ABSTRAK
Kestabilan putaran berpengaruh terhadap kwalitas hasil pembuatan cat. Penelitian ini, fokus mengidentifikasi pengendalian kestabilan kecepatan putaran pada plan vane motor pneumatik saat bergangguan. Gangguan pengereman mekanik dan penurunan tekanan inlet sumber energi angin. Plan disetting berputar 250 rpm. Sistem pengendalian digunakan digital-PID (Proportional- Integral- Derivative ) dengan nilai parameter Kp, Ki, Kd dari hasil analisa zeigler nichols. PID mengatur bukaan katup yang mengalirkan angin melalui plan. Umpan balik sistem kecepatan digunakan sebagai koreksi error. Sistem stabil dengan error steady state (ESS ) 0,46%. Saat bergangguan mekanik 5% overdamped 1,5 detik , overshoot 3,65% dan gangguan 10% overdamped 3,3 detik, overshoot 7,71%. Saat gangguan inlet 0,45 bar overdamped 3 detik, overshoot 2,54% dan gangguan inlet 1,2 bar overdamped 4,3 detik, overshoot tetap.

ABSTRACT
The rotational stability affects the quality of the paint productions. This research focuses on identifying the control of rotational speed stability on a pneumatic motor plan vane when it is disturbed. Disturbance of mechanical braking and a decrease in the inlet pressure of the wind energy source. The plan is set to rotate at 250 rpm. The control system used digital-PID (Proportional-Integral-Derivative) with parameter values Kp, Ki, Kd from the results of Zeigler Nichols analysis. PID regulates valve openings that allow air to flow through the plan. Speed system feedback is used as error correction. The system is stable with a steady state error (ESS ) 0.46%. When the mechanical disturbance is 5% overdamped for 1.5 seconds, overshoot is 3.65% and 10% is overdamped for 3.3 seconds, overshoot is 7.71%. When the inlet disturbance is 0.45 bar overdamped for 3 seconds, the overshoot is 2.54% and the inlet fault is 1.2 bar overdamped for 4.3 seconds, the overshoot remains the same.

H. Rudiansyah, “Pengembangan Alat Pengajaran Kontrol Elektropneumatik Portabel Berstandar Industri,†no. September, 2019.

P. Waktu et al., “COLORANT DARI TITANIUM DIOKSIDA Bahan dan Alat,†Ratnawati, Yoshi Al, pp. 61–65, 2018.

A. Sumadi, D. H. R. Saputra, and J. Jamaaluddin, “Informasi Gangguan Tekanan Udara Pada Peralatan Mesin Kompresor Dengan Komunikasi Sms Berbasis Arduino,†J. Elektron. List. Telekomun. Komputer, Inform. Sist. Kontrol, vol. 2, no. 1, pp. 1–8, 2020, doi: 10.30649/j-eltrik.v2i1.45.

H. Imani, H. Malekizade, H. A. Bagal, and H. Hosseinzadeh, “Surge explicit nonlinear model predictive control using extended greitzer model for a ccv supported compressor,†Automatika, vol. 59, no. 1, pp. 43–50, 2018, doi: 10.1080/00051144.2018.1498204.

S. W. Jadmiko, S. Yahya, S. Sudrajat, and F. Azizah, “Komparasi Kinerja Kendali PID dan Logika Fuzzy pada Simulator Plant Orde Dua,†JTERA (Jurnal Teknol. Rekayasa), vol. 5, no. 2, p. 237, 2020, doi: 10.31544/jtera.v5.i2.2020.237-246.

Widjonarko, R. Soenoko, S. Wahyudi, and E. Siswanto, “Design of Air Motor Speed Control System for Small Scale Compressed Air Energy Storage Using Fuzzy Logic,†IOP Conf. Ser. Mater. Sci. Eng., vol. 494, no. 1, 2019, doi: 10.1088/1757-899X/494/1/012025.

W. J. Zhang, F. Zhang, J. Zhang, J. Zhang, and J. Zhang, “Application of PLC in Pneumatic Measurement Control System,†IOP Conf. Ser. Mater. Sci. Eng., vol. 452, no. 4, 2018, doi: 10.1088/1757-899X/452/4/042074.

E. M. A. Elsadek, H. Ashour, R. A. Refaat, and M. Mostafa, “Efficiency Improvement and Saving Energy within,†2019 Int. Conf. Innov. Trends Comput. Eng., no. February, pp. 2–4, 2019.

S. Y. Chen and S. S. Gong, “Speed tracking control of pneumatic motor servo systems using observation-based adaptive dynamic sliding-mode control,†Mech. Syst. Signal Process., vol. 94, no. 129, pp. 111–128, 2017, doi: 10.1016/j.ymssp.2017.02.025.

B. Setiadi, “Solar Tracker Elektro-Pneumatik Berbasis Kendali

Fuzzy,†J. Rekayasa Hijau, vol. 4, no. 3, pp. 179–190, 2020, doi: 10.26760/jrh.v4i3.179-190.

F. Z. Raihan, B. Setiadi, H. Purnama, V. A. Wijayakusuma, and K. Kunci, “Kendali Kecepatan Vane Motor Pneumatik Berbasis Kendali Fuzzy,†pp. 4–5, 2021.

B. Setiadi, “Solar Tracker Elektro-Pneumatik Berbasis Kendali Fuzzy,†J. Rekayasa Hijau, vol. 4, no. 3, pp. 179–190, 2020, doi: 10.26760/jrh.v4i3.179-190.

F. Z. Raihan, B. Setiadi, H. Purnama, V. A. Wijayakusuma, and K. Kunci, “Kendali Kecepatan Vane Motor Pneumatik Berbasis Kendali Fuzzy,†pp. 4–5, 2021.