Difference between revisions of "Test Procedures for the Communications Technology"

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==13.3 Test Procedures for the Communications Technology==
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==<!--13.3-->Test Procedures for the Communications Technology==
  
 
Testing of the contact behavior in the communications technology is usually performed on the actual devices such as for example in relays. Experience has shown that the interaction between all design and functional parameters such as contact forces, relative movement, and electrical loads, are determining the failure mode. Therefore only statistical performance tests on a larger number of switching devices lead to meaningful results.
 
Testing of the contact behavior in the communications technology is usually performed on the actual devices such as for example in relays. Experience has shown that the interaction between all design and functional parameters such as contact forces, relative movement, and electrical loads, are determining the failure mode. Therefore only statistical performance tests on a larger number of switching devices lead to meaningful results.
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One must differentiate between static tests (for ex. contact resistance) and dynamic ones (for ex. electrical life). In certain electromechanical components and switching devices the contacts can be exposed to both, static and dynamic stresses (for ex. connectors, relays, switches, pushbuttons, circuit breakers). For statically stressed components the life expectancy is usually expressed as a time period, i.e. hours, while for dynamically stressed ones the expected functional life is defined as numbers of operations or switching cycles.  
 
One must differentiate between static tests (for ex. contact resistance) and dynamic ones (for ex. electrical life). In certain electromechanical components and switching devices the contacts can be exposed to both, static and dynamic stresses (for ex. connectors, relays, switches, pushbuttons, circuit breakers). For statically stressed components the life expectancy is usually expressed as a time period, i.e. hours, while for dynamically stressed ones the expected functional life is defined as numbers of operations or switching cycles.  
  
===13.3.1 Measuring of Contact Resistance===
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===<!--13.3.1-->Measuring of Contact Resistance===
  
 
The contact resistance in the new stage is for most contact containing electromechanical components a characteristic defining their quality. It is
 
The contact resistance in the new stage is for most contact containing electromechanical components a characteristic defining their quality. It is
 
defined in most standards and acceptance specifications of users. It is important however that a clear definition of the test conditions is given with the specification.
 
defined in most standards and acceptance specifications of users. It is important however that a clear definition of the test conditions is given with the specification.
  
The standard IEC DIN EN 61810-2 defines the application areas of relays according to their load application categories (CC) <xr id="fig:Schematic describing the contact load categories"/> (Fig. 13.5). The categories CC1 and CC2 are separated by the arc-limiting graph (DC breaking capacity). Switching operations below the graph do not generate electrical arcs, those above the graph are accompanied by electrical arcing.
+
The standard IEC DIN EN 61810-2 defines the application areas of relays according to their load application categories (CC) <xr id="fig:Schematic describing the contact load categories"/><!--(Fig. 13.5)-->. The categories CC1 and CC2 are separated by the arc-limiting graph (DC breaking capacity). Switching operations below the graph do not generate electrical arcs, those above the graph are accompanied by electrical arcing.
  
 
*CC1 is characteristic for switching operations in control circuits at low voltages, for ex. SPS input signals
 
*CC1 is characteristic for switching operations in control circuits at low voltages, for ex. SPS input signals
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</figure>
 
</figure>
  
===13.3.2 Life Testing===
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===<!--13.3.2-->Life Testing===
  
Electrical life is defined as the number of operations under a defined load (make under load current, current carrying, breaking the load current). The total sequence of this switching cycle leads for the specific design parameters of a relay (bounce characteristics, materials, etc.) to the phenomena responsible for the later device failure, such as increased contact resistance, material transfer, arc erosion, and contact welding, for example <xr id="fig:Relation between the breaking currents of relays and electrical life requirements of switching systems"/> (Fig. 13.6).
+
Electrical life is defined as the number of operations under a defined load (make under load current, current carrying, breaking the load current). The total sequence of this switching cycle leads for the specific design parameters of a relay (bounce characteristics, materials, etc.) to the phenomena responsible for the later device failure, such as increased contact resistance, material transfer, arc erosion, and contact welding, for example <xr id="fig:Relation between the breaking currents of relays and electrical life requirements of switching systems"/><!--(Fig. 13.6)-->.
  
 
As experience shows, failures during load switching are usually related to deterioration of the contact parts. Therefore the mechanical life must always be higher than the electrical life under the required load conditions. Typically the mechanical life is about 10 times higher than the electrical one.
 
As experience shows, failures during load switching are usually related to deterioration of the contact parts. Therefore the mechanical life must always be higher than the electrical life under the required load conditions. Typically the mechanical life is about 10 times higher than the electrical one.
  
===13.3.3 Criteria for Functional Life===
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===<!--13.3.3-->Criteria for Functional Life===
  
 
In the communications technology the functional life criteria for switching devices, following conventional standards and specifications are:
 
In the communications technology the functional life criteria for switching devices, following conventional standards and specifications are:
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Because of this an exact definition for the failure mode must be provided. In most cases the first failure occurrence is defined as the overall device failure, since relays are increasingly used in safety related electrical circuits. Failures to open because of contact welding must be very critically examined. In some instances a weak weld or “sticking” of the contacts can cause a delayed opening and separation of the contacts by themselves. Therefore it is useful to define weld failures as non-opening after a specified time, approx. 1 sec, after the actual switching-off event.
 
Because of this an exact definition for the failure mode must be provided. In most cases the first failure occurrence is defined as the overall device failure, since relays are increasingly used in safety related electrical circuits. Failures to open because of contact welding must be very critically examined. In some instances a weak weld or “sticking” of the contacts can cause a delayed opening and separation of the contacts by themselves. Therefore it is useful to define weld failures as non-opening after a specified time, approx. 1 sec, after the actual switching-off event.
  
===13.3.4 Determination of Functional Life===
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===<!--13.3.4-->Determination of Functional Life===
  
 
Electrical life, failure rate, and reliability are statistical measures. To determine the electrical life the relays are switching the specified load in an accelerated way with higher switching frequency until the first pre-defined failure occurs. The number of switching operations reached for the representative sample size of relays is determined through statistically valid test setups using Weibull distributions. For all switching operations the failure criteria must be monitored and recorded.
 
Electrical life, failure rate, and reliability are statistical measures. To determine the electrical life the relays are switching the specified load in an accelerated way with higher switching frequency until the first pre-defined failure occurs. The number of switching operations reached for the representative sample size of relays is determined through statistically valid test setups using Weibull distributions. For all switching operations the failure criteria must be monitored and recorded.
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</figure>
 
</figure>
  
The large quantity of data generated during the tests can be only analyzed with computer based test systems. After all the relays failed a failure statistic is calculated and the expected electrical life is calculated based on the specified switching and operating criteria. <xr id="fig:Statistical evaluation of the electrical life of relays"/> (Fig. 13.7) shows in form of a Weibull diagram the results of a relay life test for a sampling of switching relays under a resistive AC load with failures after the first and the 10<sup>th</sup> occurrence analyzed. From such electrical life test it is also possible to statistically predict the failure rate of relays under certain specified load conditions.
+
The large quantity of data generated during the tests can be only analyzed with computer based test systems. After all the relays failed a failure statistic is calculated and the expected electrical life is calculated based on the specified switching and operating criteria. <xr id="fig:Statistical evaluation of the electrical life of relays"/><!--(Fig. 13.7)--> shows in form of a Weibull diagram the results of a relay life test for a sampling of switching relays under a resistive AC load with failures after the first and the 10<sup>th</sup> occurrence analyzed. From such electrical life test it is also possible to statistically predict the failure rate of relays under certain specified load conditions.
  
===13.3.5 Testing Technology===
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===<!--13.3.5-->Testing Technology===
  
The test set-ups for relay tests consist of a load part, which allows the selection of specific electrical loads, and a control / monitoring part, which typically includes the measuring devices with data collection and mostly also a computer for data analysis <xr id="fig:Principle and sequence of testing with electronic load simulation"/> (Fig. 13.8). Variations for testing of different relay types concern mostly the load circuits, the sample size of test specimens, and the frequency of testing.
+
The test set-ups for relay tests consist of a load part, which allows the selection of specific electrical loads, and a control / monitoring part, which typically includes the measuring devices with data collection and mostly also a computer for data analysis <xr id="fig:Principle and sequence of testing with electronic load simulation"/><!--(Fig. 13.8)-->. Variations for testing of different relay types concern mostly the load circuits, the sample size of test specimens, and the frequency of testing.
  
 
*Signal Relays (Low Current Relays)
 
*Signal Relays (Low Current Relays)
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*Automotive Relays
 
*Automotive Relays
  
For these relays electrical life tests are conducted under the DC voltage used in the on-board circuitry. Since no standardized tests have been established for automotive relays, the electrical loads are agreed upon between the supplier and the end user. The multitude of load conditions, i.e. resistive, inductive motor, and lamp loads require a flexible set-up of suitable test equipment (see <xr id="fig:Principle and sequence of testing with electronic load simulation"/> (Fig. 13.8).
+
For these relays electrical life tests are conducted under the DC voltage used in the on-board circuitry. Since no standardized tests have been established for automotive relays, the electrical loads are agreed upon between the supplier and the end user. The multitude of load conditions, i.e. resistive, inductive motor, and lamp loads require a flexible set-up of suitable test equipment (see <xr id="fig:Principle and sequence of testing with electronic load simulation"/>)<!--(Fig. 13.8)-->.
  
 
During accelerated life tests the following parameters from real life loads must be observed:
 
During accelerated life tests the following parameters from real life loads must be observed:
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These requirements lead to the need to simulate the real life loads through electronically controlled load circuits. Such computerized electronic load circuit simulations easily allow the test sequences to be controlled and monitored:
 
These requirements lead to the need to simulate the real life loads through electronically controlled load circuits. Such computerized electronic load circuit simulations easily allow the test sequences to be controlled and monitored:
<figure id="fig:Automotive relays under motor load">
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[[File:Automotive relays under motor load.jpg|right|thumb|Automotive relays under motor load: Results of electrical life testing using different contact materials]]
 
</figure>
 
 
* Time saving test runs for lamp loads by reducing interval times Monitoring of each switching operation for electrical life criteria Allowing to recognize non separation of the contacts after a pre-set time limit to be classified as a relay fallure
 
* Time saving test runs for lamp loads by reducing interval times Monitoring of each switching operation for electrical life criteria Allowing to recognize non separation of the contacts after a pre-set time limit to be classified as a relay fallure
  
Results of relay life testing using different contact materials are illustrated as an example in <xr id="fig:Automotive relays under motor load"/> (Fig. 13.9). For each contact material 10 relays were tested under the prescribed motor load until a failure due to non-opening was detected. For this specific load condition AgNiO. 15 was found to be the best suited contact material.
+
Results of relay life testing using different contact materials are illustrated as an example in <xr id="fig:Automotive relays under motor load"/> <!--(Fig. 13.9)-->. For each contact material 10 relays were tested under the prescribed motor load until a failure due to non-opening was detected. For this specific load condition AgNiO. 15 was found to be the best suited contact material.
  
===13.3.6 Failure Analysis===
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===<!--13.3.6-->Failure Analysis===
 
 
The full clarification of causes for switching device failures, for example relays, is most important for quality assurance. As a starting point the full history of the relay, such as electrical load, environmental conditions, etc. must be recorded. The process flow chart in Fig. 13.10 clearly describes a proven way to conduct a failure analysis.
 
 
 
Fig. 13.10:
 
Flow diagram for
 
evaluation of failure
 
cause in switching
 
devices for
 
communications
 
technology
 
  
 +
The full clarification of causes for switching device failures, for example relays, is most important for quality assurance. As a starting point the full history of the relay, such as electrical load, environmental conditions, etc. must be recorded. The process flow chart in <xr id="fig:Flow diagram for evaluation of failure cause in switching devices for communications technology"/><!--(Fig. 13.10)--> clearly describes a proven way to conduct a failure analysis.
 +
<figure id="fig:Flow diagram for evaluation of failure cause in switching devices for communications technology">
 +
[[File:Flow diagram for evaluation of failure cause in switching devices for communications technology.jpg|right|thumb|Flow diagram for evaluation of failure cause in switching devices for communications technology]]
 +
</figure>
 
Following all procedures of such a failure evaluation carefully, the root cause of the defect can most likely be established in order to implement preventive measures limiting future occurrences.
 
Following all procedures of such a failure evaluation carefully, the root cause of the defect can most likely be established in order to implement preventive measures limiting future occurrences.
  
 
==References==
 
==References==
 
[[Testing Procedures#References|References]]
 
[[Testing Procedures#References|References]]
 +
 +
[[de:Prüfverfahren_in_der_Informationstechnik]]

Revision as of 22:03, 21 September 2014

Test Procedures for the Communications Technology

Testing of the contact behavior in the communications technology is usually performed on the actual devices such as for example in relays. Experience has shown that the interaction between all design and functional parameters such as contact forces, relative movement, and electrical loads, are determining the failure mode. Therefore only statistical performance tests on a larger number of switching devices lead to meaningful results.

One must differentiate between static tests (for ex. contact resistance) and dynamic ones (for ex. electrical life). In certain electromechanical components and switching devices the contacts can be exposed to both, static and dynamic stresses (for ex. connectors, relays, switches, pushbuttons, circuit breakers). For statically stressed components the life expectancy is usually expressed as a time period, i.e. hours, while for dynamically stressed ones the expected functional life is defined as numbers of operations or switching cycles.

Measuring of Contact Resistance

The contact resistance in the new stage is for most contact containing electromechanical components a characteristic defining their quality. It is defined in most standards and acceptance specifications of users. It is important however that a clear definition of the test conditions is given with the specification.

The standard IEC DIN EN 61810-2 defines the application areas of relays according to their load application categories (CC) Figure 1. The categories CC1 and CC2 are separated by the arc-limiting graph (DC breaking capacity). Switching operations below the graph do not generate electrical arcs, those above the graph are accompanied by electrical arcing.

  • CC1 is characteristic for switching operations in control circuits at low voltages, for ex. SPS input signals
  • CC2 is typical for release circuits in low voltage controls which for example actuate contactors (220 - 240 VAC)
  • CC0 describes as a special application the voltage – current range for dry circuits
Schematic describing the contact load categories in the current-voltage ranges according to IEC DIN EN 61810-2. Arc-limiting graph for an arc duration < 1 ms

The measuring conditions for contact resistance measurement are defined per IEC DIN EN 61810-7 for the contact load categories as follows:

  • Contact load category CC0: < 30 mV; < 10 mA
  • Contact load category CC1: < 10 V; < 100 mA
  • Contact load category CC2: < 30 V; < 1 A

For contacts designed to cover multiple load ranges the measuring category for the lowest range must be used. Contact resistance measurement usually is carried out following the 4-wire method at a temperature of 27°C ± 1°C and relative humidity of 63 – 67% RH.

By adding an upper threshold value (for ex. the 90% contact resistance value of the statistical cumulative frequency) it can be assured that that contacts are fulfilling the requirement from their new state for the respective application. The current carrying in normally dynamically operating devices is also assured by this measurement procedure. It is however not a valid indicator for the further behavior in a given application. To determine this, electrical life tests have to be performed under real electrical loads.

Relation between the breaking currents of relays and electrical life requirements of switching systems

Life Testing

Electrical life is defined as the number of operations under a defined load (make under load current, current carrying, breaking the load current). The total sequence of this switching cycle leads for the specific design parameters of a relay (bounce characteristics, materials, etc.) to the phenomena responsible for the later device failure, such as increased contact resistance, material transfer, arc erosion, and contact welding, for example Figure 2.

As experience shows, failures during load switching are usually related to deterioration of the contact parts. Therefore the mechanical life must always be higher than the electrical life under the required load conditions. Typically the mechanical life is about 10 times higher than the electrical one.

Criteria for Functional Life

In the communications technology the functional life criteria for switching devices, following conventional standards and specifications are:

  • Failure to close by exceeding an upper limit for the contact resistance
  • Failure to open by contact welding at a higher force than specifiedor by mechanical interlocking
  • Switching characteristics strongly changed by arc erosion or material transfer

As opposed to electronic components, failures in electromechanical devices can occur once and not repeat at all or at considerably later stages of the life time.

Because of this an exact definition for the failure mode must be provided. In most cases the first failure occurrence is defined as the overall device failure, since relays are increasingly used in safety related electrical circuits. Failures to open because of contact welding must be very critically examined. In some instances a weak weld or “sticking” of the contacts can cause a delayed opening and separation of the contacts by themselves. Therefore it is useful to define weld failures as non-opening after a specified time, approx. 1 sec, after the actual switching-off event.

Determination of Functional Life

Electrical life, failure rate, and reliability are statistical measures. To determine the electrical life the relays are switching the specified load in an accelerated way with higher switching frequency until the first pre-defined failure occurs. The number of switching operations reached for the representative sample size of relays is determined through statistically valid test setups using Weibull distributions. For all switching operations the failure criteria must be monitored and recorded.

Statistical evaluation of the electrical life of relays (Operating parameters: 220VAC, 8A, 0.1Hz, resistive load; contact material AgCdO 90/10)

The large quantity of data generated during the tests can be only analyzed with computer based test systems. After all the relays failed a failure statistic is calculated and the expected electrical life is calculated based on the specified switching and operating criteria. Figure 3 shows in form of a Weibull diagram the results of a relay life test for a sampling of switching relays under a resistive AC load with failures after the first and the 10th occurrence analyzed. From such electrical life test it is also possible to statistically predict the failure rate of relays under certain specified load conditions.

Testing Technology

The test set-ups for relay tests consist of a load part, which allows the selection of specific electrical loads, and a control / monitoring part, which typically includes the measuring devices with data collection and mostly also a computer for data analysis Figure 4. Variations for testing of different relay types concern mostly the load circuits, the sample size of test specimens, and the frequency of testing.

  • Signal Relays (Low Current Relays)

The DC load conditions are specified in the relevant standards (for ex. Telecom Specifications).

Principle and sequence of testing with electronic load simulation
Automotive relays under motor load: Results of electrical life testing using different contact materials
  • Switching of “dry circuits” with monitoring of the contact resistance, in some cases at elevated temperatures
  • Two load conditions at 30 W (125 VDC, 0.24 A and 37.5 VDC, 0.8 A
  • Two wiring load conditions
  • Two different overload conditions at 60 W (250 VDC, 0.24 A and 37.7 VDC, 1.6 A)

The number of test samples varies between 3 and 20 pieces, depending on the load; the switching frequency varies between 0.3 and 10 Hz. The test set-up has to follow the regulations of IEC DIN EN 61810-2.

  • Elementary Relays (or General Purpose Relays / Switching Relays)

For these relays electrical life tests according to their various DC as well as AC load conditions are required. These load conditions are also defined in well known VDE standards for power engineering products (IEC/EN 60947-4-1, IEC DIN EN 61810-2). The number of samples (mostly < 10 relays, and testing frequency are defined. Often tests for these load characteristics are used for the selection of optimum contact materials.

  • Automotive Relays

For these relays electrical life tests are conducted under the DC voltage used in the on-board circuitry. Since no standardized tests have been established for automotive relays, the electrical loads are agreed upon between the supplier and the end user. The multitude of load conditions, i.e. resistive, inductive motor, and lamp loads require a flexible set-up of suitable test equipment (see Figure 4).

During accelerated life tests the following parameters from real life loads must be observed:

  • Lamp loads are strongly temperature dependent resistive loads. Therefore a sufficient cooling time of the bulb filaments must be allowed.
  • The actual loads used in test experiments wear over time and must be replaced at regular intervals.
  • Tests at low temperatures require large cooled climate chambers and extended cool-down times.

These requirements lead to the need to simulate the real life loads through electronically controlled load circuits. Such computerized electronic load circuit simulations easily allow the test sequences to be controlled and monitored:

  • Time saving test runs for lamp loads by reducing interval times Monitoring of each switching operation for electrical life criteria Allowing to recognize non separation of the contacts after a pre-set time limit to be classified as a relay fallure

Results of relay life testing using different contact materials are illustrated as an example in Figure 5 . For each contact material 10 relays were tested under the prescribed motor load until a failure due to non-opening was detected. For this specific load condition AgNiO. 15 was found to be the best suited contact material.

Failure Analysis

The full clarification of causes for switching device failures, for example relays, is most important for quality assurance. As a starting point the full history of the relay, such as electrical load, environmental conditions, etc. must be recorded. The process flow chart in Figure 6 clearly describes a proven way to conduct a failure analysis.

Flow diagram for evaluation of failure cause in switching devices for communications technology

Following all procedures of such a failure evaluation carefully, the root cause of the defect can most likely be established in order to implement preventive measures limiting future occurrences.

References

References