Prediction of methanol loss by hydrocarbon gas phase in hydrate inhibition unit by back propagation neural networks

Q4 Chemical Engineering Journal of Chemical and Petroleum Engineering Pub Date : 2019-12-01 DOI:10.22059/JCHPE.2019.283971.1288

B. Vaferi

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引用次数: 4

Abstract

Gas hydrate often occurs in natural gas pipelines and process equipment at high pressure and low temperature. Methanol as a hydrate inhibitor injects to the potential hydrate systems and then recovers from the gas phase and re-injects to the system. Since methanol loss imposes an extra cost on the gas processing plants, designing a process for its reduction is necessary. In this study, an accurate back propagation neural network (BPNN) is designed for the prediction of methanol loss by the gas phase as a function of temperature, pressure, and methanol composition in the aqueous phase. Different configurations of BPNN were trained, tested, and a configuration providing the smallest absolute average relative deviation (AARD%) was chosen as an optimum structure. Finally, comparisons made among the accuracy of the developed BPNN model, process simulators, and probabilistic neural network (PNN). Results confirm that the designed BPNN model is more accurate than the other considered predictive tools. The BPNN provided an AARD=5.75% for prediction of experimental data, while Aspen-HYSYS, Aspen-Plus, and PNN presented an AARD% of 9.71, 12.57, and 13.27, respectively.

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用反向传播神经网络预测水合物抑制装置烃类气相甲醇损失

天然气水合物经常发生在高压低温下的天然气管道和工艺设备中。甲醇作为水合物抑制剂注入到潜在的水合物体系中，然后从气相中回收并再注入到体系中。由于甲醇的损失给气体处理厂带来了额外的成本，因此设计一种减少甲醇的工艺是必要的。在本研究中，设计了一个精确的反向传播神经网络(BPNN)，用于预测气相甲醇损失作为温度、压力和水相甲醇成分的函数。对不同配置的bp神经网络进行训练和测试，并选择具有最小绝对平均相对偏差(AARD%)的配置作为最优结构。最后，对所建立的bp神经网络模型、过程模拟器和概率神经网络(PNN)的精度进行了比较。结果证实，所设计的BPNN模型比其他考虑的预测工具更准确。BPNN预测实验数据的AARD=5.75%，而Aspen-HYSYS、Aspen-Plus和PNN的AARD%分别为9.71、12.57和13.27。

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