Electric cars are news. Every major automaker has introduced some electric vehicle, and the trend seems to be toward greater reliance on electric motors. The “Holy Grail” is a battery electric vehicle (BEV, a car powered solely by electricity) with an extended driving range, at a reasonable price.
But the greater the reliance on electric motors, the greater the potential for electrical bearing damage. At the heart of every BEV and hybrid is an alternating-current (AC), 3-phase traction motor/generator. Since batteries provide direct current (DC), inverters (also known as variable frequency drives, or VFDs) are needed to convert the DC to AC. These inverters have an unfortunate side effect: They induce unwanted voltages on motor shafts. Without effective, long-term grounding, this shaft voltage will erode and eventually destroy motor bearings.
Reliability Is Crucial
For many Americans the impetus to purchase a BEV or hybrid is a financial one — the ever-increasing price of gasoline. Still, most drivers are likely to hold onto their money until further advances in battery technology bring about longer all-electric driving ranges and lower sticker prices.
Even if reasonably priced and with longer driving ranges, BEVs are not likely to catch on unless consumers perceive them as reliable. In fact, for the trend toward these vehicles to continue, they must truly be reliable. How ironic it would be for sales to peak, then drop precipitously if people began to think of electric cars as having high maintenance costs.
Bearings in Mind
Because electrical bearing damage is a lurking problem in electric cars, automotive design engineers face a new set of challenges. Inverter-induced shaft voltages jump to the path of least resistance wherever it leads, so partial mitigation measures such as insulated motor bearings can just shift the damage to other components, such as gearbox bearings, transmission gears, or wheel bearings. Even the bearings of a hybrid’s gasoline engine are vulnerable to such damage when the vehicle is operating in electric mode.
To nip the problem of electrical bearing damage in the bud, automotive engineers need only look to other industries that have sought to be “green.” For years, design and maintenance engineers and contractors in manufacturing, processing, HVAC, and materials handling have turned to inverters as a way of controlling the speed of AC motors and thereby saving on their energy costs. These engineers found that — without an effective method of channeling inverter-induced shaft voltages safely to ground — any savings due to reduced energy consumption could quickly be wiped out by the high maintenance costs of replacing damaged motor bearings.
In short, an effective, long-term method of grounding motor shafts is needed to make inverter-driven systems reliable. Industrial engineers learned that a shaft-grounding device installed on a motor can divert harmful currents before they can cause bearing damage. Applied to the traction motor in a BEV or hybrid, such a device should prevent bearing damage and guarantee overall vehicle reliability.
One of the most reliable and cost-effective grounding devices is a ring that fits over the motor’s shaft [Figure 1]. Engineered with specially designed conductive microfibers, the AEGIS® SGR Bearing Protection Ring safely channels damaging currents to ground, bypassing the bearings entirely. Scalable to any NEMA or IEC motor regardless of shaft size or horsepower, the ring has been installed successfully on motors powering pumps, fans, turbines, conveyors, etc., in hundreds of thousands of installations worldwide. More recently, the AEGIS® ring has proven itself effective in the inverter-controlled traction motors of electric trucks, trains, trolleys [Figure 2], and construction equipment. It is now being tested by several auto manufacturers, though quietly, due to non-disclosure agreements.
Cause and Effect
For electrical damage to motor bearings, the main culprit is common-mode voltage arising from the non-sinusoidal waveforms produced by an inverter’s power-switching circuitry. The extremely fast voltage rise times (dV/dt) associated with the insulated gate bipolar transistors (IGBTs) typically found in today’s pulse-width-modulated inverters can cause charges to build up on the motor shaft. Without mitigation, these voltages discharge through bearings, causing unwanted electrical discharge machining (EDM) that erodes ball bearings and race walls and leads to premature bearing/motor failure.
Electric motors in vehicles operate in a range from 1,000 to over 16,000 rpm, and at such speeds the very thin grease layer between the rolling elements and race in a bearing can break down due to voltage discharges of 5 to 40 volts. Every time the grease dielectric is overcome, an electrical arc through the bearing burns the grease and blasts a tiny pit (fusion crater) in the steel surface [Figure 3]. At inverter carrier frequencies of over 12 kHz, many millions of pits can be created in a very short time. This process also generates steel and carbon particles that contaminate the grease, further reducing its lubrication properties and giving it a black “burnt” color
Before long, frequent discharges can leave the entire bearing race riddled with pits known as frosting. In a phenomenon called fluting, the operational frequency of the inverter causes concentrated pitting at regular intervals along the bearing race wall, forming washboard-like ridges that result in noise and vibration
Because the AEGIS® SGR Bearing Protection Ring has already proven itself to be the most effective, reliable, and universally applicable solution to the problem of inverter-induced currents in other applications, it should be equally effective in electric cars.
Key to the ring’s success are patented conductive microfibers arranged along the entire inner circumference of the ring to completely surround the motor shaft. Secured in the patented FiberLock™ channel, these fibers can flex without breaking. The deep channel also protects the fibers from dust, liquids, and other debris. Tests of the ring on multiple motors show surface wear of less than 0.001” per 10,000 hours of continuous operation and no fiber breakage after 2 million direction reversals.
The effectiveness of the AEGIS® SGR can be seen using an oscilloscope [Figure 6]. Without shaft grounding, damaging inverter-induced shaft voltages show up as peaks and valleys. After the installation of an SGR, the nearly straight line demonstrates how the ring diverts these voltages, channeling them safely to ground.
Developed by Electro Static Technology, the AEGIS® ring is superior to conventional spring-pressure grounding brushes, which corrode, become clogged with debris, and require regular maintenance. Neither metal brushes nor carbon-block (graphite) brushes work as well at high rpms, and the latter are susceptible to “hotspotting,” in which an arc briefly fuses a brush to the motor shaft. In contrast, the AEGIS® ring requires no maintenance and lasts for the life of the motor, regardless of rpm.
Non-grounding methods of mitigating electrical bearing damage tend to be expensive. Multilevel inverters and harmonic filters, for example, can cost thousands of dollars, while an AEGIS® ring solves the problem at a low cost. Ceramic bearings are also costly, and, like bearing insulation, can pass on harmful voltage discharges to other equipment.
All hybrids and BEVs use inverters. This means the need to mitigate damaging inverter-induced voltages is already upon us. The AEGIS® SGR Bearing Protection Ring offers automobile designers a way to improve the reliability of electric motor/generators now and in the future, by protecting bearings and other components. In short, it offers the promise of high reliability that buyers want before they invest in an electric vehicle.
Matthew Roman is Engineering Manager for Electro Static Technology, 31 Winterbrook Road, Mechanic Falls, ME 04256-5724, TEL: (207) 998-5140, FAX: (207) 998-5143, www.est-aegis.com.