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The article discusses the advantages of using brushless DC (BLDC) motors in ceiling fans over traditional induction motors, highlighting their higher efficiency and silent operation. It outlines a design approach for a BLDC ceiling fan system that utilizes a 24-V, three-phase motor and emphasizes the importance of motor control strategies for optimal performance. Texas Instruments offers a reference design, TIDA-00386, to facilitate the development of this energy-efficient ceiling fan solution.

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10 views3 pages

Ssztcs 8

The article discusses the advantages of using brushless DC (BLDC) motors in ceiling fans over traditional induction motors, highlighting their higher efficiency and silent operation. It outlines a design approach for a BLDC ceiling fan system that utilizes a 24-V, three-phase motor and emphasizes the importance of motor control strategies for optimal performance. Texas Instruments offers a reference design, TIDA-00386, to facilitate the development of this energy-efficient ceiling fan solution.

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debd7668
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com

Technical Article
Designing an Energy-efficient BLDC Ceiling Fan Solution

Milan Rajne
Rapid advancement in power electronics technologies and wider availability of highly integrated ICs to embed
motor control algorithms now makes it easy to use a brushless DC (BLDC) motor instead of traditional induction
or DC motors. BLDC motors do not have mechanical brushes and commutators so they provide higher torque/
power-to-weight ratio, run efficiently and silently compared to brushed DC motors. Because there are no rotor
copper losses in the permanent magnet rotor, they also provide higher efficiency over induction motors. Ceiling
fan can gain significant energy efficiency by taking advantage of a BLDC motor. Let’s take a look at how to
develop such a system using a three-phase BLDC motors.
Traditionally, single-phase induction motors dominated the ceiling fan segment because they can run directly
from most commonly available power sources in homes/offices (i.e. 110V/60Hz or 230V/50 Hz). However, these
induction motors are power hungry and mostly run at a typical efficiency level of around 30-40%. For example,
let’s say to deliver a certain amount of air-flow, the mechanical power requirement is 20 watts. Input electrical
power taken from these motors would be about 55-65 watts, depending on how optimally the motor is designed.
In addition, the speed control mechanism by controlling the voltage adds additional losses to system and
fluctuations of the input voltage, making it very challenging to have constant speed control.
Figure 1 shows one possible approach to enhance the energy efficiency of a ceiling fan system using a 24-V,
three-phase BLDC motor. Over-all system efficiency is governed by three-major system blocks, first is BLDC
motor itself including blades, second is three-phase DC/AC stage and third is AC-DC stage. With proper design
of efficiencies of each system block, input power consumption can be brought down to the 30-35 watt level.
In the approach below, a 24-V BLDC motor brings the advantage of achieving constant speed of operation
throughout universal main AC range of 90-265 volts and fluctuations in voltage does not affect the motor
speed. The other major factor to consider is right motor control strategy. For best utilization of motor efficiency,
and to run the motor silently, it is important to run the BLDC motor using a sinusoidal PWM instead of a
120-dgree trapezoidal control. For speed control, a cost-effective infrared-based remote control strategy can be
employed.

Figure 1. 3-phase BLDC ceiling fan system block diagram

SSZTCS8 – APRIL 2015 Designing an Energy-efficient BLDC Ceiling Fan Solution 1


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Next Step:
To enable quick development of this system, TI has developed reference design- TIDA-00386 “BLDC ceiling
fan controller with sensor-less sinusoidal current control”. Figure 2 shows how this reference design provides
a complete solution for a brushless DC ceiling fan controller. It features the DRV10983 24-V, three-phase
motor driver to drive motors with sinusoidal current and sensor-less control. The UCC28630 is primary-side
PWM controller IC -provides PWM to AC/DC fly-back stage to convert 90-265 VAC into a tightly regulated 24
VDC. The MSP430G2201 value-line processor decodes infrared signals for speed control.

Figure 2. Functional block diagram of BLDC ceiling fan controller reference design

Learn more about the TIDA-00386 BLDC ceiling fan controller with sensor-less sinusoidal current control
Thanks for reading, and your comments are welcome below.

2 Designing an Energy-efficient BLDC Ceiling Fan Solution SSZTCS8 – APRIL 2015


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