Analytical Study of Barrier-free Door Closer Guide Rail System based on Slider-Crank Mechanism

Man-Yee Leong and Alfred C.H. Tan
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Abstract

One of the most important elements of barrier-free design is the door entrance system, particularly door closers. Door closers ensure that doors are easy to operate and do not pose any physical barriers to users. However, existing electro-mechanical door closers are relatively heavy, costly and have reliability issues in cases of power outages. Purely mechanical door closers, such as cam action with guide rail and rack-and-pinion with scissors arm, offer a more affordable option due to simpler design and fewer components used. Static forces and torque with geometrical constraints of the door closer guide rail system are considered in deriving the mathematical expressions of a door closer guide rail system using similar approaches as slider-crank mechanism. The formulation considers the effects of pinion torque of a door closer, installation inputs as design parameters, door angle and efficiency. The mathematical model and experimental results show close agreement. The contribution of this paper is that it demonstrates the underlying physics of the door closer guide rail system, thereby aiding in understanding the door behaviour. Additionally, the model can predict the behaviour of the system under different operating conditions, which can be useful for design and optimization purposes. More importantly, this model can be utilised to identify the most effective strategies in reducing opening forces on doors thereby providing design insights to barrier-free application in the future.
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基于滑块-曲柄机构的无障碍闭门器导轨系统分析研究
无障碍设计最重要的元素之一是门禁系统,尤其是闭门器。闭门器可确保门易于操作,不会对用户造成任何物理障碍。然而,现有的电动机械闭门器相对较重、成本较高,而且在停电时存在可靠性问题。纯机械式闭门器,如带导轨的凸轮式闭门器和带剪刀臂的齿轮齿条式闭门器,由于设计简单、使用的部件较少,因此是一种更经济实惠的选择。在推导闭门器导轨系统的数学表达式时,考虑了闭门器导轨系统的静态力和扭矩以及几何约束,采用的方法与滑块曲柄机构类似。该公式考虑了闭门器小齿轮扭矩、作为设计参数的安装输入、门角度和效率的影响。数学模型和实验结果表明两者非常接近。本文的贡献在于展示了闭门器导轨系统的基本物理原理,从而有助于理解门的行为。此外,该模型还能预测系统在不同运行条件下的行为,有助于设计和优化。更重要的是,该模型可用于确定减少门开启力的最有效策略,从而为未来的无障碍应用提供设计见解。
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