BS EN IEC 60567:2024

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Oil-filled electrical equipment. Sampling of free gases and analysis of free and dissolved gases in mineral oils and other insulating liquids. Guidance

Published By	Publication Date	Number of Pages
BSI	2024	68

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Categories: 29.040.10 - Insulating oils, BSI

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Description

IEC 60567:2023 deals with the techniques for sampling free gases from gas-collecting relays from power transformers. Three methods of sampling free gases are described. The techniques for sampling oil from oil-filled equipment such as power and instrument transformers, reactors, bushings, oil-filled cables and oil-filled tank-type capacitors are no longer covered by this document, but are instead described in IEC 60475:2022, 4.2. Before analysing the gases dissolved in oil, they are first extracted from the oil. Three basic methods are described, one using extraction by vacuum (Toepler and partial degassing), another by displacement of the dissolved gases by bubbling the carrier gas through the oil sample (stripping) and the last one by partition of gases between the oil sample and a small volume of the carrier gas (headspace). The gases are analysed quantitatively after extraction by gas chromatography; a method of analysis is described. Free gases from gas-collecting relays are analysed without preliminary treatment.

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PDF Pages	PDF Title
2	undefined
5	Annex ZA (normative)Normative references to international publicationswith their corresponding European publications
6	English CONTENTS
9	FOREWORD
11	INTRODUCTION
13	1 Scope 2 Normative references
14	3 Terms, definitions, symbols and abbreviated terms 3.1 Terms and definitions 3.2 Symbols and abbreviated terms 3.2.1 Symbols 3.2.2 Abbreviated terms
15	4 Sampling of gases from gas-collecting relays 4.1 General remarks 4.2 Sampling of free gases by syringe 4.2.1 Sampling equipment
16	4.2.2 Sampling procedure Figures Figure 1 – Sampling of gas by syringe
17	4.3 Sampling of free gases by displacement of oil 4.4 Sampling of free gases by vacuum Figure 2 – Sampling of free gases by oil displacement
18	Figure 3 – Sampling of free gases by vacuum
19	4.5 Sampling of oil from oil filled equipment 5 Labelling of gas samples 6 Sampling, labelling and transferring of oil from oil-filled equipment 6.1 Sampling and labelling of oil 6.2 Transfer of oil for DGA analysis 6.2.1 General 6.2.2 Transfer from oil syringes Tables Table 1 – Information required for gas samples
20	6.2.3 Transfer from ampoules 6.2.4 Transfer from flexible metal bottles 6.2.5 Transfer from glass and rigid metal bottles 7 Preparation of gas-in-oil standards 7.1 General remarks 7.2 First method: preparation of a large volume of gas-in-oil standard 7.2.1 Equipment
21	7.2.2 Procedure
22	Figure 4 – First method of preparing gas-in-oil standards
23	7.2.3 Calculation 7.3 Second method: preparation of gas-in-oil standards in a syringe or a vial 7.3.1 General
24	Figure 5 – Second method for preparing gas-in-oil standards
25	7.3.2 Equipment 7.3.3 Procedure 8 Extraction of gases from oil 8.1 General remarks
26	8.2 Multi-cycle vacuum extraction using Toepler pump apparatus 8.2.1 General 8.2.2 Toepler pump extraction apparatus
28	Figure 6 – Example of a Toepler pump extraction apparatus
29	8.2.3 Extraction procedure
30	8.3 Vacuum extraction by partial degassing method 8.3.1 General remarks 8.3.2 Partial degassing apparatus
31	8.3.3 Extraction procedure 8.4 Stripping extraction method 8.4.1 General 8.4.2 Stripping apparatus
32	Figure 7 – Types of glass strippers
33	Figure 8 – Stainless steel stripper
34	8.4.3 Outline of procedure Figure 9 – Schematic arrangement for connecting an oil stripper to a gas chromatograph
35	8.5 Headspace method 8.5.1 Principle of the method Figure 10 – Schematic representation of headspace sampler
36	8.5.2 Headspace extraction apparatus
37	Figure 11 – Vial filled with water
39	Figure 12 – Revolving table
40	8.5.3 Headspace extraction procedure Table 2 – Examples of headspace operating conditions
44	8.5.4 Calibration of the headspace extractor
46	9 Gas analysis by gas-solid chromatography 9.1 General remarks Table 3 – Examples of headspace partition coefficients at 70 °C in mineral insulating oil
47	Table 4 – Examples of gas chromatographic operating conditions
48	9.2 Outline of suitable methods using Table 4 9.3 Apparatus 9.3.1 Gas chromatograph
49	Figure 13 – Schematic arrangement for gas chromatography
50	9.3.2 Columns 9.3.3 Carrier gas 9.3.4 Detectors 9.3.5 Methanator 9.3.6 Cold trap 9.3.7 Integrator and recorder
51	9.4 Preparation of apparatus 9.5 Analysis 9.6 Calibration of the chromatograph
52	9.7 Calculations 10 Quality control 10.1 Verification of the entire analytical system
53	10.2 Limits of detection and quantification Table 5 – Required limits of detection in oil
54	10.3 Repeatability, reproducibility and accuracy 10.3.1 General remark 10.3.2 Repeatability 10.3.3 Reproducibility
55	10.3.4 Accuracy 11 Report of results Table 6 – Examples of accuracy of extraction methods
57	Annexes Annex A (informative) Correction for incomplete gas extraction in partial degassing method by calculation Table A.1 – Examples of solubility coefficients ai (at 25 °C) reported by CIGRE TF D1.01.15 in 2006
58	Annex B (informative) Alternative gas extraction methods B.1 Mercury-free versions of the vacuum extraction methods B.1.1 Mercury-free version of the Toepler method B.1.2 Mercury-free version of the partial degassing method B.2 Syringe versions of the headspace method B.2.1 Shake test method
59	Figure B.1 – Schematic representation of mercury-free Toepler method Figure B.2 – Schematic representation of mercury-free partial degassing method Figure B.3 – Schematic representation of shake test method
60	B.2.2 Mechanical oscillation method Figure B.4 – Schematic representations of mechanical oscillation method
61	Annex C (informative) Preparation of air-saturated standards Table C.1 – Examples of solubility values of air for different oil types Table C.2 – Examples of temperature variations for oxygen and nitrogen solubility in mineral oil
62	Annex D (informative) Correction for gas bubbles in syringes and air gap in rigid bottles
63	Annex E (informative) Procedure for comparing gas monitor readings to laboratory results
64	Annex F (normative) Insulating liquids based on synthetic and natural esters and silicones
66	Bibliography

Additional information

Status	Definitive
Pages	68
Publication Date	2024-01-24
ISBN	978 0 539 18784 7
Standard Number	BS EN IEC 60567:2024
Title	Oil-filled electrical equipment. Sampling of free gases and analysis of free and dissolved gases in mineral oils and other insulating liquids. Guidance
Identical National Standard Of	EN 60567 Ed.5.0, IEC 60567 Ed.5.0
Replaces	BS EN 60567:2011
Descriptors	Extraction methods of analysis, Chemical analysis and testing, Oils, Testing conditions, Mineral oils, Relays, Precision, Insulating oils, Sampling equipment, Degassing (chemical technology), Quantitative analysis, Dissolved gases, Accuracy, Test equipment, Gas analysis, Sampling methods, Sensitivity, Gas-solid chromatography, Control samples, Error correction, Calibration, Electrical equipment, Gases, Samples, Oil-filled electrical equipment
Publisher	BSI
Committee	GEL/10
ICS Codes	29.040.10 - Insulating oils

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