JP2015219814A - Device capable of controlling cooling fan, and control method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device capable of controlling a cooling fan, and a control method thereof.SOLUTION: The device related to one embodiment of the present invention includes: a first power source for supplying a power source for rotating a cooling fan at low rotational speed; and a second power source for rotating the cooling fan at high rotational speed. The device further includes: a first register for setting whether or not the cooling fan is rotated at low rotational speed by the first power source; and a second register for setting whether or not the cooling fan is rotated at high rotational speed by the second power source. The device further includes: a detection circuit for detecting that setting of any one of the first and second registers is changed to setting for rotating the fan; and a timer circuit for starting timing when change of setting of the first or second register is detected. The device still further includes a logic circuit for making setting of the second register valid, according to a signal output from the timer circuit during timing, and rotating the cooling fan at high rotational speed by the power source supplied from the second power source.

Description

  The present invention relates to starting, stopping, and controlling a rotational speed of a cooling fan in an electronic apparatus.

  2. Description of the Related Art Conventionally, in various electronic devices, a cooling fan (hereinafter also simply referred to as a fan) is used to prevent a failure due to a temperature rise. For example, an MFP (Multi Function Peripheral) is equipped with a fan for cooling a heat source such as a CPU or a hard disk. The MFP does not always rotate the fan at a constant speed, but controls the start, stop, and rotation speed of the fan according to the state of the MFP. For example, when the user turns on the power switch of the MFP and the MFP starts, a voltage is supplied to the fan and the fan starts to rotate (fan start). When the MFP enters the power saving mode and a part of the power is cut off, voltage is not supplied to the fan, and the fan stops rotating (fan stop). When the MFP returns from the power saving mode to the normal power mode, the fan starts to rotate (fan start-up). When the power supply of the entire MFP is cut off, no voltage is supplied to the fan, and the fan stops rotating (fan stop).

  Conventionally, a technique for controlling the voltage supplied to the fan in order to control the air volume, wind speed, wind pressure, etc. of the fan is known. This technique will be described below assuming that the voltage supplied to the fan is controlled in two stages.

  The first stage is a “high-speed rotation” state used when the heat source generates a large amount of heat. By increasing the voltage supplied to the fan, the fan rotation speed is increased to increase the air volume. In the high speed rotation state, a high voltage, for example, 12V is supplied to the fan.

  The second stage is a “low speed rotation” state used when the heat generation amount of the heat source is small, and the fan speed is reduced by reducing the voltage supplied to the fan to reduce the air volume. In the low speed rotation state, a lower voltage, for example, 7V, is supplied to the fan than in the high rotation state.

  Compared with the high-speed rotation state, the low-speed rotation state has advantages such as less noise such as wind noise and less power consumption of the fan. Therefore, it is desirable that the fan be in a low-speed rotation state as much as possible.

  Conventionally, fan speed control involving software is known. For example, the software reads the temperature sensor of the CPU and sets the voltage to be supplied to the CPU fan, thereby controlling the startup and rotation speed of the CPU fan.

  In the MFP, the fan is set to the high-speed rotation state only when the cooling capacity is insufficient in the low-speed rotation state. For example, when the MFP performs printing and the amount of computation of the CPU increases and the CPU generates a lot of heat, the CPU fan is set to a high-speed rotation state. On the other hand, when the MFP is waiting for operation and the amount of calculation of the CPU decreases and the CPU generates little heat, the CPU fan is set to the low speed rotation state.

  However, since the static frictional force for stopping the fan is larger than the dynamic frictional force for maintaining the rotation of the fan, the energy required for starting the fan is larger than that for the rotation of the fan. Since there is no back electromotive force of the fan coil when the fan is stopped, an instantaneous large current flows. When the electromagnetic force generated by this current and the magnetic force generated by the fan magnet exceed the static friction force, the fan starts. When the voltage supplied to the fan is low, it is difficult to supply a large current necessary for starting, and there is a risk that a starting failure of the fan occurs. Furthermore, the risk of fan starting failure increases due to aging, such as rust, dust adhesion, and oil solidification.

  A technique for preventing such a starting failure is proposed in Patent Document 1. In the technique described in Patent Document 1, a high voltage is supplied when the fan is started to reliably start the fan, and the voltage provided to the fan is lowered after the rotation of the fan is stabilized.

Japanese Patent Laid-Open No. 10-9191

  However, in the technique described in Patent Document 1, since the voltage supplied to the fan is always lowered after the fan starts and the rotation is stabilized, the high-speed rotation state of the fan does not continue. Therefore, when the technology described in Patent Document 1 is applied to the MFP, for example, after the fan enters a low-speed rotation state, the operating temperature of the heat source may exceed the recommended operating temperature due to the heat stored in the heat source. There is sex. If the recommended operating temperature is not observed, malfunction due to thermal destruction or a reduction in service life will occur.

  Taking the MFP CPU as an example, in the normal power mode, the CPU is cooled to a recommended operating temperature (for example, the maximum surface temperature of the package of the CPU is 80 ° C.) or less by a fan. On the other hand, in the power saving mode, since the CPU is not energized, the recommended storage temperature of the CPU (for example, the maximum surface temperature of the package of the CPU is 125 ° C.) can be maintained even when the fan is stopped. Therefore, when the MFP is set to the energy saving priority mode, even if the CPU is at a high temperature, the normal power mode is changed to the power saving mode, and the fan stops. For this reason, the surface temperature of the CPU temporarily rises due to the conduction of heat stored in the CPU, and may exceed the recommended storage temperature.

  Further, even when the MFP is immediately restored from the power saving mode to the normal power mode by a user operation, the CPU rotates the fan until the OS and the fan control software start operating even when the fan and CPU are turned on. The speed cannot be changed. In this case, since the MFP operates with the fan stopped in the power saving mode setting, there is a possibility that the surface temperature of the CPU will rise and exceed the recommended operating temperature.

  An apparatus according to an embodiment of the present invention includes a first power source that supplies power to rotate a cooling fan at a low speed and a second power source that rotates the cooling fan at a high speed. The apparatus also includes a first register for setting whether or not the cooling fan is rotated at a low speed by a first power supply, and a second register for setting whether or not the cooling fan is rotated at a high speed by a second power supply. Prepare. In addition, the apparatus detects a change in the setting of either the first register or the second register to change the setting for rotating the fan, and a setting change in the first or second register. And a timer circuit for starting timing. In addition, the apparatus includes a logic circuit that validates the setting of the second register in accordance with a signal output during timing from the timer circuit and rotates the cooling fan at high speed with the power supplied from the second power supply.

  According to the present invention, the fan can be reliably started, and the rotation speed of the fan after the fan is started can be appropriately controlled according to the register setting that is set according to the temperature of the heat source. Further, according to the present invention, it is possible to appropriately control the rotation speed of the fan when shifting from the normal power mode to the power saving mode and when shifting from the power saving mode to the normal power mode.

FIG. 1 is a block diagram showing a configuration example of an information processing apparatus according to the first embodiment of the present invention. FIG. 2 is a timing chart showing the operation of the fan control unit according to the first embodiment of the present invention. FIG. 3 is a diagram showing a flowchart of processing according to the first embodiment of the present invention. FIG. 4 is a block diagram showing a configuration example of an MFP system according to the second embodiment of the present invention. FIG. 5 is a block diagram illustrating a configuration example of a power management unit according to the second embodiment of the present invention. FIG. 6 is a first timing chart showing the operation of the power management unit according to the second embodiment of the present invention. FIG. 7 is a second timing chart showing the operation of the power management unit according to the second embodiment of the present invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Throughout the drawings, the same reference numeral represents the same object.

(First embodiment)
FIG. 1 is a block diagram showing a configuration example of an information processing apparatus according to the first embodiment of the present invention. A configuration example of the information processing apparatus according to the present embodiment will be described with reference to FIG.

  The information processing apparatus 100 includes a control unit 1710 including a CPU 1700, a RAM (Random Access Memory) 1800, and a ROM (Read Only Memory) 1900.

  In control unit 1710, CPU 1700 controls each component of information processing apparatus 100 by executing a program stored in RAM 1800 or ROM 1900. The RAM 1800 is a rewritable memory, and temporarily stores a program and data of the CPU 1700. The ROM 1900 also stores programs and data that run on the CPU 1700. A bus 1701 connects each component of the CPU 1700, RAM 1800, ROM 1900, and information processing apparatus 100.

  The information processing apparatus 100 is an apparatus that can control the fan 1000 and includes a fan control unit 1100. The fan control unit 1100 includes a fan low speed ON control register 1110, a fan high speed ON control register 1120, a power mode control circuit 1500, a fan ON detection circuit 1200, a timer circuit 1300, and a logic circuit 1400. The fan control unit 1100 includes a first fan power supply 1610, a second fan power supply 1620, a first switch 1630, and a second switch 1640.

  The fan low-speed ON control register 1110 is read from and written to by the CPU 1700 via the bus 1701, and a value for controlling the low-speed rotation or stop of the fan 1000 is set. For the sake of explanation, it is assumed that the fan low speed ON control register 1110 represents fan stop when the value 0 is set, and represents fan low speed rotation when the value 1 is set. The set value of the fan low speed ON control register 1110 is output as a signal 1111 to the fan ON detection circuit 1200 and the logic circuit 1400. The set value of the fan low speed ON control register 1110 is not held in the power OFF mode, but is held in the normal power mode and the power saving mode. The set value of the fan low-speed ON control register 1110 is initialized to the value 0 (fan stop) by the reset circuit 1750 when shifting from the power OFF mode to the normal power mode. The set value of the fan low speed ON control register 1110 can be set by the CPU in the normal power mode.

  The fan high-speed ON control register 1120 is read from and written to by the CPU 1700 via the bus 1701, and a value for controlling high-speed rotation or stop of the fan 1000 is set. For explanation, it is assumed that the fan high-speed ON control register 1120 represents fan stop when the value 0 is set, and represents high-speed fan rotation when the value 1 is set. The set value of the fan high-speed ON control register 1120 is output as a signal 1121 to the fan ON detection circuit 1200 and the logic circuit 1400. The set value of the fan high-speed ON control register 1120 is not held in the power OFF mode, but is held in the normal power mode and the power saving mode. The set value of the fan high-speed ON control register 1120 is initialized to the value 1 (fan high-speed rotation) by the reset circuit 1750 when shifting from the power OFF mode to the normal power mode. The setting value of the fan high-speed ON control register 1120 can be set by the CPU in the normal power mode.

  When both the fan low-speed ON control register 1110 and the fan high-speed ON control register 1120 are set to the value 0, this indicates that the fan has stopped. When the fan low-speed ON control register 1110 is set to the value 1 and the fan high-speed ON control register 1120 is set to the value 0, the fan low-speed rotation is indicated. When the fan low-speed ON control register 1110 is set to the value 0 and the fan high-speed ON control register 1120 is set to the value 1, it indicates fan high-speed rotation. It is prohibited that both the fan low-speed ON control register 1110 and the fan high-speed ON control register 1120 are set to the value 1.

  The power supply 1520 is controlled by a power mode control signal 1501 received from a power mode control circuit 1500 described later. The power supply 1520 supplies a power supply 1521 that is turned off in the power saving mode, a power supply 1522 that is always output, and power supplies 1610 and 1620 for driving the fan. A power supply 1521 that is turned off in the power saving mode is supplied to the CPU 1700 and the like. There are no particular limitations on the power supply 1520 that is always output, such as one that converts AC voltage from an outlet into DC voltage to convert voltage, and one that converts DC voltage from a battery into voltage.

  The power mode control circuit 1500 detects that the power switch 1510 has been pressed and the power mode has been changed, and outputs a power mode control signal 1501. For the sake of explanation, when the value of the power mode control signal 1501 is 0, it represents the power-off mode or the power saving mode, and when the value of the power mode control signal 1501 is 1, it represents the normal power mode. The power mode control signal 1501 is transmitted to the power supply 1520 and notifies the power supply 1520 of the power mode. The power supply 1520 switches ON / OFF of the power supply 1521 according to the notified power mode. The power mode control signal 1501 is also transmitted to the timer circuit 1300 to notify the timer circuit 1300 of the power mode.

  The fan ON detection circuit 1200 receives the signal 1111 output from the fan low speed ON control register 1110 and the signal 1121 output from the fan high speed ON control register 1120. The fan ON detection circuit 1200 detects that the setting has been changed from the fan stop to the fan high speed rotation or the fan low speed rotation based on the received signals 1111 and 1121. For example, when the fan ON detection circuit 1200 detects that either the signal 1111 or the signal 1121 has changed to the value 1 from the state where both the signal 1111 and the signal 1121 are 0, the fan ON detection signal 1201 is pulsed. Is output.

  The timer circuit 1300 receives the fan ON detection signal 1201 from the fan ON detection circuit 1200 and receives the power mode control signal 1501 from the power mode control circuit 1500. The timer circuit 1300 detects when the fan low-speed ON control register 1110 or the fan high-speed ON control register 1120 is rewritten from 0 (OFF) to either 1 (ON), that is, detects the rising edge of the fan ON detection signal 1201. Start timing. Alternatively, the timer circuit 1300 detects that the power mode control signal 1501 has changed from 0 (power saving mode) to 1 (normal power mode), and starts measuring time. For the sake of explanation, it is assumed that the timer circuit 1300 measures 1 second from the rising edge of the fan ON detection signal 1201 or the power mode control signal 1501. The timer circuit 1300 outputs the value 1 as the timer output signal 1301 while counting time. The timer circuit 1300 outputs a value of 0 as the timer output signal 1301 when it is not timed (that is, before or after timing). The timer output signal 1301 is transmitted to the logic circuit 1400.

  The logic circuit 1400 receives the signal 1111, the signal 1121, and the signal 1301 from the fan low-speed ON control register 1110, the fan high-speed ON control register 1120, and the timer circuit 1300, respectively. Further, the logic circuit 1400 outputs a fan low speed ON control signal 1411 to the first switch 1630 and outputs a fan high speed ON control signal 1421 to the second switch 1640. For example, the fan low-speed ON control signal 1411 is a logical product of a signal obtained by inverting the timer output signal 1301 and the signal 1111. The fan high speed ON control signal 1421 is a logical sum of the timer output signal 1301 and the signal 1121. The logic circuit 1400 validates the setting of the fan high-speed ON control register 1120 according to the timer output signal 1301 output from the timer circuit 1300 during timing.

  The first fan power supply 1610 supplies the fan 1000 with a fan drive voltage 1600 (for example, 7V) that rotates the fan at a low speed via the first switch 1630.

  The second fan power supply 1620 supplies the fan 1000 with a fan drive voltage 1600 (for example, 12V) that rotates the fan at a high speed via the second switch 1640.

  The first switch 1630 is OFF (non-conductive) when the value of the fan low-speed ON control signal 1411 from the logic circuit 1400 is 0, and is ON (conductive) when the value of the fan low-speed ON control signal 1411 is 1. . When the first switch 1630 is OFF, the voltage of the first fan power supply 1610 is not supplied to the fan 1000. When the first switch 1630 is ON, the voltage of the first fan power supply 1610 is supplied to the fan 1000.

  The second switch 1640 is OFF (non-conductive) when the value of the fan high-speed ON control signal 1421 from the logic circuit 1400 is 0, and is ON (conductive) when the value of the fan high-speed ON control signal 1421 is 1. . When the second switch 1640 is OFF, the voltage of the second fan power supply 1620 is not supplied to the fan 1000. When the second switch 1640 is ON, the voltage of the second fan power supply 1620 is supplied to the fan 1000.

  Here, an example of an internal circuit of the logic circuit 1400 will be described. The logic circuit 1400 includes an AND (logical product) gate 1410 and an OR (logical sum) gate 1420. The AND gate 1410 outputs the logical product of the timer output signal 1301 and the signal 1111 to the first switch 1630 as the fan low speed ON control signal 1411. The OR gate 1420 outputs the logical sum of the timer output signal 1301 and the signal 1121 to the second switch 1640 as the fan high-speed ON control signal 1421. The logic circuit 1400 switches the rotation speed of the fan 1000 indicated by the set values of the fan low-speed ON control register 1110 and the fan high-speed ON control register 1120. When the value of the fan high-speed ON control register 1120 is 0 and the value of the fan low-speed ON control register 1110 is changed from 0 to 1, the value of the signal 1411 is 0 and the value of the signal 1421 is constant for a certain time (for example, 1 second). 1 and the fan 1000 is started at high speed. In other cases, the rotational speed of the fan is controlled at the speed indicated by the setting values of the fan low-speed ON control register 1110 and the fan high-speed ON control register 1120.

  The reset circuit 1750 monitors the power supply 1522 (for example, 3.3V power supply) and resets the fan low-speed ON control register 1110 and the fan high-speed ON control register 1120. For example, when the voltage of the 3.3V power supply 1522 rises, the value of the reset signal 1751 is set to 0 for a certain time (eg, 100 ms) after exceeding a threshold value (eg, 2.9 V), and the register is initialized. After a certain time has elapsed, the reset circuit 1750 sets the value of the reset signal 1751 to 1 and releases the reset. In addition, the reset circuit 1750 resets the register by setting the value of the reset signal 1751 to 0 as soon as it falls below a threshold value (for example, 2.9 V) when the voltage of the 3.3V power supply 1522 falls.

  Here, since the 3.3V power supply 1522 continues to be energized in the power saving mode and the normal power mode, it is reset even if the power mode control circuit 1500 transitions between the power saving mode and the normal power mode. Does not work. Here, the 3.3V power supply has been described as an example, but the power supply monitored by the reset circuit is not limited, and any power supply may be monitored. Further, the reset circuit may monitor a plurality of power supplies.

  Next, the operation of the fan control unit 1100 according to the first embodiment of the present invention will be described. FIG. 2 is a timing chart for explaining the operation of shifting from the power saving mode to the normal power mode and then shifting again to the power saving mode or the power OFF mode.

  In the first timing chart 2100 shown in FIG. 2A, a value 1 (fan low speed rotation) is set in advance in the fan low speed ON control register 1110, and a value 0 (fan stop) is set in the fan high speed ON control register 1120. Is the case.

  In the second timing chart 2200 shown in FIG. 2B, a value 0 (fan stop) is set in the fan low speed ON control register 1110 and a value 1 (fan high speed rotation) is set in the fan high speed ON control register 1120 in advance. Is the case.

  As described above, the fan control unit 1100 switches between the first timing chart 2100 and the second timing chart 2200 in accordance with the set values of the fan low speed ON control register 1110 and the fan high speed ON control register 1120.

  First, the first timing chart 2100 will be described. The power mode control signal 1501 is an output signal of the power mode control circuit 1500, and the vertical axis represents the logic level and the horizontal axis represents time. The timer output signal 1301 is an output signal of the timer circuit 1300, and the vertical axis represents the logic level and the horizontal axis represents time. In the fan low speed ON control register 1110, the vertical axis represents a set value and the horizontal axis represents time. In the fan high-speed ON control register 1120, the vertical axis represents a set value and the horizontal axis represents time. In the waveform of the fan drive voltage 1600, the vertical axis represents voltage and the horizontal axis represents time.

  In the first timing chart 2100, when the CPU can operate before the time t0 (normal power mode), the setting value of the fan low speed ON control register 1110 is 1 (fan low speed rotation) and the fan high speed ON control register 1120 is set. The value is set to 0 (fan stop).

  The first timing chart 2100 will be described with time.

[Time t0 to t1]
The value of the power mode control signal 1501 is 0 (power saving mode), and main power sources such as the CPU 1700, the first fan power source 1610, and the second fan power source 1620 are not energized. The timer circuit 1300 is stopped, and the value of the timer output signal 1301 is 0 (timer stop). The setting value of the fan low speed ON control register 1110 is 1 (fan low speed rotation), and the setting value of the fan high speed ON control register 1120 is 0 (fan stop). Since the first fan power supply 1610 and the second fan power supply 1620 are cut off, the fan drive voltage 1600 is 0 V, and the fan 1000 is stopped.

[Time t1]
The value of the power mode control signal 1501 becomes 1 (normal power mode), and main power sources such as the CPU 1700, the first fan power source 1610, and the second fan power source 1620 are energized. The power mode control circuit 1500 notifies the timer circuit 1300 of the transition from the power saving mode to the normal power mode. The timer circuit 1300 starts timing and the value of the timer output signal 1301 becomes 1 (during timing). Here, as described with reference to FIG. 1, the value of the fan low-speed ON control signal 1411 becomes 0 and the value of the fan high-speed ON control signal 1421 becomes 1 by the logic circuit 1400. Accordingly, the first switch 1630 is turned off (non-conducting) and the second switch 1640 is turned on (conducting). The fan drive voltage 1600 is substantially equal to the second fan power supply 1620 (for example, 12V) and becomes a high voltage sufficient for starting the fan 1000, so that the fan 1000 rotates at high speed. That is, it is possible to prevent a start failure of the fan 1000 by providing a high voltage at the time of transition from the power saving mode to the normal power mode.

[Time t1 to t2]
Times t1 to t2 are times (for example, 1 second) measured by the timer circuit 1300. During this time, the value of the timer output signal 1301 is 1 (during timing).

[Time t2]
Time measurement of the timer circuit 1300 is completed, and the value of the timer output signal 1301 changes to 0 (timer stop). Here, as described with reference to FIG. 1, the value of the fan low-speed ON control signal 1411 becomes 1 and the value of the fan high-speed ON control signal 1421 becomes 0 by the logic circuit 1400. Accordingly, the first switch 1630 is turned on (conductive), and the second switch 1640 is turned off (non-conductive). The fan drive voltage 1600 is substantially equal to the first fan power supply 1610 (for example, 7V), and the fan 1000 rotates at a low speed.

[Time t3]
The value of the power mode control signal 1501 becomes 0 (power saving mode or power supply OFF mode), and main power supplies such as the CPU 1700, the first fan power supply 1610, and the second fan power supply 1620 are cut off. There is no change in the timer output signal 1301 and the set values of the fan low-speed ON control register 1110 and the fan high-speed ON control register 1120. The first fan power supply 1610 and the second fan power supply 1620 are cut off, the fan drive voltage 1600 becomes 0 V, and the fan 1000 stops.

  Next, the second timing chart 2200 will be described. Each vertical axis and each horizontal axis of the power mode control signal 1501, the timer output signal 1301, the fan low-speed ON control register 1110, the fan high-speed ON control register 1120, and the fan drive voltage 1600 are the same as those in the first timing chart. Represents.

  In the second timing chart 2200, when the CPU can operate before the time t0 (normal power mode), the setting value of the fan low-speed ON control register 1110 is 0 (fan stop), and the setting value of the fan high-speed ON control register 1120 Is set to 1 (fan high speed rotation).

    The second timing chart 2200 will be described with time.

[Time t0 to t1]
[Time t0] of the first timing chart 2100 except that the setting value of the fan low speed ON control register 1110 is 0 (fan stop) and the setting value of the fan high speed ON control register 1120 is 1 (fan high speed rotation). To t1]. Therefore, the fan 1000 is stopped.

[Time t1]
Similar to [time t1] in the first timing chart 2100, the value of the power mode control signal 1501 becomes 1 (normal power mode), and the main components such as the CPU 1700, the first fan power supply 1610, and the second fan power supply 1620 are displayed. The power is turned on. The power mode control circuit 1500 notifies the timer circuit 1300 of the transition from the power saving mode to the normal power mode, the timer circuit 1300 starts measuring time, and the value of the timer output signal 1301 becomes 1 (timed). Here, the value of the fan low-speed ON control signal 1411 becomes 0 and the value of the fan high-speed ON control signal 1421 becomes 1 by the logic circuit 1400. Accordingly, the first switch 1630 is turned off (non-conducting) and the second switch 1640 is turned on (conducting). The fan drive voltage 1600 is substantially equal to the second fan power supply 1620 (for example, 12V) and becomes a high voltage sufficient for starting the fan 1000, so that the fan 1000 rotates at high speed. That is, in the second timing chart 2200 as well, it is possible to provide a high voltage when shifting from the power saving mode to the normal power mode, and to prevent a start failure of the fan 1000.

[Time t1 to t2]
Similar to [Time t1 to t2] in the first timing chart 2100, the timer circuit 1300 is measuring time, and the value of the timer output signal 1301 remains 1 (timed).

[Time t2]
Similar to [Time t2] in the first timing chart 2100, the timer circuit 1300 completes timing, and the timer output signal 1301 changes to 0 (timer stop). Here, the logic circuit 1400 sets the value of the fan low-speed ON control signal 1411 to 0, the value of the fan high-speed ON control signal 1421 to 1, the first switch 1630 is OFF (non-conduction), and the second switch 1640 is ON. (Conduction). The fan drive voltage 1600 becomes substantially equal to the second fan power supply 1620 (for example, 12V), and the fan 1000 continues to rotate at a high speed.

[Time t3]
Similar to [time t3] in the first timing chart 2100, the value of the power mode control signal 1501 becomes 0 (power saving mode or power supply OFF mode), and the CPU 1700, the first fan power supply 1610, and the second fan power supply. Majors such as 1620 are blocked. There is no change in the timer output signal 1301 and the set values of the fan low-speed ON control register 1110 and the fan high-speed ON control register 1120. The first fan power supply 1610 and the second fan power supply 1620 are cut off, the fan drive voltage 1600 becomes 0 V, and the fan 1000 stops.

  Next, processing according to the first embodiment of the present invention will be described with reference to FIG. FIG. 3 is a flowchart for explaining processing of the fan control unit 1100 and the CPU 1700 according to the present embodiment. Steps S101 to S114 show processing of the fan control unit 1100, and steps S201 to S210 show processing of the CPU 1700.

  In step S101, the fan control unit 1100 determines whether or not to return from sleep. When the power mode control circuit 1500 receives a sleep return factor such as an operation of the power switch 1510, the fan control unit 1100 determines that the sleep is returned and proceeds to step S104. If the power mode control circuit 1500 does not receive the sleep recovery factor, it is determined that the sleep mode is not recovered, and the process proceeds to step S102.

  In step S <b> 102, the fan control unit 1100 determines whether the power supply is activated. A reset circuit 1750 monitors the activation of the power supply. If the power is not activated, the process returns to step S101. If the power is activated, the process proceeds to step S103.

  In step S103, the fan control unit 1100 initializes a flip-flop such as a register. When the power supply is activated, the reset circuit 1750 asserts the reset signal 1751 so that the register of the fan control unit 1100 becomes the initial value. After a certain time (for example, 100 ms) has elapsed, the reset is released by deasserting the reset signal 1751. Next, the process proceeds to step S104.

  In step S <b> 104, fan control unit 1100 starts measuring time by timer circuit 1300. During the time measurement of the timer circuit 1300, the timer output signal 1301 becomes 1 (time measurement). The fan control unit 1100 starts the fan and rotates it at high speed. As described with reference to FIG. 1, the logic circuit 1400 rotates the fan at high speed while the timer circuit 1300 counts time. Step S104 corresponds to time t1 in FIG.

  Next, in step S105, the fan control unit 1100 determines whether or not the timer circuit 1300 has completed timing. The timer circuit 1300 counts a certain time (for example, 1 second). The determination process in step S105 is repeated until the timer circuit 1300 finishes timing. When the timer circuit 1300 finishes counting, the process proceeds to step S106. The time until the timing of the timer circuit 1300 is completed corresponds to the times t1 to t2 in FIG. 2, and the time when the timing of the timer circuit 1300 is completed corresponds to t2 in FIG.

  Next, in step S106, the fan control unit 1100 determines whether or not the register is set for high-speed rotation. If the logic circuit 1400 determines that the value of the fan low speed ON control register 1110 is 0 (fan stop) and the value of the fan high speed ON control register 1120 is 1 (fan high speed rotation), the process proceeds to step S107. On the other hand, when the logic circuit 1400 determines that the value of the fan low speed ON control register 1110 is 1 (fan low speed rotation) and the value of the fan high speed ON control register 1120 is 0 (fan stop), the process proceeds to step S108.

  In step S107, the fan control unit 1100 rotates the fan at a high speed. Based on the setting values of the fan low-speed ON control register 1110 and the fan high-speed ON control register 1120, the logic circuit 1400, the first switch 1630, and the second switch 1640 rotate the fan at high speed.

  In step S108, the fan control unit 1100 rotates the fan at a low speed. Based on the setting values of the fan low-speed ON control register 1110 and the fan high-speed ON control register 1120, the logic circuit 1400, the first switch 1630, and the second switch 1640 rotate the fan at a low speed.

  Next, in step S109, the fan control unit 1100 determines whether the register is set to stop the fan. If the values of both the fan low-speed ON control register 1110 and the fan high-speed ON control register 1120 are set to 0 (fan stop), the logic circuit 1400 determines that the fan stop register is set, and proceeds to step S111. Otherwise, the process proceeds to step S110.

  If the setting of the register is not a fan stop, in step S110, the fan control unit 1100 determines whether to turn off the power or shift to sleep. When the logic circuit 1400 detects that the CPU 1700 has turned off the first fan power supply 1610 and the second fan power supply 1620 (power supply OFF or sleep transition), the process proceeds to step S114, and the fan control unit 1100 stops the fan. . The logic circuit 1400 turns off the first switch 1630 and the second switch 1640 and stops the fan. The stop of the fan in step S114 corresponds to time t3 in FIG. On the other hand, if not detected, the process returns to step S106.

  If the setting of the register is fan stop, the fan control unit 1100 stops the fan in step S111. The logic circuit 1400 turns off the first switch 1630 and the second switch 1640 and stops the fan.

  Next, in step S112, the fan control unit 1100 determines whether or not the register setting is changed from fan stop to fan rotation. If the fan ON detection circuit 1200 detects that either the fan low speed ON control register 1110 or the fan high speed ON control register 1120 is changed from 0 (fan stop) to 1 (fan rotation), the process proceeds to step S104. On the other hand, if no register setting change is detected, the process proceeds to step S113.

  Next, in step S113, the fan control unit 1100 determines whether to power off or shift to sleep. Since this process is the same process as step S110 described above, detailed description thereof is omitted. When the power is turned off or the sleep mode is shifted to, the process proceeds to step S114, and the fan control unit 1100 stops the fan. On the other hand, when neither the power OFF nor the sleep transition is made, the process returns to step S112.

  Subsequently, the operation of the CPU 1700 will be described with reference to FIG.

  In step S201, the CPU 1700 waits until the power of the CPU 1700 is turned on. When the power of CPU 1700 is turned on, the process proceeds to step S202.

  In step S202, the CPU 1700 starts up an OS (Operation System). For example, the CPU 1700 reads the OS from the ROM 1900 in FIG. 1 and performs startup processing such as hardware initialization.

  Next, in step S203, the CPU 1700 changes the rotational speed of the fan. The CPU 1700 rewrites the fan low-speed ON control register 1110 and the fan high-speed ON control register 1120 as necessary. For example, the CPU 1700 reads the temperature from a temperature sensor (not shown), and if the temperature is higher than a certain level, writes 0 (fan stop) to the fan low speed ON control register 1110 and 1 (fan high speed rotation) to the fan high speed ON control register 1120. Then, in step S106, fan control unit 1100 determines that the register is set for high-speed rotation, and in step S107, fan 1000 rotates at high speed. Further, for example, the CPU 1700 reads the temperature from a temperature sensor (not shown), and if the temperature is lower than a certain level, 1 (fan low speed rotation) in the fan low speed ON control register 1110 and 0 (fan stop) in the fan high speed ON control register 1120. Write. Then, in step S106, fan control unit 1100 determines that the register is set for low-speed rotation, and in step S108, fan 1000 rotates at low speed.

  Next, in step S204, the CPU 1700 determines whether to turn off the power. For example, when a shutdown operation is performed by the user, it is determined that the power is off, and the process proceeds to step S205. On the other hand, if it is not determined that the power is off, the process proceeds to step S206.

  If it is determined that the power is off, in step S205, the CPU 1700 turns off the power. For example, the CPU 1700 performs OS shutdown processing and turns off various power sources.

  If it is not determined that the power is off, in step S206, the CPU 1700 determines whether or not to shift to sleep. For example, if no operation is performed by the user for a certain period of time, it is determined to shift to sleep and the process proceeds to step S207. If it is not determined to go to sleep, the process returns to step S203.

  In the case of shifting to sleep, in step S207, the CPU 1700 performs OS sleep shifting processing. For example, the CPU 1700 copies the contents of the register to the RAM 1800 or turns off the main power supply. Thereafter, the process proceeds to step S208.

  In step S208, CPU 1700 waits for the return from sleep. When returning from sleep, the process proceeds to step S209.

  In step S209, the CPU 1700 returns from sleep. For example, the CPU 1700 reads the OS from the ROM 1900 in FIG. 1, reads the register setting value from the RAM 1800, and performs processing such as hardware initialization.

  As described above with reference to FIGS. 1 to 3, the fan control unit 1100 in FIG. 1 uses the minimum drive voltage of the fan in [time t1 to t2] in FIG. 2 and steps S104 to S107 in FIG. However, by applying a sufficiently high voltage, the fan can be started reliably.

  Further, the fan control unit 1100 in FIG. 1 switches the fan speed after starting the fan to low speed rotation or high speed rotation in accordance with the register setting in [time t2 to t3] in FIG. 2 and steps S106 to S108 in FIG. it can.

  As described above, even if the CPU tries to start the fan at a low speed, the fan is started at a high voltage at a high speed, so that it is possible to reduce the fan starting failure. Further, it is not necessary to control whether the CPU starts the fan and control the rotation speed, so that the CPU load can be reduced.

(Second Embodiment)
FIG. 4 is a block diagram showing a configuration example of an MFP system according to the second embodiment of the present invention. A configuration example of the MFP system according to the present embodiment will be described with reference to FIG.

  The MFP 3100 operates as a printer, a copy, a scanner, and the like. A computer 3900 such as a personal computer is connected to the MFP 3100, transmits image data such as print data to the MFP 3100, and receives image data such as scan data from the MFP 3100. A communication path 3901 such as a LAN, USB, or wireless LAN connects the MFP 3100 and the computer 3900.

  The MFP 3100 includes a controller 3200 that controls the MFP 3100, a power source 3400, a scanner 3600, a printer 3700, and an operation unit 3800. The MFP 3100 includes fans 3500 and 3540 that cool the controller 3200, a fan 3510 that cools the power supply 3400, a fan 3530 that cools the scanner 3600, and a fan 3520 that cools the printer 3700. The MFP 3100 is a device that can control a plurality of fans 3500, 3510, 3520, 3530, and 3540.

  A power supply 3400 is connected to an outlet and generates a voltage to be supplied to the MFP 3100. Each power source such as a CPU power source supplied from the power source 3400, a power source of the power management unit 4000, and a fan power source (for example, 12V, 7V) can be switched ON / OFF. CPU power is supplied from a power source 3400 via a power line 3401. Power for the power management unit 4000 is supplied from the power source 3400 via the power line 3402. The power supply 3400 also supplies power to each component of the controller 3200.

  The scanner 3600 generates image data by scanning an image printed on a medium such as paper. The printer 3700 prints an image or the like on a medium such as paper. The operation unit 3800 includes a display function such as liquid crystal and an input function such as a touch panel and a keyboard.

  Next, the inside of the controller 3200 according to the present embodiment will be described. The CPU 3210 controls each component of the controller 3200 by executing programs stored in the RAM 3220, the ROM 3230, and the auxiliary storage device 3240. The CPU 3210 includes a temperature sensor 3211 for detecting the temperature of the CPU 3210. The RAM 3220 is a rewritable memory, and temporarily stores programs and data of the CPU 3210. The ROM 3230 stores programs and data that operate on the CPU 3210. The auxiliary storage device 3240 is a storage device such as a hard disk drive (HDD) and stores a large amount of programs and data. A scanner I / F (interface) 3250 connects the controller 3200 and the scanner 3600. A printer I / F 3260 connects the controller 3200 and the printer 3700. The operation unit I / F 3270 generates an image to be displayed on the operation unit 3800 and connects the controller 3200 and the operation unit 3800. The external I / F 3208 connects the controller 3200 and the computer 3900 via the communication path 3901. The power management unit 4000 controls the power supply 3400 and the fans 3500, 3510, 3520, 3530, and 3540. A bus 3290 connects each component in the controller 3200.

  Next, the inside of the power management unit 4000 according to the present embodiment will be described. The power control unit 4100 controls the ON / OFF state of the power source 3400. The fan control unit 4200 controls stop / rotation, rotation speed, and the like of the fans 3500, 3510, 3520, 3530, and 3540. A configuration example of the power management unit 4000 will be described later with reference to FIG.

  Next, a configuration example of the fan according to the present embodiment will be described. The CPU fan 3500 is connected to the fan control unit 4200 via the bus 3501. The bus 3501 transmits, for example, a fan drive voltage for driving the fan and a fan lock detection signal for detecting stop or rotation of the fan. Similarly, the power supply fan 3510 is connected to the fan controller 4200 via the bus 3511, the scanner fan 3520 bus 3521, and the printer fan 3530 via the bus 3531 via the auxiliary storage device fan 3540 bus 3541. The Driving voltages of the fans 3500, 3510, 3520, 3530, and 3540 are supplied from the power supply 3400 via the power management unit 4000.

  Next, a configuration example of the power management unit 4000 according to the present embodiment will be described with reference to FIG. FIG. 5 is a block diagram illustrating a configuration example of the power management unit 4000 of FIG. Here, the power management unit 4000 will be described as being connected to the power source 3400 and the fan 3500 for easy understanding.

  The power management unit 4000 includes a power supply control unit 4100 and a fan control unit 4200. The power management unit 4000 supplies power to the fan 3500 for high speed rotation and low speed rotation. When the voltage of the fan drive voltage 4271 is high (for example, 12V), the fan 3500 rotates at a high speed. When the voltage of the fan drive voltage 4271 is low (for example, 7V), the fan 3500 rotates at a low speed. When the fan drive voltage 4271 is not supplied (for example, 0 V), the fan 3500 stops. The fan lock detection signal 4281 is output from the fan 3500 to the power management unit 4000 in order to detect stop or rotation of the fan.

  Next, the configuration of the power control unit 4100 will be described. The power control unit 4100 includes a power mode control register 4110, a power saving mode transition detection circuit 4120, a power activation detection circuit 4130, and a normal power mode return detection circuit 4140.

  The power mode control register 4110 is read and written from the CPU 3210 of FIG. 4 via the bus 3290, and indicates a power saving mode or a normal power mode (for example, a value 1 in the power saving mode, a value in the normal power mode). 0) is set. The value set in the power mode control register 4110 is output as it is as the power control signal 4111 and supplied to the power source 3400. The power source 3400 switches on / off of each power source such as a CPU power source, a power source of the power management unit 4000, and a fan power source (for example, 12V, 7V) in accordance with a power control signal 4111.

  The power saving mode transition detection circuit 4120 detects a transition from the normal power mode to the power saving mode, and outputs a value 1 as a signal 4121 when shifting from the normal power mode to the power saving mode, and a value 0 otherwise. Output. The signal 4121 is supplied to a first timer 4230 described later.

  The power supply activation detection circuit 4130 detects the activation of the power supply 3400, outputs a value 1 as a signal 4131 when the power supply is activated, and outputs a value 0 otherwise. The signal 4131 is supplied to a fan ON control register 4210 and a fan speed control register 4220 described later.

  The normal power mode return detection circuit 4140 detects a return from the power saving mode to the normal power mode, and outputs a value 1 as a signal 4141 when returning from the power saving mode to the normal power mode, and a value 0 otherwise. Output. The signal 4141 is supplied to a fan ON control register 4210 and a fan speed control register 4220 described later.

  Next, the configuration of the fan control unit 4200 will be described. The fan control unit 4200 includes a fan ON control register 4210 and a fan speed control register 4220. The fan control unit 4200 includes a first timer 4230, a fan ON detection circuit 4240, a second timer 4250, a logic circuit 4260, a switch 4270, and a fan lock detection register 4280.

  The fan ON control register 4210 is read and written from the CPU 3210 via the bus 3290, and a value indicating whether the fan is rotated (ON) or stopped (OFF) is set. The set value is output as a signal 4211 to the logic circuit 4260 and is output as a signal 4212 to the fan ON detection circuit 4240. When the value 0 is set in the fan ON control register 4210, the fan is stopped, and when the value 1 is set, the fan is rotated. When the value of the signal 4131 received from the power activation detection circuit 4130 is 1 (power activation), or when the value of the signal 4141 received from the normal power mode recovery detection circuit 4140 is 1 (normal power mode recovery), A value 1 is set in the fan ON control register 4210.

  The fan speed control register 4220 is read from and written to by the CPU 3210 via the bus 3290, and a value indicating the rotational speed of the fan is set. For example, when the value 0 is set in the fan speed control register 4220, low speed rotation is indicated, and when the value 1 is set, high speed rotation is indicated. The value set in the fan speed control register 4220 is output to the logic circuit 4260 as a signal 4221. When the value of the signal 4131 received from the power activation detection circuit 4130 is 1 (power activation), or when the value of the signal 4141 received from the normal power mode recovery detection circuit 4140 is 1 (normal power mode recovery), A value of 1 is set in the fan speed control register 4220.

  When the first timer 4230 shifts from the normal power mode to the power saving mode, the first timer 4230 continues to rotate the fan for a certain time without being controlled by the CPU. For the sake of explanation, it is assumed that the first timer 4230 times 60 seconds. The first timer 4230 starts timing when the value of the signal 4211 supplied from the power saving mode transition detection circuit 4120 changes from 1 (fan rotation) to 0 (fan stop), and ends timing after 60 seconds. . The first timer 4230 outputs a value 1 as a signal 4231 during timing, outputs a value 0 at other times, and supplies it to the logic circuit 4260.

  When the fan ON detection circuit 4240 detects that the value of the signal 4212 supplied from the fan ON control register 4210 has been changed from 0 (fan stop) to 1 (fan rotation), the fan ON detection circuit 4240 pulses the value 1 as a signal 4241. Otherwise, 0 is output. The signal 4241 is output to a second timer 4250 described later.

  Second timer 4250 receives signal 4241 from fan ON detection circuit 4240. For the sake of explanation, the second timer 4250 counts 1 second. The second timer 4250 starts timing when the value of the signal 4241 supplied from the fan ON detection circuit 4240 is 1, and ends timing after 1 second. The second timer 4250 outputs a value 1 as a signal 4251 during the time measurement, and outputs a value 0 at other times and supplies the value 4 to the logic circuit 4260.

  The logic circuit 4260 switches between fan stop, high speed rotation, and low speed rotation. The logic circuit 4260 receives the signal 4211 from the fan ON control register 4210 and the signal 4221 from the fan speed control register 4220. In addition, the logic circuit 4260 receives the signal 4231 from the first timer 4230 and the signal 4251 from the second timer 4250. A signal 4261 output from the logic circuit 4260 indicates a high-speed rotation of the fan when the value is 1. A signal 4262 output from the logic circuit 4260 indicates a low-speed rotation when the value is 1. The values of the signal 4261 and the signal 4262 are not 1 at the same time. When the value of the signal 4251 supplied from the second timer 4250 is 1 (when the fan is stopped and changed to fan rotation), the value of the signal 4261 is 1 (fan high speed rotation) and the value of the signal 4262 is 0 ( It is not fan low speed rotation). When the value of the signal 4251 supplied from the second timer 4250 is 0, the values of the signal 4261 and the signal 4262 are determined by the signal 4221 supplied from the fan speed control register 4220. When the value of the signal 4231 from the first timer 4230 is 1 (transition to the power saving mode), even if the value of the fan ON control register 4210 is 0 (fan stop), the logic circuit 4260 causes the fan according to the signal 4221. Determine the rotation speed. Therefore, the fan can be rotated according to the set value of the fan speed control register 4220 while the second timer 4250 is measuring, without stopping the fan immediately even when shifting to the power saving mode. Since the inside of the logic circuit 4260 is the same as that of the logic circuit 1400 in FIG. 1, detailed description thereof is omitted.

  The switch 4270 switches the power supplied to the fan. When the value of the signal 4261 supplied from the logic circuit 4260 is 1 (fan high-speed rotation), the switch 4270 supplies a high voltage (VHIGH), for example, 12V as the fan drive voltage 4271. When the value of the signal 4262 supplied from the logic circuit 4260 is 1 (fan low speed rotation), the switch 4270 supplies a low voltage (VLOW), for example, 7 V, as the fan drive voltage 4271. When both the signal 4261 and the signal 4262 are 0, the switch 4270 supplies 0 V as the fan driving voltage 4271 to stop the fan. Since the switch 4270 is the same as the combination of the switch 1630 and the switch 1640 in FIG. 1, detailed description thereof is omitted.

  The fan lock detection signal 4281 is output from the fan 3500 to a fan lock detection register 4280 described later. The fan lock detection signal 4281 is a signal for outputting the state of the fan motor in order to detect whether the fan 3500 is rotating or stopped. Here, description will be made assuming that the fan lock detection signal 4281 has a value of 0 when the fan is rotating and a value of 1 when the fan is stopped.

  The fan lock detection register 4280 latches the fan lock detection signal 4281 so that the CPU 3210 reads the fan lock detection signal 4281.

  Next, with reference to FIGS. 6 and 7, the operation of the power management unit 4000 according to the second embodiment of the present invention will be described. 6 and 7 are timing charts for explaining the operation of the power management unit 4000 according to the second embodiment of the present invention. 6 and 7 differ in the set value of the fan speed control register 4220. 6 and 7, the horizontal axis represents time, and the vertical axis represents the voltage of each signal.

  First, the timing chart of FIG. 6 will be described with time.

[Time T0 to T1]
The MFP 3100 is in a power OFF mode. Since the power supply line 3402 of the power management unit 4000 and the power supply line 3401 of the CPU are OFF, the power management unit 4000 and the CPU 3210 do not operate. The fan drive voltage 4271 becomes 0V, and the fan 3500 is stopped.

[Time T1 to T2]
The MFP 3100 is turned on and shifts from the power-off mode to the normal power mode. Since the power supply line 3402 of the power management unit and the power supply line 3401 of the CPU are on, the power management unit 4000 and the CPU 3210 start operating. Here, since the CPU is in the process of starting up the OS and application, the settings of the fan ON control register 4210 and the fan speed control register 4220 cannot be changed.

  The fan ON control register 4210 and the fan speed control register 4220 are initial values after reset release. For example, the value of the fan ON control register 4210 is 1 (fan ON), and the value of the fan speed control register 4220 is 0 (fan high speed). Rotation).

  When the power activation detection circuit 4130 detects the activation of the power, the second timer 4250 outputs a value 1 and starts timing. Meanwhile, the fan 3500 rotates at a high speed. As described with reference to FIG. 5, the fan drive voltage 4271 becomes a high voltage (for example, 12 V) in order to rotate the fan 3500 at a high speed, so that the fan 3500 can be reliably started.

  The second timer 4250 stops timing and outputs a value of 0 after a certain time (for example, 1 second) has elapsed. (Time T2)

[Time T2 to T3]
The MFP 3100 is in the normal power mode in which the OS and applications have been activated, and the CPU can control the fan. Here, the CPU controls the fan ON control register 4210 to confirm that the fan 3500 can be controlled.

  During fan lock detection, the value in fan speed control register 4220 is set to zero. The fan 3500 repeats high-speed rotation and stop, and the CPU detects lock.

  For example, the CPU sets a value 1 (fan rotation) in the fan ON control register 4210, rotates the fan, and the CPU confirms that the value of the fan lock detection register 4280 in FIG. 4 is 0 (fan rotation). .

  Next, the CPU sets a value 0 (fan stop) in the fan ON control register 4210 to stop the fan, and the CPU confirms that the value of the fan lock detection register 4280 in FIG. 5 is 1 (fan stop). To do.

  This is repeated several times to confirm that the CPU can control the fan 3500.

[Time T3 to T4]
MFP 3100 is in the normal power mode, and the CPU can control the fan. The MFP 3100 receives a job and operates. The fan 3500 rotates at a high speed according to the value of the fan speed control register 4220.

  For example, the MFP 3100 receives a print job from the computer 3900 in FIG. 4 and performs a printing operation. At this time, the load on the CPU 3210 increases and the amount of heat generated by the CPU 3210 increases, so the CPU 3210 is cooled by rotating the fan at a high speed.

[Time T4 to T5]
The MFP 3100 shifts from the normal power mode to the power saving mode. When the CPU 3210 writes the value 1 to the power mode control register 4110 at time T4, a part of the power source 3400 is turned off, and the MFP 3100 shifts to the power saving mode. When the power saving mode transition detection circuit 4120 detects the transition to the power saving mode, the value of the signal 4121 becomes 1.

  Since the OS and the application perform the transition process to the power saving mode, the CPU cannot control the register during the time T4 to T5. The fan 3500 rotates at a high speed according to the value of the fan speed control register 4220.

[Time T5 to T6]
The MFP 3100 is in the power saving mode. Since the power supply line 3402 of the power management unit 4000 is ON, the register setting value in the power management unit 4000 is held. Since the CPU power supply line 3401 is OFF, the CPU 3210 cannot operate.

  As described with reference to FIG. 5, the fan continues to rotate for a certain time (for example, 60 seconds) by the first timer 4230 without control by the CPU. At this time, the fan 3500 rotates at a high speed according to the value of the fan speed control register 4220.

[Time T6 to T7]
The MFP 3100 is in the power saving mode. Since the power supply line 3402 of the power management unit 4000 is ON, the register setting value in the power management unit 4000 is held. Since the CPU power supply line 3401 is OFF, the CPU 3210 cannot operate.

  At time T6, the timing of the first timer 4230 ends, so the fan stops.

[Time T7 to T9]
The MFP 3100 shifts from the power saving mode to the normal power mode.

  At time T7, the MFP 3100 detects a factor for shifting from the power saving mode to the normal power mode, such as when the power button of the operation unit 3800 is pressed or the external I / F 3208 receives a print job or the like. When a transition factor is detected, the value of the power mode control register 4110 becomes 0 (normal power mode), the value of the power control signal 4111 becomes 0, and power is supplied from the power source 3400 to each part of the MFP 3100. . Thereafter, each register of the MFP 3100 is reset and returns to the normal power mode. The CPU cannot control the register while the OS and the application perform the transition process to the normal power mode, that is, until the OS and the application return to the normal power mode (between times T7 and T9).

  When the normal power mode return detection circuit 4140 detects the return from the power saving mode to the normal power mode, the second timer 4250 outputs a value 1 and starts measuring time. Meanwhile, the fan 3500 rotates at a high speed. As described with reference to FIG. 5, the fan drive voltage 4271 becomes a high voltage (for example, 12 V) in order to rotate the fan 3500 at a high speed, so that the fan 3500 can be reliably started.

  The second timer 4250 stops timing and outputs a value 0 after a certain time (for example, 1 second) has elapsed (time T8). Thereafter, the fan 3500 rotates at a high speed according to the value of the fan speed control register 4220.

[Time T8 to T9]
Subsequently, the MFP 3100 shifts from the power saving mode to the normal power mode. The CPU cannot control the register during the time T8 to T9, but the fan 3500 rotates at high speed according to the value set in the fan speed control register 4220 during the time T3 to T4.

[Time T9 to T10]
The MFP 3100 is in the normal power mode. Since it is the same as time T3-T4, description is abbreviate | omitted.

[Time T10 to T11]
The MFP 3100 shifts from the normal power mode to the power OFF mode. Since the fan control is the same as the transition process from the normal power mode to the power saving mode in the times T4 to T5, the description is omitted.

[Time T11 to T12]
The MFP 3100 is in a power OFF mode. Since it is the same as time T0-T1, description is abbreviate | omitted.

    Next, the timing chart of FIG. 7 will be described with time.

[Time T0 to T3]
Since it is the same as FIG. 6, description is abbreviate | omitted.

[Time T3 to T4]
MFP 3100 is in the normal power mode, and fan 3500 rotates at a low speed according to the value of fan speed control register 4220. Except that the fan 3500 is rotating at a low speed, it is the same as FIG. At this time, since the load on the CPU 3210 increases and the amount of heat generated by the CPU 3210 increases, the fan speed control register 4220 may be set to 0 to rotate the fan at high speed.

[Time T4 to T5]
The MFP 3100 shifts from the normal power mode to the power saving mode. Since the OS and the application perform the transition process to the power saving mode, the CPU cannot control the register. The fan 3500 rotates at a low speed according to the value of the fan speed control register 4220. Except that the fan 3500 is rotating at a low speed, it is the same as FIG.

[Time T5 to T6]
The MFP 3100 is in the power saving mode. By the first timer 4230, the fan continues to rotate for a certain time (for example, 60 seconds) without control by the CPU. At this time, the fan 3500 rotates at a low speed according to the value of the fan speed control register 4220. Except that the fan 3500 is rotating at a low speed, it is the same as FIG.

[Time T6 to T7]
The MFP 3100 is in the power saving mode. Except that the fan 3500 is rotating at a low speed, it is the same as FIG.

[Time T7 to T8]
The MFP 3100 shifts from the power saving mode to the normal power mode. At this time, the second timer 4250 causes the fan 3500 to rotate at a high speed as in FIG. After a certain time (for example, 1 second) has elapsed (time T8), the high-speed rotation of the fan 3500 by the second timer 4250 ends. Details of the processing are the same as in FIG.

[Time T8 to T9]
Subsequently, the MFP 3100 shifts from the power saving mode to the normal power mode. After the high-speed rotation of the fan 3500 by the second timer 4250, the fan 3500 rotates at a low speed according to the value set in the fan speed control register 4220 between the times T3 and T4. Except that the fan 3500 is rotating at a low speed, it is the same as FIG.

[Time T9 to T12]
Except that the fan 3500 is rotating at a low speed, it is the same as FIG.

  As described above with reference to FIGS. 4 to 7, the MFP 3100 according to the present embodiment reliably starts the fan by applying a voltage sufficiently higher than the minimum driving voltage of the fan when starting the fan. be able to. Further, even if the CPU tries to start the fan at a low speed, the MFP 3100 starts the fan at a high voltage at a high speed, so that the start failure of the fan can be reduced. Further, it is not necessary to control whether the CPU starts the fan and control the rotation speed, so that the CPU load can be reduced. In addition, after timing of the second timer 4250, the MFP 3100 can switch the rotation speed of the fan after starting the fan to low speed rotation or high speed rotation according to the set value of the fan speed control register 4220.

(Other embodiments)
The present invention is also realized by executing the following processing. That is, software (program) that realizes the functions of the above-described embodiments is supplied to a system or apparatus via a network or various storage media, and a computer (or CPU, MPU, or the like) of the system or apparatus reads the program. It is a process to be executed.

  As described above, according to the present invention, in an electronic device, by appropriately controlling the fan that cools the heat source, it is possible to reduce malfunctions and lifetime reduction due to thermal destruction.

Claims (7)

A device capable of controlling a cooling fan,
A first power supply for supplying power for rotating the cooling fan at a low speed;
A second power source that supplies a higher voltage power source than the first power source and rotates the cooling fan at a high speed;
A first register for setting whether or not the cooling fan is rotated at a low speed by the first power supply;
A second register for setting whether or not the cooling fan is rotated at a high speed by the second power source;
A detection circuit for detecting that one of the first and second registers is changed to a setting for rotating the fan;
A timer circuit that starts timing when the detection circuit detects a change in the setting of the first or second register;
A logic circuit for enabling the setting of the second register according to a signal output during timing from the timer circuit and rotating the cooling fan at a high speed with the power supplied from the second power supply;
A device characterized by comprising: A power mode control circuit for detecting that the power mode has been changed;
The apparatus according to claim 1, wherein the timer circuit starts timing when notified by the power mode control circuit that the power mode has transitioned from a power saving mode to a normal power mode. A device capable of controlling a cooling fan,
A first power source for rotating the cooling fan at a low speed;
A second power source that supplies a higher voltage power source than the first power source and rotates the cooling fan at a high speed;
A first register that sets whether to stop or rotate the cooling fan;
A second register for setting which of the first and second power sources the cooling fan is connected to;
A detection circuit for detecting that the first register has been changed to a setting for rotating the cooling fan;
A first timer circuit that starts timing when the detection circuit detects a change in the setting of the first register;
A logic circuit that rotates the cooling fan at a high speed with a power source supplied from the second power source in accordance with a signal output during timing from the first timer circuit;
A device characterized by comprising:   The apparatus further includes a power activation detection circuit that detects activation of the power supply of the device, and the power activation detection circuit notifies the first register when the power of the device is activated, and the first register is cooled. 4. The apparatus according to claim 3, wherein the fan is set to rotate.   A normal power mode return detection circuit that detects a return from the power saving mode to the normal power mode is further provided, and the normal power mode return detection circuit notifies the first register when the device returns to the normal power mode. 4. The apparatus according to claim 3, wherein the first register is set to rotate the cooling fan. A power saving mode transition detection circuit for detecting a transition from the normal power mode to the power saving mode;
A second timer circuit that starts timing when the power saving mode transition detection circuit detects a transition to the power saving mode;
The logic circuit rotates the cooling fan with the first or second power source according to the setting of the second register in accordance with a signal output during timing of the second timer circuit. The apparatus of claim 3. Determining whether a device equipped with a cooling fan has returned from sleep or powered up;
When it is determined that the device has returned from sleep or powered on, the timer circuit of the device starts timing and supplies power to rotate the cooling fan at high speed according to a signal output from the timer circuit during timing. Rotating the cooling fan at a high speed;
And a step of rotating the cooling fan according to a setting of a register for controlling a rotation speed of the cooling fan after the timer circuit completes timing.

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