Unified structure of the precision high-speed energy system and resource-saving automatic control and regulation
Keywords:
mechatronic systems, resource saving, electro-hydraulic servo system, electrohydraulic drive, automatic control systemAbstract
It is considered one of the main problems of saving energy and resources, namely the creation and introduction of new efficient technologies and technological systems in all fields of technology and industry. As a solution to this problem is proposed use of mechatronic systems with electrohydraulic servo actuators (EHSA), which are currently considered as electro-hydraulic servo system (EGSS). Their use is justified by the fact that they combine a high specific energy characteristics of the electro-hydraulic mechanisms with intelligent control and information capabilities of microprocessor electronics and allow a high degree of accuracy and speed of playback control actions, that vary in the an arbitrary, including and previously unknown laws. The algorithm for selecting the optimal circuit design of electrohydraulic drive EHD. On the basis of this algorithm is chosen the most effective typical version of the concept for use in high-speed precision EGSS - EHD single-channel version with separate volume-throttle speed control. With the direct participation of the author of this paper conducted a cycle of research and development activities in the course of which two sizes of part-turn hydraulic motors have been created. Challenge definition of introducing energy-saving of automatic systems of technological objects and processes. It is proposed as an effective management solution, based on the methods of system analysis and mathematical modelingReferences
1. T. Isii, I. Simoyapa, H. Inoue and others. Mechatronics. Mir. Japan., 1988. 318 p.
2. Kanyuk, G. I. Prospects for the use of electronic-hydraulic device in modern energy- and resource-saving energy systems. Vestn. Harkov. politehn. un. Kharkov. 1999, no 44. pp. 39–40.
3. Topcheev Yu. I. Atlas for the design of automatic control systems. Mashinostroenie. Moscow. 1989. 752 p.
4. Kanyuk G. I., Shuvanov A. N., Bliznichenko E. N., Logvinov M. V. By the choice of the type of actuator for mechatronic systems. Vestn. nats. tehn. un. «HPI». Kharkov. 2002, no.7. pp. 120–125.
5. Ivaschenko N. N. Automatic control. Theory and elements of systems. Mashinostroenie. Moscow.1978. pp 98, 736.
6. Fedorets, V. A., Strutinskiy V. B. Analysis of the dynamic properties of the hydraulic drive, controlled hydraulic booster jet of high pressure. Hydraulic and hydro pneumatic automation: Republican interdepartmental scientific and technical collection. Kyiv. 1981. pp. 44–48.
7. Komissarenko, Yu. Ya. Elastic characteristics of the exciter with gas-hydraulic batteries. Hydraulic and hydro pneumatic automation: Republican interdepartmental scientific and technical collection. Kyiv. 1988, no 27. pp.25–29.
8. Iskovich-Lototskiy R. D., Matveev I. B and others. Hydroimpulsive drive. Hydraulic and hydro pneumatic automation: Republican interdepartmental scientific and technical collection. Kyiv. 1982, no 18. pp. 56–60.
9. Kollektiv sostaviteley. Hydro and pneumatic and its elements Marketplace. Engineering. Moscow. 1992. 232 p.
10. Chuprakov Yu. I. Hydraulic tools and hydro pneumatic: Tutorial. Engineering. Moscow. 1979. 232 p.
11. Kondakov L. A., Nikitin G. A., Prokofev V. N. i dr. Machine hydraulic. Engineering. Moscow. 1978. 495 p.
12. Kanyuk G. I., Shuvanov A. N., Topchiy A. G., Bliznichenko E. N. i dr. Modular test bench elements of car transmissions. Vestn. Khar. Polytechn. Un. Kharkov. 1999, no 45. pp. 52–54.
13. Kanyuk G. I. Creation of electronic-hydraulic servo systems dynamic simulation booth. Vestn. Khar. Polytechn. Un. Kharkov. 1999, no. 46. pp. 42–46.
14. Rogachov A. I. Power saving modes control non-stationary processes: Abstract Dis. Dr. Sc. Harkiv. 2008. 36 p.
15. Duel M. O.Automated process control systems of thermal power elektrostanschy (development, research, implementation): Abstract Dis. Dr. Sc. Harkiv. 1998. 36 p.
16. Gorelik O. X. Improving the automated control of nuclear power i power plants to improve the reliability ix ekspluataschynoyi: Abstract Dis. Dr. Sc. Harkiv. 2007. 36 p.
17. Ryumshin M. O. Synthesis, development and implementation of automated process control systems and steel rolling mills: Abstract Dis. Dr. Sc.Harkiv. 2007. 36 p.
18. Severin V. P. Models i methods optimize quality parameters of automatic control unit nuclear power plant: Abstract Dis. Dr. Sc. Harkiv. 2007. 35 p.
19. Kanyuk G. I. Models i i parametric methods of structural synthesis of precision electrohydraulic servo systems automated test benches: Abstract Dis. Dr. Sc.Harkiv. 2009. 35 p.
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