BS EN 60684-2:2011:2012 Edition
$215.11
Flexible insulating sleeving – Methods of test
| Published By | Publication Date | Number of Pages |
| BSI | 2012 | 88 |
IEC 60684-2:2011 gives methods of test for flexible insulating sleeving, including heat-shrinkable sleeving, intended primarily for insulating electrical conductors and connections of electrical apparatus, although they may be used for other purposes. The tests specified are designed to control the quality of the sleeving but it is recognized that they do not completely establish the suitability of sleeving for impregnation or encapsulation processes or for other specialized applications. Where necessary, the test methods in this part will need to be supplemented by appropriate impregnation or compatibility tests to suit the individual circumstances. The main changes from the previous edition are as follows: three additional methods for circumferential extension, voltage proof and thermal shock and alignment with North American methods.
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 8 | English CONTENTS |
| 11 | INTRODUCTION |
| 12 | 1 General |
| 14 | 2 Test conditions 3 Measurements of bore, wall thickness and concentricity |
| 16 | 4 Density |
| 17 | 5 Resistance to splitting after heating 6 Heat shock (resistance to heat) |
| 18 | 7 Resistance to soldering heat 8 Loss in mass on heating of uncoated textile glass sleeving |
| 19 | 9 Longitudinal change |
| 20 | 10 Deformation under load (resistance to pressure at elevated temperature) |
| 22 | 11 Thermal stability of PVC sleeving |
| 23 | 12 Volatile content of silicone sleeving 13 Bending after heating |
| 24 | 14 Bending at low temperature 15 Brittleness temperature |
| 25 | 16 Dimensional stability on storage (applicable to heat-shrinkable sleeving only) 17 Hydrolysis of coating |
| 26 | 18 Flexibility (extruded sleeving only) 19 Tensile strength, tensile stress at 100 % elongation, elongation at breakand secant modulus at 2 % elongation |
| 30 | 20 Fraying resistance test |
| 31 | 21 Breakdown voltage |
| 33 | 22 Insulation resistance |
| 34 | 23 Volume resistivity |
| 35 | 24 Permittivity and dissipation factor |
| 36 | 25 Resistance to tracking 26 Flame propagation tests |
| 39 | 27 Oxygen index 28 Transparency 29 Ionic impurities test |
| 40 | 30 Silver staining test 31 Electrolytic corrosion resistance |
| 41 | 32 Corrosion resistance (tensile and elongation) 33 Copper corrosion (presence of corrosive volatiles) |
| 42 | 34 Colour fastness to light |
| 43 | 35 Resistance to ozone 36 Resistance to selected fluids |
| 44 | 37 Thermal endurance 38 Mass per unit length |
| 45 | 39 Heat ageing |
| 46 | 40 Water absorption 41 Restricted shrinkage (applicable to heat-shrinkable sleeving only) |
| 47 | 42 Colour stability to heat 43 Smoke index |
| 52 | 44 Toxicity index |
| 57 | 45 Halogen content |
| 59 | 46 Acid gas generation 47 Hot elongation and hot set |
| 60 | 48 Tension set (applicable to elastomeric sleeving only) 49 Tear propagation (applicable to elastomeric sleeving only) |
| 61 | 50 Long term heat ageing (3 000 h) 51 Dynamic shear at ambient temperature |
| 62 | 52 Dynamic shear at elevated temperature 53 Dynamic shear after heat shock and heat ageing |
| 63 | 54 Rolling drum peel to aluminium 55 Aluminium rod dynamic shear |
| 64 | 56 Sealing |
| 65 | 57 Adhesive T peel strength of two bonded heat-shrinkable substrates |
| 66 | 58 Circumferential extension |
| 67 | 59 Voltage proof 60 Thermal shock |
| 68 | Figures Figure 1 – Specimen for test resistance to soldering heat |
| 69 | Figure 2 – Examples of sleeving after being subjected to testfor resistance to soldering heat Figure 3 – Arrangement for the test for resistanceto pressure at elevated temperature (Method A) |
| 70 | Figure 4 – Arrangement for deformation under load (Method B) |
| 71 | Figure 5 – Dumb-bell specimen for tensile strength test (ISO 37 Type2) Figure 6 – Dumb-bell specimen for tensile strength test (ISO 37 Type 1) |
| 72 | Figure 7 – Sketch of fray test arrangement |
| 73 | Figure 8 – Specimen for insulation resistance test |
| 74 | Figure 9 – Standard propane burnerfor flame propagation test (sectional view) |
| 75 | Figure 10 – Flame propagation test – Method A |
| 76 | Figure 11 – Flame propagation test – Method B |
| 77 | Figure 12 – Flame propagation test – Method C |
| 78 | Figure 13 – Mandrel for restricted shrinkage test |
| 79 | Figure 14 – Schematic details of burner for smoke index test |
| 80 | Figure 15 – Schematic front view of smoke test sample holder,showing vertically mounted sleeving samples |
| 81 | Figure 16 – Assembly and fixture for dynamic shear at ambient temperature |
| 82 | Figure 17 – Assembly for heat shock and heat ageing |
| 83 | Figure 19 – Assembly preparation for aluminium rod dynamic shear Figure 20 – Test specimen for aluminium rod dynamic shear |
| 84 | Figure 21 – Assembly for sealing test Figure 22 – Mandrel assembly |
| 85 | Figure 23 – Slab specimen Figure 24 – T peel strength specimen |
| 86 | Bibliography |
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