115

A review and analysis of known works on the automation of control and
regulation-monitoring of the width of the working slots of the harvesting apparatus (НA)
of the cotton harvester, in particular, the automation of control and regulation of working
units, which determines the indicators of the quality of the harvest and the productivity
of the cotton harvester, is carried out. It has been substantiated that in order to increase
the efficiency of the functioning of the cotton picker, automatic control and management
systems are needed that perform the functions of information-measuring and control
systems that perform horizontal and vertical adjustment of the position of the harvesting
device and adjust the working gap according to the agricultural background, inform the
driver about other important parameters of the cotton picker and cotton-growing
machine-tractor units (CGMTU). It has been established that one of the most important
parameters to be monitored and regulated by the cotton harvester is the width of its
working slot (WWS), which determines the productivity and quality of the cotton
harvester collection. It was revealed that despite some progress in this direction, there
is still a lot of research work to be done on the development of intelligent converters,
sensors, instrumentation and control devices. At the same time, one of the main
element and node that determines the accuracy of control and regulation of the width of
the working slot is sensors that control and convert the width of the working slot into a
different type of signal proportional to them, convenient for further use, which is an
urgent issue. In this regard, the work considered and carried out a critical analysis of the
principles of construction and operation, methods and sensors for controlling the width
of the working slots (WWS), for example: contact with mechanical switches, inductive
and potentiometric sensors with outputs of the controlled parameters to various display
elements: numbered color lamps, displays, etc. The main characteristics, advantages
and disadvantages of the considered sensors are given, as a result of which it is
concluded that it is necessary to continue research and development in this direction.
 

  • Ссылка в интернете
  • DOI
  • Дата создание в систему UzSCI 09-03-2023
  • Количество прочтений 115
  • Дата публикации 30-06-2022
  • Язык статьиIngliz
  • Страницы169-178
English

A review and analysis of known works on the automation of control and
regulation-monitoring of the width of the working slots of the harvesting apparatus (НA)
of the cotton harvester, in particular, the automation of control and regulation of working
units, which determines the indicators of the quality of the harvest and the productivity
of the cotton harvester, is carried out. It has been substantiated that in order to increase
the efficiency of the functioning of the cotton picker, automatic control and management
systems are needed that perform the functions of information-measuring and control
systems that perform horizontal and vertical adjustment of the position of the harvesting
device and adjust the working gap according to the agricultural background, inform the
driver about other important parameters of the cotton picker and cotton-growing
machine-tractor units (CGMTU). It has been established that one of the most important
parameters to be monitored and regulated by the cotton harvester is the width of its
working slot (WWS), which determines the productivity and quality of the cotton
harvester collection. It was revealed that despite some progress in this direction, there
is still a lot of research work to be done on the development of intelligent converters,
sensors, instrumentation and control devices. At the same time, one of the main
element and node that determines the accuracy of control and regulation of the width of
the working slot is sensors that control and convert the width of the working slot into a
different type of signal proportional to them, convenient for further use, which is an
urgent issue. In this regard, the work considered and carried out a critical analysis of the
principles of construction and operation, methods and sensors for controlling the width
of the working slots (WWS), for example: contact with mechanical switches, inductive
and potentiometric sensors with outputs of the controlled parameters to various display
elements: numbered color lamps, displays, etc. The main characteristics, advantages
and disadvantages of the considered sensors are given, as a result of which it is
concluded that it is necessary to continue research and development in this direction.
 

Имя автора Должность Наименование организации
1 E A. . teacher TSTU
2 U M. . teacher TSTU
3 A A.A. teacher Fergana branch of TUIT of the Department of "Information Technologies"
4 S M.E. teacher 2Magistr of Moscow State University of Technology «STANKIN», Moscow, Russia.
Название ссылки
1 A.S. Sadriddinov, A.D. Abdazimov, E. Ulzhaev. Improving the working bodies and controllability of a cotton harvester with the location of harvesting machines behind the tractor drive bridge. Materials of the International Journal. NTC "Modern problems of mechanics". “Tashkent: research Institute of mechanics and SS of the academy of sciences of the Republic of Uzbekistan”. 2009. 273
2 E. Ulzhaev, A.D. Abdazimov, Sh.T. Ravutov, F.A. Tulbaev. Hardware supports the system of automatic control and regulation of parameters of mobile objects. “Chemical technology, control and management”. 2012. 29.
3 A.D. Abdazimov. “Tracking system for controlling the width of the working slot of the harvesting machine of the cotton harvesting machine”. 2003. 103
4 E. Ulzhaev, A.D. Abdazimov, U.M. Ubaydullaev, S.M. Sherkobilov, Z.G. Shodiev, A.M. Nosirov. Mechanism of adjustment of working slots of vertical-spindle cotton harvesting apparatus. “Agencies for intellectual property under the Ministry of justice of the Republic of Uzbekistan”. 2020
5 A.D. Abdazimov, E. Ulzhaev, U.M. Ubaydullaev, N.N. Omonov. “Fundamentals of automation of control and control of technological parameters of cotton harvesters”. 2014. 164
6 E. Ulyaev, U.M. Ubaydullaev. Diagnostic devise for changing the airflow velocity in the pneumatic chamber of cotton harvesters. “Ninth world conference "Intelligent industrial automation systems". 2016.
7 N. G. Farzane. Technological measurements and devices. "Higher School". 1989. 456
8 V. V. Cherenkov. Industrial devices and automation tools. "Mechanical engineering", 1987. 847
9 Analysis of the data of Table 3 shows that the main rock-forming minerals of the weeds are quartz, feldspar, fragmentary rocks, the percentage of carbonate was – 13.0. The analysis found that the content in the seeding of crushing porphyries, sulfuric and sulfuric acid compounds, organic components meet all the requirements
10 V.Y. Shishmarev. Typical elements of automatic control systems: Textbook for seed. prof. education. “Publisher Center Academy”. 2004. 304.
11 M.A. Babikov, A.V. Kosinsky. Elements and devices of automation. “Higher School of Economics”. 1975.
12 E. Ulzhaev, U.M. Ubaydullaev, G.T. Tajitdinov, S. Narzullaev. “Development of criteria for the synthesis of the optimal structure of monitoring and control systems”.2020
13 R.A. Aliev, N.R. Yusupbekov, J. Kachpshik, V. Pedrych, F.M. Sadikoglu. 11th World Conference. "Intelligent Industrial Automation Systems". WCIS. 2020
14 E. Ulzhaev, U.M. Ubaidullaev, Z.E. Ulzhaev. Electronic on-board control system for operational and technological parameters of cotton-growing plants. Monthly scientific and practical journal. "Tractors and agricultural machines". 2014. 11
15 E. Ulzhaev, A.D. Abdazimov, U.M. Ubaidullaev. Methodology for diagnosing the probability of trouble-free operation of a cotton harvester. “Proceedings of the St. Petersburg State Agrarian University”. 2018. 270
16 E.U. Ulzhaev, A.D. Abdazimov, U.M. Ubaydullaev. Intelligent onboard MPC for monitoring and controlling technological parameters of MTA with tractor TTF. International scientific and practical Conference. “Technology of the future, prospects for the development of agricultural machinery". 2013. 189
В ожидании