Journal of South China University of Technology(Natural Science) >
Modeling and Dynamic Simulation of Temperature Control Method for Hot Bar Soldering Based on Extended Kalman Filter
Received date: 2022-12-24
Online published: 2023-03-28
Supported by
the Natural Science Foundation of Guangdong Province(2021A1515011773);the Enterprise Science and Technology Commissioner Funding Project of Guangdong Province(GDKTP2021024300)
Hot bar soldering is a method used to connect electronic components. The stability of soldering horn temperature is the decisive factor of soldering quality. Due to the short time of hot bar soldering, the thermal inertia and random noise of thermocouple measurement have a great influence on the temperature control of the process. This paper developed a hot bar soldering power supply with STM32F407 microprocessor as the core, and designed the main circuit and control system of the power supply. By analyzing the delay response and time constant error of the thermocouple, this paper designed a new control method of hot bar soldering based on an Extended Kalman Filter (EKF) state observer, which realizes pulse width modulation and stable control of soldering temperature. It also analyzed the heating and thermal radiation effects of the heater tip, established a temperature model of the heater tip, and developed a simulation model of the hot bar soldering system based on the above main circuit and control scheme to verify the effectiveness of the control methods. A testing platform for the hot bar soldering system was built, and experiments were conducted according to the process parameters set by the simulation model. The simulated temperature waveform was compared and analyzed with the measured waveform. The results show that the trend of the simulated and tested temperature waveforms follows the same pattern. Compared to only using PID control, the control method based on EKF achieves a shorter adjustment time, reduces the impact of effective noise on the hot bar soldering system, and improves temperature control stability. The simulation model of the hot bar soldering system provides a reference model for the design of the hot bar soldering power supply. Finally, the hot bar soldering tests of FPC and PCB board, coaxial cable and LED circuit board were carried out to achieve the reliable connection of the components.
Key words: hot bar soldering; temperature control; extended Kalman filter; simulation
ZENG Min, XIE Jianxing, LI Zhitao, et al. . Modeling and Dynamic Simulation of Temperature Control Method for Hot Bar Soldering Based on Extended Kalman Filter[J]. Journal of South China University of Technology(Natural Science), 2023 , 51(9) : 11 -18 . DOI: 10.12141/j.issn.1000-565X.220826
| 1 | 滕瑞 .高动态热压焊电源及其温度智能控制方法研究[D].贵阳:贵州大学,2022. |
| 2 | 朱振柏 .热压焊焊点接头成形控制方法及系统研究[D].广州:华南理工大学,2018. |
| 3 | 王敏 .SAC305钎料/Cu基板的热压焊工艺及焊点组织研究[D].哈尔滨:哈尔滨理工大学,2018. |
| 4 | MICUS S, KIRSTEN I, HAUPT M,et al .Analysis of hot bar soldering,insulation displacement connections (IDC),and anisotropic conductive adhesives (ACA),for the automated production of smart textiles[J].Sensors,2020,20(1):5-15. |
| 5 | ZHANG K D, YANG K, LI G Y,et al .Effect of servo-pressurized mode on soldering process characteristics of micro-parts[J].IEEE Access,2022,10:115691-115701. |
| 6 | LI Y F, ZHANG Z J, HAO X J .Blind system identification of two-thermocouple sensor based on cross-relation method[J].Review of Scientific Instruments,2018,89(3):34901-34907. |
| 7 | 顾启泱 .精密柔性线路板焊接系统及工艺的研究[D].哈尔滨:哈尔滨工业大学,2019. |
| 8 | XU B, HAN T L, LIU H,et al .Accurate compensation of armored thermocouple based on fireworks algorithm[J].IEEE Sensors Journal,2021,21(8):9909-9918. |
| 9 | 曾家铨,曹彪,杨凯 .基于热电偶动态补偿的热压焊温度控制方法[J].焊接学报,2018,39(8):97-101. |
| ZENG Jiaquan, CAO Biao, YANG Kai .Temperature control method of hot bar bonder based on dynamic compensation for thermocouple[J].Transactions of the China Welding Institution,2018,39(8):97-101. | |
| 10 | 胥军,孙裕民,李刚炎,等 .电动物流车驱动电机冷却系统最优温度控制[J].华南理工大学学报(自然科学版),2018,46(12):51-57. |
| XU Jun, SUN Yumin, LI Gangyan,et al .Optimal temperature control strategy for electric transport vehicle drive motor cooling system[J].Journal of South China University of Technology(Natural Science Edition),2018,46(12):51-57. | |
| 11 | 刘亭剑,郝晓剑 .热电偶时间常数激光测试系统中激光加热研究[J].激光技术,2019,43(2):251-255. |
| LIU Tingjian, HAO Xiaojian .Study on laser heating of laser test system for thermocouple time constant[J].Laser Technology,2019,43(2):251-255. | |
| 12 | 孙宏健,李文军,李佳琪,等 .一种热电偶时间常数测试系统[J].中国计量大学学报,2017,28(2):146-152. |
| SUN Hongjian, LI Wenjun, LI Jiaqi,et al .A thermocouple time constant test system[J].Journal of China University of Metrology,2017,28(2):146-152. | |
| 13 | PAVLASEK P, ELLIOTT C J, PEARCE J V,et al .Hysteresis effects and strain-induced homogeneity effects in base metal thermocouples[J].International Journal of Thermophysics,2015,36(2/3):467-481. |
| 14 | ARUNPRASATH V, PATEL J V, ROY K .In-situ measurement and dynamic compensation of thermocouple time constant in nuclear reactors[J].International Journal of Advanced Technology and Engineering Exploration,2016,3(22):125-130. |
| 15 | KARAMALI M, KHODABANDEH M .A distributed solar collector field temperature profile control and estimation using inlet oil temperature and radiation estimates based on iterative extended Kalman filter[J].Renewable Energy,2017,101:144-155. |
| 16 | XUE W C, ZHANG X C, SUN L,et al .Extended state filter based disturbance and uncertainty mitigation for nonlinear uncertain systems with application to fuel cell temperature control[J].IEEE Transactions on Industrial Electronics,2020,67(12):10682-10692. |
| 17 | 张铁,许锦盛,邹焱飚 .基于扰动卡尔曼滤波的机器人免力矩传感器拖动示教方法[J].华南理工大学学报(自然科学版),2022,50(9):116-125. |
| ZHANG Tie, XU Jinsheng, ZOU Yanbiao .A force-sensorless dragging teaching method based on disturbance Kalman filter for robot[J].Journal of South China University of Technology(Natural Science Edition),2022,50(9):116-125. | |
| 18 | XIE B, HU F, CHEN S M .Modeling and simulation on temperature control system for hot pressure welding[J].Advanced Materials Research,2013,690/691/692/693:2589-2593. |
/
| 〈 |
|
〉 |