Working area of the helicopter PAD stabilization mechanism

• Autorzy: Brewczyński D. , Tora G.

Identyfikatory

DOI

10.5604/01.3001.0010.2795

• Języki publikacji: EN

Abstrakty

EN

Helicopter pad located on the ship significantly increase the operational capabilities of military and civilian ships. During the storm, especially side tilts of the ship hinder or even prevent the safe use of the helicopter pad. It is proposed to apply the system placed between the deck of the ship and landing site plate, driven by four independent cable drives located under the deck. The task of the system will be preventing from transferring to Helicopter pad the tilt of the ship around the longitudinal and transverse axis and the displacement of the deck along the transverse and vertical axis within the limits of the work area. The mechanism consists of four movable links on which the movable helicopter pad platform is located. As the linear actuators, trolleys moving along horizontal guides were used, powered by system of steel cables with four independent electric motors. In folded state the mechanism, take up appropriately little space under the deck area. For the assumed extreme amplitudes of the ship motion, minimum dimensions of the mechanism links that meets the requirement to work in one configuration and lack of collisions were determined. Kinematic relationships were created indicate which mechanical quantities should be measured in real time to determine the momentary drives speeds. For the adopted assumptions simulation was performed, confirming the predicted behaviour of the system. Based on the kinematic equations of system and taking in consideration collisions and geometrical limits, working area for the flat part of the mechanism was determined.

Słowa kluczowe

EN

mechanical engineering; maritime engineering; mechanism design; safety

PL

Inżynieria mechaniczna; inżynieria morska; bezpieczeństwo

• Wydawca: Łukasiewicz Research Network - Institute of Aviation ; European Science Society of Powertrain and Transport KONES Poland ; Wydawnictwo Instytutu Technicznego Wojsk Lotniczych
• Czasopismo: Journal of KONES
• Rocznik: 2017
• Tom: Vol. 24, No. 1
• Strony: 59--66
• Opis fizyczny: Bibliogr. 14 poz., rys.

Twórcy

autor

Brewczyński D.

• Cracow University of Technology, Faculty of Mechanical Engineering Laboratory of Techno-Climatic Research and Heavy Duty Machines Jana Pawła II Av. 37, 31-864 Krakow, Poland tel.: +48 12 6283406, fax: +48 12 3743360

autor

Tora G.

• Cracow University of Technology, Faculty of Mechanical Engineering Laboratory of Techno-Climatic Research and Heavy Duty Machines Jana Pawła II Av. 37, 31-864 Krakow, Poland tel.: +48 12 6283406, fax: +48 12 3743360

Bibliografia

• [1] Brewczyński, D., Tora, G., Dynamics model of stabilization mechanism for helicopter pad, KONES, 2016.
• [2] Brewczyński, D., Tora, G., Dynamic positioning system of helicopter pad on the ship, Journal of Kones, Vol. 21, No. 4, 21-27, 2014.
• [3] Brewczyński, D., Tora, G., Stabilization mechanism for helicopter pad with four degrees of freedom, Journal of KONES, e-ISSN: 2354-0133, OI: 10.5604/12314005.1165947, 2015.
• [4] Gogu, G., Parallel mechanisms with decoupled rotation of the moving platformin planar motion, J. Mechanical Engineering Science Proc. ImechE, Vol. 224, Part C, 710-720, 2010.
• [5] Han, C., Kim, J., Kim, J., Park, F. C., Kinematic sensitivity analysis of the 3-UPU parallel mechanism, Mechanism and Machine Theory, 37, 787-798, 2002.
• [6] Ider, S. K., Inverse dynamics of parallel manipulators in the presence of drive singularities, Mechanism and Machine Theory, 40, 33-44, 2005.
• [7] Quennouelle, C., Gosselin, C. M., Stiffness Matrix of Compliant Parallel Mechanisms, Advanced in Robot Kinematics: Analysis and Design, 331-341, 2008.
• [8] Sanchez-Lopez, J. L., Pestana, J., Saripalli, S., Campoy, P., An Approach Toward Visual Autonomous Ship Board Landing of a VTOL UAV, J Intell Robot Syst., 74:113-127, 2014.
• [9] Zhao, J-S., Feng, Z.-J, Zhou, K., Dong, J.-X., Analysis of the singularity of spatial parallel manipulator with terminal constraints, Mechanism and Machine Theory, 40, 275-284, 2005.
• [10] Zhu, Z., Li, J., Gan, Z., Zhang, H., Kinematic and dynamic modeling for real-time control of Tau parallel robot, Mechanism and Machine Theory, 40, 1051-1067, 2005.
• [11] Patent P.407136, Tora, G., Mechanizm stabilizujący ruchome lądowisko helikopterów.
• [12] Patent: US 2010/0224118, A1, Helicopter Landing Platform Having Motion Stabilizer for Compensating Ship Roll and/or Pitch, 2010.
• [13] CILAS HVLAS Helicopter Visual Landing Aid System http://www.cilas.com/helicopter-visual-landing-aids.htm.
• [14] Prism Defence company that develops support systems for helicopters landing on the ships http://www.prismdefence.com/index.html.

Uwagi

PL

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).