NO311108B1 - Switching device for processing analogue current and voltage signals - Google Patents

Abstract

A circuitry for processing analogical current and voltage signals to be further processed by microcomputers (4, 5) has at least two input modules (1) for processing voltage signals and at least two input modules (2) for processing current signals. Among these modules, at least one input module (1, 2) of each type is coupled by two constant current sources (3) to two microcomputers (4, 5). Two detachable connections (6, 7) arranged at the output of each of the other input modules (1, 2) make it possible to connect at least one input module (1, 2) to both microcomputers (4, 5), via two constant current sources (3), or to connect at least one input module (1) for voltage signals to one microcomputer (4) and at least one input module (2) for current signals to the other microcomputer (5), each time via a constant current source (3). The number of inputs of both microcomputers (4, 5) is the same and always smaller than that of the input modules (1, 2). The number of constant current sources (3) corresponds to the sum of the inputs of both microcomputers (4, 5). The advantage of this circuitry lies in the possibility to match the fixed and variable input modules (1, 2) so that the greatest possible freedom is ensured at the design stage with a minimal amount of hardware.

Description

The invention relates to a switching device for processing analogue current and voltage signals for further processing in microcomputers.

In modern innovative technical developments, the tendency towards system solutions is a common phenomenon. Thus, it is common today to arrange system protection in power plants. This unites an entire system of individual protection functions in a single piece of hardware - or software concept. A higher integration density with regard to hardware, software and functional interconnections is in principle often the only possibility to achieve significant improvements.

In EP-A 0 283 889, a processing module for recording analog input quantities, particularly for microprocessor systems, is described. An associated program store is programmed before the measurement is carried out, so that semiconductor switches are activated accordingly for each measurement. With this processing module, each input can be connected flexibly and serves for the recording of voltage measurement values and current measurement values, or for adaptation to sensors, whereby the input configuration takes place only by means of programming. A disadvantage of this processing module is that the measured values present at the input cannot be recorded simultaneously, as the sensing of the inputs takes place serially. This connection is therefore not suitable for the recording of measured values in systems where processes change rapidly.

The purpose of the invention is to provide a coupling device by which the number of inputs and outputs for the current and voltage signals can be varied and an adaptation to the different application cases is thereby possible in a simple way.

The above-mentioned purpose is achieved with the help of the invention, which is characterized by the fact that there are at least two input modules for the processing of voltage signals and at least two input modules for the processing of current signals, of which at least one respective input module is connected via two constant current sources to two microcomputers, and that on the output of the other input modules are provided with two respective, detachable connections which are circuit board connectors, single-pole circuit board switches, e.g. "dual-in-line" switches, or single-pole, electronic switches, via which either at least one input module can be connected to both microcomputers with the intermediate connection of two constant current sources, or at least one respective input module for the voltage signals can be connected to one microcomputer, and at least one input module for the current signals can be connected to the other microcomputer via a respective constant current source, and that the number of inputs to both microcomputers is the same, but always less than the number of all input modules, and that the number of constant current sources corresponds to the sum of the inputs to both microcomputers, and that the input modules, the detachable connections and the constant current sources are arranged on a printed circuit board.

The coupling according to the invention is partially variable, i.e. specific input modules are arranged exclusively for the current signals or for the voltage signals. The other input modules can optionally be connected to the microcomputers via the detachable connections. As the non-variable input modules are connected to both microcomputers, the redundancy requirements are also met. However, it is also possible to achieve redundancy with the variable input modules. With the help of the constant current sources, disturbance effects and transition resistances are eliminated, and a long-term constancy of the calibration is also achieved. By means of the arrangement of all the building parts necessary for the coupling device on a circuit board, the required compactness is ensured. As the entire circuit board is immediately replaced in the event of a defect in some input modules, a great ease of service for the connection is also achieved.

According to an embodiment of the invention, the input modules for the voltage signals consist of a voltage transformer, an adaptation coupling connected after this which is followed by a low-pass filter, and the input modules for the current signals are made up of a current transformer to which a current-voltage converter coupling is connected with adaptation with a subsequent low-pass filter. This is the simplest and most cost-effective structure of the input modules.

It is further an advantage that instead of respective four detachable connections, whereby two are from an input module for the voltage signals and two from an input module for the current signals, a two-pole, four-step switch is arranged whereby each root connection is connected to a constant current source of which each is connected to a microcomputer, and that - in the first switch position - the input module for the voltage signals is connected to both microcomputers, in the second switch position the input module for the current signals is connected to both microcomputers, in the third switch position one input module is connected to one microcomputer and the second input module connected to the second microcomputer, and in the fourth switch position, input modules and microcomputers are connected to each other in the opposite order. With the switch, the assignment of the input modules to the microcomputers takes place in a very simple way, as wiring for the four possibilities is already arranged in the switch.

A further design of the invention consists in the two microcomputers being connected to the constant current sources via a respective flat cable with flat cable connectors. This is the clearest and simplest way of interconnecting two connections on separate circuit boards with several inputs and outputs.

With the help of matching the fixed and variable input modules to current requirements, the greatest possible freedom is achieved with minimal hardware input during the design.

The invention will be described in more detail in the following with reference to the drawing, where fig. 1 shows a block diagram of the connection device according to the invention with ten input modules, and fig. 2 illustrates the possible connections of the circuit board connectors.

In fig. 1 shows five input modules 1 for processing voltage signals, and five input modules 2 for processing current signals. The input modules 1 for the voltage signals, which are all identically constructed, consist of a voltage transformer 8 to which is connected an adaptation coupling 9 which is followed by a low-pass filter 10. The input modules 2 for the current signals are likewise all identically constructed and consist of a current transformer 11 as on the secondary side is connected to a current-voltage converter connection 12 to which a low-pass filter 13 is connected. Two input modules 1 for the voltage signals and two input modules 2 for the current signals are connected at the output to two respective constant current sources 3. The constant current sources 3 for an input module 1, 2 are each connected to a microcomputer 4, 5.

Three input modules 1 for the voltage signals and three input modules 2 for the current signals are connected by detachable connections 6, 7 which comprise circuit board contacts 14. The four possible contact connections are shown in fig. 2. As can be seen here, an input module 1, 2 can be connected to both microcomputers 4,

5, or one input module 1 can be connected to one and the other input module 2 can be connected to the other microcomputer 4, 5, or vice versa.

The circuit board connectors 14 are connected via constant current sources 3 to the microcomputers 4, 5. As the connection is usually arranged on a single conductor plate, for ease of service and for reasons of overview, the connection between the constant current sources 3 and the microcomputers 4, 5 is realized with flat cables 15.

In accordance with the requirements, some input modules 1, 2 are permanently connected, and in the case of the others, the wiring can be selected via the circuit board contacts 14. This results in a very high degree of flexibility for the connection. Furthermore, the redundant processing necessary for some signals is also ensured.

Claims (4)

1. Connection device for processing analog current and voltage signals for further processing in microcomputers, characterized in that at least two input modules (1) are arranged for the processing of voltage signals and at least two input modules (2) for the processing of current signals, of which at least one respective input module (1, 2) via two constant current sources (3) are connected to two microcomputers (4, 5), and that at the output of the other input modules (1, 2) there is provided with two respective detachable connections (6, 7) which are circuit board connectors (14), single-pole circuit board switches, e.g. "dual-in-line" switches, or single-pole, electronic switches, via which either at least one input module (1; 2) can be connected to both microcomputers (4, 5) with the intermediate connection of two constant current sources (3), or at least one respective input module (1) for the sparing signals can be connected to one microcomputer (4), and at least one input module (2) for the current signals can be connected to the other microcomputer via a respective constant current source, and that the number of inputs to both microcomputers (4, 5) is the same, but always less than the number of all input modules (1, 2), and that the number of constant current sources (3) corresponds to the sum of the inputs of both microcomputers (4, 5), and that the input modules (1, 2), the detachable connections (6, 7) and the constant current sources (3) are arranged on a printed circuit board. 2. Switching arrangement according to claim 1, characterized in that the input modules (1) for the voltage signals consist of a voltage transformer (8) and a matching coupling (9) connected after this, which is followed by a low-pass filter, and that the input modules (2) for the current signals are made up of a current transformer (11) to which is connected a current-voltage converter coupling (12) with adaptation with a subsequent low-pass filter (13). 3. Connection according to claim 1 or 2, characterized in that instead of respective four detachable connections (6, 7), whereby two are from an input module (1) for the voltage signals and two are from an input module ( 2) for the current signals, a two-pole, four-stage switch is arranged whereby each root connection is connected to a constant current source (3) each of which is connected to a microcomputer (4, 5), and that in the first switch position the input module (1) is for the voltage signals connected to both microcomputers (4, 5), in the second switch position the input module (2) for the current signals is connected to both microcomputers (4, 5), in the third switch position one input module (1) is connected to one microcomputer (4 ) and the second input module (2) connected to the second microcomputer (5), and in the fourth switch position the input modules (1, 2) and the microcomputers (4, 5) are connected to each other in the opposite order. 4. Connection device according to one of claims 1-3, characterized in that the two microcomputers (4, 5) are connected to the constant current sources (3) via a respective flat cable (15) with attached flat cable connectors.