Integration of STM32 Microcontroller with Arm Cortex Architecture into the 8-Bit Measurement Circuit Customized for Real-Time Data Acquisition on Propeller Shaft to Increase Data Speed and Accuracy

The Eurasia Proceedings of Science Technology Engineering and Mathematics Pub Date : 2023-12-25 DOI:10.55549/epstem.1408850

Oğuzhan Aldemi̇r, Sedat Tarakçi, Serhan Ozdemir, Efe Isik

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Abstract

Propeller shafts transmit torque and high-speed rotational movement from the engine to related equipment. Expected propeller shaft functions are calculated and designed by using an analytical and numerical approaches. The verification tests are significant in that they provide feedback to the design and development processes. Therefore, acquiring accurate data from power transmission equipment is becoming even more important. This paper focuses on the study of circuit boards customized for use in the validation tests of the propeller shafts. It should be noted that these measurement circuits were integrated on the propeller shafts. These measurement circuits were used to acquire data such as torque, temperature, etc. in real time. Especially with instantaneous signals such as torque, data loss can occur due to low microcontroller resolution. Therefore, it was aimed to develop to the microcontroller to 32-bit resolution from 8-bit resolution to increase data speed and accuracy. As the first step, an INA125P operational amplifier was installed to amplify the low voltage values gathered from the gages and the sensors. The gain value of the amplifier was calculated in order to provide the highest data resolution and sensitivity. And then, ADS1115 analog to digital converter circuit with a rate of 860 samples per second and 16-bit resolution was used to interpret the analog data. A low pass filter was installed to remove noise from the output signal. Embedded code was also locally developed for the hardware installed. The system was calibrated on a validated test rig. Real-time torque and temperature data were acquired from the propeller shaft. It is observed that compared to the previous 8-bit system, the data accuracy and integrity from the new 32-bit board has increased by a factor of 5 to 100 Hz. The collected data was found to be 99.4% compatible with the validated test rig data.

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将采用 Arm Cortex 架构的 STM32 微控制器集成到为实时采集螺旋桨轴数据而定制的 8 位测量电路中，提高数据采集速度和精度

螺旋桨轴将扭矩和高速旋转运动从发动机传递到相关设备。螺旋桨轴的预期功能是通过分析和数值方法计算和设计的。验证测试的意义在于为设计和开发过程提供反馈。因此，获取动力传动设备的准确数据变得更加重要。本文重点研究了用于螺旋桨轴验证测试的定制电路板。需要指出的是，这些测量电路都集成在螺旋桨轴上。这些测量电路用于实时获取扭矩、温度等数据。特别是扭矩等瞬时信号，由于微控制器分辨率低，可能会造成数据丢失。因此，我们的目标是将微控制器的分辨率从 8 位提高到 32 位，以提高数据速度和精度。第一步，安装了一个 INA125P 运算放大器，用于放大从量规和传感器收集到的低电压值。为了提供最高的数据分辨率和灵敏度，对放大器的增益值进行了计算。然后，使用 ADS1115 模数转换器电路以每秒 860 次的采样率和 16 位的分辨率来解释模拟数据。此外，还安装了一个低通滤波器，以消除输出信号中的噪声。当地还为所安装的硬件开发了嵌入式代码。该系统在经过验证的测试平台上进行了校准。从螺旋桨轴上获取了实时扭矩和温度数据。据观察，与以前的 8 位系统相比，新的 32 位电路板的数据准确性和完整性提高了 5 倍，达到 100 Hz。采集到的数据与经过验证的试验台数据的吻合度高达 99.4%。

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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来源期刊

The Eurasia Proceedings of Science Technology Engineering and Mathematics

CiteScore

0.20

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0.00%

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