Increasingly common, variable frequency drives (VFDs) are used to control motor speed —
elevating the frequency of power pulses/sec fed to motors for faster turning, and decreasing that frequency to make motors turn more slowly. As for the motors controlled this way, they work best when power pulses are well regulated and current is injected in a flow optimal for sustained speed and acceleration consistency. However, VFD conversion of ac to dc to variable ac is not perfect, and introduces nonlinear spikes, wave reflections, inrush currents, and other signal mutation. The current from this nonlinear power does not support motor requirements, because change in voltage does not generate the same change in current: The distorted current either undermines or exaggerates the voltage change, resulting in highvoltage stress and heat.

What's worse, connecting cable can actually magnify these signal imperfections. To address this problem, some VFD connections include unshielded tray cables (consisting of single conductor lead wire installed in conduit) or welded armored cable. But armored cable and lead-wire conduit are heavy, difficult to install, and necessitate huge bending radii — and they do not completely solve noise and corona discharge problems, or effectively address VFD noise issues. On the other hand, well-selected motor and control features coupled with specially insulated cabling minimizes VFD distortion without the fuss.

Dc buses store and deliver steady dc power to the drive inverter; in turn, the inverter uses a bipolar transistor to change dc power back to ac with switching. However, during switching, spikes due to overshoot are generated. These spikes can damage cable insulation.

Switch spikes and cable length
For a rectified 460-V system, a drive's inverter — a fast-switching transistor — must rise from zero to 650 V and then go back to zero 20,000 times each second. This results in a very fast rise time. Several things can happen as the inverter switches and sends its pulses through the cable to the motor. The 650-V normal voltage can overshoot — spike — by 2,000 V or more. Even though these voltage spikes are very quick, lasting for only a few millionths of a second, they can cause considerable damage as power distortions created by VFD rectifiers are sent back through source power systems.

Long cable exasperates the issue: Greater lengths make for greater inductance and higher voltage-spike overshoot, so long power-supply cables have more numerous and more intense voltage spikes than shorter cable. Why is that? Long cables connecting motors to drives

Harmful harmonics
Some power distortions are caused by harmonic frequencies, multiples of a system's fundamental frequency. Harmonics, though they rotate more quickly due to their higher frequency, can be in phase with the fundamental frequency and rotate in the same direction as its field; this condition allows harmonics to contribute energy. But only power in the fundamental frequency is needed or wanted; power from harmonic frequencies makes for overheating, high-voltage stress, and can confuse electronic functions that depend on the fundamental frequency for clock or timing functions.

Harmonic-induced voltage spikes also stress motor windings. This higher flow of power pulses can cause motors to run too fast as well, so the presence of harmonic frequencies necessitate that motor movement be fine-tuned with braking and other (heat-generating) reactions.

VFD drives commonly generate 5th, 7th, 11th, and 13th harmonics. So say we have a system with a fundamental frequency of 60 Hz, as supplied in the U.S. Its 5th harmonic is 5 x 60 = 300 Hz. The 5th (and 11th) harmonics oppose the field's rotation and require additional current (which is unfortunately accompanied by heat) to correct sluggish motor speed. This ac power includes one positive and one negative voltage and current power pulse each frequency cycle. The 7th and 13th harmonics rotate with the field, and supply additional power pulses, and so require braking to correct overly fast motor speed. The 3rd, 9th, and 15th are triple harmonics that do not rotate, but are highly in phase, and add to neutral current and accompanying heat in cable.

To reduce harmonics:
Changing the pulse rate or switching the drive inverter transistor to a slower frequency can eliminate the low-number harmonics of high electrical power. Also, filters, reactors, and isolation transformers can be added to lop off harmonics and block spikes. Designers must keep in mind, however, that these add-ons do cause voltage drop between power supply and motor.

If these measures are taken, cable is left the weakest link in a VFD system. That's why since 1996 National Electrical Code Article 430-22a has specified that source-power cable conductors must be sized at 125% of the full load current of the drive. This requirement protects cables from power distortions generated by the rectifier and ensures safe and uninterrupted operation. This ensures that the cable won't fail due to power distortions — so the whole system is able to handle the type of power that a VFD drive generates.

Stressful starting
Ask anyone who's ever touched an electrified fence by accident, and they'll tell you: Current can make you go stiff in a hurry. A sudden inrush of current has the same of effect on motor windings: Upon startup, they briefly tremble before stiffening into operation, enough of a trial for the delicate insulation on the winding wires as it is. Add exaggerated startup in rush current, and the situation can quickly become dire for those copper threads of life.

A motor and its power cable can act as a large capacitor that must be charged up to the normal operating power level. So when a motor is first energized, it can draw up to six times its full-load running power requirements.

When the current from the power-pulse source ends up in the power pulses of another circuit, capacitive coupling takes place due to changing electric field in the source circuit. The change in voltage (from zero to full and back to zero) causes current to flow and couple from one copper conductor to another. In short, power pulses from one circuit are added to compatible pulses of another circuit — resulting in heat and stress.

To address inrush current: One way to ensure inrush current is not an issue is to install filters that lower inrush currents for more gradual drive startups. Another approach is to use VFD motors, which are double insulated to withstand distorted power and to prevent any penetrating nicks in the winding insulation. In fact, failed motors are often those not replaced during a system upgrade in which VFDs replace plain drives.

Because a motor can draw up to six times its full-load running power when energized, cable must be of adequate conductor AWG size, to prevent significant voltage drop. This is also an area where the improved impedance of VFD cable means inrush current shocks less, and makes for less wear and tear on delicately coated motor windings.

A VFD Casualty

Shown here is one cable not designed for VFD use. High voltage has burned through the cable in several spots.