optical waveguide 4, and via the collecting optical waveguide 4, z. B. the splice 6 and the connection optical waveguides 5 is routed to the switching units 2 . The signal causes z. B. switching off a switching unit 2 , a certain number of switching units 2 or all switching units 2 . Additional control signals and/or signals from sensors can also be transmitted via the collecting optical waveguide 4, and in particular the splice 6 and the connecting optical waveguides 5 or be directed in reverse. This enables communication, in particular in both directions, between the switching units 2 and the data acquisition unit 3 via the common collecting optical waveguide 4 . Alternatively or additionally, instead of the one data acquisition unit 3 , several data acquisition units 3 can also be connected to the collecting optical waveguide 4 . A data acquisition unit 3 includes in particular other data storage, data processing and / or data transmission units and z. B. at least one control and protection system

A specific assignment of signals to individual switching units 2 or groups of switching units 2, which z. B. can be switched simultaneously, z. B. possible by using specific units for coloring, in particular by color filters, which are not shown in the figure for the sake of simplicity. Various switching Units 2 or groups of switching units 2 can have color filters which color optical signals of the switching units 2 specifically. The data acquisition unit 3 is z. B. designed to clearly assign the signals to the switching units 2 specifically via the color of the incoming light signals in particular. Conversely, it is possible z. B. Colored light signals specifically to address individual switching units 2 o- the groups of switching units 2, and these z. B. to switch purposefully.

The exemplary embodiments described above can be combined with one another and/or can be combined with the prior art. So z. B. the features shown in the figure for each electrical phase in a switchgear 1 can be included. Each phase has a collecting optical waveguide 4, which connects the switching units 2 of the phase to a data acquisition unit 3, in particular optically. A common data acquisition unit 3 can be included for all phases or one data acquisition unit 3 per phase. Optical signals can e.g. B. visible light and/or wavelengths outside of visible light. Color filters of different colors or colors can be used as filters. Wavelengths can be used and/or polarization filters can be used. Switching units 2 can sensors for z. B. Include temperature, pressure, conductivity and / or partial discharge, the data on the collecting optical fiber 4 to the data acquisition unit 3 of the switchgear 1 are transmitted. Switching units 2 include z. B. Circuit breakers, disconnectors, and in particular associated units such. B. Bushings, Transducers, and/or Drives .

Reference sign :

1 switchgear

2 switching unit

3 data acquisition unit Collective fiber optic cable Connection fiber optic cable splice

Claims

patent claims

1. Switchgear (1) for medium and / or high voltages, with at least two switching units (2) and at least one data acquisition unit (3), characterized in that the at least two switching units (2) with the at least one data acquisition unit

(3) are connected via a collecting optical waveguide (4).

2. Switchgear (1) according to claim 1, characterized in that the at least two switching units (2) are each connected to a connection optical waveguide (5).

3. Switchgear (1) according to one of the preceding claims, characterized in that the connecting optical waveguide (5) are connected to the collecting optical waveguide (4), in particular by means of a splice (6).

4. Switchgear (1) according to Claims 2 and 3, characterized in that the at least two switching units (2) are each connected to a connecting optical waveguide (5), which are connected to the collecting optical waveguide (4) by means of a splice, which is connected to the at least one data acquisition unit (3).

5. Switchgear (1) according to one of the preceding claims, characterized in that exactly one collecting optical waveguide (4) is included.

6. Switchgear (1) according to any one of claims 1 to 4, characterized in that exactly one collecting optical waveguide (4) is included per phase.

7. Switchgear (1) according to any one of the preceding claims, characterized in that the optical waveguides (4, 5) are designed optical signals, in particular light from To transmit arcs of the at least two switching units (2) to the at least one data acquisition unit (3).

8. Switchgear (1) according to one of the preceding claims, characterized in that the at least two switching units (2) each comprise a light sensor, in particular connected to a connecting optical waveguide (5) and/or designed as a connecting optical waveguide (5). .

9. Switchgear (1) according to one of the preceding claims, characterized in that the at least two switching units (2) each comprise specific units for coloring, in particular color filters, in particular for the clear assignment of light signals of a switching unit (2) on the at least a data acquisition unit (3) to the respective switching unit (2).

10. Switchgear (1) according to one of the preceding claims, characterized in that the optical waveguides (4, 5) are designed to transmit optical control signals from the at least one data acquisition unit (3) to the at least two switching units (2).

11. Switchgear (1) according to one of the preceding claims, characterized in that the at least one data acquisition unit (3) comprises specific units for coloring, in particular color filters, and each switching unit (2) has a unit for acquiring light signals of a specific Color and / or predetermined colors includes, in particular for controlling the switching units (2) by the data acquisition unit (3).

12. A method for data exchange in a switchgear (1) for medium and / or high voltages, in particular in a switchgear (1) according to any one of the preceding claims, characterized in that at least two switching units (2) be connected to at least one data acquisition unit (3) via precisely one collecting optical waveguide (4).

13. The method according to claim 12, characterized in that the at least two switching units (2), in particular two switching units of one phase, are each connected to a connecting optical waveguide (5), which is connected to the collecting optical waveguide (4) by means of a splice which is connected to the at least one data acquisition unit (3).

14. The method according to any one of claims 12 or 13, characterized in that optical control signals, in particular specifically through color filters for switching units (2), of the at least one data acquisition unit (3) to the at least two switching units (2) via the optical waveguide (4 , 5) are transmitted, in particular for the specific switching of individual switching units (2) and/or switching unit blocks, in particular for switching off in the event of arcing.

15. The method according to any one of claims 12 to 14, characterized in that light sensors in each switching unit (2), in particular with color filters for the specific identification of a switching unit (2) and / or a switching unit block, light signals, in particular from arcs in the switching unit (2), by means of a respective connection optical waveguide (5) in a collecting optical waveguide (4) are fed, and the collecting optical waveguide (4) the light signals to a data acquisition unit

(3) which assigns the light signals to a switching unit (2) and/or a switching unit block via color coding, and/or switches switching units (2) and/or switching unit blocks specifically depending on the light signals, in particular depending on the occurrence of Arcs in switching units ( 2 ) .