Evaluation of the Stability of Dielectric Nanofluids for Use in Transformers under Real Operating Conditions
Abstract
:1. Introduction
2. Materials and Methods
2.1. Materials
2.1.1. Base Fluids
2.1.2. Nanoparticles
- A dispersion of Fe3O4 NP of approximate diameter 10 nm dispersed in a hydrocarbon to a concentration of 50% by weight (i.e., 500 g of NP in 1 kg of dispersion) manufactured by the company Magnacol Ltd (Newtown, UK). From now on this dispersion will be referred to as FF1.
- A dispersion of Fe3O4 NP of diameter 10 nm dispersed in a mixture of hydrocarbons, silicon compounds and non-flammable oils manufactured by the company MAGRON (Gyeonggi-Do, Korea), and commercialized by the company Supermagnete (Gottmadingen, Germany) under the name MFR-DP1. The concentration of this fluid is 60% by weight. From now on this dispersion will be referred to as FF2.
2.2. Synthesis of the DNF
- -
- The BF (MO or NE) is dried under vacuum (0.1 bar) for 24 h at 70 °C.
- -
- In this work DNF with different concentrations of NP were prepared (although not all of them were tested in the stability study, as will be later explained). To obtain the different concentrations, the required mass of NP dispersion is weighed in an analytical balance and added to the BF. In the case of the MO-based DNF with FF2 the concentrations were 0.05, 0.1, 0.2 and 0.35 g/L (i.e., 0.05 g, 0.1 g, 0.2g and 0.35 g of Fe3O4 NP in 1 L of BF). To obtain these concentrations 10, 20, 40, and 70 mg of FF2 were added to 100 mL of MO. In the case of NE-based DNF and FF1, concentrations 0.1 and 0.15 g/L were prepared, as samples with higher concentrations precipitated in a few hours. For the combinations MO + FF1 and NE + FF2 only samples with concentration 0.1 g/L were prepared because of the difficulty to obtain stable samples with higher concentrations.
- -
- The mixture is homogenized with the sonicator, at 40% of the rated power (i.e., power 300 W and ultrasound wave intensity 268 W/cm2), for two hours in intervals of 30 seconds of agitation and 30 s of pause to avoid overheating the oil.
- -
- The obtained DNF are stored at 50 °C under vacuum (0.1 bar) to avoid oxidation and to remove the moisture absorbed during the mixing process. All the samples are kept in identical conditions until the beginning of the tests.
2.3. Experimental Methodology
3. Results
3.1. Physical and Chemical Evaluation of the DNF
3.2. Results for the Stability Tests
3.2.1. Visual Inspection
- Type 2: Samples in which, after some time, the nanoparticles form a precipitate that remains suspended in the solution. An example of this can be seen in Figure 7c.
- Type 3: Samples in in which the nanoparticles form a precipitate at the bottom of the vial. The precipitate is solid and is deposited and adhered at the bottom of the vial. An example of this can be seen in Figure 7d.
- Type 4: Samples in which the nanoparticles could not be dispersed by ultrasounds during the manufacturing stage. An example of this can be seen in Figure 7e.
- -
- The mixture of the NE and the NP dispersion FF1 (0.1 g/L) was the liquid that presented the best long-term stability, showing a good performance at all tested temperatures. Even the sample that was subjected to 110 °C for two months remained stable showing no visible aggregates or deposits at the end of the test. The same solution remained stable at ambient temperature for at least 10 months (after 10 months the test was discontinued), which is a long time compared with the ones reported in the literature.On the other hand, the mixture of the NE with the NP dispersion FF2 led to a less stable fluid. At ambient temperature visible NP aggregates appeared after 3 months of testing. The samples that were subjected to higher temperatures also showed visible NP aggregates after 7 weeks of testing, in the case of the sample tested at 50 °C, and solid deposits after 4 weeks and 2 days when tested at 60 and 80 °C.
- -
- In the case of MO-based samples, the mixture of MO and the NP dispersion FF2 (0.1 g/L) led to a fluid which was highly stable at ambient temperature. After 10 months of testing the sample did not show any visible aggregates or deposits. The stability of this mixture was also good when subjected to moderate temperatures (50 and 60 °C), for 2 months. However, visible NP aggregates appeared in the fluid after 13 days when the sample was tested at 80 °C.The mixture of MO and the dispersion FF1 did not lead to a homogeneous fluid after the ultrasounds stirring and solutions similar to the one shown in Figure 8e were formed instead.
3.2.2. Particle-size Measurements
4. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Property | NE Bioelectra | MO Nytro 4000X |
---|---|---|
Physics and Chemicals | ||
Kinematic Viscosity (40 °C) | 39.2 cSt | 9.1 cSt |
Flash Point | 334 °C | 146 °C |
Pour point | −21 °C | −54 °C |
Density (20 °C) | 0.91 g/cm3 | 0.866 g/cm3 |
Appearance | Clear and bright | Clear, free from sediment |
Water Content | 100 mg/kg | <20 mg/kg |
Electricals | ||
Breakdown voltage | 65 kV | >70 kV |
Dissipation Factor | 0.03 | <0.001 |
Oxidation Stability | ||
Total acidity | 0.2 mg KOH/g | <0.01 mg KOH/g |
Sludge | 0.01% | <0.01% |
Dissipation Factor at 90 °C, 50 Hz | 0.05 | <0.01 |
Physical Property | FF1 | FF2 |
---|---|---|
Nanoparticle | Fe3O4 | Fe3O4 |
Nanoparticle size | ≈10 nm | ≈10 nm |
Carrier Liquid | Hydrocarbons | Hydrocarbons |
Surfactant | Carboxilic acid | - |
Solid Content | 60% | 50% |
Density (20 °C) | 1.21 g/cm3 | 1.04 g/cm3 |
Dynamic Viscosity (27 °C) | 87 cP | 80 cP |
Manufacturer | Magnacol | MAGRON |
Oil | NP (0.1 g/L) | Test Temperature | Stability | Final State |
---|---|---|---|---|
Bioelectra (NE) | FF1 | 25 °C | 10 months | Type 1 |
50 °C | 2 months | Type 1 | ||
60 °C | 2 months | Type 1 | ||
80 °C | 2 months | Type 1 | ||
110 °C | 2 months | Type 1 | ||
FF2 | 25 °C | 3 months | Type 2 | |
50 °C | 7 weeks | Type 2 | ||
60 °C | 4 weeks | Type 3 | ||
80 °C | 2 days | Type 3 | ||
Nynas Nitro 4000X (MO) | FF1 | 25 °C | Unstable | Type 4 |
50 °C | Unstable | Type 4 | ||
60 °C | Unstable | Type 4 | ||
80 °C | Unstable | Type 4 | ||
FF2 | 25 °C | 10 months | Type 1 | |
50 °C | 2 months | Type 1 | ||
60 °C | 2 months | Type 1 | ||
80 °C | 13 days | Type 3 |
Oil | NP (0.1 g/L) | Test Temperature | Stability | Main Peak (nm) | Peak FWHM (nm) |
---|---|---|---|---|---|
Bioelectra (NE) | FF1 | 25 °C | 10 months | 116 | 23 |
50 °C | 2 months | 31 | 33 | ||
60 °C | 2 months | 23 | 4,6 | ||
80 °C | 2 months | 20 | 4,8 | ||
110 °C | 2 months | 514 | 91 | ||
FF2 | 25 °C | 3 months | 28 | 6,2 | |
50 °C | 7 weeks | 17 | 8,3 | ||
60 °C | 4 weeks | 13 | 6,2 | ||
80 °C | 2 days | 69 | 13.4 | ||
Nynas Nitro 4000X (MO) | FF2 | 25 °C | 10 months | 16 | 12,3 |
50 °C | 2 months | 18 | 10.5 | ||
60 °C | 2 months | 13 | 2,3 | ||
80 °C | 13 days | 816 | 166 |
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Primo, V.A.; Pérez-Rosa, D.; García, B.; Cabanelas, J.C. Evaluation of the Stability of Dielectric Nanofluids for Use in Transformers under Real Operating Conditions. Nanomaterials 2019, 9, 143. https://doi.org/10.3390/nano9020143
Primo VA, Pérez-Rosa D, García B, Cabanelas JC. Evaluation of the Stability of Dielectric Nanofluids for Use in Transformers under Real Operating Conditions. Nanomaterials. 2019; 9(2):143. https://doi.org/10.3390/nano9020143
Chicago/Turabian StylePrimo, Victor A., Daniel Pérez-Rosa, Belén García, and Juan Carlos Cabanelas. 2019. "Evaluation of the Stability of Dielectric Nanofluids for Use in Transformers under Real Operating Conditions" Nanomaterials 9, no. 2: 143. https://doi.org/10.3390/nano9020143
APA StylePrimo, V. A., Pérez-Rosa, D., García, B., & Cabanelas, J. C. (2019). Evaluation of the Stability of Dielectric Nanofluids for Use in Transformers under Real Operating Conditions. Nanomaterials, 9(2), 143. https://doi.org/10.3390/nano9020143