If you think appliances built for the North American market lag in innovation, you're probably right. For decades, white goods built for Europe and Asia have been quieter and more efficient. But as the implications of rising energy costs sink in, this is changing. Some companies in the U.S. and Canada are updating their product emphasis to take advantage of overseas markets' latest goal—efficiency without a price premium.
For instance, take International Rectifier's latest iMotion ICs, which were unveiled at PCIM China in Shanghai earlier this month. They target the first appliance that research shows Chinese citizens look to acquire when they get some disposable income—an air conditioner.
Rather than trying merely to squeeze incremental improvements out of its classic power discretes, IR chose to engineer an efficient motor-control subsystem that would enable air-conditioner OEMs to cut their total materials and assembly costs by accommodating the latest trends in motors and compressors.
GOODBYE INDUCTION MOTORS
The biggest new trend is the total eclipse of induction motors by permanent-magnet
synchronous motors (PMSMs) (Fig. 1). Once
considerably less expensive, induction motor prices have risen, largely due
to a worldwide increase in steel and copper costs. Meanwhile, PMSM prices have
risen less steeply. As a result, IR optimized its chip set for the more efficient
motor.
PMSMs were always attractive because of their lower conduction losses, good low-speed torque, simple speed control, and compact size. Where induction motor currents flow in both stator and rotor windings, PMSMs have less copper and lower conduction losses. Where iron cores in induction motors saturate, requiring voltage to be varied along with frequency to achieve speed control, PMSM speed depends solely on frequency.
From a system standpoint, IR's iMotion products remove a potential reliability problem. For motor control, air conditioner OEMs have been accustomed to using motors with built-in Hall-effect sensors to monitor phase currents. The IR chips achieve the same effect by using on-chip sense resistors to externally sample the dc current to the pulse-width modulation (PWM) driver at precisely selected times.
ADAPTING TO TORQUE VARIATIONS
While it doesn't cost the OEM any more to use a PMSM, compressors are a different
story. Also, IR had to understand cultural differences in the market to engineer
the iMotion products.
Rotary compressors comprise an eccentric circular cam like rotor inside a
larger circular cavity. Pressure cycling and the eccentric weight distribution
of the rotor create mechanical vibration and a cyclically varying motor load.
Scroll compressors comprise an eccentric helical rotor that orbits within a
stationary helix. They're more efficient, and they tend to represent a more
constant load on the motor.
Unfortunately, the precision machining required to make them increases their cost. While generally affluent Japanese consumers will absorb the premium in return for higher efficiency and appliances that produce less noise, more price-sensitive Chinese buyers will not. So, OEMs use rotary compressors for the Chinese market.
IR's controllers deal with the potential for vibration and varying loads presented by rotary compressors by creating a more complex driving function than three phases of simple sinusoids.
The design challenges don't stop with the compressor, though. Both compressor and fan motors require speed control, but their controller requirements are different.
Speed control is necessary in both cases to allow the air conditioner to adjust
its output to match conditions and maintain a steady temperature for the best
operational efficiency, rather than merely cycling on and off under the control
of a simple on/off thermostat. Studies show that up to 40% efficiency can be
gained in systems that allow the fan and compressor to run at variable speeds.
DON'T FORGET PFC
Just like Japan, Europe, and parts of India, China requires appliances to meet
power-factor-correction (PFC) standards.
Therefore, the PWMs that control the motors must provide PFC, even though it adds losses.
To meet that challenge, IR's platform incorporates a low-loss PFC algorithm
that minimizes losses at the low switching frequencies used to drive the motors.
IR's iMotion "integrated design platform" comprises a digital control IC and
a driver IC that integrates the latest of the company's IGBTs and FETs (Fig.
2).
The IRMCF3xx iMotion digital controller is a multicore design. One side is
built around an 8051 core that handles the user interface. The other is built
around a patented Motion Control Engine (MCE), which implements a complex, sensorless,
PMSM-control algorithm in hardware.
The two cores communicate via a RAM register block that provides set-points
for the MCE and diagnostic feedback to the MCU. While the MCU is programmed
conventionally, the MCE algorithm is implemented via a graphical drag-and-drop
approach using a library of analog functions. In addition to the MCE, the chip
integrates a mixed-signal block called the embedded analog signal engine (ASE),
which integrates all signal-conditioning and conversion circuits for sensorless
motor control using built-in current shunts mentioned previously.
Implementing the MCE in hardware provides fast loop response without a super-fast DSP or CPU core. In fact, the MCE executes the sensorless field-oriented-control (FOC) algorithm in about 11µs, enabling simultaneous control of the fan and compressor motors as well as power-factor correction. And since the OEM can tweak the outer loop by graphically manipulating a library of analog functional blocks, this approach eliminates software coding from the development process.