Sage Journals: Discover world-class research

Abstract

In practice, the volatile organic compounds (VOCs) pollution can exist when refueling due to the properties of the gasoline, low viscosity and high saturated-vapor pressure. A new gasoline vapor recovery system involving frequency conversion technology and machine learning is developed to cope with this problem. In the proposed system, firstly, the pumping capacity of the vacuum pump is evaluated, and test shows an almost linear relationship between suction volume and frequency. Then, the Multi-Layer Perception (MLP) neural network and the support vector regression (SVR) are employed to predict the gas-liquid ratio, and the numerical examples are presented to prove the high prediction accuracy of the MLP and SVR, respectively, where the MLP neural network has better generalization ability. Finally, compared with the two gasoline vapor recovery systems based on the 1: 1 fixed control model and the PID control model, respectively, the gasoline vapor recovery efficiency is improved significantly by the new gasoline vapor recovery system.

Keywords

Volatile organic compounds gasoline vapor recovery frequency conversion technology gas-liquid ratio machine learning

Get full access to this article

View all access options for this article.

References

Mozaffar

Zhang

Y-L.

Atmospheric volatile organic compounds (VOCs) in China: a review. Curr Pollution Rep 2020; 6: 250–263.

Zheng

Kong

Xing

, et al. Monitoring of volatile organic compounds (VOCs) from an oil and gas station in northwest China for 1 year. Atmos Chem Phys 2018; 18: 4567–4595.

Wang

Liu

, et al. Effect of exposure to volatile organic compounds (VOCs) on airway inflammatory response in mice. J Toxicol Sci 2012; 37: 739–748.

Celebi

Vardar

Investigation of VOC emissions from indoor and outdoor painting processes in shipyards. Atmos Environ 2008; 42: 5685–5695.

Mellouki

Wallington

Chen

Atmospheric chemistry of oxygenated volatile organic compounds: impacts on air quality and climate. Chem Rev 2015; 115: 3984–4014.

Liu

Wang

, et al. Frequency conversion controlled vapor recovery system by temperature and flow signals: model design and parameters optimization. SAE Paper 2013-01-2348, 2013.

Liu

Cai

Wang

, et al. A new preset refueling mode for gasoline dispenser using frequency converter and flow rate signals. Proc IMechE, Part E: J Process Mechanical Engineering 2016; 230: 440–446.

Zhou

Zeng

FH.

Application research on frequency conversion technology on the pump control in chemical works. Adv Mater Res-Switz 2011; 338: 748–753.

Zhou

Chen

, et al. Energy saving control system for central air-conditioning based on terminal temperature measuring and frequency conversion control technology. Adv Mater Res-Switz 2011; 201–203: 2144–2153.

10.

Liu

Ritter

Kaul

BK.

Simulation of gasoline vapor recovery by pressure swing adsorption. Sep Purif Technol 2000; 20: 111–127.

11.

Chue

Park

Jeon

JY.

Development of adsorption buffer and pressure swing adsorption (PSA) unit for gasoline vapor recovery. Korean J Chem Eng 2004; 21: 676–679.

12.

Zhao

Huang

Wang

, et al. Experimental study on adsorption of gasoline vapor on activated carbon at high concentration. Adv Mater Res-Switz 2013; 807–809: 549–552.

13.

Zhong

Huang

, et al. Study on the development of ZIF-8 membranes for gasoline vapor recovery. Ind Eng Chem Res 2014; 53: 3662–3668.

14.

, et al. Preparation of ZIF-69 membranes for gasoline vapor recovery. J Porous Mater 2015; 22: 1195–1203.

15.

Eshmane

VVD

Patil

AV.

Study of In₂O₃ and alpha-Fe₂O₃ nano-composite as a petrol vapor sensor. Mater Res Express 2019; 6: 1–11.

16.

Shinde

Kapadnis

Sawant

, et al. Screen print fabricated In3+ decorated perovskite lanthanum chromium oxide (LaCrO₃) thick film sensors for selective detection of volatile petrol vapors. J Inorg Organomet Polym 2020; 30: 5118–5132.

17.

Shi

Huang

WQ.

Sensitivity analysis and optimization for gasoline vapor condensation recovery. Process Saf Environ 2014; 92: 807–814.

18.

Liang

Sun

TX.

A novel defrosting method in gasoline vapor recovery application. Energy 2018; 163: 751–765.

19.

Huang

Wang

Lin

, et al. Gasoline vapor recovery based on integrated technology of absorption-adsorption. Appl Mech Mater 2013; 295–298: 1482–1485.

20.

Chen

Xie

, et al. Research on dynamic testing platform of gas-liquid ratio based on STM32 microprocessor. Chin J Mach Tool Hydraulics 2017; 45: 110–113.

21.

Rogers TT and McClelland JL. Précis of Semantic Cognition: A Parallel Distributed Processing Approach. Behav Brain Sci 2008; 31: 689–714.

22.

Kim

Elastic exponential linear units for convolutional neural networks. Neurocomputing 2020; 406: 253–266.

23.

Fan

, et al. Improving deep neural network with multiple parametric exponential linear units. Neurocomputing 2018; 301: 11–24.

24.

Cherkassky

The nature of statistical learning theory. 2nd ed. New Jersey: Red Bank, 2000, p.138.

25.

Chen

Zhang

Xue

Structural risk minimization-driven genetic programming for enhancing generalization in symbolic regression. IEEE Trans Evol Computat 2019; 23: 703–717.

26.

Najafi

Ghobadian

Moosavian

, et al. SVM and ANFIS for prediction of performance and exhaust emissions of a SI engine with gasoline-ethanol blended fuels. Appl Therm Eng 2016; 95: 186–203.

27.

Orru

Zoccheddu

Sassu

, et al. Machine learning approach using MLP and SVM algorithms for the fault prediction of a centrifugal pump in the oil and gas industry. Sustainability-Basel 2020; 12: 4776–4790.

28.

Reiter

Rinner

Picotti

, et al. mProphet: automated data processing and statistical validation for large-scale SRM experiments. Nat Methods 2011; 8: 430–435.

29.

Smola

Scholkopf

A tutorial on support vector regression. Stat Comput 2004; 14: 199–222.

30.

Jayawardhana

Logemann

Ryan

EP.

PID control of second-order systems with hysteresis. Int J Control 2008; 81: 1331–1342.

31.

Nguyen

PD.

Overshoot and settling time assignment with PID for first-order and second-order systems. IET Control Theory Appl 2018; 12: 2407–2416.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.24 MB

0.14 MB

Machine learning approach to improve vapor recovery: Prediction and frequency converter with a new vapor recovery system

Abstract

Keywords

Get full access to this article

References

Supplementary Material