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TC655 データシート(PDF) 10 Page - Microchip Technology

部品番号 TC655
部品情報  Dual SMBus??PWM Fan Speed Controllers With Fan Fault Detection
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メーカー  MICROCHIP [Microchip Technology]
ホームページ  http://www.microchip.com
Logo MICROCHIP - Microchip Technology

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TC654/TC655
DS21734A-page 10
 2002 Microchip Technology Inc.
4.1
Fan Speed Control Methods
The speed of a DC brushless fan is proportional to the
voltage across it. For example, if a fan’s rating is
5000 RPM at 12 V, it’s speed would be 2500 RPM at
6 V. This, of course, will not be exact, but should be
close.
There are two main methods for fan speed control. The
first is pulse width modulation (PWM) and the second
is linear. Using either method the total system power
requirement to run the fan is equal. The difference
between the two methods is where the power is
consumed.
The following example compares the two methods for
a 12 V, 120 mA fan running at 50% speed. With 6 V
applied across the fan, the fan draws an average cur-
rent of 68 mA. Using a linear control method, there is
6V across the fan and 6V across the drive element.
With 6 V and 68 mA, the drive element is dissipating
410 mW of power. Using the PWM approach, the fan is
modulated at a 50% duty cycle, with most of the 12 V
being dropped across the fan. With 50% duty cycle, the
fan draws an RMS current of 110 mA and an average
current of 72 mA. Using a MOSFET with a 1
Ω RDS(on)
(a fairly typical value for this low current) the power dis-
sipation in the drive element would be: 12 mW (Irms2 *
RDS(on)). Using a standard 2N2222A NPN transistor
(assuming a Vce-sat of 0.8 V), the power dissipation
would be 58 mW (Iavg* Vce-sat).
The PWM approach to fan speed control causes much
less power dissipation in the drive element. This allows
smaller devices to be used and will not require any spe-
cial heatsinking to get rid of the power being dissipated
in the package.
The other advantage to the PWM approach is that the
voltage being applied to the fan is always near 12 V.
This eliminates any concern about not supplying a high
enough voltage to run the internal fan components
which is very relevant in linear fan speed control.
4.2
PWM Fan Speed Control
The TC654 and TC655 devices implement PWM fan
speed control by varying the duty cycle of a fixed fre-
quency pulse train. The duty cycle of a waveform is the
on time divided by the total period of the pulse. For
example, given a 100 Hz waveform (10 msec.) with an
on time of 5.0 msec, the duty cycle of this waveform is
50% (5.0 msec/10.0 msec). An example of this is
illustrated in Figure 4-2.
FIGURE 4-2:
Duty Cycle Of A PWM
Waveform.
The TC654 and TC655 generate a pulse train with a
typical frequency of 30 Hz (CF = 1 µF). The duty cycle
can be varied from 30% to 100%. The pulse train gen-
erated by the TC654/TC655 devices drives the gate of
an external N-channel MOSFET or the base of an NPN
transistor (Figure 4-3). See Section 7.5 for more
information on output drive device selection.
FIGURE 4-3:
PWM Fan Drive.
By modulating the voltage applied to the gate of the
MOSFET Qdrive, the voltage applied to the fan is also
modulated. When the VOUT pulse is high, the gate of
the MOSFET is turned on, pulling the voltage at the
drain of Qdrive to 0 V. This places the full 12 V across
the fan for the Ton period of the pulse. When the duty
cycle of the drive pulse is 100% (full on, Ton = T), the
fan will run at full speed. As the duty cycle is decreased
(pulse on time “Ton” is lowered), the fan will slow down
proportionally. With the TC654 and TC655 devices, the
duty cycle can be controlled through the analog input
pin (VIN) or through the SMBus interface by using the
Duty-Cycle Register. See Section 4.5 for more details
on duty cycle control.
T
Ton
Toff
T = Period
T = 1/F
F = Frequency
D = Duty Cycle
D = Ton / T
TC654/
TC655
FAN
12 V
Qdrive
VDD
GND
VOUT
G
D
S


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