Power Calculation of Anti-Driveaway Crane Device from Eccentric and Wedge Mechanisms

To carry out a power calculation of the anti-driveaway device (AD) of lifting cranes operating in the open air, it is necessary to know the conditions that ensure their reliable stop and fixation on rails, as well as kinematic parameters, namely, the speed and acceleration of cranes when they move along the rails under the influence of  the wind force. The considered AD for stopping cranes driven away by the force of the wind uses a tong gripper driven by an eccentric mechanism.The paper presents the calculation of the forces arising during the operation of the tong gripper, considering the possibilities of various types of friction on the contact surfaces both in the absence of lubrication and in its presence.  The calculations of the eccentric mechanism as one of the fundamental mechanisms of the anti-driveaway crane device are presented in the paper. The stronger the wind force, the more due to the kinematic connection of the two mechanisms, when turning the eccentric mechanism, the pressure of the tong mechanism increases on the side faces of the head of the crane rail. The constructive solution of the AD excludes any actions of the personnel and makes it automatic.

1. Natalevich A. N., Nesterenko N. L., Selivonchik N. M. (2022). Automatic Anti-Theft Device Fore Cranes. Patent BY No 12950 (in Russian).

2. Selivonchik N. M., Nesterenko N. L. (2021) Basics of Calculating Anti-Theft Crane Device from Eccentric and Tick-Borne Mechanisms. Nauka i Tekhnika = Science and Technique, 20 (4), 296–301. https://doi.org/10.21122/2227-1031-2021-20-4-296-301 (in Russian).

3. Rules on Ensuring Industrial Safety of Hoisting Cranes: Resolution of the Ministry of Emergency Situations of the Republic of Belarus of December 22, 2018 No 66. National Legal Internet Portal of the Republic of Belarus. Available at: https://pravo.by/document/?guid=12551&p0=W21934170p&p1=1 (аccessed 14 April 2021) (in Russian).

4. State Standard 1451-77. Cranes. Wind Load. Norms and Method of Determination. Moscow, Publishing House of Standards, 2003. 13 (in Russian).

5. Aleksandrov M. P. (1985) Lifting-Transport Machines. Moscow, Vysshaya Shkola Publ. 520 (in Russian).

6. State Standard 27674–88. Friction, Wear and Lubrication. Terms and Definitions. Moscow, Committee for Standardization and Metrology of the USSR, 1989. 21 (in Russian).

7. Acherkan N. S. (ed.) (1965) Metalworker’s Handbook. Vol. 1. Moscow, Mashinostroenie Publ., 145 (in Russian).

8. Engineering Handbook. Tables DPVA. Available at: https://dpva.ru (accessed 14 April 2021) (in Russian).

9. Ivanov E. M. (2005) Work when Moving Bodies with Friction. Sovremennye Problemy Nauki i Obrazovaniya = Modern Problems of Science and Education, (2). Available at: https://www.science-education.ru/ru/article/view?id=1468 (аccessed 14 April 2021) (in Russian).

10. Kuzmin A. V., Chernin I. M., Kozintsov B. S. (1986) Calculations of machine parts. 3rd Ed. Moscow, Vysheyshaya Shkola Publ. 400 p. (in Russian).

11. Kishkin I. V. (2006) Equipment for Forging and Stamping Shops. Part 2: Hydraulic Presses: Training Manual for Practical Exercises. Elektrostal, Elektrostal Polytechnical Institute Moscow University of Science and Technology. 107 (in Russian).

12. Calculation of Wedge Mechanisms. Encyclopedia of Mechanical Engineering XXL. Available at: https://mash-xxl.info/info/510378/ (in Russian).

13. Reshetov L. N. (1972) Designing of Rational Mechanisms. 2nd еd. Moscow, Mashinostroenie Publ. 256 (in Russian).