KR100650517B1 - Shock-resistant magnetic storage medium for a portable electronic device - Google Patents

Abstract

The impact resistant magnetic storage medium 1 has a circuit protection module 10 connected between the power converter 101 and the magnetic disk assembly 100. The circuit protection module 10 includes an acceleration sensor 104 for generating an output signal indicating a falling state of the magnetic disk assembly 100; A switch 103 operable to make or break a circuit connection between the power converter 101 and the magnetic disk assembly 100; Based on the output signal from the acceleration sensor 104, the switch 103 is controlled to cut off the circuit connection between the power converter 101 and the magnetic disk assembly 100, so that the magnetic disk when the magnetic disk assembly 100 is dropped. It is equipped with a processor 102 that would interfere with powering the assembly 100.

Description

Shock-resistant magnetic storage medium for portable electronic devices {SHOCK-RESISTANT MAGNETIC STORAGE MEDIUM FOR A PORTABLE ELECTRONIC DEVICE}

1 is a schematic diagram of a hard disk for a conventional portable electronic device,

2 is a schematic block diagram of a preferred embodiment of an impact resistant magnetic storage medium for a portable electronic device according to the present invention;

3 is a schematic view showing a shock-resistant magnetic storage medium of a preferred embodiment which forms an angle θ with respect to the Z axis when in a falling state;

4 illustrates a portable electronic device incorporating the impact resistant magnetic storage medium of the preferred embodiment when falling from the ground to the height H ₁ .

The present invention relates to a data storage medium, and more particularly to a shock resistant magnetic storage medium that is easily damaged when dropped. The present invention also relates to a portable electronic device incorporating an impact resistant magnetic storage medium.

Portable electronic devices such as MP3 players, still and mobile cameras, and smart mobile phones are very popular today. In general, some of these devices have built-in miniature hard disks that allow for the storage of large amounts of digital data such as audio and / or image files. For example, Apple Computer's iPod Mini ^® incorporates a small 4GB hard disk that can be used to store up to 1000 audio files.

Referring to FIG. 1, a conventional hard disk 9 generally includes a base 91, at least one magnetic disk 92, a spindle motor 93, a voice coil motor 94, and a base 91. And at least one read / write (R / W) arm set 95 with an arm 951 and a magnetic head 952. If there is more than one magnetic disk 92, each magnetic disk 92 is associated with a set of magnetic heads 952 each corresponding to the upper and lower magnetic recording surfaces of the disk 92. Arm 951 moves each magnetic head 952 for writing data to or reading data from the corresponding magnetic recording surface of disk 92. In addition, the hard disk 9 has a parking area (not shown) next to the magnetic disk 92. Each magnetic head 952 can be parked in the parking area to avoid scratching the magnetic disk 92.

The data is recorded on the magnetic recording surface of the magnetic disk 92 by dividing the file into sector data. The arm 951 is driven by the voice coil motor 94 to move back and forth in the sector of the magnetic recording surface of the magnetic disk 92. Since the operation of the magnetic head 952 is based on the electromagnetic sensing principle, and the magnetic head 952 is designed to float with respect to the magnetic disk 92, the magnetic head 952 is the magnetic disk 92. It is not necessary to contact the corresponding surface of the mass so that a large amount of data can be quickly written to or read from the magnetic disk 92. Therefore, it is necessary to place a magnetic disk 92 plate associated with the base 91 so that a proper distance can be maintained between the magnetic recording surface and the corresponding magnetic head 952 to prevent damage and to ensure proper writing and reading of data. There is.

Since the hard disk 9 is a mechanical device, physical damage may occur due to external force or drop, regardless of high speed or idle operation. Therefore, a small hard disk installed in a portable electronic device requires severe shock protection. In general, there are two techniques widely used in this industry to improve the impact protection characteristics of small hard disks in portable electronic devices. The first technique involves the use of buffer materials to mitigate impact. The second technique involves interrupting the read / write function based on the detected speed to minimize the possibility of damage from impact.

However, the above-described protection technique has the following drawbacks.

1. In the first technique, a buffer layer is formed on the outer circumference of a hard disk to mitigate an impact. To improve protection when falling from higher heights, the thickness of the buffer layer must be increased, which increases the overall size of the hard disk. For example, if the buffer material of the outer circumference of the hard disk is rubber, 5 mm thickness is only sufficient to alleviate the impact force of about 20 G.

2. In the second technique, a G-sensor is used to detect the fall of a portable electronic device. Thus, the read / write function of the magnetic head can be terminated before the portable electronic device reaches ground. In the case of a hard disk, when the device (not shown) detects a state in which the device is dropped, the movement of the R / W arm set 95 and the magnetic disk 92 is prevented in order to prevent damage to the magnetic disk 92. Will issue a command to, for example, the 8-bit address bus of the ATAPI of the IDE interface. However, in the second technique, the time period from the fall detection to the stop command is relatively long.

In general, while the mobile phone is placed on the user's ear during use, the MP3 player is placed in the user's pocket and the earphone is connected to the MP3 player and inserted into the user's ear. In both cases, mobile phones or MP3 players are generally placed 1 to 1.5 meters high from the ground. Therefore, storage media for portable electronic devices must have adequate impact protection when dropped from these heights to meet actual user needs.

It is a main object of the present invention to provide an impact resistant magnetic storage medium which is not easily damaged when dropped and can overcome the above-mentioned drawbacks of the prior art.

Another object of the present invention is to provide a portable electronic device incorporating the impact-resistant magnetic storage medium of the present invention.

According to a first aspect of the invention, a shock-resistant magnetic storage medium comprises: a power converter suitable for converting power from a power source into a power signal; A magnetic disk assembly having a magnetic recording unit for recording data, and a read / write mechanism for reading data from and writing data to the magnetic recording unit; Equipped with a circuit protection module. The circuit protection module includes an acceleration sensor for generating an output signal indicative of a falling state of the magnetic disk assembly; A switch connected between the power converter and the magnetic disk assembly and operable to make or break a circuit connection between the power converter and the magnetic disk assembly; It is electrically connected to acceleration sensors, switches, power converters and magnetic disk assemblies, and has a processor to control the operation of the magnetic disk assembly.

Moreover, the processor controls the switch to disconnect the circuit connection between the power converter and the magnetic disk assembly based on the output signal from the acceleration sensor, which prevents power supply to the magnetic disk assembly when the magnetic disk assembly is dropped. .

According to a second aspect of the present invention, a portable electronic device has a housing and the above-described shock-resistant magnetic storage medium provided in the housing.

(Example of the invention)

2 and 4, the shock-resistant magnetic storage medium 1 of the preferred embodiment according to the present invention is a portable computer, an MP3 player, a mobile phone or the like for storing not only audio and / or image files but also data files. Applicable for use in electronics 3 (see FIG. 4).

The shock-resistant magnetic storage medium 1 of the present invention is installed inside the housing 31 of the portable electronic device 3, and has a magnetic disk assembly 100, a power converter 101, and the magnetic disk assembly 100 and electric power. The circuit protection module 10 is connected between the transducers 101. Preferably, in order to achieve an optimal protective function, the impact-resistant magnetic storage medium 1 further includes a protective layer (not shown) made of a buffer material such as rubber and formed on the outer circumference of the magnetic disk assembly 100. . This protective layer has a thickness in the range of 1.5 mm to 2 mm.

The power converter 101 is used to convert power from a power source into a power signal suitable for applying to various components of the magnetic storage medium 1. For example, the power converter 101 may be supplied from a 5 volt power signal from an adapter or an internal battery to obtain a stable 3.3 volt DC signal for supplying the magnetic disk assembly 100 and the processor 102 of the circuit protection module 10. Can be configured to convert a 7 volt power signal.

The magnetic disk assembly 100 includes a magnetic recording unit 120 for recording data and an R / W mechanism 140 for reading data from the magnetic recording unit 120 and writing data to the magnetic recording unit 120. Equipped. Examples of such storage media include hard disks and optical R / W devices (DVD and / or CD R / W devices).

In this embodiment, the magnetic disk assembly 100 is a hard disk and further includes a spindle motor 13 for driving the base 11 and the magnetic recording unit 120. The R / W mechanism 140 is provided at the voice coil motor 14, the arm 15, the magnetic head 16 installed at the end of the arm 15, the parking seat 17, and the base 11. Equipped with a transmission interface (18). Since the basic components and operating principle of the hard disk are well known in the art and not appropriate to the claimed invention, they are not further described here for the sake of brevity.

The circuit protection module 10 connected between the magnetic disk assembly 100 and the power converter 101 includes a processor 102, a switch 103, and an acceleration sensor 104.

The processor 102 is electrically connected to the power converter 101 and the transmission interface 18 and the acceleration sensor 104 of the magnetic disk assembly 100. The processor 102 may also control various operations of the magnetic disk assembly 100 except that the processor 102 may control a power supply function of the power converter 101. For example, the processor 102 may control the speed of the spindle motor 13 through the data transmission bus, and for the operation of the controller (not shown) of the voice coil motor 14 and the magnetic recording unit 120 or the like. Data R / W function can be controlled. In addition, the processor 102 may control the switching function of the switch 103 in the manner described below.

The switch 103 is electrically connected to the magnetic disk assembly 100, the power converter 101, and the processor 102. Preferably, the switch 103 is a transistor such as a PNP or FET transistor. In this embodiment, the switch 103 is a PNP transistor controlled by the processor 102 to make or break the circuit connection 105 between the power converter 101 and the magnetic disk assembly 100.

In this embodiment, the base B of the transistor is electrically connected to the GPIO control pin of the processor 102. The collector C of the transistor is electrically connected to the magnetic disk assembly 100. The emitter E of the transistor is electrically connected to the power converter 101 to receive the later output voltage. Under normal operating conditions, the processor 102 controls the transistor via its GPIO control pin to make or break the circuit connection 105 between the power converter 101 and the magnetic disk assembly 100. That is, power is supplied to the magnetic disk assembly 100 through the collector C of the transistor. When it is determined by the processor 102 that interferes with powering the magnetic disk assembly 100, the processor 102 disconnects the circuit connection 105 between the power converter 101 and the magnetic disk assembly 100. To control the transistor through its GPIO control pin, thereby forcibly interrupting the supply of power to the magnetic disk assembly 100.

In this embodiment, the acceleration sensor 104 is a well known gravity acceleration sensor that generates an output signal in response to the detected change in rotation angle with respect to three axes, i.e., the X, Y, and Z axes. The acceleration sensor 104 is disposed at the center of a circuit board (not shown) of the circuit protection module 10. The circuit board has a processor 102 and a switch 103 mounted thereon. When the magnetic disk assembly 100 is in a falling state, the acceleration sensor 104 generates an output signal representing the detected change in rotational angle with respect to three axes, i.e., X, Y, and Z axes. The output signal of the acceleration sensor 104 is supplied to the processor 102, and the A / D (analog-to-digital) converter 110 of the processor 102 transmits the output signal to a threshold which is preset in the processor 102. Convert to a digital signal for subsequent comparison. Based on the comparison result, the processor 102 may determine whether the magnetic disk assembly 100 is in a falling state.

In the conventional protection scheme, upon detecting that the change in gravity acceleration of any of the three axes has exceeded the corresponding threshold, emergency measures such as interruption of the read / write function for the magnetic recording unit by the R / W mechanism are executed. A shock detection signal will be generated to enable this. However, this protection can only be applied for example of small vibrations. Damage to magnetic storage media is inevitable because power is still supplied at a height of 1 to 1.5 meters from the ground.

In the preferred embodiment, since the magnetic disk assembly 100 rotates as the magnetic storage medium 1 falls to ground, the processor 102 receives the output signal from the acceleration sensor 104 and receives the A / D. It is determined whether the digital signals obtained by the converter 110 exceed their corresponding thresholds. Upon detecting that one of the digital signals has exceeded the corresponding threshold, the processor 102 controls the switch 103 to disconnect the circuit connection 105 between the power converter 101 and the magnetic disk assembly 100. At this time, since the controller (not shown) of the voice coil motor 14 no longer receives power from the transmission interface 18, no energy is supplied to the voice coil motor 14, and the arm 15 and The magnetic head 16 on the arm 15 can move automatically to park the parking sheet 17 to avoid damage to the magnetic recording unit 120 and the magnetic head 16. In other words, possible damage to the magnetic recording unit 120 can be reduced to a minimum when the magnetic storage medium 1 falls to the ground.

2 and 3, the magnetic storage medium 1 is rotated at an angle θ with respect to the Z axis. The magnitude of the output signal from the acceleration sensor 104 changes with the angle θ. In the preferred embodiment, if the repeated sampling (n = 5) corresponding to the Z-axis angular component indicates that the corresponding threshold has been repeatedly exceeded, processor 102 accordingly disconnects circuitry through switch 103. You can decide to.

2 and 4, when the magnetic storage medium 1 is installed in the housing 31 of the portable electronic device 3 and the portable electronic device 3 falls from the height H ₁ , the time required for reaching the ground is shown. Is S ₁ . In the present invention, the decision to change the magnetic storage medium 1 from the operating state to the inactive state can be made within a time S _{2 which} is much shorter than the time S ₁ . That is, the portable electronic device 3 has fallen from a small portion H ₂ of height H ₁ .

Based on the actual experiment, if the height H _{1, which} is the first distance of the portable electronic device 3 embedded in the magnetic storage medium 1 from the ground 4, is 1 meter, it is necessary to deactivate the magnetic storage medium 1 in the operating state. The response time S2 required of the processor 102 to determine whether it is necessary to change to the operating state is about 200 ms. In other words, the portable electronic device 3 fell away at a distance H ₂ of about 30 cm. When disturbing the power supply to the magnetic disk assembly 100, the arm 15 of the magnetic disk assembly 100 and the magnetic head 16 on the arm 15 are to avoid damage to the magnetic recording unit 120. The parking sheet 17 is returned to. When the magnetic storage medium 1 is in the inoperative state, the impact resistance may reach as high as 2000G.

The following is a part of the advantages of the impact-resistant magnetic storage medium 1 of the present invention over the prior art.

1. In the present invention, powering the controller of the magnetic disk assembly 100 and the voice coil motor 14 exceeds a corresponding threshold in which the rotation angle for any one of the three axes is set in advance in the system. It is strongly disturbed upon detection through one acceleration sensor 104. Since the magnetic storage medium 1 is in an inoperative state at the time of power interruption, the impact resistance can reach as high as 2000G.

On the other hand, when the magnetic storage medium is in the operating state, the impact resistance is only about 200G. In addition, the prior art requires about 300 to 400 ms to pull back the arm and the magnetic head by issuing appropriate commands via the ATAPI's 8-bit address bus on the IDE interface. In the present invention, only 20-50 ms is required to interrupt the supply of power and return the arm 15 and the magnetic head 16 to the parked state.

2. If the processor 102 controls the switch 103 to interfere with supplying power to the magnetic disk assembly 100, it will interfere with supplying power to the controller of the voice coil motor 14. As a result, no energy will be supplied to the voice coil motor 14, and the arm 15 of the R / W mechanism 140 and the magnetic head 16 on the arm 15 may cause the magnetic storage medium 1 to fall. Will be moved to the parked position to minimize the possibility of damage to the magnetic recording unit 120 and the magnetic head 16.

3. For the reasons described in paragraphs 1 and 2 above, the thickness of the protective layer on the outer periphery of the magnetic disk assembly 100 can be reduced to 1.5 mm, thus allowing portable electronic devices to meet the actual needs of consumers. The corresponding increase in the overall dimensions of (3) is minimized.

Although the present invention has been described in connection with various specific embodiments, the present invention is not limited thereto, and various modifications can be made without departing from the spirit of the invention.

As described above, according to the present invention, it is possible to provide a shock-resistant magnetic storage medium which is not easily damaged when dropped and can overcome the above-mentioned drawbacks of the prior art, and also incorporates the impact-resistant magnetic storage medium of the present invention. Can be provided.

Claims (8)

Shock-resistant magnetic storage medium (1), A power converter 101 suitable for converting power from a power source into a power signal; A magnetic disk assembly having a magnetic recording unit 120 for recording data and a read / write mechanism 140 for reading data from and writing data to the magnetic recording unit 120. 100 and; Equipped with a circuit protection module (10), An acceleration sensor (104) for the circuit protection module (10) to generate an output signal indicating a falling state of the magnetic disk assembly (100); A switch 103 connected between the power converter 101 and the magnetic disk assembly 100 and operable to make or break a circuit connection between the power converter 101 and the magnetic disk assembly 100. ) And; A processor electrically connected to the acceleration sensor 104, the switch 103, the power converter 101, and the magnetic disk assembly 100, and capable of controlling the operation of the magnetic disk assembly 100 ( 102) The processor 102 controls the switch 103 to disconnect a circuit connection between the power converter 101 and the magnetic disk assembly 100 based on an output signal from the acceleration sensor 104, Impact resistant magnetic storage medium, characterized in that when the magnetic disk assembly (100) is dropped to prevent the supply of power to the magnetic disk assembly (100). The shock-resistant magnetic storage medium according to claim 1, wherein the acceleration sensor (104) is a gravity acceleration sensor which generates an output signal in response to the detected change in the rotation angle with respect to three axes. 3. The comparison according to claim 2, wherein the processor (102) converts the output signal from the acceleration sensor (104) into a digital signal, compares the digital signal with a preset threshold, and obtains a comparison obtained by the processor (102). The impact-resistant magnetic storage medium, characterized in that it is determined whether to interrupt the supply of power to the magnetic disk assembly (100) based on the result. 2. The processor (100) of claim 1, wherein the processor (102) compares the output signal from the acceleration sensor (104) with a preset threshold and based on the comparison result obtained by the processor (102). Impact resistant magnetic storage medium, characterized in that for controlling. The shock-resistant magnetic storage medium according to claim 1, wherein the switch (103) is a transistor. 6. The shock-resistant magnetic storage medium according to claim 5, wherein the transistor is one of a FET and a PNP transistor. 2. The magnetic disk assembly 100 further comprises a transmission interface 18, The R / W mechanism 140 transmits the R / W mechanism 140 when the circuit 103 disconnects the circuit connection between the power converter 101 and the magnetic disk assembly 100 by the switch 103. Shock-resistant magnetic storage medium, characterized in that returned to the parked state next to the magnetic recording unit 120 to avoid damaging the magnetic recording unit 120 when the power is not received through the interface 18 . The portable electronic device 3 is A housing 31; A magnetic storage medium 1 installed in the housing, The magnetic storage medium 1, A power converter 101 suitable for converting power from a power source into a power signal; A magnetic disk assembly having a magnetic recording unit 120 for recording data and a read / write mechanism 140 for reading data from and writing data to the magnetic recording unit 120. 100 and; Equipped with a circuit protection module (10), An acceleration sensor (104) for the circuit protection module (10) to generate an output signal indicative of a falling state of the housing (31); A switch 103 connected between the power converter 101 and the magnetic disk assembly 100 and operable to make or break a circuit connection between the power converter 101 and the magnetic disk assembly 100. ) And; A processor electrically connected to the acceleration sensor 104, the switch 103, the power converter 101, and the magnetic disk assembly 100, and capable of controlling the operation of the magnetic disk assembly 100 ( 102) The processor 102 controls the switch 103 to disconnect a circuit connection between the power converter 101 and the magnetic disk assembly 100 based on an output signal from the acceleration sensor 104, Portable electronic device, characterized in that when the housing (31) is dropped to prevent the supply of power to the magnetic disk assembly (100).

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