JP2006318354A - Electronic apparatus and power supply controller - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize an electronic apparatus and a power supply controller capable of reducing heat generation in a power supply control circuit for reducing damage caused in the circuit and a device itself due to the heat. <P>SOLUTION: When the electronic apparatus 100 detects a difference between input electric power inputted to the power supply control circuit 1 and output electric power outputted from the power supply control circuit 1 and determines that the difference exceeds a predetermined threshold, processing for reducing heat generation in the power supply control circuit 1 is carried out. When the detected difference is above a cooling threshold, a cooling device 40 for cooling the power supply circuit 1 is operated. When the detected difference is above an output reducing threshold, power quantity of the output power outputted from the power supply control circuit 1 is lowered by a predetermined ratio. When it is determined that the detected difference is above an output stopping threshold, output of the output power from the power supply control circuit 1 is stopped. In this way, heat generation in the power supply control circuit 1 is reduced, and consequently, damage caused in the power supply circuit 1 and the electronic apparatus 100 due to heat generation can be reduced. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an electronic device and a power supply control device.

  2. Description of the Related Art Conventionally, there is known a power supply device that makes it possible to reduce the power consumption in the circuit by reducing the voltage difference between the input and output of the charge control circuit so as to reduce the amount of heat generated by the device. (For example, refer to Patent Document 1).

Also, in electronic devices that have a power supply control circuit that outputs power input from the power supply to a predetermined load section (for example, light emitting section, motor drive section, etc.) of the device, the temperature associated with the heat generated by the power supply control circuit is detected 2. Description of the Related Art Electronic devices that cool a power supply control circuit by operating a predetermined cooling device when a temperature sensor that detects a temperature higher than a threshold temperature is known.
JP 2004-252658 A

  However, in the case of the above-mentioned patent document 1, the power supply device can suppress the heat generation of the device by suppressing the power consumption of the charge control circuit to a small extent, but it is not possible to cool the device or circuit that has generated heat. Since this is not possible, various elements and devices constituting the circuit accumulate damage due to heat, and the elements and devices sometimes deteriorate.

  In addition, in the case of an electronic device provided with the cooling device, depending on the installation environment of the electronic device, the time until the temperature sensor detects a temperature increase accompanying the heat generation of the power supply control circuit may vary. And if it takes time for the temperature sensor to detect the temperature rise and the timing for cooling the power supply control circuit is delayed, damage to the various elements and devices in the circuit may accumulate during that time. there were.

  An object of the present invention is to provide an electronic device and a power supply control device that can suppress heat generation of a power supply control circuit and reduce damage to the circuit and the device itself accompanying the heat generation.

  In order to solve the above-described problems, the invention according to claim 1 is an electronic device in which power input from a power supply unit is output to a predetermined load unit of the device, and the power supply control circuit is cooled. A cooling device, input power detection means for detecting input power input to the power supply control circuit, output power detection means for detecting output power output from the power supply control circuit, and input power detection means The difference between the input power detected by the output power detection means and the output power detected by the output power detection means, and the difference between the input power detected by the power difference detection means and the output power is predetermined. A determination unit that determines whether or not a threshold value exceeds a threshold value, and the determination unit that operates the cooling device based on a determination that a difference between the input power and the output power exceeds a cooling threshold value. The power of the output power output from the power supply control circuit based on the fact that the difference between the input power and the output power is determined to exceed the output suppression threshold by the cooling device control means Output suppression control means for reducing the amount by a predetermined ratio, and when the judgment means judges that the difference between the input power and the output power exceeds the output stop threshold, the power supply control circuit Output stop control means for stopping the output of the output power.

  According to a second aspect of the present invention, in the power supply control device, a power supply control circuit that outputs power input from the power supply unit to a predetermined load unit, a cooling device for cooling the power supply control circuit, and the power supply control Input power detection means for detecting input power input to the circuit, output power detection means for detecting output power output from the power supply control circuit, input power detected by the input power detection means, and the output power A power difference detecting means for detecting a difference from the output power detected by the detecting means; and determining whether or not a difference between the input power and the output power detected by the power difference detecting means exceeds a predetermined threshold value. And determining that the difference between the input power and the output power exceeds a cooling threshold by the determining means and operating a cooling device for cooling the power supply control circuit. A cooling device controlling means, characterized in that it comprises a.

  According to a third aspect of the present invention, in the power supply control device according to the second aspect, the determination unit determines that a difference between the input power and the output power exceeds an output suppression threshold. Output suppression control means for reducing the amount of the output power output from the power supply control circuit by a predetermined percentage is provided.

  According to a fourth aspect of the present invention, in the power supply control device according to the second or third aspect, the determination means determines that the difference between the input power and the output power exceeds an output stop threshold. An output stop control means for stopping the output of the output power from the power supply control circuit is provided.

  According to the first aspect of the invention, the electronic device detects a difference (power difference) between the input power input to the power supply control circuit and the output power output from the power supply control circuit, and the difference is a predetermined threshold value. When it is determined that the value exceeds the value, processing for suppressing heat generation of the power supply control circuit can be performed.

  For example, when the electronic device determines that the detected difference exceeds a cooling threshold that is a predetermined threshold, the electronic device can activate a cooling device for cooling the power supply control circuit. In other words, when the difference between the input power and the output power (power difference), which becomes a heat generation factor in the power supply control circuit, exceeds a predetermined cooling threshold, the power supply control circuit is in a state of generating heat. Since the apparatus can cool the power supply control circuit, heat generation of the power supply control circuit can be suppressed, and damage to the power supply control circuit and electronic equipment due to the heat generation can be reduced.

  In addition, when the electronic device determines that the detected difference exceeds the output suppression threshold, which is a predetermined threshold, the amount of output power output from the power supply control circuit can be decreased by a predetermined ratio. That is, based on the fact that the difference between the input power and the output power (power difference), which becomes a heat generation factor in the power supply control circuit, exceeds a predetermined output suppression threshold, the power supply control circuit is in a state of generating heat. The amount of output power output from the power supply control circuit can be reduced. Then, as the output power is reduced, the input power is also reduced by the same rate, so that the difference (power difference) between the input power and the output power that is a heat generation factor is also reduced by the same rate. Since the difference (power difference) between the input power and the output power, which is a cause of heat generation, is reduced, heat generation of the power supply control circuit can be suppressed, and damage to the power supply control circuit and electronic equipment due to the heat generation can be reduced.

  Also, the electronic device can stop the output of the output power from the power supply control circuit when it is determined that the detected difference exceeds the output stop threshold that is a predetermined threshold. That is, based on the fact that the difference between the input power and output power (power difference), which becomes a heat generation factor in the power supply control circuit, exceeds a predetermined output stop threshold value, the power supply control circuit enters a state of generating heat. The output power output from the power supply control circuit can be stopped. Then, as the output power is stopped, the electronic device itself is stopped, so that the supply of power that causes heat generation is stopped. Since the power supply that causes this heat generation stops and the electronic equipment stops, heat generation of the power supply control circuit is suppressed, and damage to the power supply control circuit and electronic equipment due to the heat generation is reduced. Can do.

  In particular, this electronic device can execute a process for suppressing heat generation of the power supply control circuit and the electronic device based on the difference between the input power and the output power (power difference) that cause heat generation. Compared to performing heat generation suppression processing such as cooling after the temperature sensor detects actual heat generation, it is possible to perform heat generation suppression at an early stage. Thereby, damage to the power supply control circuit and the electronic device due to heat generation can be reduced.

  According to the invention of claim 2, the power supply control device detects a difference (power difference) between the input power input to the power supply control circuit and the output power output from the power supply control circuit, and the difference is a predetermined value. When it is determined that the cooling threshold, which is the threshold, is exceeded, a cooling device for cooling the power supply control circuit can be activated.

  In other words, when the difference between the input power and the output power (power difference), which becomes a heat generation factor in the power supply control circuit, exceeds a predetermined cooling threshold, the power supply control circuit is in a state of generating heat. Since the apparatus can cool the power supply control circuit, heat generation of the power supply control circuit can be suppressed, and damage to the power supply control circuit and the power supply control apparatus due to the heat generation can be reduced.

  In particular, this power supply control device can execute a process for suppressing heat generation of the power supply control circuit and the power supply control device based on the difference (power difference) between the input power and the output power that is a cause of heat generation. Compared with the case where the cooling process (heat generation suppression process) is performed after the temperature sensor detects actual heat generation, it is possible to execute the cooling response (heat generation suppression response) at an earlier stage. Thereby, damage to the power supply control circuit and the power supply control device due to heat generation can be reduced.

  According to the invention described in claim 3, it is needless to say that the same effect as that of the invention described in claim 2 can be obtained, and the power supply control device includes the input power input to the power supply control circuit and the power supply control circuit. When a difference (power difference) in output power output is detected and it is determined that the difference exceeds a predetermined threshold value for output suppression, the amount of output power output from the power supply control circuit is set to a predetermined value. The rate can be reduced.

  That is, based on the fact that the difference between the input power and the output power (power difference), which becomes a heat generation factor in the power supply control circuit, exceeds a predetermined output suppression threshold, the power supply control circuit is in a state of generating heat. The amount of output power output from the power supply control circuit can be reduced. Then, as the output power is reduced, the input power is also reduced by the same rate, so that the difference (power difference) between the input power and the output power that is a heat generation factor is also reduced by the same rate.

  Thus, since the difference between the input power and output power (power difference), which becomes a heat generation factor, decreases, heat generation of the power supply control circuit can be suppressed, and damage to the power supply control circuit and the power supply control device due to the heat generation can be reduced. it can.

  According to the invention described in claim 4, it is needless to say that the same effect as that of the invention described in claim 2 or 3 can be obtained, and the power supply control device includes the input power input to the power supply control circuit, and the power supply control. Detect output power difference (power difference) output from the circuit, and stop output power output from the power supply control circuit when it is determined that the difference exceeds a predetermined threshold for stopping output. Can do.

  That is, based on the fact that the difference between the input power and output power (power difference), which becomes a heat generation factor in the power supply control circuit, exceeds a predetermined output stop threshold value, the power supply control circuit enters a state of generating heat. The output power output from the power supply control circuit can be stopped. Then, as the output power is stopped, the power supply control device itself is stopped, so that the supply of power that is a cause of heat generation is stopped.

  In this way, the supply of power that causes heat generation is stopped and the power supply control device is stopped, so the heat generation of the power supply control circuit is suppressed, and the power supply control circuit and the power supply control device are damaged due to the heat generation. Can be reduced.

  Embodiments of an electronic device and a power supply control device according to the present invention will be described below in detail with reference to the drawings.

  FIG. 1 is a block diagram showing a main configuration of an electronic apparatus according to the present invention.

  As shown in FIG. 1, the electronic device 100 includes a control unit 10 serving as a power supply control device that controls each unit of the device, a power supply unit 20 that supplies power to each unit of the device, and power supplied from the power supply unit 20. The load part 30 which act | operates, the cooling device 40 for cooling the heat_generation | fever location of an apparatus, etc. are provided.

  The power supply unit 20 includes, for example, an AC power supply, a rectifier circuit, and the like, and outputs power supplied to each unit of the electric device 100 to the control unit 10.

  The load unit 30 includes a mechanism that operates by consuming electric power supplied from the power supply unit 20, and includes, for example, a light emitting unit including a lamp that outputs light, a motor driving mechanism that drives a motor, and the like.

  The cooling device 40 is a device for cooling a portion that generates heat in the device, and is, for example, a cooling fan that blows air to the heat generating portion to cool it. In particular, the cooling device 40 blows air to cool the power supply control circuit 1 that generates heat.

  In addition, since the cooling device 40 operates by consuming electric power supplied from the power supply unit 20, the cooling device 40 may be a part of the load unit 30.

  The control unit 10 includes, for example, a CPU 5 (see FIG. 2), and stores it in a ROM (not shown) according to an operation input signal input from an operation unit (not shown), preset setting data, or the like. The operation of each unit is centrally controlled in accordance with various control programs for electronic devices, and the processing results are stored in a work area in a RAM (not shown). And the control part 10 controls operation | movement of each part which comprises the electronic device 100. FIG.

Further, as shown in FIG. 2, the control unit 10 detects the power control circuit 1 that outputs the power input from the power supply unit 20 to the load unit 30 and the input power (Pin) input to the power control circuit 1. Input power detection means 2 that outputs power, output power detection means 3 that detects output power (Pout) output from the power supply control circuit 1, and the like.

  The power supply control circuit 1 is a circuit capable of adjusting and outputting the input power (Pin) input from the power supply unit 20 to the output power (Pout) corresponding to the amount of power consumed by the load unit 30.

  Here, heat generation of the power supply control circuit 1 will be described.

  When the efficiency of the power supply control circuit 1 is 96%, for example, when the input power (Pin) input from the power supply unit 20 to the power supply control circuit 1 is 230 W (watts), the power supply control circuit 1 transfers to the load unit 30. The output power (Pout) to be output is about 220W. That is, in order to set the output power (Pout) to 220 W, the input power (Pin) must be 230 W.

This is because when the power supply control circuit 1 adjusts the input power (Pin) as the stable output power (Pout), a loss of 4% occurs in the circuit.

The 10 W energy, which is the power difference (difference) between the input power (Pin) and the output power (Pout) and is 4% of the loss, is converted into heat in the circuit. That is, an element (device) in the power supply control circuit 1 generates heat due to the loss of power energy. Measures such as lowering the temperature by the cooling device 40 are taken so as not to damage the elements, circuits, and equipment itself due to this heat generation.

Note that the temperature of the element in the power supply control circuit 1 should be maintained at about 100 ° C. or less, which is the limit temperature of the substrate, and preferably kept at 80 ° C. or less.

  The input power detection means 2 and the output power detection means 3 are, for example, power detection devices having a sensor that can detect the amount of power.

Then, the input power detection means 2 detects the input power (Pin) input to the power supply control circuit 1 and sends data relating to the detected input power to the CPU 5. The output power detection means 3 detects the output power (Pout) output from the power supply control circuit 1 and sends data relating to the detected output power to the CPU 5.

  The CPU 5 functions as a power difference detection unit 5 a that detects a difference (Pin−Pout) between the input power (Pin) detected by the input power detection unit 2 and the output power (Pout) detected by the output power detection unit 3.

The CPU 5 functions as a determination unit that determines whether or not the difference between the input power and the output power detected by the CPU 5 as the power difference detection unit 5a (Pin−Pout) exceeds a power difference that is a predetermined threshold value. .

  Note that a power difference that is a predetermined threshold (a cooling threshold, an output suppression threshold, an output stop threshold, and the like, which will be described later) is stored and stored in a ROM (not shown).

Further, the CPU 5 as the determination means determines that the difference between the input power and the output power (Pin−Pout) exceeds a cooling threshold, for example, 20 W (in FIG. 2,
Arrow A) functions as cooling device control means 5b for operating the cooling device 40. The CPU 5 serving as the cooling device control unit 5b in the present embodiment is based on the fact that the determination unit (CPU 5) determines that the difference between the input power and the output power (Pin−Pout) is 20 W or more and less than 30 W. Control to operate the device 40 is performed.

The CPU 5 as the cooling device control means 5b is a cooling fan that is operating based on the fact that the CPU 5 as the determination means determines that the power difference (Pin−Pout) exceeds a cooling threshold (for example, 20 W). The cooling device 40 may be operated so as to increase the air volume, or the cooling device 40 may be operated so as to start the cooling fan that is stopped.

Further, the CPU 5 as the determination means determines that the difference between the input power and the output power (Pin−Pout) exceeds the output suppression threshold, for example, 30 W (FIG. 2).
Middle, arrow B), functions as output suppression control means for reducing the amount of output power (Pout) output from the power supply control circuit 1 by a predetermined rate (for example, 10%). The CPU 5 as the output suppression control means in this embodiment has a difference (Pin−Pout) between input power and output power of 30 W.
As described above, based on the determination unit (CPU 5) determining that the power is less than 40 W, control is performed to reduce the output power (Pout).

When the output power (Pout) is reduced in the power supply control circuit 1, the output power (
The input power (Pin) also decreases at the same rate as the decrease rate of (Pout).

Further, the CPU 5 as the determination means determines that the difference between the input power and the output power (Pin−Pout) exceeds the output stop threshold, for example, 40 W (FIG. 2).
Middle, arrow C) functions as an output stop control means for stopping the output of the output power (Pout) from the power supply control circuit 1.

The electronic device 100 includes an alarm unit (not shown) including a buzzer for notifying a temperature abnormality in the power supply control circuit 1 and a flashing light, and the CPU 5 serving as a determination unit determines the difference between the input power and the output power (Pin−Pout). Is determined to exceed a predetermined threshold (for example, output suppression threshold, 30 W), an alarm unit is activated to warn of temperature abnormality by sound or light output from the alarm unit.

  Next, processing for suppressing heat generation of the power supply control circuit 1 in the electronic device 100 will be described based on the flowchart shown in FIG.

  First, when a power switch in an operation unit (not shown) in the electronic device 100 is turned on, the electronic device 100 is activated, and the electronic device 100 performs a predetermined operation / drive (step S101).

Then, the input power detection means 2 detects the input power (Pin), the output power detection means 3 detects the output power (Pout), and sends data relating to the detected power to the CPU 5 (step S102).

  Next, the CPU 5 detects a power difference that is a difference (Pin−Pout) between the input power (Pin) and the output power (Pout) (step S103).

  Next, the CPU 5 determines whether or not the detected power difference exceeds 20 W, which is the cooling threshold, and is less than 30 W (step S104).

  When the CPU 5 determines that the detected power difference is 20 W or more and less than 30 W (step S104; Yes), the CPU 5 operates the cooling device 40 so as to increase the air volume of the cooling fan in order to cool the power supply control circuit 1. (Step S105), the process returns to Step S102.

  On the other hand, if the CPU 5 determines that the detected power difference is not 20 W or more and less than 30 W (step S104; No), the process proceeds to step S106.

  In step S106, the CPU 5 determines whether or not the detected power difference exceeds 30 W, which is an output suppression threshold, and is less than 40 W (step S106).

  When the CPU 5 determines that the detected power difference is 30 W or more and less than 40 W (step S106; Yes), the CPU 5 decreases the output power by 10% (step S107) and returns to step S102. When the power difference detected by the CPU 5 is 30 W or more, an alarm unit (not shown) outputs light, sound, or the like to warn that the temperature is abnormal.

  On the other hand, if the CPU 5 determines that the detected power difference is not 30 W or more and less than 40 W (step S106; No), the process proceeds to step S108.

  Here, a process in which the CPU 5 reduces the output power by 10% (step S107) will be described.

  If the input power is 230 W and the output power is 200 W, the power difference is 30 W. Therefore, the CPU 5 as the output suppression control means decreases the output power by 10% to 180 W. As the output power is reduced, the input power is also reduced by 10%, so the input power is 207 W. In accordance with the process of reducing the output power and the input power, the power difference after the output power and the input power are reduced by 10% becomes 207W−180W = 27W, and the power difference is also reduced by 10%. It will be. The power difference (27 W) reduced by 10% is in the range of 20 W or more and less than 30 W.

  In step S108, the CPU 5 determines whether or not the detected power difference has exceeded 40 W, which is an output stop threshold (step S108).

  If the CPU 5 determines that the detected power difference is not 40 W or more (step S108; No), the CPU 5 returns to step S102 assuming that the power difference is less than 20 W. At this time, the air flow of the cooling fan may be returned to the normal amount, or the output power (input power) may be returned to the initial value.

  On the other hand, when the CPU 5 determines that the detected power difference is 40 W or more (step S108; Yes), the CPU 5 stops the operation of the electronic device 100 by causing the power supply control circuit 1 to stop outputting the output power. (Step S109), the driving of the electronic device 100 is terminated.

As described above, the electronic device 100 according to the present invention has a power difference (Pin−) that is a difference between the input power (Pin) input to the power supply control circuit 1 and the output power (Pout) output from the power supply control circuit 1.
Pout) is detected, and when the power difference is equal to or greater than a predetermined threshold, it is possible to execute a process of suppressing the heat generation of the power supply control circuit 1, so that the power supply control circuit 1 and the electronic device 100 itself are at abnormally high temperatures. It is hard to become.

  Specifically, as a first step, the electronic device 100 operates the cooling fan that is the cooling device 40 when the power difference exceeds the cooling threshold of 20 W (the power difference is 20 W or more and less than 30 W). Then, the power supply control circuit 1 is blown with air to cool it.

  Then, the power supply control circuit 1 is cooled by the cooling device 40, whereby the heat generation of the power supply control circuit 1 and the heat generation of the electronic device 100 itself are suppressed.

  Further, as a second stage, the electronic device 100 reduces the output power (input power) by a predetermined amount when the power difference exceeds 30 W, which is an output suppression threshold (power difference is 30 W or more and less than 40 W). Reduce power difference, which is a heat generation factor.

  Then, the power difference that causes heat generation in the power supply control circuit 1 is reduced, so that heat generation in the power supply control circuit 1 and heat generation in the electronic device 100 itself can be suppressed.

  Further, as a third stage, the electronic device 100 causes the power supply control circuit 1 to stop outputting the output power and stop the operation of the electronic device 100 when the power difference exceeds the output stop threshold 40W. . When the power difference exceeds 40 W, which is the output stop threshold, the electronic device 100 is stopped so that it is determined that there is some abnormality in the power supply control circuit 1 or the like.

  Then, when the operation of the electronic device 100 is stopped, the supply of electric power, which is a heat generation factor, is stopped, and the heat generation of the power supply control circuit 1 and the heat generation of the electronic device 100 itself are suppressed.

  Thus, the electronic device 100 can suppress the heat generation of the power supply control circuit 1 and can reduce damage to the power supply control circuit 1 and the electronic device 100 due to the heat generation.

  In particular, the electronic device 100 can execute processing for suppressing the heat generation of the power supply control circuit 1 and the electronic device 100 based on the power difference that causes the heat generation, so that the temperature sensor detects the actual heat generation as in the past. Compared with the case where the cooling process is performed after that, it is possible to execute the cooling response at an early stage. As a result, the power supply control circuit 1, various elements provided in the power supply control circuit 1, and damage caused by heat generation of the electronic device 100 itself can be reduced.

  In the present embodiment, the heat generation suppression by the three steps of the first stage, the second stage, and the third stage is executed, but the order of the first stage, the second stage, and the third stage is any other order. Alternatively, the heat generation suppression in one step or two steps may be performed without performing all the heat generation suppression (three-step heat generation suppression).

  Further, when the detected power difference exceeds the output suppression threshold and when the output power (input power) is decreased by a predetermined amount, the cooling fan that is the cooling device 40 is operated, and the power supply control circuit 1 is turned on. Air cooling may be used.

  In the above embodiment, the electronic device 100 has not been described as adapted to a specific device or device, but the electronic device 100 can be adapted to various devices or devices. For example, when the electronic device 100 according to the present invention is applied to a projector, a light emitting unit such as a lamp corresponds to the load unit 30.

  The cooling device 40 is not limited to cooling only the power supply control circuit 1, and may operate so as to cool the vicinity of the power supply control circuit 1, the load unit 30, and the like.

  In the above embodiment, the power difference detection means, determination means, cooling device control means, output suppression control means, and output stop control means have been described as being controlled by the CPU 5, but the present invention is not limited to this. However, various control processes may be performed using a logic circuit.

  Moreover, the numerical values such as the power difference shown in the above embodiment are examples in this embodiment, and the present invention is not limited to this.

  In addition, it is needless to say that other specific detailed structures can be appropriately changed.

It is a block diagram which shows the principal part structure of the electronic device which concerns on this invention. It is explanatory drawing which shows the control part (power supply control apparatus) of an electronic device. It is a flowchart which shows an example of the emitted-heat amount suppression process of the electronic device which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Power supply control circuit 2 Input power detection means 3 Output power detection means 5 CPU (Power difference detection means, judgment means, cooling device control means, output suppression control means, output stop control means)
5a Power difference detection means 5b Cooling device control means 10 Control unit (power supply control device)
20 power supply unit 30 load unit 40 cooling device 100 electronic device

Claims (4)

A power supply control circuit that outputs power input from the power supply unit to a predetermined load unit of the device;
A cooling device for cooling the power supply control circuit;
Input power detection means for detecting input power input to the power control circuit;
Output power detection means for detecting output power output from the power supply control circuit;
A power difference detection means for detecting a difference between the input power detected by the input power detection means and the output power detected by the output power detection means;
Determination means for determining whether or not a difference between the input power and the output power detected by the power difference detection means exceeds a predetermined threshold;
A cooling device control means for operating the cooling device based on the determination that the difference between the input power and the output power exceeds a cooling threshold;
When the determination means determines that the difference between the input power and the output power exceeds an output suppression threshold, the power amount of the output power output from the power supply control circuit is decreased by a predetermined ratio. Output suppression control means;
An output stop control means for stopping the output of the output power from the power supply control circuit based on the determination that the difference between the input power and the output power exceeds the output stop threshold;
An electronic device comprising: A power control circuit that outputs power input from the power supply unit to a predetermined load unit;
Input power detection means for detecting input power input to the power control circuit;
Output power detection means for detecting output power output from the power supply control circuit;
A power difference detection means for detecting a difference between the input power detected by the input power detection means and the output power detected by the output power detection means;
Determination means for determining whether or not a difference between the input power and the output power detected by the power difference detection means exceeds a predetermined threshold;
A cooling device control means for operating a cooling device for cooling the power supply control circuit based on the fact that the difference between the input power and the output power is determined to exceed a cooling threshold by the determination means;
A power supply control device comprising:   When the determination means determines that the difference between the input power and the output power exceeds an output suppression threshold, the power amount of the output power output from the power supply control circuit is decreased by a predetermined ratio. The power supply control device according to claim 2, further comprising an output suppression control unit.   Output stop control means for stopping output of the output power from the power supply control circuit based on the fact that the determination means determines that the difference between the input power and the output power exceeds an output stop threshold. The power supply control device according to claim 2, wherein the power supply control device is a power supply control device.

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