DE3342326A1 - DC sensor - Google Patents

Abstract

A DC sensor for DC switches, especially DC power switches, having a device (2) for determining the voltage drop in a region (4) of a current conductor (6) carrying DC, and having a downstream-connected voltage amplifier (8). According to the invention, the current conductor (6) is provided in this region (4) with a temperature sensor (10), downstream from which a resistance/voltage converter (12) is connected, and a common electronic controller (16) is allocated to the voltage values (US, UT, UA) of a desired-value transmitter (14), of the temperature sensor (10) and of the device (2) for measuring the voltage drop. In consequence, it is possible to indicate the DC current actually flowing in a current conductor (6) at any desired time and hence to divert excess currents or short-circuit currents away from installations or apparatuses which are to be protected. <IMAGE>

Description

DC current sensor

The invention relates to a direct current sensor for direct current switches, in particular DC circuit breaker, with a device for determining the voltage drop in an area of a DC conductor and with a downstream voltage amplifier.

To protect a system or device against damage caused by overcurrent or short-circuit current To protect the switching elements with thermal overcurrent and magnetic Short-circuit current releases. Such arrangements are called thermal Overcurrent release bimetal relay or as magnetic short-circuit current release current relay used. Bimetal relays are operated directly or indirectly by the current flowing through them warmed up. The switch-off of the bimetal relay is therefore dependent on that of the bimetal amount of heat supplied, d. H. it is current-time-dependent. As a magnetic short-circuit current release Serving current relays switch when a predetermined response current is exceeded without delay.

It is an electrical switching device with quick release, in particular DC high-speed switch, known, which is used to interrupt short-circuit currents, before they can assume impermissibly high values. A movable contact piece is is constantly biased by a spring in the opening direction and is controlled by a holding magnet held in the form of a permanent magnet with a trip coil in the switched-on position. This trip coil is via an electronic switching element, preferably a thyristor connected to an energy store.

This electronic switching element is from a current derivative scanning as well as controlled with a current level sensing organ. This organ consists of an iron core with an air gap surrounding a main current path, in or in the proximity of which can be influenced by the magnetic field of the current level sensing organ Element is arranged, which is in the control circuit of the electronic switching element (DE-AS 2 060 990).

The invention is now based on the object of a direct current sensor for direct current switch with which one can actually switch at any given time can indicate flowing direct current in a conductor, and thus over or Avoid short-circuit currents from systems or devices to be protected.

This object is achieved according to the invention with the characterizing Features of claim 1. The continuously in a predetermined range of a direct current carrying The voltage drops determined by the current conductor are each given a correction value corrected from a memory location of a memory of the controller. These correction values are determined with the help of the temperature measurement of the conductor in this area, because the temperature values are each an address of the respective memory location.

When a predetermined setpoint is exceeded, a trigger signal is issued Via a potential-free coupling device to the release of a DC switch. The control can distinguish whether the overcurrent that occurs is via a longer period of time or whether the overcurrent is just a glitch.

In an advantageous embodiment of the direct current sensor the electronic control with several analog-to-digital converters, a memory, for example a ROM (read only memory), a digital multiplier, a Parallel to serial converter, a comparator, a transfer buffer, several time stages, a digital-to-analog converter and a clock generator. Through this structure the controller gives short response times, for example about 100 microseconds up to a few milliseconds. There is also the option of triggering an alarm at the same time the digital value of the current value actually flowing in the current conductor read out either in parallel or serially and this value in a data processing system to be recorded in the form of hourly, daily or weekly logs.

In a further advantageous embodiment of the direct current sensor a micro-computer is provided as control. By this measure, one obtains a very flexible, adaptable DC current sensor that you can use with a free programming can change while the hardware version of the DC current sensor remains unchanged.

In a particularly advantageous embodiment of the direct current sensor a signal processor is provided as a control. Through this embodiment will be the advantages of the hardware design, namely the short response times, and the pure software execution, namely the flexibility of the direct current sensor.

For further explanation, reference is made to the drawing, in the one embodiment. a direct current sensor according to the invention schematically illustrative light is.

Fi.g. 1 shows a block diagram of the direct current sensor according to FIG Invention and in Fig. 2 is a block diagram of a controller of the DC current sensor shown.

In the embodiment according to FIG. 1, a direct current sensor is used for DC switch a device 2 for determining the voltage drop UA in a predetermined area 4 of a direct current carrying conductor 6, for example is a copper conductor, preferably a copper bar. The determined voltage drops UA are amplified by a downstream voltage amplifier 8. In the predetermined Area 4 is the conductor 6 with a temperature sensor 10, for example one NTC thermistor, provided. The determined temperature values of the conductor 6 are with a downstream resistance-voltage converter 12 into voltage values UT converted. In addition, a setpoint generator 14 is provided, at the output of which a predetermined voltage Us is present. The voltage values Us, UT, UA of the setpoint generator 14, the temperature sensor 10 and the device 2 for determining the voltage drop, each represented by an arrow in the figure is a common one electronic control 16 assigned. The electronic control 16 is, for example a micro-computer, preferably a signal processor, is provided. The exit 18 the controller 16 is connected to a floating coupling device, for example an optocoupler 20 connected.

The voltage values UA, UT, Us are continuously determined with the help of several Analog-to-digital converters 22, 24, 26 according to FIG. 2, which is a block diagram of a hardware-based embodiment of the electronic control tion 16 illustrates, digitized. The analog-to-digital converters 22, 24, 26 is a common clock generator 28 assigned to this converter with the help of a predetermined Clock pulse T1 clocks synchronously. In addition, the clock generator 28 provides a second Clock pulse T2 available. The output 30 of the first analog-Digi.tal converter 22 is connected to an input 32 of a digital multiplier 34. The other Input 36 of multiplier 34 is connected to output 38 of memory 40, its input 42 is connected to the output 44 of the second analog-digital converter 24 is. The output 46 of the multiplier 34 is each provided with an input 48, 50, 52, 54 of the digital-to-analog converter 56, the parallel-serial converter 58, the comparator 60 and an optocoupler 62 connected. A second input 64 of the comparator 60 is connected to an output 66 of the third analog-digital converter 26. aside from that the comparator 60 is in series with a takeover buffer 68, a first time stage 70 and a second time stage 72 switched. The output 74 is with the optocoupler 20 connected. The transfer buffer 68 is transferred to the analog-digital converter with the aid of the clock signal T2 22, 24, 26 voted. The output 78 of the digital-to-analog converter 56 is with a Isolation amplifier 80 and the output 76 of the parallel-serial converter 58 is with the Optocoupler 62 connected. At the output of the isolation amplifier 80 one always receives the actual analog value of the current in the direct current conductor 6 flows. At the output 46 of the multiplier 34 is in each case the actually flowing Current value available in the form of a parallel 8-bit word, which is then transmitted directly via an optocoupler 62 is read out in parallel. You can also get these current values also read out serially, if a parallel 8-bit word with the help of the parallel-to-serial converter 58 is converted into a serial 8-bit word. These digital values respectively the actually flowing current values in the conductor 6 are in a data processing system recorded in the form of logs.

To determine the current in the DC conductor 6, the voltage drop is continuously determined in a predetermined area 4 and at the same time the temperature of the conductor 6 measured, for example the same the ambient temperature when the current conductor 6 is switched on. The digital one The value of the measured temperature value is an address for the subsequent memory. A correction value is stored in the memory location of this address, which is linked to the digital Value of the measured voltage drop value is multiplied. This corrected Voltage value is a measure of the current value actually flowing at a conductor temperature, which is the same as the ambient temperature. The conductor temperature increases over time to their operating temperature. When the temperature of the conductor increases, will be specific resistance is greater and thus also the resistance of the current conductor 6. The voltage drop in the predetermined area 4 increases proportionally to the specific Resistance of the conductor 6, but the current actually flowing remains constant. As the temperature rises, the addresses of the memory also change and thus the correction values, which are inversely proportional to the change in resistivity of the conductor 6 change. Thus the determined current value remains constant, because the correction value decreases and the voltage drop value increases accordingly.

If a short circuit or overcurrent occurs, the changes Temperature of the conductor 6 only gradually, but the voltage drop changes with the occurrence of the short circuit proportional to the conductor current. In the multiple decorator 34, the increased voltage drop value is multiplied by the correction value that was determined before the occurrence of the short-circuit current, since the temperature is not can change by leaps and bounds. This increased corrected stress value is evidence for increasing the current as a result of a short circuit or overcurrent. With help of the setpoint generator 14, a limit value is set which is dependent on the to protective devices. With the two time stages 70, 72 one can on the one hand short Suppress interference pulses and, on the other hand, extend valid pulses.

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Claims (18)

Claims 0 DC current sensor for DC switches, in particular DC circuit breaker with a device (2) for determining the voltage drop in an area (4) of a DC conductor (6) and with a downstream Voltage amplifier (8), d a -d u r c h e k e n n n z e i c h n e t that in this Area (4) of the conductor (6) is provided with a temperature sensor (10), the a resistance-voltage converter (12) is connected downstream, and that the voltage values (UA, UT, Us) of a setpoint generator (14), the temperature sensor (10) and the device (2) assigned to a common electronic control (16) for voltage drop measurement whose output is via a potential-free coupling device with a trigger a DC switch is connected. 2. DC current sensor according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the electronic control (16) with several analog-to-digital converters (22, 24, 26), a memory (40), a digital multiplier (34), a parallel-serial converter (58), a comparator (60), a transfer buffer (68), several time stages (70, 72), a digital-to-analog converter (56) and a clock generator (28) is provided. 3. DC current sensor according to claim 1, d a d u r c h g e k e n n z e i c h n e t that a micro-computer is provided as the electronic control (16) is. 4. DC current sensor according to claim 1, d a d u r c h g e k e n n z e i. c h n e t that a signal processor is provided as the electronic control (16) is. 5. DC current sensor according to claim 1, d a d u r c h g e k e n n z e i c h n e t that a thermistor is provided as the temperature sensor (10). 6. DC current sensor according to claim 1, d a d u r c h g e k e n n z e i c h n e t that at least one optocoupler (20) is provided as a coupling device are. 7. DC current sensor according to claim 1, d a d u r c h g e k e n n z e i c h n e t that an isolating amplifier (80) is provided as a coupling device is. 8. DC current sensor according to claim 2, d a d u r c h g e k e n n z e i c h n e t that the analog-digital converters (22, 24, 26) have a common clock generator (28) is assigned. 9. DC current sensor according to claim 2, d a d u r c h g e k e n n z e i c h n e t that the output (30) of the first analog-digital converter (22) with is connected to an input (32) of the multiplier (34). 10. DC current sensor according to claim 2, d a d u r c h g e k e n n z e i c h n e t that the output (38) of the memory (40) with a different input (36) of the multiplier (34) and that the input (42) of the memory (40) with the Output (44) of the second analog-digital converter (24) is connected. 11. DC current sensor according to claim 2, d a d u r c h g e k e n n z E i c h n e t that a ROM (read only memory) is provided as the memory (40). 12. DC current sensor according to claim 2, d a d u r c h g e k e n n z e i. c h n e t that the output (66) of the third analog-to-digital converter (26) with an input (64) of the comparator (60) is connected. 13. DC current sensor according to claim 2, d a d u r c h g e k e n n z e i c h n e t that the output (46) of the multiplier (34) in each case with the input (48, 50, 52, 54) of the digital-to-analog converter (56), the parallel-to-serial converter (58), the comparator (60) and an optocoupler (62) is connected. 14. DC current sensor according to claim 2, d a d u r c h g e k e n n z e i c h n e t that the takeover buffer (68), the first time stage (70) and the second time stage (72) are connected in series. 15. DC current sensor according to claim 2, d a d u r c h g e k e n n z e i. c h n e t that the transfer buffer (68) is assigned a clock generator (28) is. 16. DC current sensor according to claim 2, d a d u r c h g e k e n n z e 1 c h n e t that the output (74, 76) of the second time stage (72) and of the parallel-to-serial converter (58) is each connected to an optocoupler (20, 62). 17. DC current sensor according to claim 2, d a d u r c h g e k e n n z e i c h n e t that the output (78) of the digital-to-analog converter (56) with a Isolation amplifier (80) is connected. 18. A method for determining the direct current according to claim 1, d a d u r c h e k e n n z e i. c h n e t that the measured voltage drop values each with one Correction value from a memory location (40) are corrected, with the temperature values in each case the address of the respective Storage space are.