Pneumatic actuation of a firefighting robot: A theoretical Foundation and an Empirical study

2019 7th International Conference on Mechatronics Engineering (ICOM) Pub Date : 2019-10-01 DOI:10.1109/ICOM47790.2019.8952050

M. T. Ajala, M. R. Khan, M. Salami, A. Shafie, M. Oladokun, M. Nor

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引用次数: 1

Abstract

In recent times, the need for a self-powered, autonomous firefighting robot, which can cope in fire hot spots, is strongly required in fire emergencies. The obtainable firefighting robots lack efficient performance in such conditions due to less reliability of their electric-powered actuators in the high-temperature environment under fire emergency. Our previous study suggests a gas actuated propulsion system (GAPS) as an alternative to the identified limitations of the existing electric actuated propulsion system. The GAPS drives a carbon dioxide propelled autonomous firefighting robot (CAFFR), which uses dry ice as its power source. However, there still exists a lack of detailed understanding of the working principle of the proposed GAPS. Thus, this study provides a theoretical framework for the novel CAFFR. Upon establishing the working theory and the concept of the CAFFR, the research carried out an empirical analysis of the key influencing design parameters for the CAFFR pneumatic actuation. The study presents a mathematical model of the effects of the design parameters and after that, discusses its implications.

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消防机器人气动驱动:理论基础与实证研究

近年来，在火灾紧急情况下，迫切需要能够在火灾热点地区应对的自供电、自主消防机器人。现有的消防机器人由于其电动执行器在火灾应急高温环境下的可靠性较低，在这种情况下缺乏有效的性能。我们之前的研究表明，气体驱动推进系统(GAPS)可以替代现有电动驱动推进系统的局限性。GAPS驱动二氧化碳驱动的自动消防机器人(CAFFR)，该机器人使用干冰作为动力来源。然而，人们对拟议的gap的工作原理仍然缺乏详细的了解。因此，本研究为新型CAFFR提供了理论框架。在建立CAFFR工作原理和概念的基础上，对影响CAFFR气动驱动设计参数的关键因素进行了实证分析。本研究提出了设计参数影响的数学模型，并讨论了其意义。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2019 7th International Conference on Mechatronics Engineering (ICOM)

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