monitoring a converter (1) includes detecting whether a value of an input variable (2) for the converter (1) assumes a first prescribed input reference value (41) and checking whether an output variable (3) from the converter (1) likewise assumes a corresponding, second prescribed output reference value (61). This means that the operation of the converter is tested only at occasional instants, specifically only using individual, prescribed values. The fact that only prescribed values (41, 61) are compared with instantaneous values of the input and output variables (2, 3) means that the invention can be implemented using very simple means. The method is particularly suitable for monitoring the operation of a converter (1) in a control or protective device for an electrical switchgear assembly. In this context, when a malfunction in the converter (1) is detected, all protective functions which are dependent on the converter (1) are preferably turned off.
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0. 30. A device for monitoring a converter, comprising:
input detector means for comparing an input variable for the converter with an input reference value;
output detector means for comparing an output variable from the converter with an output reference value; and
evaluation means for determining a converter status based on the comparison of the input variable with the input reference value and based on the comparison of the output variable with the output reference value.
0. 39. A system, comprising:
a converter;
a detector configured to compare converter variables with associated reference values, the detector comprising:
an input detector configured to compare an input variable with an input reference value; and
an output detector configured to compare an output variable with an output reference value, and
an evaluation circuit operatively coupled to the detector and configured to determine the status of the converter based on the comparisons.
0. 11. A monitoring apparatus, comprising:
a detector system configured to:
compare an input variable of a monitored device with an input reference value and generate a first flag indicative of the result of the comparison; and
compare an output variable of the monitored device with an output reference value and generate a second flag indicative of the result of the comparison; and
an evaluation unit configured to determine the status of the monitored device based on the generated first and second flags.
0. 43. A monitoring apparatus for monitoring the operation of a converter, comprising:
an input detector configured to determine whether an input variable for the converter lies within a range of an input reference value;
an output detector configured to determine whether an output variable lies within a range of an output reference value; and
an evaluation unit configured to compare results from the input detector and from the output detector and to produce a status signal indicating a status of the converter.
0. 47. A method for monitoring the operation of a converter, comprising:
determining whether an input variable for the converter lies within a first prescribed tolerance range about an input reference value;
determining whether an output variable from the converter lies within a second prescribed tolerance range about an output reference value; and
determining a status of the converter based on whether the input variable and the output variable lie within the respective prescribed tolerance range for the respective reference value.
0. 21. A computer readable medium including instructions which when executed by a microprocessor causes the microprocessor to perform monitoring of a converter, comprising the steps of:
comparing an input variable for the converter with an input reference value;
comparing an output variable from the converter with an output reference value; and
Determining a converter status based on the comparison of the input variable with the input reference value and based on the comparison of the output variable with the output reference value.
1. A monitoring apparatus for monitoring the operation of a converter having means for monitoring an input variable and at least one output variable, characterized in that the monitoring apparatus has
an input detector for detecting an input reference value for an input variable for the converter,
an output detector for detecting an output reference value for an output variable, and
an evaluation unit for comparing results from the input detector and from the output detector and for producing a corresponding status signal which conveys correct operation or a malfunction in the converter.
5. A method for monitoring the operation of a converter, characterized by
determination of whether an input variable for the converter lies within a first prescribed tolerance range about an input reference value,
determination of whether an output variable from the converter lies within a second prescribed tolerance range about an output reference value, and,
if both the input variable and the output variable lie within the respective prescribed tolerance range for the respective reference value, the converter being established to be operating correctly, and otherwise the converter being established to be malfunctioning.
2. The monitoring apparatus as claimed in
3. The monitoring apparatus as claimed in
4. The monitoring apparatus as claimed in
6. The method as claimed in
7. The method as claimed in
8. The method as claimed in
9. The method as claimed in
10. The method as claimed in
0. 12. The apparatus of
0. 13. The apparatus of
0. 14. The apparatus of
an input detector configured to compare the input variable and the input reference value; and
an output detector configured to compare the output variable and the output reference value.
0. 15. The apparatus of
0. 16. The apparatus of
0. 17. The apparatus of
0. 18. The apparatus of
0. 19. The apparatus of
0. 20. The apparatus of
0. 22. The computer readable medium of
0. 23. The computer readable medium of
0. 24. The computer readable medium of
0. 25. The computer readable medium of
0. 26. The computer readable medium of
0. 27. The computer readable medium of
0. 28. The computer readable medium of
0. 29. The computer readable medium of
0. 31. The device of
0. 32. The device of
0. 33. The device of
0. 34. The device of
0. 35. The device of
0. 36. The device of
0. 37. The device of
0. 38. The device of
0. 40. The system of
0. 41. The system of
0. 42. The system of
0. 44. The monitoring apparatus of
0. 45. The monitoring apparatus of
0. 46. The monitoring apparatus of
0. 48. The method of
0. 49. The method of
0. 50. The method of
0. 51. The method of
0. 52. The method of
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The invention relates to the field of protective technology, in particular for electrical switchgear assemblies. It relates to an apparatus and to a method for monitoring the operation of a converter in accordance with the preamble to patient claims 1 and 5.
Electrical switchgear assemblies, for example medium, high and low voltage switchgear assemblies, have control and protective devices. Protective devices must reliably detect, identify and locate electrical faults, for example short circuits or line interruptions, and must initiate suitable countermeasures in order to prevent faults from being propagated and system parts from being destroyed. At the same time, however, a protective device should not cause any system parts to be turned off unnecessarily. A protective device must therefore itself also have a high level of reliability. To this end, individual units of the protective device, in particular converters, need to be monitored. Examples of such converters are test amplifiers, digital-to-analog or analog-to-digital converters. A defect in a converter generally results in corruption of measured data and in a faulty response from the protective device.
In a generally known manner, operational monitoring is performed using a redundant design for units in a device: such a unit is of duplicate or triplicate design, and a lack of any match between output signals from the units is used to infer that a unit is malfunctioning. Such redundancy results, in the costs of the unit being at least doubled or tripled, however. Another manner of monitoring the operation of an appliance is known from U.S. Pat. No. 4,215,412. In this case, control variables and output variables for an aircraft engine are measured while the engine is operating. A computer-based simulation model of the engine continuously simulates a response of the engine and of the output variables during operation using the measured control variables. To this end, a complex mathematical model with an appropriate level of computational complexity is used. If the continuously changing, calculated and measured output variables do not match, an indicator is activated for an operator. However, producing a simulation model, matching it to a given engine and performing continuous calculations during operation require a high level of complexity.
It is therefore the object of the invention to provide an apparatus and a method for monitoring the operation of a converter of the type mentioned in the introduction which eliminates the aforementioned disadvantages.
This object is achieved by an apparatus and a method for monitoring the operation of a converter having the features of patent claims 1 and 5.
The invention's method for monitoring the operation of a converter involves detecting whether a value of an input variable for the converter assumes a first prescribed input reference value, and checking whether an output variable from the converter likewise assumes a corresponding, second prescribed output reference value.
This means that the operation of the converter is tested only at occasional instants, specifically only using individual, prescribed values. The fact that only prescribed values are compared with instantaneous values of the input and output variables means that the apparatus according to the invention can be produced using very simple means.
In one preferred variant of the invention, the prescribed values correspond to a value zero for a current, or to a value zero for a voltage, that is to say to a ground potential, and/or to a supply voltage for an electrical system.
The method according to the invention is particularly suitable for monitoring the operation of a converter in a control or protective device for an electrical switchgear assembly. In this context, when a malfunction in the converter is detected, all protective functions which are dependent on this converter are preferably turned off.
Further preferred embodiments can be found in the dependent patent claims.
The invention is explained in more detail below with the aid of preferred illustrative embodiments which are shown in the accompanying drawings, in which:
The reference symbols used in the drawings are summarized in the list of reference symbols together with their meanings. In principle, identical parts are provided with identical reference symbols in the figures.
The method according to the invention works in the following manner: the input detector 4 continuously monitors the input variable 2. So long as a value of the input variable 2 lies outside a prescribed tolerance range about the input reference value 41, the input detector 4 sets the input flag 5 to a prescribed value, for example to the value zero. If the value of the input variable 2 is approximately the same as the input reference value 41, that is to say if it lies within the prescribed tolerance range about the input reference value 41, the input detector 4 detects a match between the input variable 2 and the input reference value 41. The input detector 4 thus responds and sets the input flag 5 to another value, for example to the value one. In the same way, the output detector 6 continuously compares a value of the output variable 3 with the output reference value 61. The output detector 6 forms the output flag 7 to indicate a match between the output variable 3 and the output reference value 61, that is to say to indicate whether the output variable 3 lies within a prescribed tolerance range about the output reference value 61. In one variant of the method according to the invention, the output variable 3 is compared only if the optional connection between the input flag 5 and the output detector 6 indicates a response from the input detector 4. The evaluation unit 8 receives the input flag 5 and the output flag 7 and uses these to form the status signal 9 in the following manner: if the input flag 5 and the output flag 7 both indicate a response from the appropriate detector 4 or 6 then the status signal 9 conveys correct operation of the converter 1. If there is no match between the input flag 5 and the output flag 7, then the status signal 9 conveys a malfunction in the converter 1. The status signal 9 can also be formed either continuously or else only if the input flag 5 indicates a response from the input detector 4.
In one variant of the invention, the comparison in the output detector 6 is carried out continuously, and the comparison in the input detector 4 and/or the formation of the status signal 9 is carried out only if there is a response from the output detector 6.
In a further variant of the invention, the evaluation unit 8 incorporates a converter delay time and compares the input flag 5 with an output flag 7 value which arises only after this delay time. This means that determination of whether both the input variable 2 and the output variable 3 lie within the respective prescribed tolerance range takes place on the basis of values of the input variable 2 and values of the output variable 3 which have been determined after having been shifted relative to one another by a delay time for the converter 1.
If the converter 1 is not working by reason of it driving/overriding the output variable 3 continuously to a maximum or a minimum after an instant t1, then a curve for the output variable 3 is produced in accordance with the curve s3. The corresponding curve f3 for an output flag 7 shows that there is never any response from the output detector 6 after the instant t1. This means that no match arises between input flags 5 and output flags 7 either. Consequently, a malfunction in the converter 1 is detected and conveyed by setting the status signal 9.
If the converter 1 is not working by reason of the output variable 3 having too great an offset, then, when an input variable 2 has a curve in accordance with s1 or s2, a curve for the output variable 3 is produced in accordance with the curve s4. The corresponding curve f4 for an output flag 7 shows that the output detector 6 responds at different instants than an input detector 4 for a curve in accordance with s1. This means that no match arises between input flags 5 and output flags 7 in this case either. Consequently, a malfunction in the converter 1 is detected and conveyed by setting the status signal 9.
The reference values 41, 61 are determined by tuning the converter 1, for example when equipment is brought, into service. If the converter 1 is an analog/digital converter, the input variable 2 preferably has a value zero connected as prescribed value, preferably a ground potential or a current zero. The defined input reference value 41 for which the input detector 4 responds is likewise a value zero. An offset in the converter 1 produces a particular value of the output variable 3 which is generally different than zero. This value of the output variable 3 is selected as the output reference value 61 for which the output detector 6 responds. The output reference value 61 corresponds to the input reference value 41 zero. If the converter 1 is a digital/analog converter, the input variable 2 is varied until the output variable 3 has a value zero. The corresponding value of the input variable 2 is selected as input reference value 41 and is assigned to an output reference value 61 zero. In a similar manner, tuning which uses a supply voltage or a rated voltage of a system as reference value for an analog side of a converter 1, instead of a ground potential, is carried out.
The invention's monitoring apparatus 10 for monitoring the operation of a converter 1, the converter 1 being an analog converter or an existing converter 1 in a system, thus has
In one preferred variant of the invention, the prescribed reference values correspond to a value zero for a current, or to a value zero for a voltage, that is to say to a ground potential, and/or to a supply voltage for an electrical system. Such reference values have the advantage that they occur throughout a system and are defined. If a reference value for an analog variable corresponds to a ground potential or to a value zero, then the analog detector is simply an analog comparator whose changeover threshold is the same as an upper limit of the prescribed tolerance range about the reference value zero. If an absolute value of the analog variable falls below the upper limit of the tolerance range, the comparator sets its output signal or analog flag to the value one and thus indicates that the analog variable has the prescribed reference value zero.
The method according to the invention is particularly suitable for monitoring the operation of a converter in a control or protective device for an electrical switchgear assembly. By way of example, digital/analog converters 1 are used in order to convert signals 2 transmitted digitally via glass fibers from protective appliances to analog signals 3. These analog signals 3 are passed to analog inputs of existing prior protective appliances. Preferably, a monitoring apparatus 10 according to the invention based on the structure in
In the case of a converter 1 processing a current measurement, a malfunction in a converter 1 which causes the output variable 3 from the converter 1 to be overridden cannot be distinguished from a short circuit current in the system without delay, that is to say in a time during which a protective device needs to react. In this case, the invention enables the malfunction to be detected.
When monitoring the operation of a converter 1 in a protective device for an electrical switchgear assembly, detection of a malfunction in the converter 1 preferably involves the output variable 3 being marked as invalid, for example by transmitting an appropriate status signal. In this case, protective functions which are dependent on the converter 1 are preferably turned off. This is permissible because faults in switchgear, assemblies occur very rarely. In this context, the risk of an operating fault caused by a defective converter 1 is advantageously greater than the risk of a fault not detected in optimum fashion.
The invention has the advantage that monitoring can be realized using very simple means. By way of example, only one additional analog module is required for a digital/analog converter or an analog/digital converter, while the rest of the functions are realized in a digital unit 12, for example a programmable digital unit, which is present anyway. Monitoring according to the invention can also be implemented subsequently in an existing converter.
List of reference symbols
1
Converter
1′, 1″, 1′″
Converter section
2
Input variable
3, 3′, 3″, 3′″
Output variable
4
Input detector
5
Input flag
6, 6′, 6″, 6′″
Output detector
7, 7′, 7″, 7′″
Output flag
8
Evaluation unit
9
Status signal
10
Monitoring apparatus
12
Digital unit
41
Input reference value
61, 61′, 61″, 61′″
Output reference value
s1, s2, s3, s4
First, second, third and fourth curve
r1, r2, r3, r4
First, second, third and fourth reference value
d1, d2, d3, d4
First, second, third and fourth tolerance range
f1, f2, f3, f4
First, second, third and fourth flag
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
3816813, | |||
4215412, | Jul 13 1978 | The Boeing Company | Real time performance monitoring of gas turbine engines |
4266292, | Nov 20 1978 | Wescom Switching, Inc. | Method and apparatus for testing analog-to-digital and digital-to-analog code converters |
4419656, | Nov 07 1980 | National Semiconductor Corporation | Method and apparatus for digital converter testing |
4725814, | Apr 30 1986 | Robert Bosch GmbH | Method and circuit for analog to digital conversion of a noisy DC voltage signal |
5132685, | Mar 15 1990 | AT&T Bell Laboratories | Built-in self test for analog to digital converters |
5185607, | Jan 31 1992 | Freescale Semiconductor, Inc | Method and apparatus for testing an analog to digital converter |
5319370, | Aug 31 1992 | Cirrus Logic, INC | Analog-to-digital converter with a continuously calibrated voltage reference |
5321403, | Apr 14 1993 | WOLFF MARKETING GROUP, INC | Multiple slope analog-to-digital converter |
6087948, | Jun 03 1997 | LEINE & LINDE AB | Encoder |
6177894, | Apr 30 1998 | Advantest Corporation | Evaluation system and method for AD converter |
6297757, | Feb 11 1999 | SHENZHEN XINGUODU TECHNOLOGY CO , LTD | Method and circuit for testing an analog-to-digital converter module on a data processing system having an intermodule bus |
DE251659, | |||
EP883249, |
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