Autoclave is a tool used to sterilize medical instruments such as surgical knives and scissors. The process of autoclave sterilization is to provide heat energy to the autoclave. Hot steam will rise into the closed chamber. The control system will monitor the temperature until the required temperature is reached (121-124 °C). Temperature measurement in the autoclave is done using a thermocouple sensor. Temperature testing is done by comparing temperature measurements using a thermocouple and a mercury thermometer. Testing with a thermocouple produces output that is linear and comparable to measurements using a mercury thermometer. The correlation coefficient value of the measurement results using a mercury thermometer is 0.99982 and a thermocouple is 0.99894. Furthermore, the test is carried out by looking at the change in the line on the indicator tape to the length of time for sterilization in the autoclave chamber. As a result, the longer the sterilization time, the change in the line on the indicator tape will look darker, which indicates the sterilization process is going well.

Keywords: temperature measurement, autoclave, type K thermocouple, indicator tape

. Ministry of Health and Family Welfare New Delhi. 2010. Medical Equipment Maintenance Manual A First Line Maintenance Guide for End Users.

. [A] Sasaki, Jun-Ichi and Imazato, Satoshi. 2020. Autoclave Sterilization of Dental Handpieces: A Literature Review. Journal of Prosthodontic Research. Japan Prosthodontic Society pp 239-242. https://doi.org/10.1016/j.jpor.2019.07.013

. Safety EL. 2013. Autoclaves. (20): 2–3.

. Qin, He and Yin, Chen. 2018. Study of Temperature and Pressure Control of Autoclave Based on FPGA. 3rd International Conference on Mechanical, Control and Computer Engineering. DOI 10.1109/ICMCCE.2018.00023

. National Instrument. 2011. Temperature Measurements with Thermocouples : How-To Guide. 1–6.

. Omega. 2000. Using Termokopels. Technical Reference Section: Z21-32. Available from: http://www.omega.com/temperature/z/pdf/z021-032.pdf.

. Han, Yanhui, Yue Feng, Haozhe Lou XZ. 2018. Termokopel-Based Temperature Sensing System for Chemical Cell Inside Micro UAV Device. Journal of Physics: Conference Series, Volume 986. DOI:10.1088/1742-6596/986/1/012012.

. Igorevich, Fedosov Ivan. 2020. Thermocouple Condition Monitoring Using Thermocouple Resistance. Experimental Study. Ural Symposium on Biomedical Engineering, Radioelectronics and Information Technology (USBEREIT). Russia.

. Straubinger, D., Illes, B., Berenyi, R., and Geczy, A. 2020. Simulation of Relow-based Heat Transfer on Different Thermocouple COnstructions. 43rd International Spring Seminar on Electronics Technology (ISSE).

. Shaker, H. H., Saleh, A.A., Ali, A. H., and Elaziz, M. A. 2016. Self-Calibrating Enabled Low COst, Two Channel Type K Thermocouple Interface for Microcontrollers. Cairo, Egypt.

. Mofei, W., Zhigang, C., Yuzhao, H., and Deming, L. 2017. Design of Intelligent Temperature Controller for Thermocouple Automatic Calibrating Furnace. International COnference on Industrila Informatics.

. Popong Effendrik, Gatot Joelianto, Hari Sucipto. 2014. Karakterisasi Thermocouple Dengan Menggunakan Perangkat Lunak Matlab – Simulink. Jurnal Eltek, [S.l.], v. 12, n. 1, p. 133-145

. Noriega M, et al. 2015. Termokopels Calibration and Analysis of the Influence of the Length of the Sensor Coating. Journal of Physics: Conference Series 582(1). DOI:10.1088/1742-6596/582/1/012029.

. Martin J. 2013. Protocols for the High-Temperature Measurement of the Seebeck Coefficient in Thermoelectric Materials. Measurement Science and Technology. 24(8). DOI:10.1088/0957-0233/24/8/085601.

. Recktenwald G. 2010. Conversion of Termokopel Voltage to Temperature. 1–23.

. PSS Bapu Rao. 2020. Thermocouple: Principle, Construction, Characteristics, Advantages, and Limitations. Available from: https://instrumentationapplication.com/2020/12/06/thermocouple-principle-construction-characteristics-advantages-and-disadvantages/

. Fontes J. Sensor Technology Handbook. USA: Elsevier.Inc; 2005. DOI:10.1016/B978-075067729-5/50054-9.

. Jiayue W, et al. 2016. The Engine Temperature Real-Time Monitoring Instrument Based on Microcontroller. Proceedings of the 2016 2nd Workshop on Advanced Research and Technology in Industry Applications (Wartia): 1257–1261.