Mechanical Requirements for a Smart Inhaler Product

2020 IEEE Sensors Applications Symposium (SAS) Pub Date : 2020-03-01 DOI:10.1109/SAS48726.2020.9220048

Amelia Beckley, Baden Parr, Sanjay Mathrani, M. Legg, Andrew Drain

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Abstract

Asthma and other respiratory diseases are a significant problem for the New Zealand health sector. There are several factors that make asthma treatment difficult and these have led to the development of smart inhaler devices. However, the devices currently available on the market do not address the core problems with asthma treatment and so a new smart inhaler product is being developed. The smart inhaler product uses an acoustic sensor to detect inhalation flow rate and a haptic motor to provide vibration feedback. To avoid the vibration feedback interfering with the acoustic sensing, vibration damping methods have been employed. Passive damping using viscoelastic material was chosen as it is low-cost and compact. However, results show that these methods are not effective enough to reduce the magnitude of the vibration noise below the magnitude of the inhalation signal using the current acoustic sensor (a microphone). It is possible that effective damping could be achieved using a transducer as the acoustic sensor. However, the transducer must be integrated with the smart inhaler product and likely isolated in some way. Following this, further testing would be required.

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智能吸入器产品的机械要求

哮喘和其他呼吸道疾病是新西兰卫生部门面临的一个重大问题。有几个因素使哮喘治疗变得困难，这些因素导致了智能吸入器设备的发展。然而，目前市场上可用的设备并不能解决哮喘治疗的核心问题，因此一种新的智能吸入器产品正在开发中。智能吸入器产品使用声学传感器检测吸入流速，触觉电机提供振动反馈。为了避免振动反馈对声传感的干扰，采用了振动阻尼方法。采用粘弹性材料作为被动阻尼材料，成本低，结构紧凑。然而，结果表明，这些方法不足以有效地将振动噪声的大小降低到使用当前声学传感器(麦克风)的吸入信号的大小以下。使用换能器作为声传感器可以实现有效的阻尼。然而，换能器必须与智能吸入器产品集成，并可能以某种方式隔离。在此之后，将需要进一步的测试。

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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2020 IEEE Sensors Applications Symposium (SAS)

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