JP3187629U - External storage device - Google Patents

Abstract

An external storage device that effectively provides a necessary power supply and simplifies the design of a driving and control electric circuit.
An external storage device includes a plurality of hard disks, one bridge control unit, one bridge unit, one connection port, and one voltage conversion circuit. The bridge control unit electrically connects a plurality of hard disks, arranges several disks, and converts a USB signal into a SATA signal. The connection port electrically connects a plurality of hard disks, and the voltage conversion circuit electrically connects the control unit and bridges the bridge unit. The external storage device receives one power source provided by the electronic device via one transmission line, and the power source is directly transmitted to the hard disk via the connection port to drive the hard disk. Since the voltage conversion circuit converts the power source and supplies power to the control unit and the bridge unit, it is not necessary to externally connect the power supply unit and the transformer.
[Selection] Figure 1

Description

  The present invention relates to a circumscribing storage device, and more particularly to a circumscribing storage device having a plurality of hard disks.

  In recent years, computer multimedia has been actively developed along with the progress of science and technology, and the demand for storage data capacity is increasing day by day, so that the demand for external storage devices tends to be popular. A circumscribing storage device, such as a 500G or 1T portable hard disk, can store a relatively large amount of multimedia data by the circumscribing storage device.

  In addition, due to the widespread use of notebook computers and desktop computers, the capacity of the original hard disk becomes relatively small, or there is a problem with the data to be carried. In addition to the frequent increase in the number of days, the volume of the 2.5-inch circumscribing storage device is further reduced, so that the user has more and more opportunities to use the 2.5-inch circumscribing storage device.

However, a typical external storage device always has a transformer, and after the general external storage device connects the electronic device via a transmission line, the electronic device supplies a power supply to the general external storage device. However, since the current provided by the electronic device is insufficient, the operation of a general external storage device cannot be driven.
Thus, the designer can always block the aforementioned power supply in a general external storage device, and by considering the transformer as the main power supply, a 5 volt / 2 ampere power supply or 12 volt / Provide a 2 amp power supply.
In addition, it is necessary to provide the necessary power supply to the control chip, but the power supply still needs to reduce the voltage via the voltage step-down circuit, which drives a general external storage device. The circuit design is very complex and consumes a relatively large amount of electrical energy. For this reason, wear of electric energy is caused naturally.

  Therefore, how to effectively provide the power source demanded by the external storage device and simplify the design of the electric circuit is an issue that needs to be examined immediately.

  The present invention solves the aforementioned problems by providing a circumscribing storage device.

  The present invention provides an external storage device, and includes a plurality of hard disks, one control unit, one bridge unit, one connection port and one voltage conversion circuit. A control unit is used to electrically connect these hard disks, align these hard disks into several disk arrays, and a bridge unit electrically connects the control units to the universal A serial bus (USB) signal is converted into a (SATA) signal. A connection port electrically connects these hard disks. A voltage conversion circuit electrically connects the control unit and the bridge unit. Among them, the external storage device accepts one power source provided by the electronic device via one transmission line, and the power source directly transmits to these hard disks via the connection port, so that these hard disks are Drive, convert the voltage conversion circuit to a relatively low voltage, and provide the necessary power supply to the control unit and the bridge unit.

  In one embodiment of the present invention, the transmission line has one first connection interface and one second connection interface, the first connection interface connects the connection port, The connection interface connects the output connection port of the electronic device, the connection port is a connector that conforms to the Universal Serial Bus 3.0 or 2.0 standard, and the second connection interface is the Universal Serial Bus 3.0 standard It is a connector that conforms to

  In one embodiment of the present invention, the voltage conversion circuit described above converts the power supply to a single first voltage, and the voltage conversion circuit provides the first voltage to the bridge unit.

  In one embodiment of the present invention, the voltage conversion circuit is a pulse modulator or a low dropout voltage regulator.

  In one embodiment of the present invention, the above-described voltage conversion circuit converts the power source to one first voltage and one second voltage, and the voltage conversion circuit converts the first voltage to the first voltage. A second voltage is provided to the bridge control unit.

  In one embodiment of the present invention, the voltage conversion circuit described above has one first conversion element and one second conversion element, and the first conversion element couples the second conversion element. The first conversion element is a pulse modulator or a low dropout voltage regulator and the second conversion element is a pulse modulator or a low dropout voltage regulator.

  In one embodiment of the present invention, the above-described voltage conversion circuit includes one third conversion element, and the third conversion element is a dual output port pulse modulator.

  In an embodiment of the present invention, the transmission line is a Y-type transmission line, and has one first connection interface, one second connection interface, and one third connection interface. The first connection interface connects the connection port, the connection port is Universal Serial Bus 3.0 or Universal Serial Bus 2.0, and the second connection interface and the third connection interface are outputs of the electronic device. Connect the connection port, the second connection interface is Universal Serial Bus 3.0 or Universal Serial Bus 2.0, and the third connection interface is Universal Serial Bus 3.0 or Universal Serial Bus Bus 2.0.

In one embodiment of the present invention, the bridge control unit described above is used to convert a USB signal into a SATA signal, and the bridge control unit has one disk array controller, It is used to align these hard disks to these disk arrays.
In addition, the disk array controller distinguishes the disk array to be in different storage modes, thereby achieving an effective transmission effect and data backup support function, and each hard disk is a 2.5 inch hard disk (HDD). ) Or solid state disk (SSD).

  In an embodiment of the present invention, the external storage device further includes a communication unit, the communication unit electrically connects the bridge control unit, and the communication unit wirelessly transmits one data signal. Used to receive and / or transmit.

  The above overview and the following embodiments are all used to further explain the technical means and achievements of the present invention, however, only the described embodiments and drawings are provided for reference and explanation, and It is not used to limit the idea more.

The specific means of the present invention is to supply the power transmitted using the electronic device directly to these hard disks, and to obtain a voltage that meets the demand of the bridge control unit via the voltage conversion circuit. Then, the bridge control unit controls the hard disk to access data.
Based on the above-described mechanism, the design of the drive circuit of the external storage device may be simplified, and the availability and electrical energy saving effect / function of the electrical energy can be improved.

It is a block schematic diagram of the function of the external storage device of an embodiment of the present invention. It is a block schematic diagram of the function of the external storage device of another embodiment of the present invention. It is a block schematic diagram of the function of the external storage device of another embodiment of the present invention. It is a block schematic diagram of the function of the external storage device of another embodiment of the present invention.

[First embodiment]
FIG. 1 is a schematic block diagram of functions of a circumscribed storage device according to an embodiment of the present invention. Please refer to FIG. The external storage device 1 includes a plurality of hard disks 10, one bridge control unit 12, one connection port 16, one voltage conversion circuit 18, and one transmission line 20.
In practice, the external storage device 1 connects the electronic device 9 via the transmission line 20, and the electronic device 9, such as a computer, a notebook computer, or a tablet PC (personal computer), is connected to the external storage device by the electronic device 9. Data access and data backup operations may be performed on the device 1.

The transmission line 20 is a transmission line of, for example, a single cable, and has a first connection interface 202 and a second connection interface 204. The first connection interface 202 connects the connection port 16 and the second connection interface 202. The connection interface 204 connects the output connection port 16 of the electronic device 9 and the second connection interface 204 is the universal serial bus 3.0 or the universal serial bus 2.0.
The present embodiment is not limited to the mode of the transmission line of a single cable, but in other embodiments, the transmission line 20 may be a Y-type transmission line. A person having ordinary knowledge may design based on the actual use situation.

Specifically, the Universal Serial Bus 3.0 standard can provide 900 milliamps of current, and the Universal Serial Bus 2.0 standard can provide 500 milliamps of current. Thus, when the transmission line 20 is, for example, a Y-type transmission line, the transmission line 20 provides a current of 1400 milliamperes or more via the universal serial bus 3.0 and 2.0 standards, or the transmission line 20 For example, when the transmission line is a single-cable cable, the transmission line 20 provides a current of 900 milliamperes or more via the universal serial bus 3.0 standard, or the transmission line 20 is a universal serial bus. Provides over 500 milliamps of current through the bus 2.0 standard.
This drives the operation of the external storage device 1 of the present invention. This embodiment does not limit the magnitude of current for driving and operating the external storage device 1.

  The external storage device 1 of the present invention does not have a complicated transformer circuit design, but this reduces the wear of electrical energy and simplifies the drive based on the power supply provided by the electronic device 9 The circuit is designed to achieve the data access operation of the external storage device 1.

The plurality of hard disks 10 in this embodiment are, for example, 2.5 inch hard disks (HDD) or solid disks (SSD), and the number of hard disks 10 in this embodiment is two. Do not limit the quantity of ten.
In practice, the hard disk (HDD) may be a hard disk that conforms to SATAI (1.5 Gb / s), SATAII (3.0 Gb / s), or SATAIII (6.0 Gb / s) or higher. Solid disks (SSD) are hard disks that can meet SATA III (6.0 Gb / s) or higher standards, and hard disks that conform to SATA standards such as hard disks (HDD) or solid disk (SSD) can also be stored in physical storage blocks. The hard disk 10 may be used for data access and data backup.

A bridge control unit 12 is electrically connected between these hard disks 10 and the voltage conversion circuit 18 and is used to combine these hard disks 10 into several disk arrays.
The bridge control unit 12 is, for example, a FUJITSU MB86E501 chip, but this embodiment does not limit the mode of the bridge control unit 12. For example, in this embodiment, the bridge control unit 12 has various functional blocks, and the bridge control unit 12 has a bridge block (not shown) and a control block (not shown). The embodiment of the various functional blocks of the bridge control unit 12 is not limited by the present embodiment, and a person who has ordinary knowledge in the technical field to which the user belongs may design based on the actual use situation.

  In this embodiment, the bridge control unit 12 can control the hard disk 10 by converting the USB signal into a SATA signal. The control unit 12 controls the hard disk 10 to access data. In addition, a data backup operation may be performed.

In addition, the bridge control unit 12 uses an independent disk redundant array (Redundant Array of Independent Disks, RAID) technology to integrally align a plurality of small-capacity hard disks together, and has a logical drive having a stretchability (logical drive), and the logical drive can be differentiated into several disk arrays.
When the bridge control unit 12 stores data, one piece of data is divided into a plurality of data blocks and stored in each hard disk 10. RAID technology can provide more favorable data access efficiency.
In addition, in order to avoid the loss of data caused by a certain hard disk failure, the RAID technology further utilizes the same bit checking concept to cooperate in data restoration work when necessary.

Furthermore, the bridge control unit 12 can match a 3.3 volt or 1.2 volt voltage regulator. For example, a bridge block (not shown) of the bridge control unit 12 can match a 1.2 volt voltage regulator so that the voltage conversion circuit 18 does not need to provide a 1.2 volt voltage to the bridge control unit 12; The voltage conversion circuit 18 can then provide a voltage of 3.3 volts to the bridge block (not shown).
Thereby, the voltage conversion circuit 18 can simplify the design of an electric circuit that provides a voltage of 1.2 volts, and the complexity of the electric circuit design of the voltage conversion circuit 18 is reduced.

A connection port 16 is electrically connected between these hard disks 10 and the transmission line 20, is used to accept the power interface of the electronic device 9 and supplies power directly to these hard disks 10.
In practice, the connection port 16 matches, for example, the universal serial bus 3.0 or the universal serial bus 2.0, and the electronic device 9 sends the USB signal via the connection port 16 to the bridge control unit 12. And the electronic device 9 provides power to these hard disks 10 via the connection port 16.

The voltage conversion circuit 18 electrically connects the control unit 12 and the connection port 16. The voltage conversion circuit 18 can provide one or two sets of voltages to the bridge control unit 12, for example, within the bridge control unit 12, converts a voltage of 3.3 volts to a voltage of 1.2 volts. To have an electrical circuit design.
Accordingly, the bridge control unit 12 may accept the voltage provided by the set of voltage conversion circuits 18, and the voltage conversion circuit 18 is realized via, for example, a pulse modulator and a low dropout voltage regulator.

In other embodiments, the voltage conversion circuit 18 can also provide two sets of voltages to the bridge control unit 12. For example, the bridge control unit 12 has two types of voltage demands, such as 3.3 and 1.2 volts, and the voltage conversion circuit 18 is, for example, any combination of a pulse modulator and a low dropout voltage regulator or a dual output port. This is realized via a pulse modulator.
For example, the voltage demand of the control block (not shown) of the bridge control unit 12 is 3.3 volts, and the voltage demand of the bridge block (not shown) is 3.3 and 1.2 volts. A voltage of 3.3 volts is provided to the control block (not shown) and the bridge block (not shown), and a voltage of 1.2 volts is provided to the bridge block (not shown). However, this embodiment does not limit the mode in which the voltage conversion circuit 18 supplies power to the bridge control unit 12.

  For example, when the external storage device 1 connects the electronic device 9 via the transmission line 20, the electronic device 9 detects the aspect of the external storage device 1 and thereby identifies the external storage device 1. In this case, the universal serial bus 3.0 is regarded as a communication protocol, and the bridge control unit 12 needs to convert and output the SATA signal. May occupy. Thus, the normal operation of the external storage device 1 is maintained by providing two sets of voltage demands to the bridge control unit 12.

From the above, the external storage device 1 of the present invention receives the power supply of the electronic device 9 through the transmission line 20 and directly transmits the power supply to these hard disks 10, and the power supply further passes through the connection port 16. These hard disks 10 are driven by supplying them directly to these hard disks 10.
In addition, the present invention converts the voltage demand to match the control unit 12 and the bridge unit 14 via the voltage conversion circuit 18, and the bridge control unit 12 provides a SATA signal. By controlling the hard disk 10, data access and data backup are performed.
With the above-described mechanism, the design of the drive circuit of the external storage device 1 may be simplified, and the utility of electric energy and the effect / function of saving electric energy can be improved.

[Second Embodiment]
FIG. 2 is a schematic block diagram of functions of the external storage device according to another embodiment of the present invention. Please refer to FIG. The structures of both the circumscribing storage device 1a in FIG. 2 and the circumscribing storage device 1 in FIG. 1 are similar, and hereinafter, the same elements included in both are denoted by the same reference numerals.
The difference between the external storage devices 1a and 1 is that the voltage conversion circuit 18a has one first conversion element 182 and one second conversion element 184, and the first conversion element 182 includes the bridge control unit 12a, The second conversion element 184 and the connection port 16 are electrically connected. The second conversion element 184 electrically connects the bridge control unit 12a.

In practice, the first conversion element 182 is a pulse modulator or low dropout voltage regulator, and the second conversion element 184 is a pulse modulator or low dropout voltage regulator. Since the combination of the elements 182 and 184 has four types, any of them can be provided so as to achieve the voltage demand of the bridge control unit 12a.
In the present embodiment, only one example will be described. The rest of the system and operation are the same as in this embodiment, and a person having ordinary knowledge in the technical field to which the system belongs belongs to the first and second conversion elements between the pulse modulator and the low dropout voltage regulator. 182 and 184 can be easily converted and applied. This embodiment does not limit the mode of the bridge control unit 12a.

In addition, the voltage conversion circuit 18a changes the power supply to one first voltage V1 and one second voltage V2. However, the voltage conversion circuit 18a uses the first voltage V1 and the second voltage V2 as the second voltage V2. The voltage V2 is provided to the bridge control unit 12a.
Although the present embodiment does not limit the numerical values of the first voltage V1 and the second voltage V2, those who have ordinary knowledge in the technical field to which they belong can freely design according to the demand.

  For example, the first conversion element 182 is a pulse modulator and the second conversion element 184 is a low dropout voltage regulator, but each pulse modulator has one input port and one output port. The low dropout voltage regulator also has one input port and one output port, and the pulse modulator electrically connects the low dropout voltage regulator, and the pulse modulator and the low dropout voltage regulator Electrically connects the control unit 12a.

  More specifically, the first conversion element 182 can output the first voltage V1, and supplies the first voltage V1 to the bridge control unit 12a and the second conversion element 184. The second conversion element 184 receives the first voltage V1, converts and outputs the second voltage V2, and supplies it to the bridge control unit 12a.

For example, although the connection port 16 accepts the 5 volt voltage transmitted by the electronic device 9, naturally the 5 volt voltage can be supplied directly to these hard disks 10, so that these hard disks 10 operate, The first conversion element 182 receives a power source and converts it to a first voltage V1 of 3.3 volts.
The first voltage V1 is supplied to the control unit 12a and the second conversion element 184. Among them, the second conversion element 184 handles the second voltage V2 converted to 1.2 volts, Soon, the second voltage V2 is supplied to the bridge control unit 12a.

It is worth noting that the bridge control unit 12 a has a disk array controller 122 and is used to transmit a SATA signal to each hard disk 10. As a result, these hard disks 10 are combined to form several disk arrays.
In practice, the disk array (Redundant Array of Independent Disks, RAID) is already in multiple different storage modes, for example, RAID0, RAID1, RAID + 1, RAID2, RAID3, RAID4, RAID5, RAID6, RAID7, RAID10, RAID50 and RAID50. However, the electronic device 9 regards these hard disks 10 as one single hard disk or one single logical storage hard disk.
Of course, the disk array controller 122 also has data integrity enhancement, error tolerance enhancement, and utility to increase handling volume and capacity. By being aligned to be an array and being able to distinguish these disk arrays to be in different storage modes, more effective transmission effects and data backup support functions are achieved, and consequently the data of these hard disks 10 is Protect safety.

  Except for the above-mentioned differences, as those who have ordinary knowledge in the technical field to which the user belongs belong to, the operation part of the second embodiment is substantially equivalent to the first embodiment, so that the normal knowledge in the technical field to which the user belongs. Since it can be easily guessed after referring to the first embodiment and the above-described difference, no further description will be made here.

[Third embodiment]
FIG. 3 is a schematic block diagram of functions of the external storage device according to another embodiment of the present invention. Please refer to FIG. The external storage device 1b of the present embodiment is similar to the external storage device 1 of the first embodiment described above. For example, the external storage device 1b may accept the power supply of the electronic device 9 and each hard disk 10 You may supply directly to.
However, there is still a difference between the circumscribed storage devices 1b, 1. This is that the voltage conversion circuit 18b includes one third conversion element 186, and among these, the third conversion element 186 electrically connects the connection port 16 and the bridge control unit 12a.

  More specifically, the third conversion element 186 is a dual output port pulse modulator, and the third conversion element 186 can output the first voltage V3 and the second voltage V4, respectively. V3 and the second voltage V4 are supplied to the bridge control unit 12a, respectively.

For example, although the connection port 16 accepts the 5 volt voltage transmitted by the electronic device 9, naturally the 5 volt voltage can be supplied directly to these hard disks 10, so that these hard disks 10 operate, The third conversion element 186 accepts a voltage of 5 volts and converts it to a first voltage V3 of 3.3 volts and a second voltage V4 of 1.2 volts.
For example, the first voltage V3 is supplied to the control block (not shown) and the bridge block (not shown) of the bridge control unit 12a, and the second voltage V4 is supplied to the bridge block (not shown) of the bridge control unit 12a. To supply.
The present embodiment does not limit the mode of operation for supplying the first voltage V3 and the second voltage V4 to the bridge control unit 12a.

  Other than the above differences, as those who have ordinary knowledge in the technical field to which they belong know the operation part of the third embodiment is substantially equivalent to the first embodiment, normal knowledge in the technical field to which they belong. Since it can be easily guessed after referring to the first embodiment and the above-described difference, no further description will be made here.

[Fourth embodiment]
FIG. 4 is a schematic block diagram of functions of the external storage device according to another embodiment of the present invention. Please refer to FIG. The circumscribing storage device 1c of the present embodiment is similar to the circumscribing storage device 1 of the first embodiment described above. For example, the external storage device 1 c may also receive the power of the electronic device 9 and supply it directly to each hard disk 10.
However, there are still differences between the circumscribed storage devices 1c, 1. This is because the external storage device 1 c further includes one communication unit 14, the communication unit 14 electrically connects the bridge control unit 12, and the communication unit 14 accepts one data signal wirelessly and the bridge control unit 12 is used to supply

  In practice, the communication unit 14 includes, for example, a Bluetooth (registered trademark) communication transceiver, a wireless local area network (Wireless LAN) communication radio frequency transceiver, a wireless personal area network (Wireless PAN) communication high frequency transceiver, a wireless WiFi (Wi-Fi). -Fi (registered trademark)) communication high-frequency transceiver, IEEE 802.11 communication high-frequency transceiver or ZigBee (registered trademark) (802.5.4) communication high-frequency transceiver, this embodiment does not limit the mode of the communication unit 14 A person who has ordinary knowledge in the technical field to which the user belongs may design based on the actual use situation.

  For example, the communication unit 14 is, for example, a Bluetooth communication transceiver, and the user's smartphone also has a communication module of the Bluetooth communication transceiver, which allows the user to operate the smartphone and wirelessly encloses personal data within the smartphone. The data can be transmitted to the storage device 1c, or the data in the external storage device 1c can be accessed to the smartphone wirelessly, thereby achieving data access and data backup operations.

It is understood that the user can wirelessly communicate with the communication unit 14 of the external storage device 1c via a wireless device (not shown) such as a smartphone, a tablet personal computer, a notebook computer, a mobile phone, or a personal digital assistant (PDA). Communication may be performed, and this embodiment does not limit the mode of the wireless device (not shown).
Furthermore, in this embodiment, the description has been made by connecting the external storage device 1c wirelessly by one wireless device and accessing the data. However, in other embodiments, the wireless external connection is made by a plurality of wireless devices. The data storage device 1c can also be connected, and data access work may be performed simultaneously on the external storage device 1c by a plurality of wireless devices. Therefore, this embodiment does not limit the number of wireless devices (not shown).

For example, when the external storage device 1c is connected wirelessly by a plurality of wireless devices and the data access operation is performed, the bridge control unit 12 is based on the order of data access commands of these wireless devices. Then, the hard disk 10 is controlled to perform data access work. Of course, the bridge control unit 12 can also provide data access priorities of these wireless devices based on the setting of its own program. The operation method of the bridge control unit 12 is not limited.
In addition, in other embodiments, the communication unit 14 may also be a one-way radio transmission launcher or a one-way radio receiver, but this embodiment limits the operation of the communication unit 14. do not do.

In addition, the external storage device 1c of the present embodiment can electrically connect the electronic device 9 via the transmission line 20, and the electronic device 9 can also provide power to the external storage device 1c.
Of course, the user can operate the electronic device 9 so that personal data in the electronic device 9 is transmitted to the external storage device 1c by wire, or data in the external storage device 1c is transmitted to the electronic device 9 by wire. However, this accomplishes data access and data backup operations. This embodiment does not limit the mode of data access operation of the external storage device 1c and the electronic device 9.

As a result, it can be understood that the external storage device 1c of the present embodiment has two types of data access methods, and one of them is a data access method by a wireless method via the communication unit 14. Other types of systems perform data access work by wired system via the transmission line 20, but those who have ordinary knowledge in the technical field to which they belong will design based on the actual usage situation You may do it.
It is worth mentioning that this embodiment will be described by supplying power to the communication unit 14 by the bridge control unit 12a, and among other embodiments, the voltage conversion circuit 18a is also used to supply power to the communication unit. However, a person having ordinary knowledge in the technical field to which the user belongs may design based on the actual use situation.

  Other than the above-mentioned differences, as the person having ordinary knowledge in the technical field to which he belongs belongs to, the operation part of the fourth embodiment is substantially equivalent to the first embodiment, so that the normal knowledge in the technical field to which he belongs. Since it can be easily guessed after referring to the first embodiment and the above-described difference, no further description will be made here.

In summary, the spirit of the present invention is that the electronic device and the external storage device are electrically connected mainly using a transmission line, and the power transmitted by the electronic device is directly supplied to these hard disks. Further, the voltage is converted to a voltage that matches the demand of the bridge control unit through the voltage conversion circuit, and the disk is controlled by this bridge control unit to access the data.
In addition, the bridge control unit has a disk array controller, thereby providing different storage modes to these hard disks, thereby achieving effective transmission effects and data backup support functions to Protect the safety of your data.
With the above-described mechanism, the design of the drive circuit of the external storage device may be simplified, and the availability of electrical energy and the effect / function of saving electrical energy can be improved.

  In the detailed description of the preferred embodiment, the specific embodiment submitted is used to conveniently explain the technical content of the present invention, and the present invention is strictly limited to the foregoing embodiment. is not. Various modifications and implementations completed without departing from the spirit of the present invention and the following claims belong to the scope of the present invention. Therefore, the protection scope of the present invention may be limited based on the appended claims.

V1, V4 first voltage
V2, V5 Second voltage V3, V6 Third voltage 1, 1a, 1b, 1c External memory device
9 Electronic devices
10 Hard disk
12, 12a Control unit
14 Communication Unit 16 Connection Port 18, 18a, 18b Voltage Conversion Circuit 20 Transmission Line 122 Disk Array Controller 182 First Conversion Element
184 Second conversion element 186 Third conversion element 202 First connection interface 204 Second connection interface

Claims (10)

The external storage device includes a plurality of hard disks, one bridge control unit, one connection port and one voltage conversion circuit.
A bridge control unit is used to electrically connect these hard disks, align these hard disks to form several disk arrays, and a connection port electrically connects these hard disks, and further voltage A conversion circuit electrically connects the control unit, the bridge unit and the connection port, wherein the external storage device receives one power source provided by the electronic device via one transmission line; and The power source is directly transmitted to the hard disks via the connection port to drive the hard disks, and the voltage conversion circuit converts the power source and supplies power to the bridge control unit. And
External storage device.   The transmission line is a Y-type transmission line and has one first connection interface and one second connection interface, the first connection interface connects the connection port, and the connection port is a universal Matches the serial bus 3.0 or the universal serial bus 2.0, the second connection interface connects the output connection port of the electronic device, and the second connection interface is the universal serial bus 3 The external storage device of claim 1, wherein the external storage device conforms to 0.0 or Universal Serial Bus 2.0.   The voltage conversion circuit converts the power source into one first voltage, and the voltage conversion circuit provides the first voltage to the bridge control unit. The circumscribed storage device described.   4. The external storage device according to claim 3, wherein the voltage conversion circuit is a pulse modulator or a low dropout voltage regulator.   The voltage conversion circuit converts the power supply to be the first voltage and the second voltage, and the voltage conversion circuit provides the first voltage and the second voltage to the bridge control unit. The circumscribed storage device according to claim 3, wherein:   The voltage conversion circuit has one first conversion element and one second conversion element, the first conversion element couples the second conversion element, and the first conversion element 6. The external storage device according to claim 5, wherein the external storage device is a pulse modulator or a low dropout voltage regulator, and the second conversion element is a pulse modulator or a low dropout voltage regulator.   6. The external storage device according to claim 5, wherein the voltage conversion circuit has one third conversion element, and the third conversion element is a dual output port pulse modulator.   The transmission line is a Y-type transmission line, and has one first connection interface, one second connection interface, and one third connection interface, and the first connection interface connects the connection ports. The connection port is a universal serial bus 3.0 or universal serial bus 2.0, and the second connection interface and the third connection interface connect the output connection port of the electronic device; The second connection interface is a universal serial bus 3.0 or universal serial bus 2.0, and the third connection interface is a universal serial bus 3.0 or universal serial bus 2.0. The circumscribed storage device according to claim 1, wherein:   The bridge control unit is used to convert a USB signal into a SATA signal, and the bridge control unit has one disk array controller, and these hard disks become these disk arrays. To achieve effective transmission effects and data backup support functions by distinguishing these disk arrays to be in different storage modes, and 2. The external storage device according to claim 1, wherein each of the hard disks is a 2.5-inch hard disk (HDD) or a solid disk (SSD).   And further comprising a communication unit, wherein the communication unit electrically connects the bridge control unit, and the communication unit is used to receive and / or transmit a single data signal wirelessly. The circumscribed storage device according to claim 1.

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