JPH05308729A - Cooling fan control method - Google Patents

Abstract

(57) [Summary] [Objective] Regarding the control method of the cooling fan of the power supply unit, the purpose is to control the rotation of the cooling fan according to the power loss of the power supply unit 1. In a method of controlling a cooling fan 6 that cools a power supply unit 1 that supplies power to a first load 2 and a second load 3 that assists the first load, a current flowing through the second load 3 is detected. And a fan control unit 5 that controls the rotation of the cooling fan 6 based on the detected current value of the current detection unit 4, and the rotation of the cooling fan 6 based on the current value flowing through the second load. It has a configuration to control.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling fan control method for cooling a power supply section. The power supply unit of the information processing device
To prevent the loss of data when the main power supply fails,
An auxiliary power supply for supplying power to the information processing device is provided instead of the main power supply unit.

The auxiliary power supply is usually composed of a storage battery and is charged by the main power supply when the main power supply is operating, and supplies power to the load when the main power supply fails. In such a power supply system, if the capacity of the storage battery is large, the charging current is large and the power loss of the main power supply unit is large. Therefore, a cooling fan (hereinafter abbreviated as a fan) is attached to the power supply unit for cooling. ..

However, although the charging current of the storage battery is large at the start of charging, it is small after the completion of charging, so that the power loss is small. Therefore, after charging is completed, stop the rotation of the fan,
Alternatively, the number of rotations may be reduced.

In the conventional power supply system, control is performed only to turn on / off the fan regardless of the charging current.

[0005]

2. Description of the Related Art FIG. 5 shows a conventional fan control method.
In the figure, 100 is a power supply system and 101 is a power supply unit (AC-DC conversion) for converting a commercial power supply into a DC voltage. A fan controller 102 controls the rotation of the cooling fan 103 of the power supply 101. A cooling fan 103 cools the power supply unit 101. 104 and 105 are chargers,
It charges a storage battery. Storage batteries 106 and 107 supply electric power to a load instead of the power supply unit 101 when the power supply unit 101 has a power failure. Reference numeral 108 denotes a power supply unit (DC-DC conversion), which converts the voltage supplied from the power supply unit 101 or the storage batteries 106 and 107 into an appropriate DC voltage.

[0006]

As described above, in the conventional cooling fan control of the power supply unit 101, only the on / off control of the electric power supplied to the fan is performed, and the cooling fan 103 is controlled.
Was rotating regardless of the electric power supplied to the load 109 and the storage batteries 106 and 107.

However, after the storage batteries 106 and 107 have been charged, the current flowing through the storage batteries is small, so cooling by the cooling fan 103 is not necessary or the number of rotations may be reduced. Therefore, the conventional power supply system 1
No. 00 wastes power supplied to the cooling fan 103. Further, the cooling fan 103 also continued to rotate more than necessary, which shortened the life.

An object of the present invention is to provide a control method for a cooling fan, which controls the rotation of the fan according to the power loss of the power supply unit 101.

[0009]

The present invention detects the supply current of a second load 3 such as a storage battery which supplements the first load 2 which operates mainly, and controls the fan according to the supply current. To do.

FIG. 1 shows the basic configuration of the present invention. In the figure, reference numeral 1 is a power supply unit for supplying electric power to a first load and a second load. Reference numeral 2 is a first load, which is a load that operates mainly. Reference numeral 3 denotes a second load, which operates auxiliary to the first load such as a storage battery.

Reference numeral 4 is a current detecting section for detecting the current flowing through the second load. A fan control unit 5 controls the drive voltage of the fan so that the rotation speed of the fan changes depending on the current flowing through the second load 3.
The fan control unit 5 is composed of, for example, a serial constant voltage power supply circuit. A cooling fan 6 cools the power source unit 1. An output voltage variable signal generator 7 outputs a voltage signal for controlling the output voltage of the fan controller 5 according to the detected current value of the current detector 4. Reference numeral 8 is a charger when the second load is a storage battery.

In the fan control section 5, 10 is an output voltage control section which controls the voltage for driving the fan. For example, it is constituted by a voltage control transistor or the like in a series type constant voltage circuit. Reference numeral 11 denotes an output voltage selection unit, which controls the selection of the output voltage based on the output signal of the output voltage variable signal generation unit 7. A reference voltage unit 12 serves as a reference for the control voltage of the output voltage control unit 10. The reference voltage unit 12 is composed of, for example, a shunt regulator or the like. A voltage dividing resistor 13 is connected in parallel to the output of the output voltage control unit 10 and has a resistance value selected according to the output of the output voltage variable signal generating unit 7. 14, 1
Reference numerals 4 ', 14 "are active elements (for example, photocouplers), which operate to select the resistance value of the dividing resistors based on the output of the output voltage variable signal generator 7. The figure shows an example. The case of a coupler is shown.

[0013]

The operation of the basic configuration of FIG. 1 will be described. The current detector 4 detects the current flowing through the second load 3. The current detection unit 4 is composed of, for example, a resistor, converts a current value into a voltage value, and outputs the voltage value. The output voltage variable signal generator 7 outputs a signal according to the current value. For example, when controlling in three steps according to the current value, (1) When the current is large, "L, H,
H ”, (2) When the current level is medium,“ L, L,
H ”, (3) When the current reher is small,“ L, L,
L "is output.

As a result, assuming that the resistance between XY is R, in the case of (1), the photocoupler 14 is turned on and the photocouplers 14 ', 14 "are turned off, and R = R1 + R2 + R.
It becomes 3.

At the time of (2), the photocouplers 14, 14 '
Is on and 14 "is off, and R = R2 + R3. In the case of (3), the photocouplers 14, 14 ', 14" are on and R = R3.

As described above, the divided voltage is divided according to the detected current value.
The voltage division ratio of the resistance changes. And, for example, the reference voltage section
If 12 is a shunt regulator, its reference voltage
To V _REFAnd_,Output voltage V₀= V_REF(1 + R / R
4), the output voltage should be adjusted according to the voltage dividing ratio of the voltage dividing resistor.
Can be controlled.

The output voltage control unit 10 outputs a voltage according to the output of the reference voltage unit 12. According to the present invention, the power supplied to the fan can be minimized without affecting the first load. In particular, when the second load is a storage battery, in the state where the power loss of the power supply unit after the completion of charging is small, the powerful cooling required at the time of charging is not continued, so that the power supply to the fan is wasted. Can be significantly reduced.

[0018]

FIG. 2 shows the construction of an embodiment of the present invention. In the figure, 20 is a power supply system, 21 is a power supply unit (AC-DC conversion), 22 is a fan control unit, 23 is a cooling fan, 24,
24 'is a charger, 25, 25' is a current detection unit, 26 is an output voltage variable signal generation unit, 27 is a second load, 28, 29.
Is a storage battery, which is the second load. Thirty
Is a power supply unit (DC-DC conversion), and 31 is a first load.

FIG. 3 shows an embodiment of the current detector and the output voltage variable signal generator of the present invention. In the figure, reference numeral 35 is a current detection unit which is composed of a resistor and detects a current as a voltage value. Reference numeral 36 is an output voltage variable signal generator, and 37 and 38 are comparators for comparing the voltage value detected by the current detector 35 with a reference voltage. For example, the detected voltage value of the current detector 35 is higher than the reference voltage. If is large, the output is H, and if it is low, it is L. A plurality of comparators are provided according to the number of detection steps of the current value. The figure shows the case of setting in five stages, and five comparators are provided, but only two of them are shown and the others are omitted. Reference numerals 39 and 40 are reference voltage sources. For example, the reference voltage source 39 is set to have a voltage value larger than that of the reference voltage source 40. Therefore, as the detected voltage value becomes smaller, the output value of the lower comparator (the comparator 37 being the upper and the comparator 38 being the lower) becomes L.
Reference numeral 41 denotes a register which holds and outputs the output value of H or L corresponding to the comparators 37 and 38.

The correspondence between the output value of the register 41 and the output voltage of the fan controller is as follows. (1) "L, H,
H, H, H ”, output 24V, (2)“ L,
L, H, H, H ”, output 22V, (3)“
L, L, L, H, H ”, output 20V, (4)
When "L, L, L, L, H", output 18V,
(5) Output 16 when "L, L, L, L, L"
It is V.

The reason why the output voltage changes according to the output of the register 41 will be described later. FIG. 4 shows an embodiment of the fan controller of the present invention.

In the figure, reference numeral 44 is an output voltage variable signal generator. Reference numeral 45 is a fan control unit, which is a series-type constant voltage power supply. Then, the fan control unit 45 has terminals,
The voltage (29V) is input from the power source between the terminals,
It outputs a voltage for controlling the fan in the meantime.

Reference numeral 46 is a photocoupler. 47,4
Reference numerals 8 and 49 are transistors, and 49 is an output control transistor for controlling the output voltage. 5
Reference numeral 0 is a shunt regulator, and a voltage dividing resistance ratio (R10, R11, R) is provided between the cathode (K) and the anode (A).
As long as the combined resistance R and R14 of 12, R13 and R15 is constant, it is maintained at a constant value. And
The transistor 49 is controlled by the constant value to stabilize the output voltage, and the output voltage of the transistor 4) is changed based on the change of the voltage dividing resistance ratio. 52,
Reference numerals 53, 54 and 55 are photocouplers. R1, R
2, R3, R4, R6, R7, R8, R9, R10, R
Reference numerals 11, R12, R13, R14, R15 and R16 are resistors.

The operation of the configuration shown in the figure will be described. Power supply (AC
-The output voltage (29V) from the DC power supply section is the terminal,
Entered in.

Photocouplers 52, 53, 54, 55
Depending on the ON or OFF state of the
The combined resistance (sum of series resistance) of 10, R11, R12, R13, and R15 changes. Let R be the combined resistance.

In the circuit shown in the figure, assuming that the reference voltage of the shunt regulator 50 is V _REF , the output voltage (voltage between the terminals) V ₀ is V ₀ = V _REF (1 + R / R14)
Becomes Further, in the circuit shown in the figure, the output voltage control transistor 49 of the shunt regulator 50 changes the output voltage by changing the voltage dividing resistance ratio, and at the same time, performs constant voltage control for a minute change in the output voltage.

That is, when the output voltage rises, a current is drawn into the anode A of the shunt regulator 50, the base current decreases, the collector-emitter voltage of the transistor 49 increases, and the output voltage decreases. On the contrary, when the output voltage decreases, the base current of the transistor 49 increases, the collector-emitter voltage of the transistor 49 decreases, and the output voltage is increased.

Next, the output voltage variable operation of the illustrated circuit will be described. (0) The output of the terminal of the output voltage variable signal generator 44 is H
At this time, the photocoupler 46 is turned off, the transistors 47, 48, 49 are turned off, and the output voltage becomes zero.

(1) Terminal is L and photo coupler 46
Is turned on, and the transistor 48 is turned on. As a result, the transistor 47 is turned on and the transistor 49 is turned on.
The output voltage controlled by is output between the terminals. And at this time, if all the terminals ,, are H,
The photocouplers 52, 53, 54, 55 are turned off, and the combined resistance R = R10 + R11 + R12 + R13 + R
15, the output voltage 24V corresponding to V ₀ = V _REF (1 + R / R14) is obtained.

(2) Similarly, when L, ..., H, the combined resistance R = R11 + R12 + R13 + R15, and the output voltage 22V is obtained according to the ratio of the combined resistance R and the resistance R14.

(3) Similarly, when L, L, and H, the combined resistance R = R12 + R13 + R15, and the output voltage of 20V is output according to the ratio of the combined resistance R and the resistance R14.
To get

(4) Similarly, when L, H, the combined resistance R = R13 + R15, and the output voltage 18V is obtained according to the ratio of the combined resistance R and the resistance R14. (5) Similarly, when L ,,, L, combined resistance R =
It becomes R15, and the output voltage 16V corresponding to the value is obtained.

In the above, the voltage dividing resistor (R10,
Although the case where the photocoupler is used for controlling R11, R12, R13, R14, and R15) has been described, the voltage dividing resistance may be controlled by another active element such as a transistor.

Further, the output voltage may be linearly controlled with respect to the change of the detection voltage of the current detecting portion, and the rotation of the fan may be linearly controlled.

[0035]

According to the present invention, the fan rotation control is performed by detecting the change in the current flowing through the second load that operates in an auxiliary manner with respect to the first load. The power supplied to the fan can be controlled to a minimum without affecting the. In particular, when the second load is a storage battery, the rotation of the fan is suppressed to the necessary minimum after the completion of charging, so that power is not wastefully supplied to the fan. Further, it is possible to prevent the fan from rotating unnecessarily at a high speed and being unnecessarily worn.

[Brief description of drawings]

FIG. 1 is a diagram showing a basic configuration of the present invention.

FIG. 2 is a diagram showing a configuration of an embodiment of the present invention.

FIG. 3 is a diagram showing an embodiment of a current detector and an output voltage variable signal generator of the present invention.

FIG. 4 is a diagram showing an embodiment of a fan control unit of the present invention.

FIG. 5 is a diagram showing a conventional fan control method.

[Explanation of symbols]

 1: Power supply part 2: First load 3: Second load 4: Current detection part 5: Fan control part 6: Cooling fan 7: Output voltage variable signal generation part 10: Output voltage control part 11: Output voltage selection part 12: Reference voltage part 13: Voltage dividing resistors 14, 14 ', 14 ": Active element

Claims (5)

[Claims] 1. A method of controlling a cooling fan (6) of a power supply section (1) for supplying electric power to a first load (2) and a second load (3) which assists the first load, comprising: Current detector (4) that detects the current flowing through the load (3)
And the cooling fan based on the current detected by the current detector (4).
A fan control unit (5) for controlling the rotation of (6),
A method for controlling a cooling fan, characterized in that the rotation of the cooling fan (6) is controlled based on the value of the current flowing through the load (3). 2. The load (3) according to claim 1, wherein the second load (3) is a backup storage battery for supplying electric power to the first load (2), and the current detector (4) detects a charging current of the storage battery. A method for controlling a cooling fan, comprising: 3. The fan control according to claim 1, further comprising an output voltage variable signal generator (7) which outputs a stepwise signal according to the magnitude of the current value detected by the current detector (4). A cooling fan control method characterized in that the section (5) controls the rotation speed of the cooling fan (6) stepwise based on the output signal of the variable output voltage signal generation section (7). 4. The output voltage control unit (10) according to claim 3, wherein the fan control unit (5) receives the output voltage from the power supply unit (1), and controls and outputs the voltage, and an output voltage variable signal generator. Department
Based on the signal value output by (7), the active element (14, 1
4 ', 14 ") determines the voltage division ratio of the voltage dividing resistors connected in parallel to the output side by the output voltage selection unit (11) and the resistance voltage division ratio output from the output voltage selection unit (11). A reference voltage unit (12) for inputting a voltage value and controlling the output voltage control unit (10) based on the voltage value, and making the output voltage of the fan control unit (5) variable Cooling fan control method. 5. The cooling fan control method according to claim 1, wherein the fan control unit (5) continuously controls the rotation speed of the cooling fan according to the detected current value.