Publicado:

2021-06-25

Número:

Vol. 18 Núm. 1 (2021): Revista Tekhnê

Sección:

Artículos

Temperature control system for a hatchery

Sistema para el control de temperatura de una incubadora de huevos de gallina

Autores/as

  • Karen L. Cruz Universidad Distrital Francisco José de Caldas
  • Fernando F. Vera Universidad Distrital Francisco José de Caldas

Palabras clave:

Control, PID, función de transferencia, incubadora, temperatura (es).

Palabras clave:

Control, incubator, PID, temperature, transfer function (en).

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Resumen (en)

A closed-loop PID controller tuning method is presented, as well as a control mechanism that functions as an egg incubator controller to control the temperature. The method’s performance is compared using digital simulation tests, and the PID controller gains are determined based on the system requirements. Finally, recommendations for using the tested method as well as arguments for why we reject other methods are provided.

Resumen (es)

Se presenta un método de sintonización de controladores PID de lazo cerrado, un mecanismo de control que opera como regulador de una incubadora de huevos, el cual controla la temperatura. Mediante pruebas de simulación digital se compara el desempeño del método y se determinará las ganancias del controlador PID según los requerimientos del sistema. Finalmente, se ofrecen recomendaciones sobre la utilización del método probado y los argumentos por los cuales descartamos otros métodos.

Referencias

Aldair, A. A., Rashid, A. T., & Mokayef, M. (2018). Design and implementation of intelligent control system for egg incubator based on iot technology. 2018 4th International Conference on Electrical, Electronics and System Engineering (ICEESE), 49–54.

Bello, D., García, L., & Martínez, F. (2013). Planta robusta de levitación neumática para investigación y formación en control y visión artificial. Tekhnê, 10(2), 33–41.

Blanco, L., & Ramos, M. (2019). Sustainable diets and meat consumption reduction in emerging economies: Evidence from colombia. Sustainability, 11(23), 6595. https://doi.org/10.3390/su11236595

Che, A., Muzaffar, A., Shukri, A., Mohd, R., Rozali, S., Mohamad, S., & Hadinata, A. (2019). Analysis of light bulb temperature control for egg incubator design. International Journal of Integrated Engineering, 11(4), 268–276. https://doi.org/10.30880/ijie.2019.11.04.031

Colmenares, J., Ospino, C., & Vargas, O. (2003). Adecuación y automatización para un horno industrial a gas natural. Tekhnê, 1(1), 24–29.

Diseño e implementación de una incubadora de huevos con aire forzado basada en microcontrolador. (n.d.). 2018 Conferencia Internacional sobre Avance en Ingeniería Eléctrica y Electrónica (ICAEEE).

Farfán, D., Martínez, F., & Pirajan, R. (2011). Development system for atmel microcontroller oriented towards plc. Tekhnê, 8(1), 47–54.

Guzmán, J., & Ramírez, J. (2017). How can concrete be improved through processes that are bio-friendly to the environment and that enhance its construction qualities? Tekhnê, 14(2), 49–58.

Kapen, P. T., Youssoufa, M., Foutse, M., Manfouo, H., & Mbakop, F. O. N. (2020). Design and prototyping of a low-cost, energy efficient eggs incubator in developing countries: A case study of cameroon. Scientific African, 10(1), e00618. https://doi.org/10.1016/j.sciaf.2020.e00618

Khera, N., & Kohli, S. Comparison of fuzzy and on/off controller for winter season egg hatching incubator system. In: 2018 international conference on sustainable energy, electronics, and computing systems (SEEMS). 2018, 1–6. https://doi.org/10.1109/SEEMS.2018.8687365.

Kokieva, G. E., Trofimova, V. S., & Fedorov, I. R. Greenhouse microclimate control. In: Iop conference series: Materials science and engineering. 1001. (1). 2020, 012136. https://doi.org/10.1088/1757-899X/1001/1/012136.

Lata, S., Sah, R., Singh, S., & Jaiswal, S. Greenhouse monitoring using wsn and sensenuts nodes. In: Aip conference proceedings. 2294. 2020, 030006. https://doi.org/10.1063/5.0031711.

López, C. (2014). Performance evaluation of two bio-inspired optimization techniques: Genetic algorithms and particle swarm. Tekhnê, 11(1), 49–58.

Maasoum, S. M. H., Mostafavi, A., & Sadighi, A. An autoencoder-based algorithm for fault detection of rotating machines, suitable for online learning and standalone applications. In: 2020 6th iranian conference on signal processing and intelligent systems (ICSPIS). 2020, 1–6. https://doi.org/10.1109/ICSPIS51611.2020.9349574.

Marçal, T., Antunes, B., Ferreira, R., Correia, C., Pires, D., Matos, A., & Simões, J. N. (2015). Wireless multi-physiological signal monitor for clinical discharge and readmissions criteria setting and ambulatory usage. 2015 IEEE 4th Portuguese Meeting on Bioengineering (ENBENG), 1–6.

Millette, S., Hull, C. E., & Williams, E. (2020). Business incubators as effective tools for driving circular economy. Journal of Cleaner Production, 266(1), 121999. https://doi.org/10.1016/j.jclepro.2020.121999

Páramo, M., Romero, M., & Wilches, F. (2020). International journal of engineering research and technology. International Journal of Engineering Research and Technology, 13(11), 4004–4010.

Roscoe, A., Knueppel, T., Silva, R. D., Brogan, P., Gutierrez, I., Elliott, D., & Campion, J.-C. P. (2020). Response of a grid forming wind farm to system events, and the impact of external and internal damping. IET Renewable Power Generation, 14(19), 3908–3917. https://doi.org/10.1049/iet-rpg.2020.0638

Sanjaya, W. S. M., Maryanti, S., Wardoyo, C., Anggraeni, D., Aziz, M. A., Marlina, L., Roziqin, A., & Kusumorini, A. (2018). The development of quail eggs smart incubator for hatching system based on microcontroller and internet of things (iot). 2018 International Conference on Information and Communications Technology (ICOIACT), 407–411.

Santoso, S. B., Adhy, S., Bahtiar, N., & Waspada, I. Development of the smart chicken eggs incubator based on internet of things using the object oriented analysis and design method. In: 2020 4th international conference on informatics and computational sciences (ICICoS). 2020, 1–6. https://doi.org/10.1109/ICICoS51170.2020.9299000.

Shafiudin, S., & Kholis, N. (2018). Monitoring system and temperature controlling on pid based poultry hatching incubator. IOP Conference Series: Materials Science and Engineering, 336(1), 012007.

Torres, J., & Ramírez, L. (2012). Adequacy of festo vacuum system belonging to the laboratoryof automation and control (le-mc-01) of the program inmechanical technology ud. Tekhnê, 9(1), 69–78.

Zutta, J. (2005). Diseño, construcción y evaluación de prototipo mecánico para el lavado y sedimentación del almidón de arracaha (arracacia xantorriza). Tekhnê, 4(1), 1–3.

Cómo citar

APA

Cruz, K. L., y Vera, F. F. (2021). Temperature control system for a hatchery. Tekhnê, 18(1), 21–36. https://revistas.udistrital.edu.co/index.php/tekhne/article/view/19258

ACM

[1]
Cruz, K.L. y Vera, F.F. 2021. Temperature control system for a hatchery. Tekhnê. 18, 1 (jun. 2021), 21–36.

ACS

(1)
Cruz, K. L.; Vera, F. F. Temperature control system for a hatchery. Tekhnê 2021, 18, 21-36.

ABNT

CRUZ, K. L.; VERA, F. F. Temperature control system for a hatchery. Tekhnê, [S. l.], v. 18, n. 1, p. 21–36, 2021. Disponível em: https://revistas.udistrital.edu.co/index.php/tekhne/article/view/19258. Acesso em: 31 ene. 2023.

Chicago

Cruz, Karen L., y Fernando F. Vera. 2021. «Temperature control system for a hatchery». Tekhnê 18 (1):21-36. https://revistas.udistrital.edu.co/index.php/tekhne/article/view/19258.

Harvard

Cruz, K. L. y Vera, F. F. (2021) «Temperature control system for a hatchery», Tekhnê, 18(1), pp. 21–36. Disponible en: https://revistas.udistrital.edu.co/index.php/tekhne/article/view/19258 (Accedido: 31 enero 2023).

IEEE

[1]
K. L. Cruz y F. F. Vera, «Temperature control system for a hatchery», Tekhnê, vol. 18, n.º 1, pp. 21–36, jun. 2021.

MLA

Cruz, K. L., y F. F. Vera. «Temperature control system for a hatchery». Tekhnê, vol. 18, n.º 1, junio de 2021, pp. 21-36, https://revistas.udistrital.edu.co/index.php/tekhne/article/view/19258.

Turabian

Cruz, Karen L., y Fernando F. Vera. «Temperature control system for a hatchery». Tekhnê 18, no. 1 (junio 25, 2021): 21–36. Accedido enero 31, 2023. https://revistas.udistrital.edu.co/index.php/tekhne/article/view/19258.

Vancouver

1.
Cruz KL, Vera FF. Temperature control system for a hatchery. Tekhnê [Internet]. 25 de junio de 2021 [citado 31 de enero de 2023];18(1):21-36. Disponible en: https://revistas.udistrital.edu.co/index.php/tekhne/article/view/19258

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