Enhanced TDS
Identification & Functionality
- Chemical Family
- Fillers Included
- RTU Product Type
- Technologies
- Product Families
Features & Benefits
- Ready-to-Use Product Features
- Key Properties
- High mechanical and electrical properties
- Good thermal shock resistance
- Possibility of high filler content
Applications & Uses
- Composites Processing Methods
- Product End Uses
- Remarks
End properties of this system have been tested with silica filler. No flexibilizer is added to produce switch parts, pin insulators and bushings but we recommend to add some flexibilizer for the production of instrument and distribution transformers.
- Processing Methods
- Automatic pressure gelation process (APG)
- Conventional gravity casting process under vacuum
Properties
- Physical Form
- Processing (Guideline Values)
General instructions for preparing liquid resin systems
- Long pot life is desirable in the processing of any casting resin system. Mix all of the components together very thoroughly at room temperature or slightly above and under vacuum. Intensive wetting of the filler is extremely important.
- Proper mixing will result in: - better flow properties and reduced tendency to shrinkage - lower internal stresses and therefore improved mechanical properties on object - improved partial discharge behaviour in high voltage applications.
- For the mixing of medium- to high viscous casting resin systems and for mixing at lower temperatures, we recommend special thin film degassing mixers that may produce additional self-heating of 10-15 °C as a result of friction.
- For low viscous casting resin systems, conventional anchor mixers are usually sufficient. In larger plants, two pre-mixers are used to mix the individual components (resin, hardener) with the respective quantities of fillers and additives under vacuum.
- Metering pumps then feed these premixes to the final mixer or a continuous mixer. The individual premixes can be stored at elevated temperature (about 60°C) for up to about 1 week, de- pending on formulation.
- Intermittent agitation during storage is advisable to prevent filler sedimentation. Mixing time can vary from 0.5 to 3 hours, depending on mixing temperature, quantity, mixing equipment and the particular application. The required vacuum is 0.5 to 8 mbar.
- The vapor pressure of the individual components should be taken into account. In the case of dielectrically highly stressed parts, we recommend checking the quality consistency and pre-drying of the filler. Their moisture content should be < 0.2%.
Specific Instructions
- The effective pot-life of the mix is about 1 to 2 days at temperatures below 25°C. Conventional batch mixers should be cleaned once a week or at the end of work.
- For longer interruptions of work, the pipes of the mixing and metering installations have to be cooled and cleaned with the resin component to prevent sedimentation and/or undesired viscosity increase.
- Interruptions over a week-end (approx. 48h) without cleaning are possible if the pipes are cooled at temperatures below 18°C. For data on viscosity increase and gel time at various temperatures, refer to Figs: 4.1 and 4.4.
Property Value Unit Condition Mould Temperature (APG process) 120 - 150 °C APG process Mould Temperature (Conventional vacuum casting) 80 - 100 °C Conventional vacuum casting
Demoulding Time (APG process) 10 - 45 min APG process Demoulding Time (Conventional vacuum casting) 1 - 6 hours Conventional vacuum casting
Cure Conditions (APG process) 10h hours APG process (minimal postcure)
Cure Conditions (Conventional vacuum casting) 4h at 80°C + 8h at 140°C hours Conventional vacuum casting
- To determine whether crosslinking has been carried to completion and the final properties are optimal, it is necessary to carry out relevant measurements on the actual object or to measure the glass transition temperature.
- Different gelling and cure cycles in the manufacturing process could lead to a different crosslinking and glass transition temperature respectively.
Processing Viscosities
Fig.4.1: Viscosity increase at 60 and 80°C (measurements with Rheomat 115, shear rate D = 10 s-1)
Fig.4.2: Initial viscosity as a function of temperature (measurements with Rheomat 115, D =10 s-1)
Gelation-/Cure Times
Technical Details & Test Data
- Special Properties (Guideline Values)
Mechanical and Physical Properties
Property Value Unit Test Method Condition Tensile Strength 80 - 90 MPa ISO 527 Cured for 10h at 140°C
Elongation at Break 0.90 - 1.10 % ISO 527 Cured for 10h at 140°C
E Modulus from Tensile Test 11'000 - 12'000 MPa ISO 527 Cured for 10h at 140°C
Flexural Strength 125 - 135 MPa ISO 178 Cured for 10h at 140°C
Surface Strain 1.2 - 1.4 % ISO 178 Cured for 10h at 140°C
E Modulus from Flexural Test 11'000 - 12'000 MPa ISO 178 Cured for 10h at 140°C
Impact Strength 8 - 12 kJ/m² ISO 179 Cured for 10h at 140°C
Double Torsion Test - - CG 216-0/89 Cured for 10h at 140°C
Critical Stress Intensity Factor (K1c) - MPa·m¹/² - Cured for 10h at 140°C
Specific Energy at Break (G1c) - J/m² - Cured for 10h at 140°C
Glass Transition Temperature (DSC) 110 - 120 °C ISO 11357-2 Cured for 10h at 140°C
Coefficient of Linear Thermal Expansion 36 - 39.10⁻⁶ K⁻¹ ISO 11359-2 Below Tg, Cured for 10h at 140°C
Thermal Conductivity 0.95 - 1.05 W/mK Similar to ISO 8894-1 Cured for 10h at 140°C
Flammability (Thickness of specimen: 4 mm) HB - UL 94 Specimen: 4 mm, Cured for 10h at 140°C
Flammability (Thickness of specimen: 12 mm) V1 - UL 94 Specimen: 12 mm, Cured for 10h at 140°C
Water Absorption (Specimen: 50×50×4 mm) 0.10 - 0.15 % by wt. ISO 62 10 days at 23°C, Cured for 10h at 140°C
Water Absorption (Specimen: 50×50×4 mm) 0.05 - 0.10 % by wt. ISO 62 60 min at 100°C, Cured for 10h at 140°C
Decomposition Temperature (DTA) ≤ 350 °C DTA Heating rate: 10 K/min, Cured for 10h at 140°C
Density (Filler Load 65% by wt.) 1.75 - 1.85 g/cm³ ISO 1183 Cured for 10h at 140°C
Electrical Properties
Property Value Unit Test Method Condition Breakdown Strength 20 - 24 kV/mm IEC 60243-1 Cured for 10h at 140°C
Diffusion Breakdown Strength - kV/mm IEC 60243-1 Cured for 10h at 140°C
Temperature of Specimen After Test - °C IEC 60243-1 Cured for 10h at 140°C
HV Arc Resistance - class DIN/VDE 0441/1 Cured for 10h at 140°C
Tracking Resistance (Test Solution A) < 23 - IEC 61621 Cured for 10h at 140°C
Tracking Resistance (Test Solution B) 185 - 195 class IEC 60112 Cured for 10h at 140°C
Electrolytic Corrosion - S IEC 60426 Cured for 10h at 140°C
CTI (Comparative Tracking Index) > 600 - < 1 grade IEC 60112 Cured for 10h at 140°C
CTI (Comparative Tracking Index) > 600M - < 1 grade IEC 60112 Cured for 10h at 140°C
Fig.6.1: Loss factor (tan 8) and dielectric constant (Er) as a function of temperature (measurement frequency: 50 Hz, IEC 60250)
Fig.6.2: Volume resistivity (p) as a function of temperature (measurement voltage: 1000 V, IEC 60093)
Fig 7.3: CY 228-2/HY 918-1/ DY 062/ SiO2 : 100 : 80 : 0.8 : 336 pbw Average crack temperature -13°C
- Embedded metal part with 2mm radius
- Passed specimen (%) = f (temp. steps)
- Processing Information
General instructions for preparing liquid resin systems
- Long pot life is desirable in the processing of any casting resin system. Mix all of the components together very thoroughly at room temperature or slightly above and under vacuum. Intensive wetting of the filler is extremely important. Proper mixing will result in:
- better flow properties and reduced tendency to shrinkage
- lower internal stresses and therefore improved mechanical properties on object
- improved partial diskharge behavior in high voltage applications.
- For the mixing of medium- to high viscous casting resin systems and for mixing at lower temperatures, we recommend special degassing mixers that may produce additional selfheating of 10-15°C as a result of friction. For low viscous casting resin sys-tems, conventional mixers are usually sufficient.
- In larger plants, the individual components (resin, hardener) are mixed with the respective quantities of fillers and additives under vacuum. Metering pumps then feed these premixes to the final mixer or a continuous mixer. The individual premixes can be stored at elevated temperature (about 60°C) for up to about 1 week, de-pending on formulation. Intermittent agitation during storage is advisable to prevent filler sedimentation.
- Mixing time can vary from 0.5 to 3 hours, depending on mixing temperature, quantity, mixing equipment and the particular application. The required vacuum is 0.5 to 8 mbar. The vapor pressure of the individual components should be taken into account. In the case of dielectrically highly stressed parts, we recommend checking the quality consistency and predrying of the filler. Their moisture content should be <0.2%.
Specific Instructions
The effective pot-life of the mix is about 1 - 2 days at temperatures below 25°C. Conventional batch mixers should be cleaned once a week or at the end of work. For longer interruptions of work, the pipes of the mixing and metering installllations have to be cooled and cleaned with the resin component to prevent sedimentation and/or undesired viscosity increase. Interruptions over a week-end (approx. 48h) without cleaning are possible if the pipes are cooled at temperatures below 18°C. Viscosity increase and gel time at various temperatures.
Mold temperature
APG process: 120 - 150°C
Conventional vacuum casting: 80 - 100°C
Demolding times (depending on mold temperature and casting volume)
APG process: 10 - 45 min
Conventional vacuum casting: 1 - 6 h
Cure conditions
APG process (minimal postcure): 10h at 140°C
Conventional vacuum casting: 4h at 80°C + 8h at 140°C
- To determine whether crosslinking has been carried to completion and the final properties are optimal, it is necessary to carry out relevant measurements on the actual object or to measure the glass transition temperature. Different geling and cure cycles in the manufacturing process could lead to a different crosslinking and glass transition temperature respectively.
Safety & Health
- Handling Precautions
Safety precautions at workplace Protective clothing Yes Gloves Essential Arm protectors Recommended when skin contact likely Goggles/safety glasses Yes Respirator/dust mask No Skin protection Before starting work Apply barrier cream to exposed skin After washing Apply barrier or nourishing cream Cleansing of contaminated skin Dab off with absorbent paper, wash with warm water and alkali-free soap, then dry with disposable towels. Do not use solvents Clean shop requirements Cover workbenches, etc. with light colored paper. Use disposable breakers, etc. Disposal of spillage Soak up with sawdust or cotton waste and deposit in plastic-lined bin Ventilation Of workshop Renew air 3 to 5 times an hour Of workplace Exhaust fans. Operatives should avoid inhaling vapors. - First Aid
Contamination of the eyes by resin, hardener or casting mix should be treatedimmediately by flushing with clean, running water for 10 to 15 minutes. A doctor should then be consulted.
Material smeared or splashed on the skinshould be dabbed off, and the contaminated area then washed and treated with a cleansing cream (see above). A doctor should be consulted in the event of severe irritation or burns. Contaminated clothing should be changed immediately.
Anyone taken ill after inhalingvapors should be moved out of doors immediately. In all cases of doubt call for medical assistance.- Industrial Hygiene
- Mandatory and recommended industrial hygiene procedures should be followed whenever the products are being handled and processed.
Storage & Handling
- Storage Conditions
- Store the components at 18-25°C, in tightly sealed and dry original containers.
- Under these conditions, the shelf life will correspond to the expiry date stated on the label.
- Product specific advise regarding storage can be found on product label. After this date, the product may be processed only following reanalysis.
- Partly emptied containers should be closed tightly immediately after use.
Other
- Application Information
Value Units Test Method / Conditions Mix Ratio 0.008 %(W) %(W) Accelerator : Resin Mix Ratio 0.8 %(W) %(W) Hardener : Resin