KR970006779Y1 - Cooling fan operate speed control device - Google Patents

Abstract

none

Description

Cooling Fan Drive Speed Control

1 is a detailed circuit diagram of a conventional cooling fan drive device

2 is a detailed circuit diagram of another example of a conventional cooling fan drive device.

3 is a detailed circuit diagram of a cooling fan drive speed control device according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10: DC power supply RT31: thermistor

M: Cooling Fan Drive Motor

The present invention relates to a cooling fan drive speed control device. More specifically, the cooling fan can be rotated at high speed by extending the range of rotation speed change by allowing the voltage applied to the cooling fan to be 12V or more. Cooling fan drive speed control device.

In recent years, in order to increase the performance of a computer system, there is a tendency to increase the density of chips used in the computer system and to increase the system clock speed.

However, if the system clock speed is increased in this manner, the heat generated from the central processing unit (CPU) and other peripheral chips increases, which increases the internal temperature of the computer system, causing the computer system to suddenly increase. By stopping, a problem occurs that the currently running work file is damaged or lost information.

Conventionally, in order to solve the above problems, a cooling fan is installed inside the computer system.

Hereinafter, a conventional cooling fan driving apparatus will be described with reference to the accompanying drawings.

1 is a detailed circuit diagram of a conventional cooling fan drive device.

As shown in FIG. 1, the cooling fan is driven at a constant speed by connecting the cooling fan motor M to the 12V output terminal of the DC power supply unit 10 conventionally.

However, the conventional technology as described above simply drives the cooling fan (M) at a constant speed only, causing severe noise pollution by rotating the cooling fan motor (M) even in the ambient environment that does not require cooling, such as winter, In the hot summer, although the cooling fan motor (M) has to be rotated more quickly, it does not have the disadvantage. In order to solve this problem, a technique for converting the driving speed of the cooling fan according to the ambient temperature has been disclosed.

2 is a detailed circuit diagram of another example of a conventional cooling fan drive device.

The operation of the conventional cooling fan drive device shown in FIG. 2 is performed as follows.

When the output voltage (+ 12V) of the DC power supply unit 10 is divided by the thermistor RT21 and the resistor R21 and applied to the base terminal of the transistor Q21, the transistor Q21 is turned on so that the DC power supply unit 10 is turned on. Output voltage (+12 V) is applied to the cooling fan motor (M). When power is applied to the cooling fan motor M, the cooling fan rotates to perform a cooling function.

In this case, the thermistor RT21 adjusts the rotational speed of the cooling fan motor M by changing the resistance value according to the ambient temperature. When the ambient temperature is low, the resistance value of the thermistor RT21 is increased and the transistor ( When a low voltage is applied to the base terminal of Q21), the rotation speed of the cooling fan motor M becomes slow. When the ambient temperature is high, the resistance value of the thermistor RT21 is lowered, and a high voltage is applied to the base terminal of the transistor Q21. The rotation speed of the cooling fan motor M is increased by being applied, and the speed of the cooling fan motor M is changed according to the ambient temperature.

In addition, the conventional technology for controlling the rotational speed of the cooling fan according to the ambient temperature is disclosed in Korean Patent Application Publication No. 93-8572 (air date: May 21, 1993 AD) "Overheat prevention control device of computer system And control method.

However, the conventional techniques for controlling the cooling fan driving speed according to the ambient temperature as described above, because the maximum voltage that can be applied to the cooling fan motor in the computer system is limited to 12V, the cooling fan is above a certain value. The disadvantage is that it cannot be driven faster.

Moreover, in the conventional technique using thermistor RT21 as the temperature sensor as shown in FIG. 2, the transistor Q21 is not turned on by the high resistance value of the thermistor RT21 at the beginning of operation, thereby cooling it. There is a problem that the fan motor (M) is not initially driven.

In order to solve such a disadvantage, the rotation speed of the cooling fan is controlled in proportion to the temperature when the internal temperature of the computer system is lower than the predetermined error, and the rotation speed of the cooling fan can no longer be increased. Therefore, a technique for cooling the system by reducing the clock speed of the system is disclosed in the "Computer System Protection Circuit" of Korean Utility Model Registration Application No. 94-13219 (filed date: June 8, 1994). It has been disclosed.

However, the above-mentioned "computer system protection circuit" has a disadvantage in that the temperature sensor is installed inside the computer system to detect the overall internal temperature, so that the temperature of the critical chip such as the central processing unit cannot be accurately understood. That is, even though the heat generation temperature of the central processing unit has already exceeded the dangerous level, if the internal temperature of the computer system is less than this, the clock speed of the system is not reduced, resulting in damage to the central processing unit. have.

In order to solve such a conventional problem, the user directly detects the temperature of a specific chip such as a central processing unit, and if the temperature rises above the threshold, an alarm sounds and the user stops using the computer. The technology for enabling the same has been disclosed in Korean Patent Application No. 94-26360 (filed date: October 14, 1994) "Overheat alarm of the microcontroller chip".

However, the conventional "overheat alarm device for a microcontroller chip" has the inconvenience that the user should stop using the computer when the temperature of the microcontroller chip rises above a certain value.

The object of the present invention is to solve the conventional inconvenience as described above, by allowing the voltage applied to the cooling fan to be more than 12V to expand the range of rotation speed change of the cooling fan to rotate the cooling fan at high speed. It is to provide a cooling fan drive speed control device. As a means for achieving the above object, the constitution of the present invention comprises: a DC power supply unit having an input terminal connected to a power plug and generating and outputting a DC + 12V and -5V power source;

Cooling fan motor,

A temperature sensing unit connected between a + 12V and -5V power supply from the DC power supply unit for detecting a temperature change;

And a driving unit for driving the cooling fan motor (M) using a + 12V and -5V power supply from the DC power supply unit as a driving power supply, and using the output value of the temperature sensing unit as a control signal.

Hereinafter, the most preferred embodiments of the present invention will be described with reference to the accompanying drawings in order to be described in detail that can be easily carried out by those of ordinary skill in the art.

3 is a detailed circuit diagram of a cooling fan drive speed control device according to an embodiment of the present invention.

As shown in Figure 3, the configuration of the cooling fan drive speed control apparatus according to the embodiment of the present invention,

An input terminal is connected to the power plug, and the DC power supply unit 10 generates and outputs a DC + 12V and -5V power source, a cooling fan motor (M),

Temperature detection units RT31, R31, and R32 connected between + 12V and -5V power supplies from the DC power supply unit 10 to detect temperature changes, and + 12V and -5V from the DC power supply unit 10. A power source is used as a driving power source, and the drive unit Q31, Q32, R33, R34, R35 for driving the cooling fan motor M using the output values of the temperature sensing units RT31, R31, and R32 as a control signal, A potential difference of up to 17V is generated at both electrodes of the cooling fan motor M.

The temperature sensing unit RT31, R31, R32 and the driving units Q31, R32, R33, R34, R35 are

A thermistor RT31 having one terminal connected to the + 12V signal line, a first voltage divider R31 connected in series with the other terminal of the thermistor RT31, and the first resistor resistor R31; A base is connected to a connection point between the second voltage divider resistor R32 and the first voltage divider resistor R31 and the second voltage divider resistor R32 connected in series between the -5V signal line of the DC power supply unit 10. The first transistor Q31,

A third resistor R33 connected between the emitter terminal of the transistor Q31 and the -5V signal line of the DC power supply unit 10;

A second transistor Q32 having a base connected to the collector of the transistor Q31;

A fourth resistor R34 connected between the emitter of the second transistor Q32 and the -5V signal line of the DC power supply unit 10;

The fifth resistor R35 is connected between the collector of the transistor Q31 and the + 12V signal line of the DC power supply unit 10.

The first transistor Q31 is composed of a PNP type, and the second transistor Q32 is composed of a PNP type.

By the above configuration, the operation of the cooling fan drive speed control device according to an embodiment of the present invention is as follows.

When the operation starts, voltages of + 12V and -5V are applied from the DC power supply unit 10 to the thermistor Q31, the capacitor C31, the first voltage divider R31, and the second voltage divider R32. .

In this case, the thermistor RT31 also has the same effect as the short circuit due to the initial short circuit of the capacitor C31, and as a result of the high resistance of the thermistor RT21 initially as shown in FIG. The conventional problem that the cooling fan is not driven can be solved.

After the voltage is divided by the first voltage divider R31 and the second voltage divider R32 after the voltage is applied through the capacitor C31 and then applied through the first voltage divider C31, the voltage is divided into the first transistor Q31. The first transistor Q31 is turned on by being applied to the base terminal of the first transistor.

When the first transistor Q31 is turned on, the second transistor Q32 is turned on so that the cooling fan motor M is rotated.

In this case, the thermistor RT31 adjusts the rotational speed of the cooling fan motor M by changing the resistance value according to the ambient temperature. When the ambient temperature is low, the thermistor RT31 has a high resistance value. When a low voltage is applied to the base terminal of the transistor Q31, and thus the base current of the second transistor Q32 is reduced, the rotation speed of the cooling fan motor M becomes slow, and the thermistor RT31 when the ambient temperature is high. When the resistance of the transistor is lowered, a high voltage is applied to the base terminal of the first transistor Q31, and accordingly, the rotational speed of the cooling fan motor M is increased by increasing the base current of the second transistor Q32. Accordingly, the speed of the cooling fan motor M is changed.

As a result, a voltage of about + 17V, which is a potential difference between + 12V and -5V, is applied to the cooling fan motor M, thereby extending the driving speed range of the cooling fan motor M.

As described above, in the embodiment of the present invention, the cooling fan drive having the effect of rotating the cooling fan at high speed by extending the range of change in the rotational speed of the cooling fan so that the applied voltage of the cooling fan can be more than 12V Speed control can be provided. This effect of the invention can be used in the field of computer system protection.

Claims (5)

An input terminal is connected to the power plug, and the DC power supply unit 10 generates and outputs DC + 12V and -5V power, Cooling fan motor (M), A temperature sensing unit (RT31, R31, R32) connected between the + 12V and -5V power sources from the DC power supply unit (10) for detecting a temperature change; A driving unit for driving the cooling fan motor M by using + 12V and -5V power from the DC power supply unit 10 as a driving power, and output values of the temperature sensing units RT31, R31 and R32 as control signals ( And Q31, Q32, R33, R34, and R35, so that a potential difference of up to 17V is generated at both electrodes of the cooling fan motor (M). The method of claim 1, The temperature sensing units RT31, R31, and R32 and the driving units Q31, Q32, R33, R34, and R35 include the thermistor RT31 and one terminal connected to a + 12V signal line, and the thermistor RT31. A first voltage divider R31 connected in series with the other terminal; A second voltage divider resistor R32 connected in series between the first voltage divider resistor R31 and a -5V signal line of the DC power supply unit 10; A first transistor Q31 having a base connected to a connection point of the first voltage divider resistor R31 and the second voltage divider resistor R32, A third resistor R33 connected between the emitter terminal of the transistor Q31 and the -5V signal line of the DC power supply unit 10; A second transistor Q32 having a base connected to the collector of the transistor Q31; A fourth resistor R34 connected between the emitter of the second transistor Q32 and the -5V signal line of the DC power supply unit 10; And a fifth resistor (R35) connected between the collector of the transistor (Q31) and the + 12V signal line of the DC power supply unit (10). The method of claim 2, Cooling fan drive speed control device characterized in that it further comprises a capacitor (C31) connected in parallel to the thermistor (RT31). The method of claim 2, The first transistor (Q31) is a cooling fan drive speed control device, characterized in that consisting of NPN type. The method of claim 2, The second transistor (Q32) is a cooling fan drive speed control device, characterized in that consisting of a PNP type.