Graphical Interface Design for Water Pumping Process which Works with a Hydrophore

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Abstract

In this paper, the application of water pumping process is presented. This article presents the design of a human machine interface. Using this interface, it can be possible to track the evolution of pumping water flow. The applications consists of water pumping process simulation. Also, are illustrated and analyzed several cases, depending on the water flow which is inside the tank.

Abstract

In this paper, the application of water pumping process is presented. This article presents the design of a human machine interface. Using this interface, it can be possible to track the evolution of pumping water flow. The applications consists of water pumping process simulation. Also, are illustrated and analyzed several cases, depending on the water flow which is inside the tank.

REFERENCES

  • [1] M. Capelli-Schellpfeffer, Safety when we will the way, IEEE Industry Applications Magazine, vol. 17, no. 5, ISSN 1077-2618,2011.

  • [2] D.S. Bernstein, Rules Rule – Real Time Engineering, IEEE Control Systems Magazine, vol. 31, no. 3, pp. 6-7. 2011.

  • [3] C. R. Costea, H. Silaghi, E.I. Gergely, G. Husi, L. Coroiu, Z. Nagy, Approach of PID Controller Tuning for Ball Mill, Proceedings of 2014 International Symposium on Fundamentals of Electrical Engineering, Bucharest, Romania, November 28-29, 2014, pp. 371-374, 2014.

  • [4] W.H. Kersting, The whys of distribution system analysis, IEEE Industry Applications Magazine, vol. 17, no. 5, ISSN 1077-2618, pp. 59-65, 2011.

  • [5] D. Inverso, R. Sokoll, Optimum human-machine interface design, Control Eng. 44(12), pp. 93-98, 1997.

  • [6] S. Weiss, R. Siegwart, Real-time metric state estimation for modular vision inertial systems, Proceedings of the IEEE International Conference in Robotics Automation, pp. 4531-4537, 2011.

  • [7] A. Bobtsov, A. Borgul, Human-machine interface for mechatronic devices control, IFAC Proceedings Volumes, ISSN 1474-6670, pp. 614 – 618, 2013.

  • [8] L. Scott, A. Joseph Torzillo, Human-machine interface systems for production aplications, SMT Surface Mount Technology Magazine, 26(10), pp. 16-30, 2011.

  • [9] Graham C. Goodwin, Stefan Graebe, Mario E. Salgado, Control System Design. Industrial Applications of Feedforward Control, pp. 227, Valparaiso, Chile, 2000.

[1] M. Capelli-Schellpfeffer, Safety when we will the way, IEEE Industry Applications Magazine, vol. 17, no. 5, ISSN 1077-2618,2011.

[2] D.S. Bernstein, Rules Rule – Real Time Engineering, IEEE Control Systems Magazine, vol. 31, no. 3, pp. 6-7. 2011.

[3] C. R. Costea, H. Silaghi, E.I. Gergely, G. Husi, L. Coroiu, Z. Nagy, Approach of PID Controller Tuning for Ball Mill, Proceedings of 2014 International Symposium on Fundamentals of Electrical Engineering, Bucharest, Romania, November 28-29, 2014, pp. 371-374, 2014.

[4] W.H. Kersting, The whys of distribution system analysis, IEEE Industry Applications Magazine, vol. 17, no. 5, ISSN 1077-2618, pp. 59-65, 2011.

[5] D. Inverso, R. Sokoll, Optimum human-machine interface design, Control Eng. 44(12), pp. 93-98, 1997.

[6] S. Weiss, R. Siegwart, Real-time metric state estimation for modular vision inertial systems, Proceedings of the IEEE International Conference in Robotics Automation, pp. 4531-4537, 2011.

[7] A. Bobtsov, A. Borgul, Human-machine interface for mechatronic devices control, IFAC Proceedings Volumes, ISSN 1474-6670, pp. 614 – 618, 2013.

[8] L. Scott, A. Joseph Torzillo, Human-machine interface systems for production aplications, SMT Surface Mount Technology Magazine, 26(10), pp. 16-30, 2011.

[9] Graham C. Goodwin, Stefan Graebe, Mario E. Salgado, Control System Design. Industrial Applications of Feedforward Control, pp. 227, Valparaiso, Chile, 2000.

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