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BS EN 61400-25-6:2017 – TC:2020 Edition

BS EN 61400-25-6:2017 – TC:2020 Edition

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Tracked Changes. Wind energy generation systems – Communications for monitoring and control of wind power plants. Logical node classes and data classes for condition monitoring

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BSI 2020 131
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IEC 61400-25-6:2016 specifies the information models related to condition monitoring for wind power plants and the information exchange of data values related to these models. This standard is to be used with other standards of the IEC 61400-25 series. This new edition includes the following significant technical changes with respect to the previous edition: – major restructuring of the data model to accommodate flexibility; removal of UFF58 format; – access to data using the standard reporting and logging functions; – recommendations for creating data names to accommodate flexibility

PDF Catalog

PDF Pages PDF Title
77 National foreword
80 Annex ZA(normative)Normative references to international publicationswith their corresponding European publications
82 CONTENTS
85 FOREWORD
87 INTRODUCTION
88 Figures
Figure 1 – Condition monitoring with separated TCD/CMD functions
89 1 Scope
Figure 2 – Schematic flow of condition monitoring information
90 2 Normative references
3 Terms and definitions
92 4 Abbreviated terms
93 Tables
Table 1 – Abbreviated terms applied
94 5 General
5.1 Overview
5.2 Condition monitoring information modelling
95 5.3 Coordinate system applied for identifying direction and angles
Figure 3 – Reference coordinates system for the drive train
Table 2 – Coordinate system and wind turbine related characteristics
96 5.4 Operational state bin concept
5.4.1 General
5.4.2 Example of how to use active power as an operational state
6 Logical nodes for wind turbine condition monitoring
6.1 General
Figure 4 – Active power bin concept
97 6.2 Logical nodes inherited from IEC 61400-25-2
6.3 Wind turbine condition monitoring logical node WCON
6.3.1 General
98 6.3.2 CDCs applicable for the logical node WCON
7 Common data classes for wind turbine condition monitoring
7.1 General
7.2 Common data classes defined in IEC 61400-25-2
7.3 Conditions for data attribute inclusion
Table 3 – LN: Wind turbine condition monitoring information (WCON)
99 7.4 Common data class attribute name semantic
Table 4 – Conditions for the presence of a data attribute
100 7.5 Condition monitoring bin (CMB)
Table 5 – Common data class attribute name semantic
101 7.6 Condition monitoring measurement (CMM)
Table 6 – CDC: Condition monitoring bin (CMB)
102 7.7 Scalar value array (SVA)
Table 7 – CDC: Condition monitoring measurement (CMM)
103 7.8 Complex measurement value array (CMVA)
Table 8 – CDC: Scalar value array (SVA)
104 8 Common data class CMM attribute definitions
8.1 General
Table 9 – CDC: Complex measurement value array (CMVA)
105 8.2 Attributes for condition monitoring measurement description
8.2.1 General
8.2.2 Condition monitoring sensor (trd)
Table 10 – Data attributes used for measurement description
Table 11 – Sensor identification convention for “trd” attribute
106 Table 12 – Abbreviated terms for “trd” – “location” description
108 Table 13 – Sensor type code
109 Figure 5 – Sensor angular orientation as seen from the rotor end
Figure 6 – Sensor motion identification
Table 14 – Reference code for sensor sensitive axis orientation
110 8.2.3 Shaft identification (shfId) and bearing position (brgPos)
Figure 7 – Sensor normal and reverse motion
111 8.2.4 Measurement type (mxType)
Figure 8 – Principle of shaft and bearing identification along a drive train
Table 15 – Gearbox shaft and bearing identification
113 Annexes
Annex A (informative) Recommended mxType values
A.1 General about tag names and datanames of the WCON Class
A.2 Mapping of measurement tags to mxTypes
A.2.1 General
A.2.2 Scalar values (MV) (Descriptors)
A.2.3 Array measurements (SVA) – Frequency domain
A.2.4 Array measurements (SVA) – Time domain
A.3 mxType values
114 Table A.1 – Examples of applicable mappings from tag to MxType
117 Annex B (informative) Application of data attributes for condition monitoring measurement description for measurement tag naming
B.1 General
B.2 Naming principle using the data attributes in CMM CDC
Figure B.1 – Naming principles for trd data attribute
118 B.3 Examples
Table B.1 – Examples of Tag names and corresponding short datanames
119 Annex C (informative) Condition monitoring bins examples
C.1 Example 1: One dimensional bins
Table C.1 – CMB example 1
Table C.2 – CMB data object example 1
120 C.2 Example 2: Two dimensional bins
Figure C.1 – Bin configuration example 1
121 Table C.3 – CMB example 2
Table C.4 – CMB data object example 2
122 C.3 Example 3: Two dimensional bins with overlap
Figure C.2 – Bin configuration example 2
123 Table C.5 – CMB example 3
Table C.6 – CMB data object example 3
124 Figure C.3 – Bin configuration example 3
125 Annex D (informative) Application example
D.1 Overview of CDCs essential to IEC 61400-25-6
D.2 How to apply data to CDCs
Figure D.1 – Linkage of the CDCs
126 Table D.1 – Object overview
Table D.2 – Name plate (LPL)
127 D.3 How to apply an alarm
Table D.3 – CDC example: Condition monitoring measurement (CMM)
Table D.4 – CDC example: Condition monitoring bin (CMB)
128 Table D.5 – CDC example: Alarm definition (ALM)
Table D.6 – LN example: Alarm container definition
129 Bibliography

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