在轮胎耦合道路模拟器上模拟新生儿患者的全身振动。

IF 1.7 4区 医学 Q3 ENGINEERING, BIOMEDICAL Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine Pub Date : 2024-02-01 Epub Date: 2024-01-25 DOI:10.1177/09544119231219531
Patrick Kehoe, Keely Gibb, Jason Hurley, Robert G Langlois, James R Green, Adrian Dc Chan, Elton Toma, Cheryl Aubertin, Kim Greenwood, Andrew Ibey, Stephanie Redpath
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引用次数: 0

摘要

过度的全身振动与健康问题有关,可能导致婴儿死亡率和发病率上升。需要在新生儿重症监护室接受专门治疗的新生儿往往需要通过公路救护车运送到专门的护理中心,从而使婴儿暴露在可能有害的振动和噪音中。加拿大安大略省部署了标准化的新生儿患者转运系统(NPTS),为患者提供救生设备,并为临床护理人员提供安全操作。然而,有证据表明,与车辆振动相比,患者可能会在某些频率上感受到更大的振动幅度。在一个为期多年的合作项目中,我们试图创建一个标准化的测试程序,以评估振动水平和缓解策略的有效性。以往的研究主要针对运输系统或运输保温箱的实验室振动测试,仅限于单自由度激励,忽略了旋转运动的综合影响。本研究考虑在 MTS 320 型轮胎耦合道路模拟器上对整车和病人运输系统进行实验室测试。通过在轮胎耦合道路模拟器上模拟道路轮廓和离散事件,可以评估运输系统的振动水平,并在受控环境下探索缓解策略。轮胎耦合模拟器可激发运输系统的六个自由度运动,以评估三个正交方向的振动,包括三个旋转自由度的贡献。轮胎耦合测试期间在运输系统上测量到的振动数据与相应的道路测试数据进行了比较,以评估振动环境复制的准确性。在实验室测试期间,对相同的驱动文件进行了三次运行,从而确定了异常情况并评估了重复性。轮胎耦合整车测试显示,在重新创建路段和合成随机轮廓方面具有很高的准确性。高振幅离散事件的模拟(如穿越减速带)具有很高的可重复性,但在患者处产生的峰值振幅方面,结果的准确性较低。在人体模型的输入端(位于床垫下的传感器)收集到的加速度结果与真实世界和道路模拟器的结果非常吻合。测试中使用的传感器包括 PCB Piezotronics 公司生产的 3741B 系列单轴加速度计和 356A01 系列三轴加速度计。这些结果表明,轮胎耦合道路模拟器可用于准确评估振动水平,并在受控环境下评估未来减震策略的益处,而且具有很高的可重复性。
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Simulating whole-body vibration for neonatal patients on a tire-coupled road simulator.

Exposure to excessive whole-body vibration is linked to health issues and may result in increased rates of mortality and morbidity in infants. Newborn infants requiring specialized treatment at neonatal intensive care units often require transportation by road ambulance to specialized care centers, exposing the infants to potentially harmful vibration and noise. A standardized Neonatal Patient Transport System (NPTS) has been deployed in Ontario, Canada, that provides life saving equipment to patients and safe operation for the clinical care staff. However, there is evidence that suggests patients may experience a higher amplitude of vibration at certain frequencies when compared with the vehicle vibration. In a multi-year collaborative project, we seek to create a standardized test procedure to evaluate the levels of vibration and the effectiveness of mitigation strategies. Previous studies have looked at laboratory vibration testing of a transport system or transport incubator and were limited to single degree of freedom excitation, neglecting the combined effects of rotational motion. This study considers laboratory testing of a full vehicle and patient transport system on an MTS Model 320 Tire-Coupled Road Simulator. The simulation of road profiles and discrete events on a tire-coupled road simulator allows for the evaluation of the vibration levels of the transport system and the exploration of mitigation strategies in a controlled setting. The tire-coupled simulator can excite six degrees-of-freedom motion of the transport system for vibration evaluation in three orthogonal directions including the contributions of the three rotational degrees of freedom. The vibration data measured on the transport system during the tire-coupled testing are compared to corresponding road test data to assess the accuracy of the vibration environment replication. Three runs of the same drive file were conducted during the laboratory testing, allowing the identification of anomalies and evaluation of the repeatability. The tire-coupled full vehicle testing revealed a high level of accuracy in re-creating the road sections and synthesized random profiles. The simulation of high amplitude discrete events, such as speed hump traverses, were highly repeatable, yet yielded less accurate results with respect to the peak amplitudes at the patient. The resulting accelerations collected at the input to the manikin (sensor located under the mattress) matched well between the real-world and road simulator. The sensors used during testing included series 3741B uni-axial and series 356A01 tri-axial accelerometers by PCB Piezotronics. These results indicate a tire-coupled road simulator can be used to accurately evaluate vibration levels and assess the benefits of future mitigation strategies in a controlled setting with a high level of repeatability.

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来源期刊
CiteScore
3.60
自引率
5.60%
发文量
122
审稿时长
6 months
期刊介绍: The Journal of Engineering in Medicine is an interdisciplinary journal encompassing all aspects of engineering in medicine. The Journal is a vital tool for maintaining an understanding of the newest techniques and research in medical engineering.
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