Welcome to Francis Academic Press

International Journal of Frontiers in Engineering Technology, 2022, 4(1); doi: 10.25236/IJFET.2022.040106.

Design and Implementation of Chemical Automatic Drawing System Based on Computer Technology

Author(s)

Cheng Cheng

Corresponding Author:
Cheng Cheng
Affiliation(s)

Sichuan Vocational and Technical Collge, Sichuan 629000, China

Abstract

With the continuous development of computer technology, people pay more and more attention to the drawing process, and gradually improve it when designing and developing new software. This paper will study based on computer-aided graphics rendering system. Firstly, this paper introduces the concept and characteristics of chemical automatic drawing, then studies the straight-line algorithm and arc algorithm in drawing based on computer technology, designs and develops the framework of chemical automatic drawing system, and tests the performance of the system. Finally, the test results show that the system has strong response load, stable system performance, good stability and high sensitivity. These reasons make the automation technology in the chemical process operate effectively in the actual work, so as to improve the production efficiency and product quality of the enterprise.

Keywords

Computer Technology, Chemical Automation, Automatic Drawing, Drawing System

Cite This Paper

Cheng Cheng. Design and Implementation of Chemical Automatic Drawing System Based on Computer Technology. International Journal of Frontiers in Engineering Technology (2022), Vol. 4, Issue 1: 31-36. https://doi.org/10.25236/IJFET.2022.040106.

References

[1] Benussi L, Bertani M, Bianco S , et al. Design and implementation of an automatic gas-cylinder inversion system based on an embedded computer[J]. Nuclear Inst & Methods in Physics Research A, 2017, 461(1-3):98-99.

[2] Xin J, Kaixuan Z, Jiangtao J, et al. Design and implementation of Intelligent transplanting system based on photoelectric sensor and PLC[J]. Future Generation Computer Systems, 2018:127-139.

[3] Hassold E, Galert W, Schulze J. Options for an environmental risk assessment of intentional and unintentional chemical mixtures under REACH: the status and ways forward[J]. Environmental Sciences Europe, 2021, 33(1):1-17.

[4] Gunderson J, Mitchell D W ,  Bullis R G , et al. Design and Implementation of Three-Dimensional Printable Optomechanical Components[J]. Journal of Chemical Education, 2020, 97(10):3673-3682.

[5] Wang Y, Gao S, Liu Y, et al. Design and Implementation of project-oriented CDIO approach of instrumental analysis experiment course at Northeast Agricultural University - ScienceDirect[J]. Education for Chemical Engineers, 2020, 34:47-56.

[6] Collison C G ,  Kim T ,  Cody J , et al. Transforming the Organic Chemistry Lab Experience: Design, Implementation, and Evaluation of Reformed Experimental Activities—REActivities[J]. Journal of Chemical Education, 2018, 95(1): págs. 55-61.

[7] Nada B, Enp*A B. Model-based multi-parametric programming strategies towards the integration of design, control and operational optimization [J]. Computer Aided Chemical Engineering, 2017, 40:1867-1872.

[8] Jiang Z. Development and implementation of systematic model-development strategy using model-based experimental design[J]. Chemical Engineering Research and Design, 2019, 146:290-310.

[9] Vitkovsky S L ,  Danilov A P ,  Shchedrin M G , et al. Design chemistry implementation experience during the power unit start-up and commissioning[J]. Nuclear Energy & Technology, 2017, 3(4):313-318.

[10] Wei Zhimin, Li Youming, Hou Yice. Quick estimation for pollution load contributions of aromatic organics in wastewater from pulp and paper industry[J]. Nordic Pulp & Paper Research Journal, 2018, 33(3):568-572.

[11] Wright F D, Conte T M. Standards: Roadmapping Computer Technology Trends Enlightens Industry[J]. Computer, 2018, 51(6):100-103.

[12] Chow, James C L. Internet-based computer technology on radiotherapy[J]. Rep Pract Oncol Radiother, 2017, 22(6):455-462.