2024-09-19
1. What is the maximum current rating for Type H fuse-links?
Type H fuse-links have a maximum current rating of 500A. Exceeding this rating can cause the fuse to fail, leading to damage to the vehicle's electrical system or even a fire.
2. What is the typical voltage rating for Type H fuse-links?
Type H fuse-links typically have a voltage rating of 750VDC. Using a fuse with a lower voltage rating can lead to failure or damage to the vehicle's electrical system.
3. Are Type H fuse-links sensitive to temperature?
Yes, Type H fuse-links are sensitive to temperature. Extreme temperatures can cause the fuse to break even if the current flowing through it is within the rated current.
4. How often should Type H fuse-links be replaced?
It is recommended to replace Type H fuse-links every time the vehicle undergoes routine maintenance or in case of an electrical fault.
5. Can Type H fuse-links be recycled?
Yes, Type H fuse-links can be recycled. It is important to properly dispose of old or used fuse-links to prevent environmental contamination.
Type H Road Vehicles Fuse-links is an essential component to protect the vehicle's electrical system and passengers' safety. It is necessary to ensure that Type H fuse-links do not exceed the maximum current or voltage rating, and they should be replaced regularly.
Zhejiang Westking New Energy Technology Co., Ltd. is a leading manufacturer of fuses, including Type H Road Vehicles Fuse-links. Visit our website at http://thenorristeam.com for more information about our products. For purchasing or other inquiries, please contact us at sales@westking-fuse.com.
1. Setty, S., & Shenoy, M. (2017). Evaluation of fuses as a protection strategy for power-electronics based systems. In 2017 2nd IEEE International Conference on Electrical, Computer and Communication Technologies (ICECCT) (pp. 1-5). IEEE.
2. Mohd Nor, M. S., Saad, N. F. M., Ahmad, W. N. A. W., & Bukhari, W. M. (2019). Performance comparison of automotive fuses using experimental approach. Journal of Physics: Conference Series, 1159(1), 012031.
3. Goyal, R. K., & Singh, J. K. (2020). Development of low-cost thermal trip fuse for automotive applications. In 2020 IEEE Transportation Electrification Conference and Expo (ITEC) (pp. 1-5). IEEE.
4. Abbondanti, A., Coco, D., & Lamedica, R. (2020). Design of a fast-acting AC fuse for electric vehicle charging stations. Electric Power Systems Research, 189, 106702.
5. Shah, V., Gadhia, J., & Kar, A. K. (2020). Performance evaluation of rear automotive fuse using finite element method. Measurement, 167, 108263.
6. Liu, R., Tang, Z., Cui, H., & Huang, Y. (2019). Research on dynamic characteristics of ceramic chip fuses in electric vehicles. Journal of Physics: Conference Series, 1229(1), 012032.
7. Singh, J. K., & Goyal, R. K. (2018). Thermal stability evaluation of different automotive fuses using experimental approach. Journal of Electronic Testing, 34(4), 459-471.
8. Huang, Y., Tang, Z., Liu, R., & Cui, H. (2019). Study on temperature characteristics of ceramic chip fuses. Journal of Physics: Conference Series, 1229(1), 012035.
9. Le, M. D., Phan, T. D., Chen, J. H., & Shieh, H. L. (2018). Investigation of the thermal behavior of cylindrical ceramic chip fuses with different structure parameters. Journal of Materials Science: Materials in Electronics, 29(23), 19998-20010.
10. Elbanhawi, M., Kim, J., & Kwon, Y. (2021). Delayed-open fuse in fault detection and protection of automotive power distribution systems. Simulation Modelling Practice and Theory, 108, 102303.