TC642BEUA Microchip Technology, TC642BEUA Datasheet - Page 17

TC642BEUA

Manufacturer Part Number

TC642BEUA

Description

IC PWM FAN SPEED CTRLR 8-MSOP

Manufacturer

Microchip Technology

Type

Controller - PWM Fanr

Datasheet

1.TC647BEOA.pdf (34 pages)

Specifications of TC642BEUA

Applications

Fan Controller, Brushless (BLDC)

Number Of Outputs

Voltage - Supply

3 V ~ 5.5 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

8-MSOP, Micro8™, 8-uMAX, 8-uSOP,

Motor Type

PWM

No. Of Outputs

Output Current

5mA

Output Voltage

4.4V

Supply Voltage Range

3V To 5.5V

Driver Case Style

MSOP

No. Of Pins

Operating Temperature Range

-40Â°C To +85Â°C

Product

Fan / Motor Controllers / Drivers

Operating Supply Voltage

6 V

Supply Current

400 uA

Mounting Style

SMD/SMT

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current - Output

Voltage - Load

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

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Company

Part Number

Manufacturer

Quantity

Price

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Part Number:

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Manufacturer:

MICROCHIP

Quantity:

12 000

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

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Manufacturer:

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Quantity:

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Current page: 17 of 34
Download datasheet (684Kb)

5.0

5.1

The PWM frequency of the V

capacitor value attached to the C

quency will be 30 Hz (typical) for a 1 µF capacitor. The

relationship between frequency and capacitor value is

linear, making alternate frequency selections easy.

As stated in previous sections, the PWM frequency

should be kept in the range of 15 Hz to 35 Hz. This will

eliminate the possibility of having audible frequencies

when varying the duty cycle of the fan drive.

A very important factor to consider when selecting the

PWM frequency for the TC642B/TC647B devices is the

RPM rating of the selected fan and the minimum duty

cycle that the fan will be operating at. For fans that have

a full speed rating of 3000 RPM or less, it is desirable

to use a lower PWM frequency. A lower PWM fre-

quency allows for a longer time period to monitor the

fan current pulses. The goal is to be able to monitor at

least two fan current pulses during the on time of the

Example: The system design requirement is to operate

the fan at 50% duty cycle when ambient temperatures

are below 20°C. The fan full speed RPM rating is

3000 RPM and has four current pulses per rotation. At

50% duty cycle, the fan will be operating at

approximately 1500 RPM.

EQUATION

If one fan revolution occurs in 40 msec, each fan pulse

occurs 10 msec apart. In order to detect two fan current

pulses, the on time of the V

20 msec. With the duty cycle at 50%, the total period of

one cycle must be at least 40 msec, which makes the

PWM frequency 25 Hz. For this example, a PWM fre-

quency of 20 Hz is recommended. This would define a

5.2

As discussed in previous sections, the V

has a range of 1.20V to 2.60V (typical), which repre-

sents a duty cycle range on the V

100%, respectively. The V

as representing temperatures. The 1.20V level is the

low temperature at which the system requires very little

cooling. The 2.60V level is the high temperature, for

which the system needs maximum cooling capability

(100% fan speed).

One of the simplest ways of sensing temperature over

a given range is to use a thermistor. By using an NTC

thermistor, as shown in Figure 5-1, a temperature

variant voltage can be created.

OUT

2003 Microchip Technology Inc.

Time for one revolution (msec.)

capacitor value of 1.5 µF.

output.

APPLICATIONS INFORMATION

Setting the PWM Frequency

Temperature Sensor Design

OUT

voltages can be thought of

OUT

pulse must be at least

OUT

output is set by the

pin. The PWM fre-

----------------------- -

1500

output of 0% to

1000

analog input

FIGURE 5-1:

Circuit.

Figure 5-1 represents a temperature-dependent volt-

age divider circuit. R

while R

a parallel resistor combination that will be referred to as

increases, the value of R

desired relationship for the V

ize the response of the sense network and aids in

obtaining the proper V

perature range. An example of this is shown in

Figure 5-2.

If less current draw from V

thermistor should be chosen. The voltage at the V

can also be generated by a voltage output temperature

sensor device. The key is to get the desired V

to system (or component) temperature relationship.

The following equations apply to the circuit in

Figure 5-1.

EQUATION

In order to solve for the values of R

for V

occur, need to be selected. The variables T1 and T2

represent the selected temperatures. The value of the

thermistor at these two temperatures can be found in

the thermistor data sheet. With the values for the ther-

mistor and the values for V

equations from which the values for R

found.

TEMP

increases as temperature increases, giving the

, and the temperatures at which they are to

will decrease with it. Accordingly, the voltage at

and R

TEMP

TC642B/TC647B

V T1

V T2

= R

are standard resistors. R

* R

is a conventional NTC thermistor,

Temperature Sensing

----------------------------------------- -

voltages over the desired tem-

/ R

TEMP

decreases and the value of

+ R

is desired, a larger value

DIV

input. R

, there are now two

). As the temperature

and R

DS21756B-page 17

helps to linear-

and R

, the values

voltage

can be

form

TC642BEUA Microchip Technology, TC642BEUA Datasheet - Page 17

TC642BEUA

Specifications of TC642BEUA

Available stocks

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