分布式冲击检测和压电传感器应用的低功耗电子器件

K. Champaigne
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引用次数: 19

摘要

由于所涉及的可探测高频信号的短暂性,对飞机和航天器的自动撞击检测和表征一直是一个难以实现的目标。日前,Invocon公司获得了NASA第二阶段小企业创新研究(SBIR)项目的授权,该项目旨在开发自给自足、小型化的压电传感节点,该节点具有超低功耗触发模式,可在射频网络中同步。每个节点将持续监测加速度计、声发射传感器或PZT元件的撞击事件,如微流星撞击或导致哥伦比亚悲剧的泡沫撞击。当超过可编程阈值时,低延迟信号采集电路将捕获事件作为数字波形进行后处理和影响表征,包括幅度和到达时间分析。创新的信号调理电路设计能够在平均微瓦范围内工作,同时不断保持获取和处理高频声信号的能力。这样的性能可以提供5年的潜在运行寿命在一个AA电池,或无限的操作从清除电源。此外,该系统将提供一个通用的硬件平台,在该平台上可以实现综合结构健康监测(ISHM)算法和传感技术。相同的基本系统设计,具有可配置的采样率、传感器接口、驱动输出和局部处理算法,可用于主动或被动损伤检测,通过产生的机载和地面超声能量定位加压车辆和栖息地的泄漏,或通过声发射(AE)技术检测结构中的裂纹扩展或分层。通过允许这些ISHM能力的开发、演示和潜在部署在针对低功耗和分布式操作优化的小型化设备上,ISHM的目标将更有效地实现在飞机和航天器上。本文将提供触发能力、数据采集电路设计、整体系统设计和潜在应用的一般描述。
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Low-power Electronics for Distributed Impact Detection and Piezoelectric Sensor Applications
Automated impact detection and characterization on aircraft and spacecraft has been an elusive goal due to the transitory nature of the detectable high-frequency signals involved. Invocon, Inc. has been awarded a NASA Phase 2 Small Business Innovation Research (SBIR) program to develop self-contained, miniaturized, piezoelectric sensory nodes with extremely low-power trigger modes that are synchronized within a radio frequency network. Each node will continuously monitor an accelerometer, acoustic emission sensor, or PZT element for an impact event, such as a micro-meteor impact or the foam impact that caused the Columbia tragedy. When a programmable threshold is exceeded, a low-latency signal acquisition circuit will capture the event as a digital waveform for post-processing and impact characterization including amplitude and time-of-arrival analysis. The innovative signal conditioning circuit design is capable of operation in the micro-watt range on average while constantly maintaining the capability to acquire and process very high frequency acoustic signals. Such performance can potentially provide operating lifetimes of 5 years on a single AA battery, or unlimited operation from scavenged power sources. Additionally, the system will provide a general purpose hardware platform on which Integrated Structural Health Monitoring (ISHM) algorithms and sensing techniques can be implemented. The same basic system design, with configurable sample rates, sensor interfaces, actuation outputs, and local processing algorithms, could be used for active or passive damage detection, locating leaks from pressurized vehicles and habitats through the produced airborne and surface-borne ultrasonic energy, or detecting crack propagation or delamination in structures through Acoustic Emission (AE) techniques. By allowing the development, demonstration, and potentially deployment of these ISHM capabilities on miniaturized devices optimized for low-power and distributed operation, the goals of ISHM will be more effectively achieved for aircraft and spacecraft. This paper shall provide a general description of the triggering capabilities, data acquisition circuit design, overall system design, and potential applications.
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