JP3994160B2 - Electronics - Google Patents

Description

  The present invention relates to an electronic device, and more particularly to an electronic device including a rotation unit such as a cooling fan.

  It is already known that mechanical vibration applied from the outside adversely affects the operation performance of a storage device such as a hard disk drive mounted on an electronic device such as a computer. Also known is a phenomenon in which the operating performance of a hard disk drive deteriorates due to resonance of mounted components inside the storage device.

Conventionally, in order to suppress the transmission of vibration to the hard disk drive, a vibration absorbing device using a damper devised in shape and material has been proposed (see, for example, Patent Document 1). In addition, a technology has been proposed in which vibration is detected by a sensor and the hard disk drive is switched between a normal high-speed seek mode and a low-speed seek mode with low noise and high vibration resistance according to the level of vibration (for example, patents) Reference 2). Furthermore, a technique has also been proposed in which vibration energy is absorbed by a pendulum having a natural frequency that matches the vibration frequency to suppress vibration of the hard disk drive (see, for example, Patent Document 3).
JP 2002-349634 A Japanese Patent Laid-Open No. 11-126422 JP 2002-304870 A

  The above-described countermeasures based on the existing technology are intended to protect a target unit such as a hard disk drive by controlling the amplitude of the mechanical vibration that is a problem, that is, the magnitude of the vibration. In the techniques disclosed in Patent Literature 1 and Patent Literature 3, a space is required for sandwiching components such as a damper and a pendulum in the housing of the hard disk drive or installing them separately. However, in recent electronic devices such as computers, it is difficult to secure a space for inserting an element for reducing vibration because a large number of components are mounted in a limited-size housing. . Further, according to the technique disclosed in Patent Document 2, since the mode is switched to the low-speed seek mode when vibration is large, there is a possibility that data transfer may be hindered.

The present invention has been made in view of the foregoing circumstances, and its object is to conventional using different approaches, the operation performance of the disk drive unit protected target unit, due to vibration frequency caused by the driving of another device The purpose is to provide technology that will not be affected.

In order to solve the above-described problems, the electronic device according to the present invention reduces the data transfer rate of the disk drive unit by transmitting vibration due to the rotational drive of the cooling fan fixed in the same housing to which the disk drive unit is fixed. An electronic device for preventing the rotation speed of the cooling fan as an upper limit of the rotation speed of the cooling fan, and the rotation speed at which the data transfer rate deteriorates due to an increase in vibration amplitude of the cooling fan measured in advance and the resonance frequency of the disk drive unit A storage unit that stores a resonance rotational speed that is a rotational speed of the cooling fan that generates vibration; a temperature sensor that measures a temperature of the disk drive unit that sets a lower limit of the rotational speed of the cooling fan; and A rotational speed sensor for measuring the rotational speed, and the rotational speed measured by the rotational speed sensor Zui and, the rotational speed and to avoid the resonance rotational speed between the upper and lower limits, and is characterized in that a control unit for controlling the rotational speed of the cooling fan.

It is preferable that the control unit controls the number of rotations of the cooling fan with the number of rotations avoiding the resonance number of rotations as a number of rotations within 100 rpm from the resonance number of rotations. The control unit detects that said disk drive unit has been replaced, the rotation speed of the cooling fan is continuously changed, may be measured the resonance rotational speed.

According to the present invention, so that the resonance phenomenon protected units of the disk drive unit by the vibration caused by the rotation of the cooling fan does not occur, also, to prevent the deterioration of the data transfer rate of the disk drive unit, cooling By controlling the rotational speed of the fan , it is possible to realize a stable operation performance of the disk drive unit that is the protection target unit.

  FIG. 1 shows a configuration of an electronic apparatus 1 according to an embodiment of the present invention. The electronic device 1 includes a disk drive unit 3, a plurality of cooling fans 4a and 4b, rotational speed sensors 5a and 5b, a storage unit 6, a temperature sensor 7, a speaker 8, and a control unit 10. Hereinafter, the cooling fans are collectively referred to as “cooling fans 4”, and the rotation speed sensors are collectively referred to as “rotation speed sensors 5”. The cooling fan 4 is rotationally driven by a motor. The disk drive unit 3 and the cooling fan 4 are fixed and supported in the same housing 2. Specifically, the disk drive unit 3 and the cooling fan 4 are fixed to a frame in the housing 2, and the vibration of the cooling fan 4 is transmitted to the disk drive unit 3 through the frame. In the electronic device 1 illustrated in FIG. 1, other configurations are also supported in the housing 2, but some configurations may be provided outside the housing 2. The electronic device 1 is a device including a disk drive such as a personal computer.

  In recent years, since the open space in the housing 2 has become smaller due to higher mounting density, it is difficult to provide a vibration absorbing member such as a damper. In particular, for portable personal computers, so-called notebook personal computers, it is particularly difficult to secure space due to the large user needs for downsizing including thinning. Therefore, the cooling fan 4 has to be reduced in size, and the cooling capacity is reduced. Therefore, in order to sufficiently cool the disk drive unit 3, it is necessary to increase the number of rotations and increase the number of the disk drive units 3, and it is also necessary to bring the disk drive unit 3 and the cooling fan 4 close to each other. For this reason, the influence of the rotation of the cooling fan 4 is easily transmitted to the disk drive unit 3.

  FIG. 2 shows a state in which the head 13 accesses the disk 11 in the disk drive unit 3. The actuator 12 can rotate in the horizontal direction around the bearing shaft 14, and the carriage 15 moves and positions the head 13 to the target sector of the disk 11. This positioning requires micron-order accuracy. Therefore, when the actuator 12 vibrates, positioning takes time, and positioning may not be possible. A tracking error occurs and the data transfer rate deteriorates. Therefore, it is preferable to reduce the vibration of the disk drive unit 3 as much as possible.

  FIG. 3 shows an example of experimental results showing the relationship between the rotational speed of the cooling fan 4 and the data transfer rate of the disk drive unit 3. In the measurement of the data transfer rate, conditions other than the rotation speed of the cooling fan 4 are the same. The horizontal axis represents the number of rotations of the cooling fan 4, the right vertical axis represents the transfer rate, and the left vertical axis represents the dispersion value. The number of rotations of the cooling fan 4 was set at intervals of about 100 rpm, and the transfer rate was measured 10 times per rotation number. In FIG. 3, the maximum transfer rate, the average transfer rate, the minimum transfer rate, and the dispersion values of the measured 10 transfer rates are plotted. The rotational speed of the disk drive unit 3 was 7200 rpm.

  FIG. 4 shows an example of experimental results obtained by performing the same measurement using a shaking table that can arbitrarily set the vibration frequency while keeping the vibration amplitude constant, instead of the cooling fan 4. The vibration frequency of the shaking table is set at an interval of 1 Hz (corresponding to the rotation speed of 60 rpm), and at each frequency, continuous area reading (Seq.Read), continuous area writing (Seq.Write), and random The transfer rate in the case of area reading (RandomRead) and random area writing (RandomWrite) is measured and plotted. The rotational speed of the disk drive unit 3 was 7200 rpm. In this experiment, the influence of the change in the amplitude of vibration could be eliminated, and the data transfer rate could be measured over a wider range of rotation speeds.

  According to the results of these experiments, as shown in the figure, a downward peak occurs when the rotation speed of the cooling fan 4 is in the range of about 2800 rpm to 3700 rpm, and about 3900 rpm, about 6000 rpm, and about 6500 rpm. The transfer rate has dropped significantly. The present inventor analyzed this experimental result, and the resonance phenomenon occurred when the frequency of vibration generated by the rotation of the cooling fan 4 coincided with or approached the resonance frequency of the structure inside the disk drive unit 3. It was found that the transfer rate was deteriorated due to the increase in the vibration amplitude of the actuator 12. In this case, it was also found that the transfer rate is normal at a rotational speed shifted by 100 rpm from the rotational speed causing the resonance phenomenon. Further, as shown in the figure, the measurement value of the transfer rate varies greatly in the region exceeding about 4200 rpm. The inventor found that the drop in the transfer rate in the region exceeding about 4200 rpm is not due to the vibration frequency, but the increase in the vibration amplitude with the increase in the rotational speed, by comparison with the transfer rate in the region of about 4200 rpm or less. According to the knowledge.

  Based on the knowledge obtained from the above experimental results, in this embodiment, the upper limit of the rotational speed of the cooling fan 4 is set to the rotational speed at which the transfer rate deteriorates due to an increase in the vibration amplitude of the cooling fan 4. That is, according to the example of FIG. 3, about 4200 rpm is set as the upper limit of the rotation speed. By suppressing the number of rotations of the cooling fan 4 below this upper limit, it is possible to avoid deterioration of the transfer rate due to vibrations generated during high rotations and to suppress the generation of noise. Further, since the cooling fan 4 cools the disk drive unit 3, the number of rotations determined so as to exhibit the minimum cooling effect is set as a lower limit according to the temperature of the disk drive unit 3. This lower limit value varies depending on the temperature. Specifically, the lower limit value increases if the temperature of the disk drive unit 3 is high, and the lower limit value decreases if the temperature is low.

  In this embodiment, the cooling fan is within a range away from the rotational speed (hereinafter referred to as “resonant rotational speed”) that generates vibration at the resonant frequency of the disk drive unit 3 between the lower limit and the upper limit of the rotational speed. 4 is controlled. 3 and 4, the range of 2800 rpm to 3700 rpm and 3900 rpm, 6000 rpm, and 6500 rpm correspond to the resonance rotational speed, and the cooling fan 4 is controlled so that the rotational speed does not fall within 100 rpm from these resonance rotational speeds. . Specifically, the rotation speed of the cooling fan 4 is controlled so that it does not fall within the range of about 2700 to about 4000 rpm between the lower limit and the upper limit.

  Returning to FIG. 1, the resonance frequency of the disk drive unit 3 is hardly affected by aging and the like, and hardly changes unless the mounting state in the housing 2 is changed. On the other hand, the output characteristics of the cooling fan 4 are easily affected by aging, and there are large individual differences. Therefore, even when the same drive voltage is applied to the cooling fan 4, the output varies from individual to individual, and the output varies with time. This is because the cooling fan 4 does not require strict output characteristics. Therefore, in order to control the rotational speed of the cooling fan 4 within a range away from the resonant rotational speed, the actual rotational speed of the cooling fan 4 is measured instead of monitoring the applied voltage, and the measurement result is obtained. It is necessary to feed back to the applied voltage. In this embodiment, the rotation speed sensor 5 measures the number of rotations of each cooling fan 4 and transmits an electric pulse signal proportional to the number of rotations to the control unit 10.

The storage unit 6 stores a resonance rotational speed that is the rotational speed of the cooling fan 4 that generates vibration at the resonance frequency of the disk drive unit 3. The resonance rotational speed may be measured, for example, before shipment of the electronic device 1 and may be already stored in the storage unit 6 at the time of shipment. Furthermore, the storage unit 6 also stores an upper limit of the rotational speed of the cooling fan 4. The storage unit 6 may be a partial area of the disk 11 in the disk drive unit 3. The temperature sensor 7 measures the temperature of the disk drive unit 3 and transmits the measurement result to the control unit 10.

  The control unit 10 receives the measurement result of the temperature sensor 7 and sets the lower limit of the rotational speed of the cooling fan 4. Further, the control unit 10 reads the resonance rotational speed and the upper limit of the rotational speed from the storage unit 6 and sets a suitable range of the rotational speed of the cooling fan 4. As described above, the control unit 10 sets the rotation speed range away from the resonance rotation speed. This setting range may be determined by the control unit 10 or may be stored in the storage unit 6 in advance. The control unit 10 performs control so that the number of rotations of the cooling fan 4 falls within this setting range based on the measurement result by the rotation speed sensor 5. That is, when the rotational speed of the cooling fan 4 deviates from the setting range, the control unit 10 controls the voltage applied to the cooling fan 4 so as to return to the setting range. Thereby, it is possible to prevent the transfer rate of the disk drive unit 3 from deteriorating due to resonance. If the rotation speed cannot be controlled within the set range due to a failure of the cooling fan 4, an alarm may be issued from the speaker 8.

  The present invention has been described above based on the embodiment. The present invention is not limited to this embodiment, and various modifications thereof are also effective as aspects of the present invention.

The resonance rotational speed is determined not only by the structure of the disk drive unit 3 but also by the influence of the internal structure of the electronic device 1, and may be different for each manufacturer or model of the electronic device 1 and the disk drive unit 3. In particular, in recent years, model changes are fast, and even with the same model, the resonance frequency may differ due to minor version upgrades. Therefore, when the disk drive unit 3 is replaced or when the internal mounting state of the electronic device 1 is changed, it is preferable to newly measure the resonance rotational speed of the cooling fan 4 again.

  For example, when the control unit 10 detects that the disk drive unit 3 has been replaced, it is preferable to continuously change the rotational speed of the cooling fan 4 and measure the resonant rotational speed. Thereby, the control part 10 becomes possible [controlling the rotation speed of the cooling fan 4 appropriately according to the change of an environment]. Note that the timing for measuring the resonance rotational speed may be performed at a predetermined cycle, or may be performed when the frequency of occurrence of tracking errors becomes high. By updating the resonance rotational speed to an appropriate value, it is possible to avoid resonance that occurs in the electronic device 1.

It is a figure which shows the structure of the electronic device which concerns on an Example. It is a figure which shows the state in which a head accesses a disk in a disk drive unit. It is a figure of the experimental result which shows the relationship between the rotation speed of a cooling fan, and the data transfer rate of a disk drive unit. It is a figure of the experimental result which shows the relationship between the vibration of a vibration stand, and the data transfer rate of a disk drive unit.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Electronic device, 2 ... Housing, 3 ... Disk drive unit, 4 ... Cooling fan, 5 ... Rotational speed sensor, 6 ... Memory | storage part, 7 ... Temperature sensor , 8 ... Speaker, 10 ... Control unit, 11 ... Disk, 12 ... Actuator, 13 ... Head, 14 ... Bearing shaft, 15 ... Carriage.

Claims (3)

An electronic device that transmits a vibration caused by a rotational drive of a cooling fan fixed in the same housing to which the disk drive unit is fixed to prevent deterioration of a data transfer rate of the disk drive unit,
The rotation of the cooling fan that generates vibrations at the resonance frequency of the disk drive unit and the rotation speed at which the data transfer rate deteriorates due to the increase in the vibration amplitude of the cooling fan measured in advance as the upper limit of the rotation speed of the cooling fan. A storage unit for storing the number of resonance rotations that is a number;
A temperature sensor for measuring a temperature of the disk drive unit for setting a lower limit of the number of rotations of the cooling fan;
A rotation speed sensor for measuring the number of rotations of the cooling fan;
Based on the rotational speed measured by the rotational speed sensor, a controller that controls the rotational speed of the cooling fan between the upper limit and the lower limit and avoiding the resonant rotational speed;
An electronic device comprising: The electronic device according to claim 1,
The electronic device according to claim 1, wherein the control unit controls the number of rotations of the cooling fan by setting the number of rotations avoiding the resonance number of rotations as a number of rotations within 100 rpm from the resonance number of rotations. The electronic device according to claim 1,
When the control unit detects that the disk drive unit has been replaced, the control unit continuously changes the number of rotations of the cooling fan and measures the resonance number of rotations.

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