Electrically Insulated Rolling Bearings

Protection against bearing damage caused by the passage of electric current

Steyr, Austria, March 2015. Electrically insulated rolling bearings feature electrical insulation that is built into the bearing, providing reliable protection against current passage and electrical corrosion. Typical applications are electric motors, generators and other electrical machines. The Austrian manufacturer NKE Austria GmbH offers electrically insulated rolling bearings in several versions. In this article, Klaus Grissenberger, Application Engineer with NKE, explains the causes of passage of electrical current through rolling bearings, damage symptoms and countermeasures, properties and production processes of electrically insulated bearings.

NKE Bild 3 SQ77E_sl1

NKE SQ77E deep groove ball bearing with insulation on the inner ring.

A difference in electrical potential between the outer and inner ring of a rolling bearing can lead to a damaging electric current that permanently damages the bearing’s raceways and impairs its running characteristics. A current flow results in electrical discharge in the contact zone between the rolling elements and the inner or outer ring. This, in turn, causes local melting of the surfaces. The result: pitting, material transfer and local microstructural damage through thermal stress. At least a very thin layer of the eroded surface is re-hardened, making it extremely hard and prone to cracking. This process is called electrical corrosion and often affects bearings in electromechanical applications, such as generators and electric motors, but also machines that are powered by electric motors, such as pumps and gearboxes. In addition, the electric discharge renders the lubricant useless. The base oil and additives contained in the lubricant oxidise, resulting in the characteristic black colour of the lubricant. Premature ageing permanently impairs the lubricant’s ability to form a separating layer between the metal surfaces. The bearing’s damaged functional surfaces and the loss of lubrication action result in a rapid loss of the bearing’s functionality.

Possible causes of undesirable passage of electrical current through rolling bearings

NKE-Bild-1a-Stromdurchgang-WK-CRB

Fig. 1a

NKE Bild 1b Stromdurchgang IR CRB_sl2

Fig. 1b

Current passage has led to a formation of craters/flutes on the inner ring raceway (Fig. 1a) and the lateral surface of the rolling elements (Fig. 1b) of a cylindrical roller bearing.

The main reasons for current discharge are known. Asymmetries in the magnetic flux of an electrical machine give rise to a low-frequency voltage between the shaft and the housing, which results in a flow of current through the rolling bearings. Such a passage of current can also result from the use of unshielded asymmetrical electric cables if the earth connection of the machine is ineffective. Another cause is the use of frequency converters: The operating principle of many frequency converters is based on pulse width modulation (PWM) and generates high-frequency common mode voltage, which also results in a passage of current through the rolling bearings. Lastly, electrostatic charging of the shaft and housing followed by discharge through the rolling bearings is also a possible cause.

Damage symptoms and possible countermeasures

Typical signs of electrical corrosion include grey, tarnished tracks in the raceways and on the rolling element surfaces. Melt craters (Figs. 1a and 1b) or fluting is also discernible, mainly on the raceway surfaces. Damage due to current discharge usually manifests itself in increased running noise.

In order to prevent damage of this kind, it is advisable to insulate the bearing seat in the housing or on the shaft. However, this entails additional design measures of the surrounding parts. A simple, economical solution in this case is to use electrically insulated rolling bearings from NKE. Since the key dimensions and performance data of the insulated bearings is identical with those of the corresponding uninsulated models, no changes to the overall design are required.

Electrically insulated bearings – properties and application

Electrically insulated bearings from NKE, designated with the suffix SQ77, are provided with an oxide ceramic insulation layer. An overview of the various design variants of the insulation layer is given in the table. Electrically insulated rolling bearings from NKE offer exactly the same outer dimensions and technical characteristics as the corresponding uninsulated types.

The most important advantages of these bearings are higher operating reliability, which is assured by optimal protection against electrical corrosion. Electrically insulated bearings are less expensive than, for example, applying insulation to housings or shafts. They are interchangeable with conventional bearings because they have the same key dimensions and technical characteristics. They also offer a reduced risk of damage and thus also longer operating life than conventional bearings when used in electrical machines. When electrically insulated bearings are handled properly, there is no risk of damage to the coating.

The main range of electrically insulated bearings consists of cylindrical roller bearings and deep groove ball bearings, but all other bearing types can also be electrically isolated. Application areas include traction motors of railway vehicles, electric motors and generators, particularly in conjunction with fast-switching frequency converters.

Production process and operating principle of electrically insulated rolling bearings

For electrically insulated bearings from NKE, the insulating layer is applied to the outer ring (SQ77 or SQ77C – Fig. 2a) or the inner ring (SQ77E or SQ77H – Fig. 2b) by plasma- spraying, a thin-film technology. During plasma- spraying, an electric arc is created between two electrodes with a suitable gas supply. The plasma jet serves as a carrier medium for applying the aluminium oxide powder (Al2O3) either to the outer or inner ring at high velocity. In order to obtain optimum protection the oxide layer also covers the side faces of the sprayed rings. In the next process step, the layer is then sealed to prevent any penetration by moisture.

NKE Bild 2a und 2b

Fig. 2a                                                                         Fig. 2b

Figs. 2a and 2b: For electrically insulated bearings from NKE, the insulating layer is applied to the outer ring (SQ77 or SQ77C – Fig. 2a) or the inner ring (SQ77E or SQ77H – Fig. 2b) by plasma-spraying, a thin-film technology.

The physical effect of the insulation layer depends on the frequency of the voltage that causes the harmful currents in the bearings. In the case of DC voltage, the insulated bearing has Ohmic resistance. The higher this resistance is, the lower the electrical current. The resistance value of the insulated bearings is greater than 50 MΩ, thus limiting the electrical current to a level that cannot cause damage to the bearing.

In the case of AC voltage the capacitive nature of the insulated bearing is advantageous. The bearing then behaves in approximately the same way as a parallel circuit consisting of a resistor and a capacitor with a frequency-dependent resistance, called impedance. The impedance determines the magnitude of the alternating current that flows through the bearing for given values of voltage and frequency. Here too, the impedance should be as high as possible in order to reduce the current to a level that is incapable of damaging the bearing.

To achieve high impedance values, the resistance of the insulating layer must be high and its capacitance must be low. This can be achieved by making the insulating layer as thick as possible and by reducing the overall insulation surface area. When transferred to the bearings, this means that this layer should preferably be applied to the bore of the inner ring. However, the coating is usually applied to the outer diameter for reasons of cost and due to the constraints of the manufacturing process. In most cases, this still results in more than adequate protection against damage from electrical corrosion. Another important property of the coating is its dielectric strength. Depending on their version, the bearings from NKE have a dielectric strength of at least 1000 V or 2000 V.

Author:

Klaus Grissenberger, Application Engineer, NKE Austria GmbH.

Table:

Overview of the design variants of electrically insulated NKE rolling bearings:

NKE suffixesSQ77 (standard)SQ77CSQ77ESQ77H
Insulation onouter ringinner ring
Breakdown voltage> 1000 V> 2000 V> 1000 V> 2000 V
Bearing typesDeep groove ball bearings, cylindrical roller bearings (further types please enquire)
Bearing sizesOuter diameter D
90 ≤ D ≤ 500
(for up to D = 1000 mm please enquire)
Narrow or single-row bearings Bore diameter d
75 ≤ d ≤ 150
Boundary ratio bore diameter d to width Bd > 3∙B
Wide or double-row bearings Bore diameter d
150 < d ≤ 315
Width range20 < B < 315

 

Company information:

NKE Austria GmbH is a bearing manufacturer with headquarters in Steyr, Austria. The company with about 140 employees was founded in 1996 by a group of senior staff members of former company Steyr Wälzlager. NKE produces standard and special bearings for all industrial applications. Engineering, product development, production and final processing of components, modular assembly, quality assurance, logistics, sales and marketing – are centralised at NKE’s headquarters in Steyr, Austria. The factory in Steyr is certified to ISO 9001:2008, ISO 14001:2004 and OHSAS 18001. Its wide range of standard bearings is available from stock or at short production lead-times. NKE also provides tailored products and solutions. In addition to product development and application engineering NKE provides a full range of technical, consulting, documentation and training services. NKE’s products are distributed through 15 international representative offices and more than 240 distribution outlets in 60 countries.

Contact:

NKE AUSTRIA GmbH
Rene Hörwertner, Marketing Im Stadtgut C4
A-4407 Steyr, Austria
Tel.: +43 7252 86667 435
Fax: +43 7252 86667 59
E-Mail: [email protected]
Internet: www.nke.at

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Tel.: +49 (0)8142 44 82 301
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