JP5692782B2 - Method and apparatus for inspecting computer system having fan - Google Patents

Description

  The present invention relates to an inspection method and an inspection apparatus for a computer system having a fan.

  Various inspection methods have been proposed for fans built in computer systems. For example, in Patent Document 1, when the fan rotation speed is smaller than a threshold value, if the fan operation time is less than the guaranteed time, it is determined that the fan has failed. A technique for determining that it has been reached is disclosed. Patent Document 2 discloses a technique for notifying a fan failure by comparing the rotational speed of a fan with an indicated rotational speed, and notifying a warning when the accumulated fan operating time exceeds the life time of the fan. Yes.

  Patent Document 3 discloses a technique for notifying a fan failure if there is no change in the rotational speed of the fan after an instruction to change the rotational speed of the fan is given. In Patent Document 4, in a series of fans, one fan is rotated at a high speed and the other fan is rotated at a low speed. Techniques for determining are disclosed.

JP 2003-307194 A JP 2006-140031 A JP 2008-208806 A JP 2010-133330 A

  By the way, in general, in a computer system having a fan, when inspecting the entire computer system including the fan, a fan inspection process for operating the fan for a specified inspection time with a specified rotation pattern is an inspection process other than the fan. It is provided separately. That is, in another inspection process of the computer system, it is not measured whether the fan is operating in a specified rotation pattern. Therefore, as a result, in the inspection process of the entire computer system, a fan having a specified rotational speed exceeding the specified inspection time is operated, and there is a problem that an extra inspection process occurs.

  The present invention has been made to solve such problems, and an object thereof is to provide an inspection apparatus and an inspection method capable of efficiently inspecting a computer system having a fan.

  An inspection apparatus according to the present invention is an inspection apparatus for inspecting a computer system including a fan and fan rotation speed control means for controlling the rotation speed of the fan, and measures the rotation speed of the fan, Based on the determination by the rotation speed determination means for determining whether or not the rotation speed is substantially the same, a cumulative time during which the fan is rotating at substantially the same speed as the specified rotation speed is calculated. An accumulated time calculating means; an accumulated time determining means for determining the magnitude of the accumulated time calculated by the accumulated time calculating means and a prescribed time; and If it is determined that the fan speed is low, an instruction to rotate the fan at the specified rotational speed is output to the fan rotational speed control means of the computer system. A rotation speed instruction means that, those comprising a.

  An inspection method according to the present invention is an inspection method for inspecting a computer system including a fan and fan rotation speed control means for controlling the rotation speed of the fan, wherein the fan rotates at a speed substantially equal to a specified rotation speed. A first step of calculating the accumulated time, a second step of determining the magnitude of the accumulated time calculated in the first step and a prescribed time, and the accumulated time in the second step A third step of outputting an instruction to rotate the fan at the specified rotation speed to the fan rotation speed control means when it is determined that is less than the specified time.

  According to the present invention, it is possible to provide an inspection apparatus and an inspection method capable of efficiently inspecting a computer system having a fan.

1 is a block diagram illustrating a configuration example of a computer system and an inspection apparatus according to a first embodiment. It is the figure which compared the inspection process using the inspection apparatus concerning this Embodiment and the normal inspection process which is not used concerning Embodiment 2. FIG. FIG. 3 is a block diagram illustrating a configuration example of a computer system and an inspection apparatus according to a second embodiment. 6 is a flowchart illustrating a specific example of a fan inspection method according to the second exemplary embodiment; It is a figure which shows the specific example of the operating time integration | accumulation of the fan concerning Embodiment 2. FIG. It is a figure which shows the specific example of the test result of the fan concerning Embodiment 2. FIG.

Embodiment 1
Embodiment 1 of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram illustrating a configuration example of a computer system and an inspection apparatus in the present embodiment. In FIG. 1, the computer system 1 includes a fan 4 and fan rotation speed control means 3 that controls the rotation speed of the fan 4. The inspection apparatus 2 that is an inspection apparatus of the computer system 1 includes a rotation speed determination means 5, an accumulated time calculation means 6, an accumulated time determination means 7, and a rotation speed instruction means 8.

  Further, the computer system 1 and the inspection apparatus 2 are connected by wiring or a network, and information on the rotational speed of the fan 4 is output to the rotational speed determination means 5. The rotation speed instruction of the fan 4 output from the rotation speed instruction means 8 is output to the fan rotation speed control means 3. The arrow in FIG. 1 indicates that information is output, and the direction of the arrow indicates the information output direction.

  The computer system 1 is a processing system for a large amount of data such as a server, a mainframe, or a supercomputer. Alternatively, a computer that performs information processing such as a workstation may be used.

  The fan 4 is provided in the computer system 1 and has a function of cooling the inside of the computer system 1.

  The fan rotation speed control means 3 determines the rotation speed of the fan 4 according to the processing performed by the computer system 1 and outputs an instruction for the determined rotation speed to the fan 4. Further, when a rotation speed instruction is acquired from the outside (rotation speed instruction means 8), the fan 4 is rotated at a specified speed based on the instruction.

  Although not shown here, as a specific configuration, the computer system 1 has a memory such as a central processing unit (CPU), a random access memory (RAM), and a read only memory (ROM), and an auxiliary storage device, as in a normal computer. Etc. The auxiliary storage device is configured by a hard disk drive, a magnetic tape, or the like, and can store a large amount of data. The fan rotation speed control means 3 is composed of a CPU, a RAM, a ROM, an auxiliary storage device, and the like. The CPU reads information stored in the RAM and executes a program stored in the ROM. It functions as the fan rotation speed control means 3.

  The inspection device 2 can be connected to the computer system 1 to transmit and receive information, and is composed of a terminal device such as a personal computer or a workstation. The inspection device 2 is a device that determines whether or not the fan 4 has rotated for a specified time at a specified rotation speed related to the inspection.

  The rotational speed determination means 5 acquires information related to the rotational speed of the fan 4 from the connected computer system 1. Further, the rotational speed determination means 5 measures the rotational speed of the fan 4 from the acquired information, determines whether or not it is substantially the same as the specified rotational speed, and outputs the determination result to the accumulated time calculation means 6.

  Here, as information regarding the rotational speed of the fan 4, for example, there is a pulse signal output in synchronization with the rotation of the fan 4. In this case, the fan 4 is provided with a terminal for outputting a pulse signal synchronized with the rotation, and the computer system 1 is connected to the terminal. The computer system 1 acquires the pulse signal output from the terminal of the fan 4 and outputs the pulse signal to the rotation speed determination means 5, so that the rotation speed determination means 5 uses the pulse signal output from the computer system 1 as the rotation speed of the fan 4. Get as information about.

  The accumulated time calculating means 6 acquires the determination result information of the rotation speed determining means 5 and calculates the accumulated time during which the fan 4 is rotating at substantially the same speed as the prescribed rotation speed based on the determination result. The calculation result is output to the accumulated time determination means 7. Here, the allowable range for determining whether or not they are substantially the same is determined according to the required quality and the performance of the fan.

  The accumulated time determination means 7 acquires information on the accumulated time calculated by the accumulated time calculation means 6 and determines the magnitude of the accumulated time and the specified time. When it is determined that the accumulated time is less than the specified time, the accumulated time determining unit 7 outputs information on the rotation speed determined to be less to the rotation speed instruction unit 8.

  The rotation speed instruction means 8 acquires information on the rotation speed determined to be low, and outputs an instruction to rotate the fan 4 at the rotation speed to the fan rotation speed control means 3. As described above, the fan rotation speed control unit 3 rotates the fan 4 at the rotation speed determined to be low based on the acquired instruction information of the rotation speed instruction unit 8.

  Although not shown here, as a specific configuration, the inspection apparatus 2 includes a memory such as a CPU, a RAM, and a ROM, an auxiliary storage device, and the like, as in a normal computer. The rotational speed determination means 5, the cumulative time calculation means 6, the cumulative time determination means 7, and the rotational speed instruction means 8 are composed of a CPU, a RAM, a ROM, an auxiliary storage device, etc., and the CPU stores information stored in the RAM. By reading and executing the program stored in the ROM, the CPU or the like functions as each unit. Note that the data of the specified rotation speed and specified time of the fan is stored in an auxiliary storage device or the like in the inspection device 2, and the rotation speed determination means 5 or the accumulated time determination means 7 stores the data as necessary. You can refer to it. Further, the data of the specified rotation speed and the specified time of the fan can be arbitrarily changed.

  Hereinafter, a process in which the inspection apparatus 2 inspects the fan 4 will be described. The computer system 1 is operating, and the fan 4 is rotating according to the control of the fan rotation speed control means 3. First, the rotational speed determination means 5 acquires information on the rotational speed of the fan 4 from the connected computer system 1. Then, the rotational speed determination means 5 measures the rotational speed of the fan 4 from the acquired information, determines whether or not it is substantially the same as the specified rotational speed, and uses the information of the determination result as the accumulated time calculation means 6. Output to.

  The accumulated time calculating means 6 calculates the accumulated time during which the fan 4 is rotating at substantially the same speed as the specified rotation speed based on the acquired information. The accumulated time calculating means 6 outputs information relating to the calculated accumulated time to the accumulated time determining means 7. The processing performed by the rotational speed determination unit 5 and the accumulated time calculation unit 6 is described as a first step.

  The accumulated time determination means 7 determines the magnitude of the accumulated time and the specified time based on the acquired information. This determination process is described as a second step. When it is determined that the accumulated time is less than the specified time, the accumulated time determining unit 7 outputs information on the rotation speed determined to be less to the rotation speed instruction unit 8.

  Based on the acquired information, the rotation speed instruction means 8 outputs an instruction to rotate the fan 4 at the rotation speed determined to be low to the fan rotation speed control means 3. This determination process is described as a third step. As described above, the fan rotation speed control means 3 rotates the fan 4 at a rotation speed determined to be low based on the acquired instruction information.

  With the configuration of the inspection apparatus 2 described above, an inspection apparatus that can efficiently inspect a computer system having a fan can be provided. In addition, a computer system having a fan can be efficiently inspected by the inspection method including the first, second, and third steps.

  As an example of the use of the inspection apparatus, an example in which the entire computer system 1 including the fan 4 is inspected can be considered as follows. In this inspection, the computer system 1 first performs an inspection other than the fan inspection, and then performs the fan-only inspection. Note that “inspection other than fan inspection” indicates that the computer system 1 performs inspections other than the fan 4 and the fan rotation speed control means 3, and “fan only inspection” refers to the fan in the computer system 1. 4 and the fan rotation speed control means 3 only. The same applies to the following.

  First, when the computer system 1 performs an inspection other than the fan inspection, the first step described above is executed, but the second step and the third step are not executed. In other words, the inspection device 2 performs only the process of measuring the rotational speed of the fan 4 and calculating the accumulated time of rotation at the specified speed, determines the magnitude of the accumulated time and the specified time, When the time is less than the time, processing for outputting an instruction to the fan rotation speed control means 3 is not performed. It is the rotational speed determination means 5 and the accumulated time calculation means 6 that perform processing at the stage of performing inspections other than the fan inspection, and details of the processing are as described above. During the time when the inspection other than the fan inspection is performed, the rotational speed of the fan 4 is controlled by the fan rotational speed control means 3 in accordance with the processing performed by the computer system 1, and is determined by the rotational speed instruction means 8. There is no control.

  Next, after the inspection other than the fan inspection is completed, the inspection apparatus 2 performs the inspection of only the fan. At this time, the second step is executed, and when it is determined that the accumulated time is less than the specified time, the third step is executed. Thereafter, the first and subsequent steps are executed. Specifically, the accumulated time determination means 7 determines the magnitude of the calculated accumulated time and the specified time, and when it is determined that the accumulated time is less than the specified time, the rotation speed determined to be less Information is output to the rotation speed instruction means 8. The rotation speed instruction means 8 acquires the information and outputs an instruction to rotate the fan 4 at the rotation speed determined to be low to the fan rotation speed control means 3. As described above, the fan rotation speed control means 3 rotates the fan 4 at a rotation speed determined to be low based on the acquired instruction information. The rotation speed determination means 5 measures the rotation of the fan 4 performed by the above control, and performs the same processing as described above. Thereafter, the cumulative time calculation means 6, the cumulative time determination means 7, and the rotation speed instruction means 8 perform the same processing as described above. In this way, only the fan 4 is inspected until the accumulated time determination means 7 determines that the fan 4 has rotated at the specified rotational speed for the specified time.

  By performing the above processing, when the computer system 1 performs an inspection other than the fan inspection, the inspection device 2 calculates the accumulated time during which the fan 4 is rotating at a specified speed. Therefore, when the computer system 1 performs the inspection of only the fan after completion of the inspection other than the fan inspection, the rotational speed instruction means 8 is (the specified time)-(accumulated time calculated by the inspection other than the fan inspection). It is sufficient to perform control to rotate the fan 4 at the rotational speed determined to be low for the time represented by (). In other words, when the inspection of only the fan is performed, it is not necessary to rotate the fan 4 at a specified rotational speed for a specified time. As described above, it is possible to provide an inspection apparatus and an inspection method capable of performing an efficient inspection by reducing the inspection process of a computer system having a fan.

Embodiment 2
The second embodiment of the present invention will be described below with reference to the drawings. In the description of the present embodiment, the description similar to that of Embodiment 1 is omitted as appropriate. In the present embodiment, a plurality of prescribed rotational speeds and prescribed times corresponding thereto are set for inspection.

  FIG. 2 is a diagram comparing an inspection process of a computer system using the inspection apparatus according to the present embodiment and a normal inspection process that is not used. The inspection process shown in FIG. 2 is performed at the time of shipment of the computer system, and the functions and tolerances of the entire computer system including the fan are confirmed. For example, in this inspection process, if it is confirmed that the fan has rotated at a specified rotational speed for a time specified in the inspection, it is considered that the quality of the fan is guaranteed.

  In FIG. 2, in the inspection process from “power test to temperature test”, the computer system is started, and then inspections other than the fan in the computer system are performed. In the “fan test”, the computer Only fans in the system are being tested. Further, in the “stability test” in FIG. 2, the computer system is not operated and the fan does not rotate. Hereinafter, in the description of the present embodiment, “inspection other than fan inspection in the computer system” is referred to as “power supply test to temperature test”, and “fan only inspection in the computer system” is referred to as “fan test”.

  In the normal inspection process shown in FIG. 2, the fan is not measured in the power supply test to the temperature test process. That is, in the fan test, it is measured for the first time whether or not the fan has rotated at a specified rotational speed for a specified time. Therefore, in the inspection process of the entire computer system, the fan exceeds the specified inspection time and operates at the specified rotational speed.

  In the inspection process using the inspection apparatus according to the present embodiment shown in FIG. 2, the fan is also measured in the inspection process of the power supply test to the temperature test. In this measurement, the time during which the fan rotates at substantially the same rotational speed as a plurality of defined fans is accumulated.

  Here, at a specified rotation speed of the fan, the accumulated time and the specified inspection time are compared, and if the accumulated time exceeds the specified inspection time, the specified rotation For speed, it is considered that the fan inspection has already been completed. Therefore, in the fan test process, only when there is a rotation speed of the fan that has not reached the specified inspection time in the power supply test to the temperature test process, the fan is maintained at the rotation speed until the specified inspection time is reached. It is sufficient to perform control to rotate the.

  The table at the bottom of FIG. 2 shows the fan 11, fan 12, fan 13, and fan 14 (see FIG. 3) that are the four types of fans of the computer system. It is an example of the result of having measured. The rotation speeds defined here are three types of 2000 rpm, 3000 rpm, and 4000 rpm. In addition, the circles in the table indicate that the rotation has been performed for a specified time with respect to the corresponding rotation speed of the corresponding fan. In the table, “X” indicates that the rotation for the specified time has not been performed for the corresponding rotation speed of the corresponding fan.

  In the table of FIG. 2, the fans 11 and 14 rotate at a specified time at all specified rotation speeds in the power supply test to the temperature test process. That is, it is not necessary to inspect the fans 11 and 14 in the fan test.

  Further, the fan 12 rotates at a specified time at specified rotation speeds of 2000 rpm and 3000 rpm, but does not rotate at a specified time at a specified rotation speed of 4000 rpm. The fan 13 rotates at a specified speed at a specified rotation speed of 4000 rpm, but does not rotate at a specified time at a specified rotation speed of 2000 rpm and 3000 rpm. From the above, the fan test may be executed for the rotational speed of 4000 rpm for the fan 12 and the rotational speeds of 2000 rpm and 3000 rpm for the fan 13.

  By performing the above processing, in the fan test, the fan can be inspected with the minimum necessary man-hours. This is because, in a normal inspection process, it is necessary to perform a fan test for each of the three specified rotational speeds of 2000 rpm, 3000 rpm, and 4000 rpm for each of the fans 11, 12, 13, and 14. is there. However, if it is an inspection process using the inspection apparatus according to the present embodiment, each fan is measured in the power supply test to the temperature test process, so the rotational speed of 4000 rpm for the fan 12 and 2000 rpm for the fan 13. This is because only the inspection for the rotational speed of 3000 rpm should be performed.

  Next, configuration examples of the computer system and the inspection apparatus will be described with reference to the drawings. FIG. 3 is a block diagram illustrating a configuration example of a computer system and an inspection apparatus. In FIG. 3, the computer system 1 includes fans 11 to 14 and fan rotation speed control means 10 that controls the rotation speeds of the fans 11 to 14. The inspection apparatus 2 that is an inspection apparatus of the computer system 1 includes a monitor unit 20, a storage unit 28, an inspection time determination unit 29, and a rotation speed instruction unit 30. The monitor unit 20 includes a rotation speed measurement unit 21, a rotation speed comparison unit 22, a rotation time measurement unit 23, a rotation time integration unit 24, a rotation time comparison unit 25, a determination result holding unit 26, and a determination result notification unit 27. Yes.

  The computer system 1 and the inspection apparatus 2 are connected by wiring or a network, and information on the rotational speed of the fans 11 to 14 is output to the rotational speed measuring means 21. Moreover, the rotation speed instruction | indication means 30 outputs the rotation speed instruction | indication of the fans 11-14, and the fan rotation speed control means 10 acquires the information. The arrows in FIG. 3 indicate information output as in FIG.

  Each of the fans 11 to 14 is provided with a terminal for outputting a pulse signal synchronized with the rotation. As described in the first embodiment, the rotational speed measuring unit 21 acquires information about the rotational speed.

  The computer system 1 outputs information related to the individual fan rotational speeds of the fans 11 to 14 to the rotational speed measuring means 21. In addition, the information output here includes identification information of the fans 11 to 14 indicating “which fan is rotating” in addition to information related to the rotating speed.

  The fan rotation speed control means 10 determines the rotation speed of the fans 11 to 14 according to the processing performed by the computer system 1 and outputs an instruction of the determined rotation speed to the fans 11 to 14. Further, when the fan rotation speed control means 10 acquires instruction information from the outside (rotation speed instruction means 30), the fans 11 to 14 are rotated at a specified speed based on the instruction information. In the present embodiment, the fan rotation speed control means 10 can control the rotation speeds of the fans 11 to 14 with a plurality of patterns of rotation speeds. Note that a specific example and a specific configuration of the computer system 1 are the same as those of the first embodiment, and thus description thereof is omitted.

  The inspection device 2 can be connected to the computer system 1 to transmit and receive information. The monitor unit 20 is a section that accumulates the time during which the fans 11 to 14 are rotating at a specified rotational speed and determines whether or not the accumulated time has reached a specified time. Hereinafter, the rotation speed measurement unit 21 to the determination result notification unit 27 will be described. Here, the rotational speed measuring means 21, the rotational speed comparing means 22, the rotational time measuring means 23, and the rotational time integrating means 24 are the same functions as the rotational speed determining means 5 and the accumulated time calculating means 6 of the first embodiment, respectively. Have The rotation time comparison unit 25, the determination result holding unit 26, and the determination result notification unit 27 have the same functions as the accumulated time determination unit 7 of the first embodiment. Note that a specific example of the inspection apparatus 2 and a specific configuration of the inspection apparatus 2 are the same as those in the first embodiment, and a description thereof will be omitted.

  The rotational speed measuring unit 21 sequentially acquires information on the rotational speeds of the fans 11 to 14 from the computer system 1 and measures the rotational speeds of the fans 11 to 14. The rotational speed measuring means 21 outputs information on the measured rotational speed of the fan to the rotational speed comparing means 22. The information to be output includes identification information of the fans 11 to 14 indicating “which fan is rotating” in addition to the information of the measured rotating speed. The information output by each means below also includes fan identification information.

  The rotation speed comparison unit 22 acquires the rotation speed information, then acquires the specified rotation speed information from the storage unit 28, compares the fan rotation speed with the specified rotation speed, and determines the fan rotation speed. It is determined whether or not the rotational speed is substantially the same. The rotation speed comparison unit 22 outputs the determination result to the rotation time measurement unit 23.

  The rotation time measuring means 23 acquires the determination result of the rotation speed comparison means 22, measures the time during which the fan is rotating at substantially the same rotation speed as the result, and uses the measurement result as the rotation time integration means. 24.

  The rotation time integration unit 24 acquires the measurement result of the rotation time measurement unit 23 and, based on the result, integrates the time measured in each fan for each specified rotation speed. The rotation time integration unit 24 outputs the result of the integration time (cumulative time) to the rotation time comparison unit 25.

  The rotation time comparison unit 25 acquires and stores information on the integration time (cumulative time) output from the rotation time integration unit 24. In addition, the magnitudes of the accumulated time and the specified inspection time are compared for each of a plurality of rotational speeds. For example, in the fan 11, when the accumulated time that the fan 11 is rotated at 35 rpm is 35 hours and the specified inspection time is 30 hours, it is determined that the inspection at the rotation speed 2000 rpm of the fan 11 has been completed, Down. In addition, in the fan 11, if the accumulated time that the fan 11 has rotated at 2000 rpm is 25 hours and the specified inspection time is 30 hours, the inspection at the rotational speed of the fan 11 at 2000 rpm has not been completed. Make a pass decision. The determination as described above is performed, and the rotation time comparison unit 25 outputs the determination result to the determination result holding unit 26. Whether or not the determination process of the accumulated time and the specified inspection time and the output process of the determination result are executed by the control by the inspection time determination unit 29 is determined.

  The determination result holding unit 26 acquires the determination result of the rotation time comparison unit 25 and holds it as a data table. A specific example of the data table is the table of the test result example shown in FIG.

  When the determination result notifying unit 27 acquires the determination result from the determination result holding unit 26 and determines that there is a fan for which the determination result has failed, the fan that has failed from the determination result and the rotation speed thereof. Is selected and notified to the rotation speed instruction means 30. For example, if the determination result is the table of the inspection result example shown in FIG. 2, the determination result notifying unit 27 fails the inspection of the specified rotational speeds of 4000 rpm for the fan 12 and 2000 rpm and 3000 rpm for the fan 13. Judge that there is. The determination result notifying unit 27 outputs information about the failed fan and the rotation speed to the rotation speed instruction unit 30.

  Moreover, the determination result notification means 27 notifies the result of the determination processing to the outside when it is determined that there is no fan whose determination result has failed in the acquired determination result (all fans are passing). At the same time, the inspection apparatus 2 is controlled to end the inspection of the computer system 1.

  The storage means 28 stores information on a prescribed rotational speed and a prescribed time relating to the fan inspection. Specifically, the storage unit 28 includes an auxiliary storage device of the external terminal 2 or the like. Note that the prescribed rotational speed or the prescribed time may be stored in advance as a data table.

  The inspection time determination means 29 determines whether or not the inspection process of the computer system 1 is in the process of power supply test to temperature test. When it is determined that the inspection process of the computer system 1 is in the process of the power supply test to the temperature test, the determination result is not stored in the rotation time comparison unit 25, and the determination result is stored as a determination result holding unit. A control signal not to be output to the terminal 26 is output. When it is determined that the inspection process of the computer system 1 is not in the process of the power source test to the temperature test and is in the fan test process, the above-mentioned pass / fail determination is made to the rotation time comparison unit 25 to determine A control signal for outputting the result to the determination result holding means 26 is output.

  The inspection time determination means 29 detects the input information when there is input information from the outside (inspector) indicating that the inspection from the power supply test to the temperature test has been completed for the inspection device 2. Judgment regarding the above-described power supply test to temperature test process is performed.

  The rotation speed instruction means 30 obtains information on the failed fan and the rotation speed from the determination result notification means 27, and based on the information, “with which specified rotation speed each fan 11 to 14 is rotated. Is output to the fan rotation speed control means 10. The fan rotation speed control means 10 acquires the instruction, and outputs a control command to operate each fan at the specified rotation speed in response to the instruction.

  The function of each part of the computer system 1 and the inspection apparatus 2 has been described above. Next, how each part of the inspection apparatus 2 functions in a specific process of the inspection of the computer system 1 will be described with reference to FIGS. FIG. 4 is a flowchart illustrating a specific example of a fan inspection method performed by the inspection apparatus 2. Hereinafter, the fan inspection will be described along the steps of FIG. In the inspection of the computer system 1, first, the power supply test to the temperature test in FIG. 2 are performed, and then the fan test is performed. Further, the detailed description of the processing of each part of the inspection apparatus 2 has been described in the description related to FIG.

  First, the rotational speed measuring unit 21 sequentially acquires information on the rotational speeds of the fans 11 to 14 and measures the rotational speed (step S1). Next, the rotational speed comparison means 22 determines whether or not the rotational speed of the fans is substantially the same as the specified rotational speed based on the rotational speeds of the fans 11 to 14 measured by the rotational speed measuring means 21 (step). S2). If it is determined that the rotational speed of the fan is not substantially the same as the specified rotational speed, the inspection apparatus 2 returns to step S1 and performs processing.

  If it is determined in step S <b> 2 that the rotational speed of the fan is substantially the same as the prescribed rotational speed, the rotational speed comparing means 22 outputs the result to the rotational time measuring means 23. Based on the acquired information, the rotation time measuring means 23 measures the time during which the fan can be regarded as rotating at a specified rotation speed (step S3). The rotation time measuring unit 23 outputs the sequentially measured time to the rotation time integrating unit 24.

  In step S3, the rotation time accumulating unit 24 accumulates the operation time for each rotation speed in the fans 11 to 14 based on the information of the measured operation time (step S4). Note that steps S1 to S4 correspond to the first step of the first embodiment.

  A specific example of the processing in steps S2 to S4 will be described with reference to FIG. FIG. 5 is a diagram illustrating a specific example of the operation time integration process in the fan 11. The fan 11 is rotated in order of time from 1990 rpm for 1 hour, 2300 rpm for 1 hour, 3020 rpm for 1 hour, and 2050 rpm for 1 hour since the rotation speed measuring means 21 starts measurement. Further, there are three types of specified rotation speeds of 2000 rpm, 3000 rpm, and 4000 rpm. If the measured value of the rotation speed is different from any one of the specified rotation speeds by ± 100 rpm or less, the rotation speed comparison means 22 It is determined that the fan 11 is rotating at substantially the same speed as the specified rotation speed. That is, if the rotation speed of the measured value is 1900 rpm to 2100 rpm, 2900 rpm to 3100 rpm, 3900 rpm to 4100 rpm, it is determined that the rotation speed is substantially the same as the specified rotation speed 2000 rpm, 3000 rpm, and 4000 rpm, respectively.

  First, a process when the fan 11 rotates at 1990 rpm for 1 hour will be described. In step S <b> 2, the rotation speed comparison unit 22 acquires a measurement value from the rotation speed measurement unit 21, and compares whether there is a substantially same value within a specified rotation speed. At this time, the rotational speed comparison means 22 determines that the measured value 1990 rpm falls within the range of 1900 rpm to 2100 rpm. From this determination, the rotation speed comparison means 22 determines that the fan 11 is rotating at a specified speed of 2000 rpm. The “comparison result” in FIG. 5 indicates the result of the determination.

  The rotation speed comparison unit 22 outputs information indicating that the fan 11 is rotating at a specified speed of 2000 rpm to the rotation time measurement unit 23. In step S3, the rotation time measuring unit 23 measures the time during which the fan 11 is rotating at 2000 rpm while acquiring the information output by the rotation speed comparing unit 22. In FIG. 4, since the fan 11 rotates at 1990 rpm for 1 hour, the rotation time measuring means 23 measures that the fan 11 rotates at 2000 rpm for 1 hour. The “measurement result” in FIG. 5 indicates the measurement result. Further, the rotation time measuring means 23 sequentially outputs the measurement results to the rotation time integrating means 24.

  The rotation time integration means 24 integrates that the fan 11 has been rotated at 2000 rpm for one hour based on the measurement result. In FIG. 5, “integration result” indicates the result of the integration.

  Next, processing when the fan 11 rotates at 2300 rpm for 1 hour will be described. In step S <b> 2, the rotation speed comparison unit 22 acquires a measurement value from the rotation speed measurement unit 21, and compares whether there is a substantially same value within a specified rotation speed. In this case, the measured value does not fall within the range of 1900 rpm to 2100 rpm, 2900 rpm to 3100 rpm, and 3900 rpm to 4100 rpm, so the rotation speed comparison unit 22 does not output information to the rotation time measurement unit 23. From the above, the integration result does not change while the fan 11 remains rotated for 1 hour at 2000 rpm.

  Thereafter, when the fan 11 rotates at 3020 rpm for 1 hour or when it rotates at 2050 rpm for 1 hour, the rotation speed comparison unit 22, the rotation time measurement unit 23, and the rotation time integration unit 24 perform the same processing. . The rotation speed comparison means 22 determines that the fan 11 is rotating at 3000 rpm and 2000 rpm in each case. The rotation time measuring means 23 measures from the information output from the rotation speed comparison means 22 that it has been rotated at 3000 rpm for 1 hour and 2000 rpm for 1 hour, and sequentially outputs the measurement results to the rotation time integrating means 24. From the measurement result, the rotation time integration unit 24 counts that the fan 11 has rotated at 3000 rpm for 1 hour and 2000 rpm for 1 hour as an integration result. From the above, in the specific example shown in FIG. 5, when 4 hours have elapsed from the start of measurement of the fan 11, the fan 11 rotates for 2 hours at 2000 rpm and rotates for 1 hour at 3000 rpm. An integration result is obtained.

  In the specific example shown in FIG. 5, only the fan 11 has been described, but the same processing can be performed for other fans such as the fans 12, 13, and 14.

  Hereinafter, returning to FIG. 4, a specific example of the inspection method will be described. After the rotation time integrating unit 24 integrates the operation time in step S <b> 4, the rotation time integrating unit 24 outputs the accumulated time information to the rotation time comparing unit 25. The rotation time comparison unit 25 acquires and stores the output information. Here, the inspection time determination means 29 determines whether or not the computer system 1 is in the period from the power supply test to the temperature test (step S5). When it is determined that the computer system 1 is in the period from the power supply test to the temperature test, the inspection time determination unit 29 performs control so that the rotation time comparison unit 25 does not perform the above pass / fail determination process. Do. Therefore, the inspection apparatus 2 returns to step S1 and performs processing. That is, during the inspection period of the power supply test to the temperature test of the computer system 1, the processes from step S1 to step S4 are repeatedly performed, so that the fans 11 to 14 are rotating at the specified rotational speeds. Time is accumulated sequentially.

  In step S5, when it is determined that the computer system 1 is not in the period of the power source test to the temperature test (in the period of the fan test), the inspection time determination unit 29 instructs the rotation time comparison unit 25 to Outputs a control signal for performing pass / fail judgment processing. The rotation time comparison means 25 compares the accumulated operation time at each prescribed rotation speed of the fans 11 to 14 with the prescribed inspection time at each prescribed rotation speed obtained from the storage means 28, and passes or fails. A pass determination process is performed (step S6). The rotation time comparison unit 25 outputs the result of the determination process to the determination result holding unit 26, and the determination result holding unit 26 writes and holds the acquired determination result in the data table (step S7).

  The determination result notifying unit 27 determines whether or not there is a rejected result among the determination results held in the determination result holding unit 26 (step S8). Steps S6 to S8 correspond to the second step of the first embodiment.

  If there is no failure result in step S8, the determination result notifying means 27 notifies the result of the determination process to the outside (step S9), and ends the fan inspection of the computer system 1 by the inspection device 2.

  If it is determined in step S8 that there is a failure result, the determination result notifying unit 27 outputs information on the type of fan that has failed and its specified rotation speed to the rotation speed instruction unit 30. (Step S10). The rotation speed instruction means 30 outputs a command to the fan rotation speed control means 10 so that a test for rotating the fan at the failed rotation speed is performed according to the information acquired from the determination result notification means 27 ( Step S11). Steps S10 and S11 correspond to the third step of the first embodiment.

  The fan rotation speed control means 10 controls the fans 11 to 14 according to the acquired command (step S12). Thereafter, the inspection apparatus 2 returns to the process of step S1 and performs a fan test until there is no result of failure in step S8. When all the fans 11 to 14 have rotated for a specified time at all the specified rotation speeds, the fan test is completed when the determination result notification means 27 makes a determination in step S8.

  A specific example of the processing in steps S6 to S11 will be described with reference to FIG. FIG. 6 is a diagram illustrating a specific example of the inspection result in the fan 13. In FIG. 6, in the fan 13, the specified rotation speed and the corresponding specified inspection time are set to 30 hours at 2000 rpm, 30 hours at 3000 rpm, and 30 hours at 4000 rpm.

  In FIG. 6, in step S4 immediately after the power supply test to the temperature test are completed, the rotation time integrating means operates with the fan 13 operating at 2000 rpm for 20 hours, 3000 rpm for 15 hours, and 4000 rpm for 35 hours. Accumulated results are obtained. In FIG. 6, the time relating to the integration result is described as an intermediate integration time. The following is described similarly.

  In the example of FIG. 6, at the specified rotational speed of 2000 rpm, the integrated time is 20 hours with respect to the specified inspection time of 30 hours. A pass is determined. Similarly, at 2000 rpm, since the halfway integration time is 15 hours with respect to the specified inspection time of 30 hours, it is determined that “time is insufficient for 15 hours”. In addition, at 3000 rpm, since the integrated time is 35 hours with respect to the specified inspection time of 30 hours, the determination is acceptable. These determinations are described as “intermediate determination” in FIG. 6, and the following is also described in the same manner.

  The determination result holding means 26 holds the determination result holding means 26. The determination result table of FIG. 2 is an example. In FIG. 2, the fan 13 passes only when the rotational speed of the fan is 4000 rpm, and fails when the rotational speed is 2000 rpm and 3000 rpm.

  In FIG. 6, the inspection of the fan 13 does not reach the specified inspection time for the specified rotational speeds of 2000 rpm and 3000 rpm. Accordingly, in the fan test process, the determination result notification unit 27 notifies the rotation speed instruction unit 30 of an instruction to rotate the fan 13 at 2000 rpm. The rotation speed instruction means 30 outputs an instruction to rotate the fan 13 at 2000 rpm to the fan rotation speed control means 10. The fan rotation speed control means 10 performs control to rotate the fan 13 at 2000 rpm in accordance with an instruction.

  In FIG. 6, after 10 hours have elapsed, the rotation time integrating means 24 accumulates that the fan 13 has rotated at 2000 rpm for 10 hours. That is, in the fan 13, the result of the accumulated time that the fan 13 is rotated for 30 hours at the specified rotational speed of 2000 rpm is obtained in the power source test to the temperature test and the fan test. This result is described as the final accumulated time at 2000 rpm in FIG. From the above, the determination result of the fan 13 at 2000 rpm is acceptable. In addition, (circle) of the final determination in FIG. 6 has shown the pass result. The same notation is used in the following descriptions.

  Next, the rotation speed instruction means 30 outputs an instruction to rotate the fan 13 at 3000 rpm to the fan rotation speed control means 10. The fan rotation speed control means 10 performs control to rotate the fan 13 at 3000 rpm in accordance with an instruction. In FIG. 6, after 15 hours have elapsed, the rotation time integration means 24 accumulates that the fan 13 has rotated at 3000 rpm for 15 hours. In other words, the fan 13 can obtain the result of the accumulated time that the fan 13 has been rotated for 30 hours at a specified rotational speed of 3000 rpm. This result is described as the final integration time at 3000 rpm in FIG. From the above, the determination result at 3000 rpm is acceptable.

  When all the prescribed rotational speeds of the fan 13 are determined to pass, it is determined that all inspections for the fan 13 have been completed. Note that the determination result notification unit 27 may output an instruction to rotate the fan 13 at 3000 rpm first, and then output an instruction to rotate the fan 13 at 2000 rpm later.

  As described above, in the present embodiment, the inspection device 2 integrates the operation time for each rotation speed of each fan, and compares the “integrated time” with the “specified inspection time”. When the inspection device 2 detects a rotational speed that has not reached the “specified inspection time” in a certain fan, an instruction to rotate the fan at that rotational speed is reached until the “specified inspection time” is reached. It is possible to output to the instruction means. As a result, the inspection apparatus 2 can efficiently inspect the fan with the minimum required man-hours. Further, the inspection apparatus 2 can perform the same inspection as that of the first embodiment even for a computer system that includes a plurality of fans and is capable of controlling a plurality of types of rotational speeds for each fan.

  Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention. For example, the inspection apparatus according to Embodiments 1 and 2 may be provided with warning means for notifying the outside of the fan or fan rotation speed control means. The warning means is, for example, that the rotation speed determination means or the rotation speed measurement means causes the fan to elapse for a certain period of time even though the rotation speed instruction means instructs the fan rotation speed control means to rotate at a specified speed. Even if it is determined that the motor does not rotate at the specified speed, a warning is notified to the outside.

  In the second embodiment, the determination in step S5 in FIG. 4 is not limited to the method in which the inspection time determination unit detects input information from the outside (inspector), and may be performed by the following method. Good. First, the preset time of the power supply test to the temperature test is stored in the storage means. After starting the power supply test, the inspection time determination means may perform the determination process in step S5 by sequentially determining whether or not the elapsed time since the test has passed the stored set time. Alternatively, the computer system outputs the information to the inspection device when the inspection of the power source test to the temperature test is completed, and the inspection time determination unit acquires the information to perform the determination in step S5. Good.

  Further, the inspection apparatus may inspect a plurality of computer systems. In this case, the information output from each computer system to the inspection device may include identification information of the computer system in addition to information related to the rotational speed and identification information of each fan.

  In the second embodiment, the rotational speed comparison means is configured such that when the measured value of the rotational speed of the fan is different from any one of the predetermined rotational speeds by ± 100 rpm or less, the fan is substantially the same as the specified rotational speed. It has been described that it is determined that it is rotating at the same speed. However, the difference that can be regarded as substantially the same as the specified speed is not ± 100 rpm, but may be any value as long as it is a value that can be considered to be comparable to the specified rotational speed, such as ± 50 rpm or ± 150 rpm. Alternatively, a setting such that the value is different between the upper limit and the lower limit, such as −50 rpm to +100 rpm, may be performed. Moreover, you may make it change the value which can be considered substantially the same for every rotation speed. Of course, the specified rotation speed is not limited to the values of 2000 rpm, 3000 rpm, and 4000 rpm shown as examples.

  In the first and second embodiments, in the computer system, the inspection apparatus is used to perform the entire inspection including the fan. However, the inspection apparatus may be used when performing the inspection of only the fan in the computer system.

DESCRIPTION OF SYMBOLS 1 Computer system 2 Inspection apparatus 3 Fan rotational speed control means 4 Fan 5 Rotational speed determination means 6 Accumulated time calculation means 7 Accumulated time determination means 8 Rotational speed instruction means 10 Fan rotational speed control means 11, 12, 13, 14 Fan 20 Monitor Unit 21 Rotational speed measuring means 22 Rotational speed comparing means 23 Rotating time measuring means 24 Rotating time integrating means 25 Rotating time comparing means 26 Determination result holding means 27 Determination result notifying means 28 Storage means 29 Inspection time determining means 30 Rotating speed indicating means

Claims (4)

An inspection method for inspecting a computer system comprising a fan and fan rotation speed control means for controlling the rotation speed of the fan,
A first step of calculating an accumulated time during which the fan is rotating at a speed substantially equal to a specified rotation speed;
A second step of determining the magnitude of the accumulated time calculated in the first step and a specified time;
When it is determined in the second step that the accumulated time is less than the specified time, an instruction to rotate the fan at the specified rotation speed is output to the fan rotation speed control means. comprising a step of, the,
Performing at least the first step while performing an inspection other than the inspection of the fan in the computer system;
In the computer system, the second step and the third step are executed after the inspection other than the fan inspection is completed.
Test査方method. The first to third steps are executed for a plurality of the prescribed rotational speeds.
The inspection method according to claim 1 . The first to third steps are executed for the plurality of fans.
The inspection method according to claim 1 or 2 . An inspection apparatus for inspecting a computer system comprising a fan and fan rotation speed control means for controlling the rotation speed of the fan,
A rotational speed determination means for measuring the rotational speed of the fan and determining whether or not the rotational speed is substantially the same as a specified rotational speed;
An accumulated time calculating means for calculating an accumulated time during which the fan is rotating at substantially the same speed as the specified rotation speed based on the determination of the rotation speed determining means;
Cumulative time determination means for determining the magnitude of the cumulative time calculated by the cumulative time calculation means and a specified time;
When the cumulative time determination means determines that the cumulative time is less than the specified time, the fan is rotated at the specified rotation speed with respect to the fan rotation speed control means of the computer system. and a rotational speed instruction means for outputting an instruction to,
While performing the inspection other than the inspection of the fan in the computer system, at least the rotational speed determination means and the accumulated time calculation means cause the fan to rotate at a speed substantially equal to the specified rotational speed. Calculate the accumulated time,
After the inspection other than the fan inspection is completed in the computer system, the accumulated time determination means and the rotation speed instruction means cause the fan to rotate at the specified rotation speed with respect to the fan rotation speed control means of the computer system. Outputs instructions to rotate,
Inspection equipment.

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