Optimization of Performance Characteristics of Magnetofluidic Seals for Wind Power Plants

Q3 Energy

Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations Pub Date : 2023-02-07 DOI:10.21122/1029-7448-2023-66-1-80-90

O. N. Labkovich, S. G. Pogirnitskaya

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引用次数: 0

Abstract

The use of magnetofluidic seals are a promising direction in sealing rotating shafts of wind power plants. Magnetofluidic seals are characterized by high tightness, simplicity of the design, low losses by friction. Magnetic fluid seal of the rotating shaft consists of a ring magnet and two concentrators of magnetic field, forming with the shaft a narrow ring gap in which the magnetic fluid retained by magnetic field is a hermetic seal. Magnetic forces provide balance of volume of magnetic fluid under the impact of pressure drop and centrifugal forces. With an increase in the speed of rotation of the shaft up to 10 m/s, deformation of the free surface of the magnetic fluid at the surface of the shaft in the form of a funnel is visually observed, which causes a decrease in the retained pressure drop. As the rotation speed increases, the funnel increases, part of the magnetic fluid is ejected from the working area, the retained pressure drop decreases, and at 50 m/s there is a complete release of the magnetic fluid and depressurization of the seal. In order to increase the stability of the free surface of the magnetic fluid in the field of centrifugal forces, multilayer carbon nanotubes were introduced into it. They are characterized by a high specific surface area and, accordingly, a strong Van der Waals attraction. In a magnetic fluid, multilayer carbon nanotubes form structures which are oriented along the magnetic field lines. The following increase in the static load retained by a layer of magnetic fluid has been experimentally determined with the introduction of nanocarbon structures: when coinciding with the axis of the structures the increase was by 100 %, for the normal direction of the load to the axis of the structure – by 50 %. In the seal, with an increase in the shaft rotation speed, deformation of the free surface of a magnetic fluid with nanocarbon structures was observed at 18 m/s at a distance of 3 mm from the shaft surface. The pressure drop retained by the seal increased in the speed range of 10–40 m/s, the maximum effect of 50 % was obtained at a speed of 40 m/s. Thus, the introduction of nanocarbon structures into the magnetic fluid made it possible to reduce the influence of centrifugal forces on the retained pressure drop and increase the efficiency of the magnetofluidic seal at high speeds of rotation of the shaft of wind power plants.

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风电场磁流体密封性能特性优化研究

采用磁流密封是风力发电转轴密封的一个很有前途的方向。磁流体密封具有密封性高、设计简单、摩擦损耗小等特点。旋转轴的磁流体密封由一个环形磁铁和两个磁场集中器组成，与轴形成一个狭窄的环形间隙，磁场保留在环形间隙中的磁流体是一个密封密封。磁力在压力降和离心力的作用下提供磁性流体的体积平衡。当轴的转速增加到10 m/s时，可以直观地观察到轴表面磁性流体的自由表面以漏斗的形式发生变形，导致保留压降减小。随着转速的增加，漏斗增大，部分磁性流体被喷射出工作区域，保留压降减小，在50 m/s时，磁性流体完全释放，密封降压。为了提高磁流体自由表面在离心力场中的稳定性，在磁流体中引入了多层碳纳米管。它们的特点是具有较高的比表面积，因此具有很强的范德华引力。在磁性流体中，多层碳纳米管形成沿磁力线取向的结构。通过引入纳米碳结构，实验确定了一层磁性流体保留的静载荷的以下增加:当与结构的轴线重合时，增加了100%，对于结构轴线的载荷的法线方向-增加了50%。在密封中，随着轴转速的增加，在距离轴表面3mm处观察到具有纳米碳结构的磁性流体的自由表面以18 m/s的速度变形。在10 ~ 40 m/s的速度范围内，密封保留的压降增大，在40 m/s的速度范围内效果最大，达到50%。因此，在磁流体中引入纳米碳结构，可以减小离心力对保留压降的影响，提高风力发电厂轴高速旋转时磁流体密封的效率。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations Energy-Nuclear Energy and Engineering

CiteScore

1.60

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： The most important objectives of the journal are the generalization of scientific and practical achievements in the field of power engineering, increase scientific and practical skills as researchers and industry representatives. Scientific concept publications include the publication of a modern national and international research and achievements in areas such as general energetic, electricity, thermal energy, construction, environmental issues energy, energy economy, etc. The journal publishes the results of basic research and the advanced achievements of practices aimed at improving the efficiency of the functioning of the energy sector, reduction of losses in electricity and heat networks, improving the reliability of electrical protection systems, the stability of the energetic complex, literature reviews on a wide range of energy issues.