Eddy Current Drive- Efficiency Deficiency… A Modern Myth
Eddy Current drives, known alternately as magnetic or eddy
current couplings, have been a trusted and reliable means of controlling pump
speed dating back to before World War II. They enjoyed a period of widespread
growth in the municipal water and wastewater treatment industries during the
two decades beginning about 1965. The Clean Water Act of 1972 fueled the
expansion of wastewater treatment processing and supplied federal funding to
municipalities facing new requirements for better levels of wastewater
treatment. During this period, eddy current drives were routinely selected for
variable speed pumping applications, such as raw water pumps, effluent pumps
filter pumps, and various pumping stations where response to demand made
variable speed the best choice for process and energy considerations.
An eddy current drive controls speed by regulating a DC
excitation coil on a magnetic rotor, rotating concentrically with a steel drum,
driven at by the motor at full speed, as illustrated in fig. 1.
fig. 1 |
The “slip” between the input drum and the output rotor a
“slip loss” proportional to slip speed and the driven load. Thus, the
efficiency of the drive, plotted as a function of speed, illustrates an
approximate one-to-one relationship as shown in fig. 2.
fig. 2 |
Because a common reason for choosing variable speed is to
reduce energy consumption, this efficiency performance may leave engineers and
specifiers wanting something better. When variable frequency drives were
developed and began to gain a foothold in the market, they boasted efficiency
well in the 90’s, across the entire speed spectrum. This promise of better
efficiency fueled a shift in the market thought to justify preference of VFDs,
even to the point of removing existing eddy current drives to achieve better
energy performance.
However, a comparison of efficiency exaggerates the
differences and ignores associated losses not considered in the calculation of
VFD efficiency. It’s more instructive to examine the losses in a system, as
this is a truer indication of energy consumption and associated electrical
costs.
A variable speed behaves according to well-known “affinity
laws”, such that the load bhp decreases in proportion to the speed reduction
cubed. When applying the eddy current drive efficiency to a centrifugal pump
load curve, the associated losses prove to be much lower than one might expect,
as shown in fig. 3.
fig. 3 |
Figure 3 also illustrates an often-overlooked fact: The pump
only operates above the speed necessary to overcome static head and produce a
useful flow. This is usually no lower than 75% of rated speed; in this example,
80% and above, we can approximate the performance from zero to full flow as in
fig. 4.
Figure 4 now includes published VFD efficiency and
associated losses, to compare for those of eddy current drives. Note that while
efficiency still appears to strongly favor VFDs, the actual loss comparison is
close. The eddy current drive exhibits less loss than the VFD above 90% flow.
However, most VFD installations include losses not
considered in the efficiency calculation.
VFD input harmonic currents induce losses in feeders,
transformers and harmonic mitigation devices often necessary for the safe
operation of the VFD. These losses are usually impossible to quantify
accurately, but result in marginally higher kW-hr usage nonetheless.
fig. 4. |
In a similar manner, the output waveform of a VFD is not purely
sinusoidal. This causes additional losses to appear in the motor, which must be
supplied by the system. These losses are also very difficult to isolate and
quantify, but are generally acknowledged to exist.
Many VFD installations require air conditioning or powered
ventilation to provide adequate cooling to the VFD itself, which is sensitive
to ambient temperature, due to the electronic nature of the equipment. In
addition to the extra cost for this cooling equipment, the cost of powering the
air conditioning substantial. A rule of thumb holds that each 1kW of heat load
requires 3 kW of power. When these additional losses are considered, the eddy
current drive solution is a good or better than the VFD, as shown in fig. 5.
fig. 5 |
These results have been demonstrated in actual
installations. Fig. 6 shows actual field results comparing eddy current drives
and VFDs on identical pumps in the same application.
Most such comparisons will exhibit a crossover point where the
VFD power consumption will exceed that of the eddy current drive. Experience
has shown that above such a crossover speed, the eddy current drives uses less
energy than the VFD. In the illustrated case, average speed of operation to be
about 90%. Under this condition, the customer estimates saving $7000/year in
electrical costs.
fig 6 |
Long Lasting,
Reliable operation
Eddy Current drives are acknowledged to be unfailing
workhorses in pumping applications. Many installations remain in service after
nearly 50 years of continuous duty. Many others would probably remain, had they
not been replaced by VFDs, in a misguided quest for “better efficiency”
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