JP2017059141A - Method for maintaining fan of electronic apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for maintaining the fan of an electronic apparatus, capable of preventing a deadlock occurring in the fan from being wrongly detected.SOLUTION: A method for maintaining the fan of an electronic apparatus comprises: exchanging one fan 21 with another fan in the state of rotating the remaining fans 21 except one of a plurality of fans 21 provided in an electronic apparatus 20; reducing each set rotation frequency of the plurality of fans 21; turning on the other fan 21; turning off the other fan 21 when the rotation frequency of the other fan 21 does not reach a preset threshold value rotation frequency Rt in a regular time tb; and turning on the other fan 21 again after waiting for only a predetermined time tc.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a method for maintaining a fan in an electronic device.

  Electronic devices such as servers are provided with fans for cooling internal electronic components. If there is only one fan, when the fan fails, the electronic component cannot be cooled, and the temperature of the electronic component may exceed the operation guarantee temperature.

  Therefore, the electronic device is provided with a plurality of fans, and even when any one of the fans fails, the electronic components can be cooled by continuing to rotate the remaining fans.

JP-A-9-275289 JP 20061655312 A

  By the way, when a plurality of fans are provided in the electronic device as described above, if the failed fan is removed from the electronic device for replacement, an air hole is formed in the removed electronic device. The wind generated by the remaining fans may leak out of the electronic device through the air holes.

  If a new fan is installed in a place where the wind is leaking in this way, the fan will reversely rotate due to the wind, and it will take a long time to reach the specified number of revolutions even if the fan is turned on .

  The fan may have a failure called deadlock in which the motor is seized when the rotation stops due to foreign matter or the like. A detection unit for detecting the deadlock is built in the fan, and if it takes a long time to reach the predetermined rotation speed as described above, the detection unit erroneously detects the occurrence of the deadlock. . If this happens, the detection unit stops the fan to ensure safety, and the fan cannot generate wind.

  The disclosed technique has been made in view of the above, and an object thereof is to provide a fan maintenance method in an electronic device that can prevent erroneous detection of a deadlock in a fan. To do.

  According to one aspect of the following disclosure, in a state where the remaining fans except for one of a plurality of fans provided in an electronic device are rotating, the one fan is replaced with another fan. The rotation speed of each of the plurality of fans is lowered, the power of the other fan is turned on, and after the power is turned on, the rotation speed of the other fan falls within a specified time within a predetermined threshold speed. If not, a fan maintenance method is provided in an electronic device in which the other fan is turned off, waits for a predetermined time and then turned on again.

  According to the following disclosure, it is possible to prevent erroneous detection of the occurrence of deadlock in the fan.

FIG. 1 is a plan view of the inside of the electronic device used for the study. FIG. 2 is a graph showing how the rotational speed of a new fan that has been changed changes with time. FIG. 3 is a perspective view of a fan that can prevent the wind from flowing backward. FIG. 4 is a perspective view of the electronic apparatus according to the present embodiment. FIG. 5 is a functional block diagram of the electronic device. FIG. 6 is a flowchart showing a fan maintenance method. FIG. 7 is a timing chart schematically showing a fan maintenance method. FIG. 8 is a graph for explaining the minimum value of the specified rotational speed Ra.

  Prior to the description of the present embodiment, items studied by the inventor will be described.

  FIG. 1 is a plan view of the inside of the electronic device used for the study.

  The electronic device 1 is a server, for example, and includes a housing 2 and a circuit board 4 accommodated therein. A plurality of electronic components 5 such as a CPU (Central Processing Unit) and a memory are mounted on the circuit board 4, and a plurality of fans 3 for cooling these electronic components 5 are provided on the front surface of the housing 2. .

  Each fan 3 is provided with a detection unit 3a for detecting that the aforementioned deadlock has occurred.

  In the example of FIG. 1, one of the four fans 3 indicated by a dotted line has failed, the one fan 3 is removed from the housing 2 for replacement, and the air hole 2a is vacant in the removed part. Assumes that

  In this case, the wind A generated by the remaining fans 3 flows backward to the outside of the housing 2 through the air holes 2a.

  In particular, when a plurality of electronic components 5 are mounted on the circuit board 4 with high density, it is difficult for the wind A to circulate inside the housing 2, so that the wind A flows backward through the air holes 2 a. It becomes easy. Further, when a high-performance fan with a large air volume is used as each fan 3, backflow is likely to occur.

  In this state, if the failed fan 3 is replaced with a new fan 3, there is a risk of erroneous detection that a deadlock has occurred in the new fan as follows.

  This will be described with reference to FIG.

  FIG. 2 is a graph showing how the rotational speed of a new fan 3 that has been replaced changes with time. The horizontal axis represents the elapsed time since the fan 3 was turned on, and the vertical axis represents The rotation speed of the fan 3 is shown.

  Although the fan 3 is provided with a motor (not shown), the negative rotation number indicates a reverse rotation state rotating in the opposite direction to the motor, and the positive rotation number is in the same direction as the motor. Represents a positive rotation state.

  Further, in FIG. 2, the graphs of the case where the wind is flowing backward as described above and the case where the wind is not flowing backward are shown together.

  Further, in this example, it is assumed that a new fan 3 is inserted into the housing 2 at time tr on the left side of the origin, and the new fan 3 is turned on at the origin. In FIG. 2, periods indicated by “ON” and “OFF” respectively indicate a period during which the power source of the fan 3 is ON and an OFF period.

  When the fan 3 is deadlocked, the rotation of the fan 3 is hindered by foreign matter or the like, so that the rotational speed does not increase easily even after a certain period of time has elapsed since the power was turned on.

  Therefore, in this example, the determination time tj and the threshold rotation speed R0 are determined in advance, and if the rotation speed does not reach the threshold rotation speed R0 within the determination time tj, it is determined that a deadlock has occurred in the fan 3. Otherwise, it is determined that no deadlock has occurred. This determination is performed by the detection unit 3a by monitoring the rotation speed of the fan 3 by the detection unit 3a (see FIG. 1).

  As shown in FIG. 2, when no reverse flow occurs, the rotational speed immediately increases when the power is turned on at the origin, and the rotational speed exceeds the threshold rotational speed R0 within the determination time tj. Therefore, in this case, the possibility of erroneous detection that a deadlock has occurred is low.

  On the other hand, when a reverse flow is generated, the fan 3 is reversely rotated by the reverse flow of the wind before turning on the power at the origin. Therefore, it takes a long time until the rotational speed reaches the threshold rotational speed R0 even when the power is turned on at the origin, and the rotational speed does not exceed the threshold rotational speed R0 even after the determination time tj has elapsed. Therefore, in this case, the detection unit 3a erroneously detects that the fan 3 is deadlocked.

  If it is erroneously detected that a deadlock has thus occurred, the detection unit 3a forcibly stops the fan 3 to ensure safety, and the fan 3 cannot generate wind.

  In order to avoid such an inconvenience, it is considered that the wind does not flow backward when the fan 3 is replaced.

  FIG. 3 is a perspective view of the fan 10 that can prevent the wind from flowing backward.

  The fan 10 includes a main body 12 including blades 11 and a plurality of flaps 13 provided at positions facing the blades 11. The flap 13 is opened by the wind pressure of the wind A when the wind A is generated by the blades 11 and closed by its own weight when the wind A is not present.

  When the fan 10 fails, only the main body 12 is replaced with a new one while the flap 13 is closed. According to this, since the flap 13 is closed at the time of replacement, the wind A does not flow backward as described above.

  However, in this structure, a depth D for providing the flap 13 is required, and it is difficult to reduce the size of the electronic device 1 (see FIG. 1).

  In order to narrow the depth D, it is conceivable to bring the flap 13 closer to the blade 11. However, since the wind A immediately after exiting the blades 11 is in a turbulent state, the lift of the flap 13 is not stable and the flap 13 flutters. Therefore, a certain depth D is required to prevent the flap 13 from fluttering.

  Hereinafter, this embodiment will be described.

(This embodiment)
FIG. 4 is a perspective view of the electronic apparatus according to the present embodiment.

  The electronic device 20 is, for example, a rack mount server, and a plurality of electronic devices 20 are accommodated in the rack 22. Each electronic device 20 is provided with a plurality of fans 21 for cooling an electronic component 23 such as a CPU provided therein.

  FIG. 5 is a functional block diagram of one electronic device 20.

  As shown in FIG. 5, the electronic device 20 includes a power supply unit 25, a control unit 26, and a fan 21. In FIG. 5, the electronic component 23 shown in FIG. 4 is omitted.

  In this example, by providing a plurality of fans 21 in one electronic device 20, even if any one of the fans 21 breaks down, the remaining fan 21 can generate wind A that cools the inside of the electronic device 20. To do. Below, each fan 21 is distinguished by attaching | subjecting code | symbol # 1, # 2, and # 3 to each of the fan 21. FIG.

  These fans 21 also output to the control unit 26 status signals IST # 1 to IST # 3 indicating whether or not the fans 21 are mounted on the electronic device 20.

  The method for generating the status signals IST # 1 to IST # 3 is not particularly limited. For example, when the fan 21 is mounted on the electronic device 20, the ground potential of the ground line of the electronic device 20 is output as the low level state signals IST # 1 to IST # 3. The signals IST # 1 to IST # 3 may be set to a high level.

  Further, the fan 21 outputs a rotation speed signal RT # 1 to RT # 3 indicating the actual rotation speed to the control unit 26.

  Further, the power supply unit 25 converts, for example, an AC voltage into a DC voltage and outputs the DC voltage to the power line 29. The power supply line 29 is connected to each fan 21 so that each fan 21 can receive power from the power supply unit 25.

  On the other hand, the control unit 26 outputs rotation speed control signals CT # 1 to CT # 3 including the set rotation speed of the fan 21 to the fan 21. The set rotational speed included in the rotational speed control signals CT # 1 to CT # 3 is a target value for the rotational speed of the fan 21, and each fan 21 rotates so as to be the set rotational speed.

  Further, the control unit 26 outputs power control signals TC # 1 to TC # 3 to the switches SW1 to SW3. The switches SW1 to SW3 are provided on a power supply line 29 between the power supply unit 25 and each fan 21, and TC # 1 to TC # 3 are control signals for controlling on / off of these switches SW1 to SW3.

  For example, when the switch SW1 is turned on by the power control signal TC # 1, the power of the power supply unit 25 is supplied to the fan 21 of # 1, the fan 21 is turned on, and the fan 21 rotates. On the contrary, when the switch SW1 is turned off by the power control signal TC # 1, the fan 21 is turned off. The same applies to the fans 21 of # 2 and # 3.

  Further, the control unit 26 is provided with a timer A and a timer B. The functions of these timers will be described later.

  Each of the plurality of fans 21 is provided with a detection unit 21a that detects whether or not a deadlock has occurred in the fans 21.

  The method for detecting the deadlock by the detection unit 21a is the same as described in FIG. For example, the detection unit 21a determines that a deadlock has occurred in the fan 21 when the actual rotational speed of the fan 21 does not reach the threshold rotational speed R0 within the determination time tj after the power of the fan 21 is turned on. Otherwise, it is determined that no deadlock has occurred.

  In this example, the set rotational speed included in the rotational speed control signals CT # 1 to CT # 3 is used as the threshold rotational speed R0 used for deadlock determination. For example, if the actual rotation speed of the # 1 fan 21 does not reach the set rotation speed within the determination time tj, the detection unit 21a determines that a deadlock has occurred in the # 1 fan 21.

  The threshold rotation speed R0 is not limited to this, and the threshold rotation speed R0 may be set to be equal to or less than the set rotation speed.

  Next, a fan maintenance method capable of preventing the detection unit 21a from erroneously detecting deadlock when the fan 21 is replaced with another fan will be described.

  FIG. 6 is a flowchart showing a maintenance method for the fan 21.

  In the example of FIG. 6, it is assumed that the fan 21 of # 3 is replaced with another fan 21 while the fans 21 of # 1 and # 2 are rotating. Thus, the operation | work which replaces | exchanges the fan 21 without stopping rotation of the other fan 21 is also called active replacement | exchange.

  As shown in FIG. 6, each step is roughly divided into processing A to processing D.

  Among these, the process A is a preliminary process, and the process B is a process for monitoring whether or not there is a high possibility of deadlock. The process C is a process for stopping the monitoring of deadlock, and the process D is a post process.

  FIG. 7 is a timing chart schematically showing a maintenance method of the fan 21. The rotation speed signals RT # 1 to RT # 3, the rotation speed control signals CT # 1 to CT # 3, and the status signal IST are described above. The time changes of # 1 to IST # 3 and power control signals TC # 1 to TC # 3 are shown. Further, FIG. 7 also shows processes A to D in FIG.

  First, processing A in FIG. 6 will be described.

  First, in step S1, the control unit 26 determines whether or not the # 3 fan 21 is replaced with another fan 21 and the other fan 21 is mounted on the electronic device 20. The control unit 26 may determine that the state signal IST # 3 has been exchanged (YES) when the state signal IST # 3 is at a low level, and determine that it has not been exchanged (NO) when the state signal IST # 3 has a high level.

  If it is determined that no replacement has been made (NO), the process ends.

  On the other hand, if it is determined that the replacement has been made (YES), the process proceeds to step S2.

  In step S2, the control unit 26 starts the timer A described above. The timer A counts the time limit ta from the time point tr when the # 3 fan 21 is replaced with another fan in step S1. The significance of the time limit ta will be described later.

  As shown in FIG. 7, the remaining # 1 and # 2 fans 21 that are not to be replaced are rotating at the normal rotation speed at this time tr, and the rotation speed control signal CT # 1 of those fans 21 is rotated. The set rotation speed included in CT # 2 is Rb.

  At this time tr, TC # 3 is in an off state, and the power of the replaced fan 21 of # 3 is not turned on.

  Next, the process proceeds to step S3, and the set rotational speeds included in all the rotational speed control signals CT # 1 to CT # 3 are lowered to a specified rotational speed Ra smaller than the above Rb.

  As a result, the air volume of the wind A generated by the # 1 and # 2 fans 21 that are not to be replaced is weakened. Therefore, even if the replaced # 3 fan 21 is reversely rotated by the wind A, the reverse rotation The number of rotations can be reduced.

  In addition, as described above, the threshold rotational speed R0 for the detection unit 21a to determine the presence or absence of deadlock is set to be equal to or lower than the set rotational speed, so that the threshold rotational speed R0 is also defined by reducing the set rotational speed as described above. The rotational speed Ra is reduced below. As a result, the determination by the detection unit 21a is relaxed, and the possibility that a deadlock is erroneously detected by the detection unit 21a is reduced.

  If the specified rotational speed Ra is too low, the electronic component 23 (see FIG. 4) such as a CPU in the electronic device 20 may be insufficiently cooled. Therefore, it is preferable to provide a minimum value for the specified rotational speed Ra to prevent the electronic component 23 from being insufficiently cooled.

  FIG. 8 is a graph for explaining the minimum value of the specified rotational speed Ra.

  This graph is a graph showing the relationship between the elapsed time from when the set rotational speed of the fan 21 is lowered and the temperature of the electronic component 23 (CPU temperature).

  In this example, it is assumed that the CPU temperature is Tx ° C. at the time of 0 seconds, and the set rotational speed of the fan 21 is decreased from that time.

  As shown in the graph, the CPU temperature rises with the lapse of time by reducing the rotational speed of the fan 21.

An operation guarantee temperature Tj _max is set for the CPU, and it is preferable to determine the specified rotational speed Ra of the fan 21 so as not to exceed this. In the example of FIG. 8, _assuming that the rotation speed is R _lm , the CPU temperature does not exceed the guaranteed operating temperature Tj _max even if the CPU temperature reaches a steady state after a lapse of time. Therefore, by setting the rotation speed R _lm to the minimum value of the specified rotation speed Ra (R _lm ≦ Ra), it is possible to prevent the CPU temperature from exceeding the guaranteed operation temperature Tj _max .

  Refer to FIG. 6 again.

  After performing step S3 as described above, the process proceeds to step S4, where the control unit 26 starts the timer B described above to start counting the specified time tb. The specified time tb is an estimated time to turn off the power of the fan 21 before the detection unit 21a erroneously detects that a deadlock has occurred in the # 3 fan 21.

  If the specified time tb is equal to or longer than the determination time tj (see FIG. 2), the fan 21 is turned on at least until the determination time tj. Therefore, when the rotation speed does not exceed the threshold rotation speed within the determination time tj, the detection unit 21a may erroneously detect deadlock. In order to eliminate this possibility, it is preferable that the specified time tb is shorter than the determination time tj.

  Next, the process proceeds to step S5, and the switch SW3 is turned on by the power control signal TC # 3 to turn on the power of the replaced fan # 3.

  Here, as shown in FIG. 7, at time 0 when the power is turned on in this step, the value Rc of RT # 3 indicating the rotation speed of the replaced # 3 fan 21 is negative. This is because the wind flows backward by the fans 21 of # 1 and # 2, and the fan 21 rotates in reverse.

  When the power is turned on in this step, the rotational speed of the # 21 fan 21 starts to increase.

  Thus, the process A in FIG. 6 is completed.

  Next, the process proceeds to process B in FIG.

  First, in step S6, it is determined whether or not the actual rotational speed R of the replaced # 3 fan 21 is equal to or higher than a specified rotational speed Ra. This determination can be made by the control unit 26 comparing the aforementioned rotational speed signal RT # 3 with the specified rotational speed Ra.

  Here, as described above, since the threshold rotational speed for the detection unit 21a to determine whether or not there is a deadlock is the predetermined rotational speed Ra, it is determined in this step that it is equal to or higher than the predetermined rotational speed Ra (YES). In this case, the detection unit 21a does not detect a deadlock.

  Therefore, in this case, the process proceeds to process D described later.

  On the other hand, if it is determined in this step that the rotational speed Ra is not equal to or higher than (NO), the process proceeds to step S7.

  In step S7, the control unit 26 determines whether or not the count value Ta of the timer A exceeds the aforementioned limit time ta.

As described above, in step S3, the rotational speeds included in all the rotational speed control signals CT # 1 to CT # 3 are lowered to the specified rotational speed Ra that is smaller than the initial Rb, so the air volume of each fan 21 is weak. The state has continued until now. If this state continues, the electronic component 23 (see FIG. 4) of the electronic device 20 exceeds its guaranteed operating temperature Tj _max and becomes insufficiently cooled, so that the rotation speed of each fan 21 is increased after a certain amount of time has elapsed. Is preferred.

The time limit ta is a time during which the temperature of the electronic component 23 in the electronic device 20 does not exceed the guaranteed operation temperature Tj _max , and it is preferable to increase the air volume of each fan 21 after this time has passed.

  Therefore, if it is determined in this step S7 that the count value of the timer A exceeds the limit time ta (YES), the process proceeds to process D, and the rotational speed of each fan 21 is increased as described later. Insufficient cooling of the device 20 is prevented.

  On the other hand, if it is determined in step S7 that the time limit ta has not been exceeded (NO), the process proceeds to step S8.

  In step S8, the control unit 26 determines whether or not the count value Tb of the timer B exceeds the specified time tb.

  As described above, the specified time tb is an estimated time to turn off the power of the fan 21 before the detection unit 21a erroneously detects that a deadlock has occurred in the replaced # 3 fan 21.

  Therefore, if it is determined in step S8 that the specified time tb has been exceeded (YES), the process proceeds to process C and the power of the # 3 fan 21 is turned off as described later.

  On the other hand, if it is determined in step S8 that the specified time tb has not been exceeded (NO), there is a time margin until the detection unit 21a erroneously detects deadlock, and the process returns to step S6 again.

  Processing B is thus completed.

  Next, process C will be described.

  As described above, the process C is performed to turn off the power of the fan 21 before the detection unit 21a erroneously detects that a deadlock has occurred in the replaced # 3 fan 21.

  Therefore, in the first step S9, the power of the replaced # 3 fan 21 is turned off. This step can be performed by the control unit 26 turning off the switch SW3 by the power supply control signal TC # 3.

  Accordingly, as indicated by an arrow X in FIG. 7, RT # 3 indicating the rotational speed of the # 21 fan 21 starts to decrease.

  Then, the process proceeds to step S10 and waits for a predetermined time tc.

  As shown in FIG. 7, the predetermined time tc is set shorter than the time required for the rotation speed of the # 3 fan 21 to coincide with the rotation speed Rc when the power is turned on at the origin. Therefore, the rotation speed of the # 3 fan 21 does not fall below Rc.

  Next, the process proceeds to step S11 in FIG. 6, and the fan # 3 is turned on simultaneously with the end of the predetermined time tc. This step can be performed when the control unit 26 turns on the switch SW3 by the power supply control signal TC # 3.

  Then, the process proceeds to step S12, and the count value of the timer B is reset to 0. Note that the timer B continues to count even when resetting in this way.

  Thereafter, the process returns to step S6 of process B again.

  Thus, the process C is completed.

  According to the process C described above, in step S11, the fan 21 is turned on before the rotational speed of the # 3 fan 21 returns to the original rotational speed Rc.

  Therefore, as indicated by the arrow Y in FIG. 7, the rotation speed signal RT # 3 indicating the rotation speed of the # 3 fan 21 is easily increased as compared to when the power of the # 3 fan 21 is first turned on. To do. As a result, the rotation speed signal RT # 3 tends to exceed the specified rotation speed Ra, which is a threshold rotation speed for determining the presence or absence of deadlock, and the possibility that the detection unit 21a erroneously detects deadlock is reduced. Can do.

  Next, process D will be described.

  First, in step S13, the control unit 26 returns the set rotational speed included in the rotational speed control signals CT # 1 to CT # 3 to the original Rb, so that the rotational speeds of all the fans 21 # 1 to # 3 are set. increase.

  Thereby, since the air volume of each fan 21 increases, the inside of the electronic device 20 can be prevented from being insufficiently cooled.

  Subsequently, the process proceeds to step S14, and the count operations of the timer A and the timer B are stopped under the control of the control unit 26.

  Then, the process proceeds to step S15, and the control unit 26 resets the count values of the timers A and B to 0.

  Processing D is thus completed.

  According to the present embodiment described above, since the set rotational speed of the fans 21 of # 1 and # 2 that are not to be replaced in step S3 is lowered to the specified rotational speed Ra, the air volume of these fans 21 is weakened. Therefore, the reverse rotation amount of the # 3 fan 21 immediately after the replacement is reduced, and the rotation speed of the fan 21 is likely to exceed the specified rotation speed Ra, which is a threshold rotation speed for determining the presence or absence of deadlock. 21a makes it difficult to erroneously detect deadlock.

  In step S11, the fan 21 is turned on before the rotational speed of the # 3 fan 21 returns to the original rotational speed Rc. Therefore, since the rotation speed of the fan 21 increases compared to when the power is first turned on, the possibility that the detection unit 21a erroneously detects deadlock can be further reduced.

  The following additional notes are disclosed for each embodiment described above.

(Supplementary Note 1) With the remaining fans except one of the plurality of fans provided in the electronic device rotating, the one fan is replaced with another fan,
Lowering the set rotational speed of each of the plurality of fans,
Turn on the other fan,
After turning on the power, if the rotational speed of the other fan does not reach a preset threshold rotational speed within a specified time, turn off the other fan, wait for a predetermined time, and then again A method of maintaining a fan in an electronic device, wherein the power of another fan is turned on.

  (Supplementary note 2) The fan maintenance method in the electronic device according to supplementary note 1, wherein the threshold rotational speed is set to be equal to or less than the set rotational speed.

  (Supplementary note 3) The electronic device according to supplementary note 1 or supplementary note 2, wherein the predetermined time is shorter than a time required for the rotational speed of the another fan to coincide with the rotational speed when the power is turned on. How to maintain fans in equipment.

  (Appendix 4) The specified time is shorter than a determination time in which it is determined that a deadlock has occurred in the another fan. Maintenance method.

  (Supplementary Note 5) After the power is turned on, when the rotational speed of the another fan reaches the threshold rotational speed within the specified time, the set rotational speed of each of the plurality of fans is increased. A maintenance method for a fan in an electronic device according to any one of appendix 1 to appendix 4, wherein

  (Supplementary Note 6) When it is determined that the rotational speed of the another fan has not reached the threshold rotational speed within the specified time, when the time limit has elapsed from the time of replacement with the another fan The method for maintaining a fan in an electronic device according to any one of appendix 1 to appendix 5, wherein the set rotational speed of each of the plurality of fans is increased.

  (Additional remark 7) The said time limit is the time when the temperature of the electronic component in the said electronic device does not exceed the operation | movement guarantee temperature of the said electronic component, The maintenance method of the fan in the electronic device of Additional remark 6 characterized by the above-mentioned.

  (Supplementary Note 8) When the set rotational speed of each of the plurality of fans is decreased, the set rotational speed is decreased so that the temperature of the electronic component in the electronic device does not exceed the operation guaranteed temperature of the electronic component. A maintenance method for a fan in an electronic device according to any one of appendices 1 to 7,

DESCRIPTION OF SYMBOLS 1,20 ... Electronic device, 2 ... Housing, 2a ... Air hole 3, 10, 21 ... Fan, 3a ... Detection unit, 4 ... Circuit board 5, 23 ... Electronic component, 11 ... Blade, 12 ... Main body, 13 ... Flap, 22 ... Rack, 25 ... Power supply unit, 26 ... Control unit.

Claims (5)

In a state where the remaining fans except for one of the plurality of fans provided in the electronic device are rotating, the one fan is replaced with another fan,
Lowering the set rotational speed of each of the plurality of fans,
Turn on the other fan,
After turning on the power, if the rotational speed of the other fan does not reach a preset threshold rotational speed within a specified time, turn off the other fan, wait for a predetermined time, and then again A method of maintaining a fan in an electronic device, wherein the power of another fan is turned on.   2. The fan maintenance method for an electronic apparatus according to claim 1, wherein the threshold rotation speed is set to be equal to or less than the set rotation speed.   3. The electronic device according to claim 1, wherein the predetermined time is shorter than a time required for the rotation speed of the another fan to coincide with the rotation speed when the power is turned on. Fan maintenance method.   After the power is turned on, when the rotational speed of the another fan reaches the threshold rotational speed within the specified time, the set rotational speed of each of the plurality of fans is increased. The method for maintaining a fan in an electronic device according to any one of claims 1 to 3.   When it is determined that the rotational speed of the another fan has not reached the threshold rotational speed within the specified time, when the time limit has elapsed from the time when the other fan is replaced, The method for maintaining a fan in an electronic device according to any one of claims 1 to 4, wherein the set rotational speed of each of the fans is increased.

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