WO2017209456A1 - Ssd multiplier and storage system based thereon - Google Patents

Abstract

The present invention provides an SSD multiplier wherein multiple M.2 memory cards are arranged in multiple tiers in the vertical or horizontal direction with regard to an exterior having the same size as that of a 3.5-inch hard disk drive such that, in an environment employing a 3.5-inch hard disk drive, M.2 memory cards are mounted at a large density, in place of the 3.5-inch hard disk drive, so as to provide a larger capacity. Particularly, given that M.2 memory cards having various lengths are provided according to the specifications, the present invention provides an environment in which the SSD multiplier can be used in conformity with the length of a M.2 memory card. Moreover, the SSD multiplier according to the present invention provides a PCI Express interface or a SATA interface according to the type of an interface supported by a M.2 memory card having a SFF-8639 connector, which supports both the PCI express and SATA interfaces as external interfaces, provided and mounted in the same position as that of a connector of a 3.5-inch hard disk drive, and according to the RAID configuration scheme of an embedded control unit. In addition, the present invention provides a separate USB connector and supports a USB interface such that the SSD multiplier can be easily used as a portable storage device. Particularly, the present invention provides a PCI Express interface dongle such that a high-speed PCI Express interface can be used while the SSD multiplier is used on the move. Finally, the present invention provides a concise bus architecture of a large-capacity storage system on which a M.2 multiplier is mounted, and a storage system based thereon.

Description

Ss multiplexer and storage system based on it

The present invention reduces the weight of the computer compared to the case where the M.2 memory card is used as the main storage of the notebook computer and uses the 2.5 inch SSD (SSD), in particular, the M.2 memory card that supports the PCI EXPRESS interface For example, to use a single M.2 memory card for the purpose of shortening the boot time, it is possible to replace the 3.5-inch hard disk drive by mounting a plurality of M.2 memory cards in the same shape as the 3.5-inch hard disk drive. Or it relates to an SSD multiplexer to be used as a portable storage device.

In the prior art, there have been attempts to mount a plurality of M.2 memory cards in the shape of a 3.5-inch hard disk drive, but in the case of the M.2 memory card, the width of the card used mainly is constant at 22 mm, but the length is constant. For various types of lengths such as 30, 42, 60, 80, 110 (mm) is proposed as a standard.

In the present invention, since a plurality of M.2 memory cards are applied to the same appearance as a 3.5-inch hard disk drive, but for the purpose of realizing a larger storage capacity, three types of memory cards having a longer length among M.2 memory cards having various lengths are used. The present invention proposes a method that can be configured variably in response to a 60, 80, and 110 (mm) length M.2 memory card.

In addition, the M.2 memory card is placed in a case of the same size as a 3.5-inch hard disk drive in a horizontal or vertical direction at regular intervals so that the M.2 memory card is correctly guided to a predetermined position and is not released. Suggest.

In addition, the circuit connection method corresponding to the PCI EXPRESS interface or the SATA interface supported by the M.2 memory card and the interface method when the controller supports or does not support RAID are described.

On the other hand, the SD multiplier of the present invention is basically the same appearance as the 3.5-inch hard disk drive, but when disposed in the vertical direction according to the arrangement of the M.2 memory card, the failure occurs in any M.2 memory card In this case, it is easy to replace the M.2 memory card by opening the storage media inlet cover, but it cannot be thinner than the 3.5-inch hard disk drive. In the horizontally arranged form, the outer case of the case is the same size as the 3.5-inch hard disk drive in the horizontal and vertical directions, but the thickness can be made thinner than the 3.5-inch hard disk drive.

Therefore, the SSD multiplexer of the present invention can be mounted in place of a 3.5-inch hard disk drive, and can be a high-performance portable storage system by itself.

In addition to the SFF-8639 connector, which supports both the PCI EXPRESS interface and the SATA interface, which are installed as the basic means of connection for easy connection with any computer, the USB connector is provided in the same position as that of the 3.5-inch hard disk drive. It also comes with a USB interface.

In order to smoothly support high-performance data input and output over the USB interface while using the SSD multiplexer of the present invention as a portable storage medium, a dongle for the PCI EXPRESS interface is additionally provided.

The PCI Express dongle is equipped with SFF-8639 connector of the SD Multiplier main body and a connector corresponding to the USB connector so that they can be combined in close contact with each other.The PCI EXPRESS dongle is provided on one side of the dongle for PCI Express interface. Implemented by connecting a separate commercial PCI Express cable to the connector and connected to the connector provided in the fixed bracket of the interface card provided in the PCI EXPRESS ADD-IN card type provided in the PCI EXPRESS slot on the motherboard inside the computer Present a plan.

In accordance with the prior art, the 3.5-inch hard disk drive type SD multiplexer 10 has M.2 connectors 25, 27, and 29 to which M.2 memory cards 35, 37, and 39 are coupled as shown in FIG. ) Is coupled to the M.2 connector 51 of the RIGHT ANGLE type as shown in Fig. 2, so that the M.2 memory cards 35, 37, and 39 are only horizontal to the printed circuit board. Combined.

The horizontal M.2 connectors 51 corresponding to the M.2 connectors 25, 27, and 29 of FIG. 1 are respectively fixed to corresponding points on the printed circuit board according to the predetermined length of the M.2 memory card to be used. The interface signal constituting the PCI EXPRESS lane branched from the PCI EXPRESS switch 19 used as a control unit is directly connected to the M.2 connectors 25, 27, and 29.

Therefore, in the case of the conventional 3.5-inch hard disk drive type M.2 memory expansion card, the internal configuration is possible only corresponding to the length of one type of M.2 memory card, and the other length of the M.2 memory card In this regard, since the arrangement positions of the M.2 connectors 25, 27, and 29 must be arranged in accordance with M.2 memory cards of different lengths, a problem arises in that they must be separately configured on a separate printed circuit board.

In addition, if the M.2 memory card consists only of those that support the PCI EXPRESS interface, the PCI EXPRESS interface signal is directly connected between the SFF-8639 connector (11) and the PCI EXPRESS switch (19) used as the control unit. , If the M.2 memory card is composed of those that support the SATA interface, the SATA port of the SFF-8639 connector 11 and the first M.2 connector (25), the first SATA connector without going through the control unit 19 (13) and the second M.2 connector 27, the second SATA connector 15 and the third M.2 connector 29 is a form of a direct SATA interface signal connected.

Meanwhile, the conventional multi-device bay 1 is connected to the PCIe slot 3-1 provided in the host computer 2 through the PCI Express hub card 3-7 as shown in FIG. In the computer 2, it is recognized as each device.

The PCI Express Hub Card (3-7) is equipped with the PCI Express Switch (4) and is connected to the PCIe slot (3-1) side by PCIe x16, and the signal branched out to PCIe x4 on the outside. It consists of a port to connect to.

The PC-i Express switch 4 has a separate control pin (CONFIGURATION PIN) that can adjust the branch form of the PCIe signal connected to the outside.

18 illustrates a conventional expansion multi-device bay 1 connected to an external PCIe hub 5 using an expansion multi-device bay, and the external PCIe hub 5 is a PCIe expansion card 3 installed inside the host computer 2. It shows the connected state through 5).

FIG. 19 is a block diagram illustrating an external PCIe hub 5 having a second PCIe hub card 7 mounted in a sliding manner based on a conventional expansion multi device bay 1, To use 1) as a storage system, a RAID card 8 must be provided.

The present invention has been invented to solve the above problems, the first object of the present invention is the same appearance as the 3.5-inch hard disk drive is widely used using a PCI Express interface or SATA interface M.2 memory card It is to provide a SD multiplexer constituting a mass storage by configuring a plurality of M.2 memory card in a high density in the vertical or horizontal direction.

A second object of the present invention is a first vertical in which an M.2 memory card is inserted to correspond to the length of several types of M.2 memory cards having the same horizontal width but different vertical widths in using an M.2 memory card. It is to provide a SD multiplexer that can be moved according to the length of the M.2 memory card by moving the connection board.

A third object of the present invention is to provide two M.2 memory cards of two lengths, each having two second vertical connection boards on the left and right sides of the main printed circuit board, and the length of the M.2 memory card. According to the present invention, there is provided an SD multiplexer that couples a first vertical connection board to a second vertical connection board to accommodate two kinds of M.2 memory cards having different lengths.

A fourth object of the present invention is to form a logical storage of a single volume or multiple volumes of a plurality of M.2 memory card through a RAID configuration in the control unit, and even if a failure occurs in any M.2 memory card is recognized by the error display LED It is to provide an SD multiplexer which replaces only the corresponding M.2 memory card with the same one so that normal data can be recovered.

A fifth object of the present invention is to provide an SD multiplier supporting a USB interface by having a USB connector so that the SD multiplier can be connected to any computer and used conveniently.

The sixth object of the present invention is to use a commercially available PCI Express cable by combining the PCI Express Dongle (DONGLE) provided separately to support the high performance data transmission of the PCI EXPRESS interface while using the SD Multiplexer portable It is to provide a type of SD doubler that can be used by connecting to the exposed connector as a fixing bracket of the PCI EXPRESS ADD-IN card provided in the computer main body.

The seventh object of the present invention is to store a large amount of data through an internal configuration similar to the case of the M.2 memory card described above using 2.5-inch SD which is generally used even if it is larger than the appearance of a 3.5-inch hard disk drive. It is to provide an SD multiplexer that provides a means.

In order to achieve the above object, the SSD multiplexer of the present invention includes a printed circuit board having PCI Express or SATA interface connection means; A plurality of storage media of the PCI EXPRESS interface method or the SATA interface method; A control unit connected to the PCI EXPRESS or SATA interface connecting unit; A first vertical connection board disposed in a vertical direction with respect to the printed circuit board and configured of at least one or more;

A storage media connector comprising at least one or more disposed on one side of the first vertical connection board; The storage medium is connected to the storage medium connector.

The printed circuit board may include at least one or more first vertical connection board lower connectors at a lower end of the first vertical connection board, and the lower connector of the first vertical connection board is connected to the first vertical connection board. The controller is connected to the circuit.

In addition, the second vertical connection board connector connected to the control unit and composed of one or two, disposed in the vertical direction on the left / right side of the printed circuit board; A second vertical connection board coupled to the second vertical connection board connector and configured as one or two perpendicular to the printed circuit board; A first vertical connection board connector configured on at least one side of the second vertical connection board and configured to correspond to the length of the storage media; And a first vertical connection board coupled to the arbitrary first vertical connection board connector.

In addition, the printed circuit board is further provided with a USB interface connection means to be connected to the control unit.

In addition, a storage media connector provided in the vertical direction on the first vertical connection board is provided in a vertical direction with the printed circuit board is coupled to the storage media in a vertical direction with respect to the printed circuit board.

In addition, a storage media connector provided in a vertical direction on the first vertical connection board is provided in a horizontal direction with the printed circuit board so that the storage media is coupled in a horizontal direction with respect to the printed circuit board.

In addition, at least one or more storage media connectors arranged on the first vertical connection board are arranged horizontally so that the storage media are coupled in a multi-stacked manner.

In addition, the first vertical connection board is coupled to the first vertical connection board connector provided in the second vertical connection board in a forward / backward direction to correspond to the length of the storage medium.

In addition, the second vertical connection board mounts the first vertical connection board connector to mount the first vertical connection board connector at a position corresponding to the length of the storage media for each length of the storage media. Coupling the second vertical connecting board to the second vertical connecting board connector, wherein the second vertical connecting board is provided with the second vertical connecting board, respectively, and the length of the storage medium is the same, and the first vertical connecting board is connected to the second vertical connecting board. The coupling is made to correspond to the length of the storage media by coupling to the first vertical connection board connector on the connection board.

In addition, when the length of the storage medium is two types, the first vertical connection board is provided in a bisected form each having a length corresponding to the number of the two types of storage media, the location corresponding to the storage media length Each of the first vertical connection boards may be coupled to a lower connector of the first vertical connection boards, respectively, to connect the storage media having different lengths to the respective first vertical connection boards.

In addition, when the length of the storage medium is two types, the first vertical connection board is provided in a bisected form each having a length corresponding to the number of the two types of storage media, the location corresponding to the storage media length Each of the first vertical connection boards may be coupled to the second vertical connection boards so that the storage media having different lengths may be coupled to the respective first vertical connection boards.

In addition, the printed circuit board is provided with side supports on the left and right sides, respectively, the side supports are provided with holes corresponding to the fixing holes of the hard disk drive on the lower side and the outer surface at the same position as the hard disk drive will be.

In addition, the upper cover and the lower cover and the inlet cover of the storage medium is further provided on the top and bottom of the printed circuit board.

In addition, the side support and the top cover is an integral structure.

In addition, a guide structure having a concave-convex structure surrounding the printed circuit board exposed on the left and right sides of the storage medium, the storage medium is guided by the guide structure.

In addition, when the storage medium is introduced through the inlet of the storage media inlet cover, it is provided with a series of storage media guide projections projecting in a vertical direction from the inner surface of the top cover and the bottom cover.

In addition, the guide protrusion is to be guided along the surface of the storage medium.

In addition, the storage media guide protrusion is a 'V' shape of the inlet for smooth guide.

In addition, the storage media guide protrusion is to form a 'V' shaped guide shape at the inlet of the first vertical connection board connector for accurate guide of the storage media.

In addition, the inner bottom guide structure is provided at the bottom of the first vertical connection board to form a 'V' shaped guide shape.

In addition, as the position of the first vertical connection board is moved corresponding to the length of the storage medium, the inner lower guide structure is also moved together.

In addition, the inner bottom guide structure is to have at least one support protrusion at the bottom.

In addition, at least one first vertical connection board fixing protrusion protruding from the bottom surface of the top cover corresponding to the position where the first vertical connection board is moved according to the length of the storage medium.

In addition, when the storage media is an M.2 memory card, the storage media inlet cover forms a 'U'-shaped protrusion inside the storage media inlet cover to prevent separation from the semi-circular fixing hole of the M.2 memory card. It is to have a fixing groove.

In addition, the control unit supports a RAID function for the storage media coupled to the first vertical connection board so that the storage media is converted into at least one or more logical storages according to a user's designation.

In addition, when the storage medium is a PCI EXPRESS interface method, the control unit is connected to the PCI EXPRESS interface side in the PCI EXPRESS or SATA connection means, when the storage medium is a SATA interface, the control unit is PCI EXPRESS in the PCI EXPRESS or SATA connection means It is connected to the interface side or SATA interface side.

The control unit may be configured as a PCI EXPRESS switch, connected to each of the storage media in a PCI EXPRESS x1, x2 or x4 lane configuration, and connected to the PCI EXPRESS interface to the PCI EXPRESS interface connection unit.

In addition, when the SSD multiplexer is installed at a position where the 3.5-inch hard disk drive bay of the computer system is mounted, the SD card is connected to an interface card provided in the PCI EXPRESS slot of the computer system by using a separate cable.

In addition, the LED is operated by the operation operation indicator LED signal output from the storage media connector on the upper end of the printed circuit board in the vicinity of the opposite end surface of the storage media coupled to the storage media connector. .

The printed circuit board may include an LED operated by an operation indicator LED signal output from the storage media connector at a lower end of the first vertical connection board, and corresponding to an LED provided at the bottom of the first vertical connection board. By having a PHOTO-TR on the top to form a PHOTO COUPLER, the operation indication LED signal is output to the PHOTO-TR on the printed circuit board without going through a separate connector.

In addition, the LED is provided by an error display LED signal output from the controller on the upper end of the printed circuit board in the vicinity of the opposite end surface of the storage media coupled to the storage media connector.

In addition, the PCI EXPRESS or SATA interface connecting means having a pin-to-pin corresponding SFF-8639 connector and the USB connector pin-to-pin corresponding to the USB connector, the connector is fixed A printed circuit board, an external interface having a PCI EXPRESS external interface connector connected to the SFF-8639 connector on one side of the printed circuit board, and a USB connector connected to the USB plug connector It is additionally provided with a dongle (DONGLE).

In addition, a circuit connection relationship is formed only with respect to a power pin between the USB connector and the USB plug connector.

In addition, the upper cover is provided with a dongle fixing nut groove in the front portion in the vertical direction.

In addition, the dongle fixing nut groove is composed of a nut groove upper support, a nut, a nut groove lower support when the dongle is used, and a nut nut full plug when the dongle is not used.

In addition, the dongle is composed of a dongle top cover, a dongle bottom cover and a dongle fixing bolt.

In addition, the PCI Express expansion card connected to an external host computer; A PC-I Express switch connected to the PC-I Express expansion card and a PC-I Express interface signal; An SD multiplier equipped with a control unit having a RAID function and a plurality of SD storage media connected thereto; And at least one or more SD multiplexers connected to the PCX express interface signal branched to the PCX express switch to configure a series of unit BAY-ROW.

In addition, the storage system is to form a unit storage arrangement consisting of the PCI Express expansion card, PCI Express switch and BAY-ROW in at least one or more arrangements

In addition, a first PCIe slot is provided with the PCI Express expansion card; A second PCIe slot in which pin-to-pin wiring is formed; Any other BAY-ROW configured only with SSD multiplier; And any BAY-ROW configured only with a hard disk drive, wherein the BAY-ROW equipped with the M.2 multiplexer is connected to a PC-I Express interface signal branched to the PC-I Express switch, and the hard disk For a BAY-ROW having a drive, a RAID card is additionally provided in the second PCIe slot to connect a SATA or SAS interface signal input and output from the RAID card.

In addition, the storage media mounted on the SD multiplexer are arranged in a direction parallel to the direction of the air flow from the front portion to the rear portion of the storage system.

In addition, the PCI Express expansion card connected to an external host computer; A first PC Express switch connected to the PC Express expansion card and a PCI Express interface signal; At least one or more BAY-ROWs that include a second PCX Express switch branched from the first PCA Express switch and connected to a plurality of PCX Express interface signals, respectively; It is composed of an SDS multiplexer which is branched from the second PC Express switch on the BAY-ROW and connected to the PCI Express interface signals of a plurality of channels, respectively.

The SD multiplexer is equipped with a control unit having a RAID function and a plurality of SD storage media connected thereto.

In addition, the storage media mounted on the SD multiplexer are arranged in a direction parallel to the direction of the air flow from the front portion to the rear portion of the storage system.

In accordance with the present invention, the SD multiplier uses a commercially available cable even when a case main body and a case main body in which a plurality of M.2 memory cards are built in a high density inside a 3.5 inch hard disk drive size case are used as a portable storage device. It is divided into DONGLE, which makes it easy to use the PCI EXPRESS interface.

The SD multiplier of the present invention can correspond to the length of the M.2 memory card is 60mm, 80mm, or 110mm, respectively, the user of any of the M.2 memory card of the length of the Provides the longest three types of length by combining the position of the first vertical connection board provided in the demultiplexer with the corresponding position on the second vertical connection board according to the length of the M.2 memory card to be used. It is possible to accommodate an M.2 memory card of any one length among M.2 memory cards.

In addition, if a user wants to mount two kinds of M.2 memory cards of the present invention to the SD MULTI PLUG, the first vertical connection board which is separated into two for the left / right and into which the M.2 memory card is inserted Connect the first vertical connection board to the vertical connection board connector at the corresponding position on the second vertical connection board respectively provided on the left and right sides corresponding to the respective M.2 memory card lengths, and to the first vertical connection board at the corresponding position. By inserting an M.2 memory card of the correct length, it is possible to install two different types of M.2 memory cards together.

On the other hand, if the M.2 memory card supports SATA interface or PCI EXPRESS interface, if it supports PCI EXPRESS X1 or X2 lane, only one second and one vertical board is used. It is possible to configure using.

If you want to respond to the M.2 memory card that supports the PCI EXPRESS X4 interface, it consists of two second vertical connection boards and one first vertical connection board. 2 vertical connection board connectors can be distributed respectively.

SSD multiplexer of the present invention can be easily used as a portable storage device by providing a USB interface by additionally provided with a USB connector.

Finally, even if any M.2 memory card fails due to a RAID function provided by the control unit used in the SD multiplexer of the present invention, the data of the storage configured by the SD multiplexer of the present invention is not lost. The stable status can be maintained and the entire data management status is returned to the state before the error occurred by simply replacing the failed M.2 memory card identified through the LED inside the cover of the inlet cover of the translucent material. It is possible to restore.

FIG. 1 is a block diagram of an SDD multiplexer of a 3.5-inch hard disk drive type according to the related art.

2 is an M.2 memory card according to a connector used in the prior art and the present invention for connecting an M.2 memory card and a length coupled to the connector.

Figure 3 is a block diagram of a BS multiplexer according to the present invention.

4 is an interface card to which the SSD multiplexer according to the present invention is connected.

5 is a perspective view of the SD multiplexer according to the present invention.

Figure 6 is a perspective view showing the internal structure of the SSD multiplexer of the form with the top cover of the SD multiplexer of the present invention removed.

7 is an exploded perspective view of the SD multiplexer of the present invention.

8 is a perspective view of a storage media inlet cover according to an exemplary embodiment of the present invention.

9 is a plan view of an SSD multiplexer according to an exemplary embodiment of the present invention.

10 is a perspective view and a rear perspective view of the inner lower guide structure according to an embodiment of the present invention.

11 is a perspective view of a lower end connector to which the inner bottom guide structure and the first vertical connection board of another form according to the embodiment of the present invention are coupled;

12 is a perspective view of a bottom cover according to an embodiment of the present invention.

13 is a perspective view of a top cover according to an embodiment of the present invention.

14 is a perspective view of a dongle (DONGLE) for using the PCI EXPRESS interface in accordance with an embodiment of the present invention coupled to the S-D multiplexer.

15 is a perspective view of the connector surface of the dongle in accordance with an embodiment of the present invention exposed.

FIG. 16 is a view illustrating a conventional expansion multi-device bay connected through an internal PCIe hub card installed in a user's computer.

FIG. 17 is a block diagram of an embedded PCIe hub card used in FIG. 16 according to the related art.

FIG. 18 is a view illustrating a conventional expansion multi-device bay connected to an external PCIe hub using the expansion multi-device bay, and the external PCIe hub is connected through a PCIe expansion card installed inside the host computer.

19 is a block diagram illustrating an external PCIe hub incorporating a second PCIe hub card that is mounted in a slide manner based on a conventional expandable multi-device bay.

FIG. 20 is a diagram illustrating a rackmount case type storage system equipped with an M.2 multiplier of the present invention connected to PCIe expansion cards of respective PCIe slots provided on a host computer.

21 is a rackmount case type storage system equipped with an M.2 multiplier of the present invention is connected to each connection port of a storage expansion system, and the storage expansion system is a PCIe expansion card of a PCIe slot provided on a host computer. A diagram showing a state connected to the.

FIG. 22 is a block diagram illustrating a rack mount case type storage using an M.2 multiplexer or a hard disk drive of the present invention as a unit storage medium.

FIG. 23 is a second block diagram illustrating a rackmount case type storage system using the M.2 multiplexer of the present invention as a unit storage medium.

24 is a perspective view and a rear view of an embodiment of a rackmount case type storage system equipped with an M.2 multiplier of the present invention.

Hereinafter, the SD multiplier according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram of a solid state disk (SSD) multiplexer (Mulitpler) according to the present invention, the description of each functional block according to the code is as follows.

SSD multiplexer 100 of the present invention is provided on the printed circuit board 101 SFF-8639 connector 111 is the same position as the SATA (or SAS) connector of the 3.5-inch hard disk drive.

SFF-8639 connector 111 is a connector in which pins for PCI EXPRESS X4 interfaces are arranged on the opposite side where pins are not arranged in a conventional SAS (serial attached SCSI) connector (not shown). The PCI EXPRESS interface consists of the pins required to configure the PCI EXPRESS X4 lane (LANE), pins to form two SATA interfaces, and a power pin that supplies + 5V and + 12V power from the outside.

The SFF-8639 connector 111 is connected to the pins for the PCI EXPRESS interface of the controller 117 or the SATA interface pins.

The power supply unit 115 receives power supplied from the outside of the SFF-8639 connector 111 and the USB connector 113 to generate various power supplies used in the SSD multiplexer 100 of the present invention.

The controller 117 may be provided in various forms according to the type of interface supported by the M.2 memory cards 151, 152, and 158 as a storage medium to be used.

That is, if the M.2 memory card 150 supports the SATA interface and the SATA interface is used as the external interface, the SATA PORT MULTIPLIER is preferable as the IC for the control unit 117. In this case, the SATA interface of the control unit 117 is used. The pins are connected to the pins for the SATA interface on the SFF-8639 connector 111.

If the control unit 117 configured by using the SATA PORT MULTIPLIER supports RAID function, the M.2 memory card 150 is connected as a single volume or storage represented by a plurality of volumes depending on the type of the RAID configuration. If it is recognized by a computer system (not shown) and the control unit 117 does not support the RAID function, it functions as a simple PORT MULTIPLIER, so that individual M.2 memory cards 150 are stored separately in a computer system (not shown) to which they are connected. Is recognized.

If the M.2 memory card 150 supports the SATA interface and the PCI EXPRESS interface is used as an external interface, the PCI EXPRESS-TO-SATA conversion IC may be used for the control unit 117. PCI EXPRESS interface pins of 117 are connected in correspondence with signals for the PCI EXPRESS interface pins on the SFF-8639 connector 111.

In this case, as in the above example, if the PCI EXPRESS-TO-SATA conversion IC used for the control unit 117 supports the RAID function, the M.2 memory card 150 may be a single volume or Recognized by a computer system (not shown) connected as storage represented by a plurality of volumes, and if the control unit 117 does not support the RAID function, each of the M.2 memory cards 150 are connected computer system (not shown) Is recognized as an individual repository.

If the M.2 memory card 150 supports the PCI EXPRESS interface and the external interface also supports the PCI EXPRESS interface, the IC for the PCI EXPRESS switch may be used for the control unit 117. PCI EXPRESS interface pins of 117 are connected in correspondence with signals for the PCI EXPRESS interface pins on the SFF-8639 connector 111.

In this case, as in the above example, if the PCI EXPRESS switch IC used for the control unit 117 supports the RAID function, the M.2 memory card 150 is divided into a single volume or a plurality of volumes depending on the type of the RAID configuration. Recognized by a computer system (not shown) connected as storage to be displayed, and if the control unit 117 does not support the RAID function, each of the M.2 memory cards 150 are connected to the individual storage in the connected computer system (not shown). It is recognized.

The USB connector 113 is provided to be easily connected to any computer (not shown) and used when the SSD multiplexer 100 of the present invention is used as a portable data storage device. It is connected to the USB port.

One or two second vertical connection board connectors 119 may be provided according to the interface type of the M.2 memory card 150 used as the storage medium and the configuration of the signal lane LANE. Is provided on the left / right side of the control unit 117.

That is, the connector used as the second vertical connection board connector 119 is also vertical as with the other connectors used between the control unit 117 and the M.2 memory cards 150 used in the present invention mentioned later. The M.2 connector is used. In the present invention, since the M.2 connector having a key is provided on only one side, the number of usable pins is 67, whereas the M.2 memory card is PCI EXPRESS X2 or PCI EXPRESS X4. When the interface is connected to the control unit 117, respectively, the number of signal lines exceeds the number of pins of one second vertical connection board connector 119, so that only one second vertical connection board connector 119 is shortened. In order to solve this problem, the second vertical connection board connectors 119 are provided at left and right sides of the controller 117, respectively.

On the other hand, when the M.2 memory cards 150 used as storage media support the SATA interface or are configured with the PCI EXPRESS X1 interface, only the pins provided by the second vertical board connector 119 may be used. As it can fully correspond, only one second vertical connection board connector 119 is provided on only one side of the control unit 117 as shown in FIG.

As mentioned above, only one or two second vertical connection boards 127 may be used depending on the number of signal lines connected between the controller 117 and the M.2 memory card 150 used as a storage medium. It is coupled to the second vertical connection board connector 119.

As shown in FIG. 3, the second vertical connection board 127 has a length of 60 mm, 80 mm, and 110 mm for the M.2 memory cards 151, 152, and 158 used as a storage medium. Vertical to the corresponding position on the second vertical connection board 127 based on the position where the end of the memory card with the fixing groove 31 is aligned at the designated position on the M.2 memory card inlet (not shown). A first vertical connection board connector 121 for 110 mm, a first vertical connection board connector 123 for 80 mm, and a first vertical connection board connector 125 for 60 mm are configured as M.2 connectors.

First vertical connection board connector connectors 121 including an edge finger portion (not shown) connected to the second vertical connection board 127 to the second vertical connection board connector 119 and the respective M.2 connectors; Signal lines are connected between the pins corresponding to the same signal of the 123 and 125 by utilizing inner / outer wiring spaces of the printed circuit board constituting the second vertical connection board 127.

The first vertical connection board 136 directly fixes the first storage media connector 141, the second storage media connector 142, and the eighth storage media connector 148 into which the M.2 memory cards 150 are inserted. It is provided in the vertical or horizontal direction at intervals.

The first storage media connectors 141 to 8th storage media connectors 148 are arranged in the horizontal direction with respect to the printed circuit board 101 and are provided on the first vertical connection board 136 in a multi-layered arrangement in a stacked structure. In this case, high density storage is possible depending on how many stages of the same M.2 connector are arranged in the same row as one connector arranged horizontally.

As mentioned above, the first vertical connection board 136 may include any first vertical connection board connector 121 provided on the second vertical connection board 127 corresponding to the length of the M.2 memory card 150. 123, 125).

If the length of the M.2 memory card 150 to be installed is two types, regardless of the interface type of the M.2 memory card 150 mentioned above, the half size or the other ratio is different. Two first vertical connection boards 136 having a size of 2 are provided separately on the second vertical connection board connector 119 and the second vertical connection board 127 provided on the left and right sides of the control unit 117. This may be solved by connecting two first vertical connection boards 136 to the corresponding ones of the first vertical connection board connectors 121, 123, and 125 corresponding to the lengths of the M.2 memory cards 150, respectively. .

As such, branching a signal input / output to the control unit 117 in a left / right direction by configuring two first vertical connection boards 136 having a size of 1/2 is performed by one first vertical connection board 136. In this case, the length of the signal wiring for the storage medium located at the farthest distance from the control unit 117 may be excessively long, which may be a means of preventing a problem that a signal delay occurs.

LED display unit 161, 162, 168 is composed of the operation display LED 186 and the error display LED (187), the fixed portion of the M.2 memory card 150 used as a storage medium of It is provided on the printed circuit board 101 around the storage media inlet (not shown) of the plug 100.

The operation display LED 186 is driven by an operation display signal output from the first storage media connector 141 to the eighth storage media connector 148.

When the M.2 memory cards 150 used as the storage media are connected to the control unit 117 through the PCI EXPRESS X2 or PCI EXPRESS X4 interface, respectively, the number of pins of the connector to be used for the intermediate signal connection path In this case, the operation indication signal outputted from the first storage media connector 141 to the eighth storage media connector 148 is provided with an LED on the first vertical connection board. By providing a PHOTO COUPLER at a corresponding position on the printed circuit board 101 to form a PHOTO COUPLER, it is possible to additionally secure a connector pin on a insufficient connection path during signal wiring by not passing a separate connector in the signal path. .

The error display LED 187 is directly driven by a signal output from the controller 117.

On the other hand, the position indicated by the arrow in Figure 3 is a position where the fixing holes (HH_A1, HH_B1, HH_C1) of the 3.5-inch hard disk drive is provided.

4 is an interface card to which the SSD multiplexer according to the present invention is connected, and a PCI on a motherboard (not shown) provided inside a personal computer system (not shown) to which the SSD multiplexer 100 of the present invention is mounted. PCI EXPRESS ADD-IN card 80 is installed by inserting the PCI EXPRESS edge finger 83 in the EXPRESS slot (not shown).

Looking at the configuration of the interface card 80 as follows.

The PCI EXPRESS edge finger 83 is used for connection to a PCI EXPRESS slot (not shown) on a motherboard (not shown), and is connected to the control unit 87 through a PCI EXPRESS interface signal.

The power supply unit 85 receives power supplied from a motherboard (not shown) from a power supply terminal provided on the PCI EXPRESS edge finger unit 83 to generate various powers used in the interface card 80.

The control unit 87 is composed of a PCI EXPRESS switch, connected by a PCI EXPRESS edge finger 83 and a PCI EXPRESS interface signal, and branched into an internal connection connector 91 and an external connection connector 93, respectively. Connected to the interface signal.

The + 5V power generated through the power supply unit 85 and the + 12V power supplied through the power pins of the PCI EXPRESS edge finger unit 83 as the power required by the SSD multiplexer 100 of the present invention are for internal connection. The power supply pins provided on the connector 91 and the external connection connector 93 may be connected and supplied, respectively.

In some cases, only the signals necessary for the operation of the interface may be connected to the connector 91 for internal connection and the connector 93 for external connection. In this case, the USB connector 113 provided in the SD multiplexer 100 of the present invention. ) Is connected to the USB connector of the computer system 100 through a separate cable it is also possible to receive power from the power pin of the USB connector 113.

If the PCI EXPRESS switch 87 used as the controller 87 in the interface card 80 supports the RAID function, the data input / output in units of a predetermined buffer memory size is stored in the cache memory unit 89 once. After that, the data is read from the cache memory unit 89, and the PARITY operation required for the RAID5 or RAID6 configuration is performed to be stored in another designated area of the cache memory unit 89.

FIG. 5 is a perspective view of the SD multiplier 100 according to the present invention and shows a front portion provided with the SFF-8639 connector 111 and a rear portion provided with the storage media inlet cover 173, respectively.

According to FIG. 5, the external appearance of the SSD multiplexer 100 of the present invention includes the following elements.

The top cover 170 includes a front vent hole array 169 for securing air permeability to the front part where the SFF-8639 connector 111 is located, a dongle fixing nut 171 for fixing the PCI EXPRESS dongle (DONGLE), and a USB. The connector 113 is provided, and the rear portion is provided with the storage media inlet cover 173 and the inlet cover fixing protrusion and the separating handle 175 protruding therefrom.

In addition, the lower cover 200 and the side support 180 are not exposed in FIG. 5, and the side support guide fixing hole 181 and the inner hard guide fixing hole 179 provided on the outer surface of the side support 180 are provided. In this manner, the inner hard guide 177 is fixed to the side support 180 through fixing means such as a screw bolt (not shown).

The inner hard guide 177 is slidably coupled to an outer hard guide (not shown) provided in the mass storage system (not shown), so that the inner hard guide handle 178 is not moved artificially inwards without being moved inward. Used to prevent departure from (not shown).

FIG. 6 is a perspective view illustrating an internal structure of the SSD multiplexer 100 in which the top cover 170 of the SSD multiplexer 100 of the present invention is removed, and includes only one second vertical connection board connector ( 119), a connection relationship between the components constituted by the second vertical connection board 127 and the first vertical connection board 136 is illustrated.

Referring to FIG. 6, the lengths of the M.2 memory card 150 used as the storage media of the present invention are 60 mm M.2 memory card 150-1, 80 mm M.2 memory card 150-2, and 110 mm, respectively. Assuming that the M.2 memory card 150-3 is mounted at the same time, the first vertical connection board 136 is disposed along the length of each M.2 memory card 150 and the M.2 memory card 150 ) Is shown in a form overlapping with it in more detail as follows.

The second vertical connection board connector 119 is disposed on the side of the lower right side of the front portion of the SD multiplier 100 of the present invention, and the second vertical connection board 127 is inserted thereon.

On the second vertical connection board 127, the first vertical connection board connector 121 for 110 mm, the first vertical connection board connector 123 for 80 mm, and 60 mm for a position corresponding to the length of the M.2 memory card 150. Each of the first vertical connection board connectors 125 is provided.

The first vertical connecting board 136 is located at the bottom of the inner bottom guide structure 195 in the first position according to the length of the M.2 memory card 150 is positioned on the second vertical connecting board 127 It is connected to one of the first vertical connection board connector 121 for 110mm, the first vertical connection board connector 123 for 80mm or the first vertical connection board connector 125 for 60mm.

On the first vertical connection board 136, the first storage media connector 141 to the eighth storage media connector 148 for the M.2 memory card 150 is directly inserted and connected to the circuit. It is provided at regular intervals toward the (173) direction.

In this way, the M.2 memory cards 150 inserted into the storage media connectors 141, 142, and 148 are aligned in an arbitrary line at the rear end of the printed circuit board 101, and the storage media inlet cover 173 is provided. Is secured to the M.2 memory card 150 without being separated outward by the fixing means (described later in FIG. 8) provided inside the storage media inlet cover 173 when the side support 180 is coupled to the side support 180. do.

In FIG. 6 and the following drawings, the M.2 memory card 150 is illustrated in the drawing on the assumption that the memory card 150 is inserted in the vertical direction. However, as described above, the M.2 memory card 150 is provided on the first vertical connection board 136. 1 Arrange the storage media connector 141 to the eighth storage media connector 148 in the horizontal direction, but in the horizontal direction, the first storage media connector 141 is disposed at the bottom of the second vertical connection board 136 and the second The storage medium connector 142 is disposed on the top of the first storage medium connector 141 in a manner that the M.2 memory cards 150 are stacked so that the eighth storage medium connector 148 is disposed in the same manner. As a result, the M.2 memory card 150 may be installed in a two-stage stacked structure as a whole.

When the M.2 memory card 150 is arranged in the horizontal direction, the SSD multiplier 100 is arranged in a large amount of rack mount storage through an array of vent holes on the side of the side support 18 and the top cover 170. Smooth internal cooling can be achieved when mounted in the system 400.

Although the storage media connectors 141, 142,..., 148 are arranged in a two-stage stacking structure, in some cases, the storage media connectors 141, 142,... And the second vertical connection board connector 119 to the first vertical connection board connector 121, 123, and 125 for reinforcing input / output signals and power pins corresponding to a larger number of memory cards. It is desirable to replace the connector used with a connector that provides a higher pin count.

FIG. 7 is an exploded perspective view of the SSD multiplexer 100 of the present invention, and illustrates in detail the rear portion of the SSD multiplexer 100 in which the M.2 memory cards 150 are installed.

According to FIG. 7, the SD multi-plug 100 of the present invention includes side support members 180 on both left and right ends of the printed circuit board 101, and an inner hard guide 177 on the side support members 180. ) And the storage media inlet cover 173 are fixed.

That is, the inner hard guide 177 is fixed using a separate fixing means by matching the inner hard guide fixing hole 179 and the side support guide fixing hole 181, the storage media inlet cover 173 is the storage media inlet The inlet fixing protrusion 175 protruding inward from the left and right sides of the cover 173 is fixed to the inlet fixing groove 189 of the side support 180.

The M.2 memory card 150 is inserted toward the storage media connectors 141, 142, and 148 provided on the first vertical connection board 136 in a sliding manner with the storage media inlet cover 173 removed. In order to guide the M.2 memory card more stably in the process, the top cover 170 and the bottom cover 200 are provided with guide protrusions 201, 202, 182, and 185 having inlet openings having a 'V' shape. This will be described later with reference to FIGS. 12 and 13.

On the printed circuit board 101 at the bottom left and right of the M.2 memory card 150 inserted into the storage media connectors 141, 142, and 148 on the first vertical connection board 136, an operation display LED 186 and an error display LED 187 are provided respectively.

The lights of the operation display LED 186 and the error display LED 187 enable the user to monitor the respective LED operation status from the outside through a material such as smog acrylic of a translucent material.

8 is a perspective view of the storage media inlet cover 173 according to an embodiment of the present invention, the inlet vent holes 174 are arranged throughout, and the inlet fixing protrusion 175 is inward from both left and right sides thereof. It is provided in a protruding form.

M.2 memory card fixing groove guide protrusion 191 to prevent separation of the M.2 memory cards 150 inserted into the storage media connectors 141, 142, and 148 across the inner center of the storage media inlet cover 173. ) Is protruded, and the M.2 memory card fixing groove 193 engraved in the shape of a semi-circular concave structure is provided corresponding to each of the M.2 memory cards 150.

FIG. 9 is a plan view of the SDS multiplexer 100 according to an exemplary embodiment of the present invention, and the shapes of the inner lower guide structure 195 and the lower cover guide structure 194 are not shown on the above-mentioned perspective view. Along with the M.2 memory cards 150-1, 150-2, 150-3 are shown.

The inner lower guide structure 195 is moved together when the first vertical connection board 136 is to be moved to correspond to the length of the M.2 memory card 150, and the lower cover guide structure 194 is the lower cover Since it is formed by a protrusion protruding from the inner surface of the (200) always maintains a fixed state.

10 is a perspective view and a rear perspective view of the inner bottom guide structure 195 according to an embodiment of the present invention, wherein the bottom surface of the printed circuit board constituting the first vertical connection board 136 is the first vertical connection board fixing groove. When the M.2 memory card 150 is inserted, the M.2 is guided by a 'V' shaped guide groove formed by an inner right vertical guide protrusion 197 and an inner left vertical guide protrusion 199. An edge finger (not shown) of the memory card 150 is guided to be inserted into the storage media connectors 141, 142, and 148 correctly.

The lower surface of the inner lower guide structure 195 is provided with an anti-rolling protrusion 196, and a series of holes are provided on the printed circuit board 101 corresponding to the anti-rolling protrusion 196, so that the inner lower The guide structure 195 is tightly coupled to the surface of the printed circuit board 101.

Even when the user pushes the M.2 memory card with excessive force while the M.2 memory card 150 is mounted in a slide manner, the first vertical connection board 136 is the first vertical connection board fixing groove 198. Since the first vertical connection board 136 is not pushed back by the anti-rolling projection 196 is inserted into the).

11 is a perspective view of a lower connector 190 of the first vertical connection board to which the inner bottom guide structure and the first vertical connection board 136 of another form according to the embodiment of the present invention are coupled; Otherwise, without using the second vertical connection board 127 and the second vertical connection board connector 119, the first vertical connection board 136 is a M.2 memory card (150-1, 150-2, 150-3) ) Is previously fixed on the printed circuit board 101 at the bottom of the first vertical connection board 136 on a position corresponding to the length of each type.

  As such, when the first vertical connection board lower end connector 190 is provided, the first vertical connection board 136 is inserted into the first vertical connection board lower end connector 190 at the bottom so that a series of circuit connection relationships are formed. An edge finger portion (not shown) or a separate connector (not shown) coupled with the lower connector 190 of the first vertical connection board should be provided.

An inner bottom guide structure 195 of another type shown in FIG. 11 is located in front of the first connector board bottom connector 190, and the incoming M.2 memory card is stored on the first connector board 136. The role of accurately guiding the connectors 141, 142, 148 is the same as the inner bottom guide structure 195 shown in FIG. 10.

12 is a perspective view of a bottom cover 200 according to an embodiment of the present invention, and forms a series of guide protrusions 182, 183, 184, and 185 protruding from an inner side surface.

When the M.2 memory card 150 is inserted, the edge fingers (not shown) of the M.2 memory card 150 may include the lower cover left primary guide protrusion 182 and the lower cover right primary guide protrusion 185. A storage memory element 159 which is guided along the 'V' shaped guide groove formed by the M.2 memory card 150 and is mounted in the M.2 memory card 150 as the M.2 memory card 150 is gradually inserted inward. ) Is sequentially guided by the lower cover left (right) side secondary guide protrusion 183 and the lower cover left (right) side third guide protrusion 184.

The lower cover left (right) side secondary guide protrusion 183 and the lower cover left (right) side third guide protrusion 184 have a curved end surface for smooth guide of the M.2 memory card.

The printed circuit board 101 is cut to a suitable size so that the above-mentioned series of guide protrusions 182, 183, 184, and 185 protrude from the bottom cover 200.

13 is a perspective view of the top cover 170 according to an embodiment of the present invention, even if the first vertical connection board 136 is disposed according to the length of the M.2 memory card 150 corresponds to the first vertical connection board The first vertical connection board fixing protrusions 213, 215, 217 are provided to firmly support the position.

In addition, the upper cover (left) right guide protrusions 207, 209, and 211 correspond to the inner lower guide structure 195 coupled to the first vertical connection board 136 to form the M.2 memory card 150. It is provided on the inner side of the top cover 170 corresponding to the length.

When the M.2 memory card 150 is inserted The edge fingers (not shown) of the M.2 memory card 150 may include the upper cover right primary guide protrusion 201 and the upper cover left primary guide protrusion 202. A storage memory element 159 which is guided along the 'V' shaped guide groove formed by the M.2 memory card 150 and is mounted in the M.2 memory card 150 as the M.2 memory card 150 is gradually inserted inward. ) Is sequentially guided by the top cover (left) right secondary guide protrusion 203 and the top cover (left) right third guide protrusion 205.

The upper cover (left) right secondary guide protrusion 203 and the upper cover (left) right third guide protrusion 205 have a curved end surface for smooth guide of the M.2 memory card 150.

An upper cover fixing support 212 is provided to fix the upper cover 170 to the printed circuit board 101, and the lower cover provided on the lower cover 200 located on the lower surface of the printed circuit board 101. It is fixed together using a separate fixing means inserted through the cover fixing hole (199).

Meanwhile, a dongle (DONGLE) fixing nut 171 may be provided at the center of the front portion of the top cover 170.

If the user will not use the dongle 300, the dongle fixing nut 171 can be removed and the entire nut groove stopper 280 can be inserted to maintain a clean appearance. The upper support 285, the dongle fixing nut 171, the nut groove lower support 281 in order to assemble the top cover so that only the dongle fixing nut 171 portion is exposed to the outside.

13 and 14, the guide protrusions 182, 183, 184, 185, 201, which protrude from the upper cover 170 and the lower cover 200, respectively, in guiding the M.2 memory card 150, 202, 203, 205, 207, 209, and 211 are described as guiding the outer surface of the unit storage memory element such as NAND FLASH memory mounted on the printed circuit board of the M.2 memory card 150. Preferably, a guide structure having a concave-convex structure surrounding a portion of the printed circuit board exposed to the left and right outer sides of the M.2 memory card 150 is provided to protrude from the top cover 170 and the bottom cover 200. The M.2 memory card 150 may be guided, and the guide of this type may be configured in which the unit storage memory device is mounted only on one side of the M.2 memory card 150 or both sides of the M.2 memory card 150. Even in the mounted form, the M.2 memory card 150 In addition, the guide structure protruding from the top cover 170 and the bottom cover 200 can be stably guided on the M.2 memory card 150 as well as being able to guide stably without shaking by mounting or removing by sliding. After guiding the mounted unit storage memory device, the protruding guide structure covers the unit storage memory device, thereby fundamentally eliminating the factors that hinder heat dissipation of the unit storage memory device.

12 and 13 illustrate the guide of the M.2 memory card 150 in the vertical direction as an embodiment, but the M.2 memory card 150 is mounted in the horizontal direction. Even in this case, the method of guiding the printed circuit board exposed to the left and right outer surfaces of the M.2 memory card 150 described above by the uneven structure may be similarly applied.

14 is a perspective view of a dongle (DONGLE) 300 for use in the PCI EXPRESS interface according to an embodiment of the present invention is coupled to the SD multiplexer 100, Figure 15 is a perspective view of the dongle 300 itself only As a combination of the SFF-8639 receptacle (RECEPTACLE) connector 307 is inserted corresponding to the SFF-8639 connector 111 and the USB plug connector 309 inserted in correspondence with the USB connector 113, The dongle fixing bolt 301 provided on the opposite side is fastened to the dongle fixing nut 171 provided on the front part of the main body 100 through the dongle fixing bolt through hole 311 for fixing more firmly.

The PCI EXPRESS connector 303 provided on the outer side of the dongle 300 is connected to the same signal line pin-to-pin as the SFF-8639 receptacle connector 307, and has a USB plug connector ( 309 is a connection between the USB connector 305 and the power pin only.

That is, the USB connector 305 is used only for the purpose of supplying the auxiliary power, and when the user wants to use the PS multiplexer 100 of the present invention as a USB interface, the dongle 300 is separated and the SD The USB connector 113 provided in the front of the multiplexer 100 may be directly used.

FIG. 20 shows a PCIe expansion card of each PCIe slot 3-1 provided on the host computer 2 with a rackmount case type storage system 400 equipped with the M.2 multiplexer 100 of the present invention. (3-5) shows a state connected to, the number of expandable storage system 400 is limited by the number of PCIe slots (3-1) provided on the host computer (2).

21 is a rack mount case type storage system 400 of the present invention, on which the M.2 multiplexer 100 of the present invention is mounted, is connected to each connection port of the storage expansion system 5, and the storage expansion system ( 5) is a block diagram showing the state connected to a single PCIe expansion card (3-5) of the PCIe slot (3-1) provided on the host computer (2), a limited slot (3- 1) is useful for mounting a larger number of storage systems 400, and is always at least 5Gbps (PCIe Gen.2 x1) or any storage system 400 connected on the storage expansion system 5 or It has a feature that can exhibit performance of at least 8Gbps (PCIe Gen.3 x1).

FIG. 22 is a first block diagram illustrating a rackmount case type storage system 400 using an M.2 multiplexer 100 or a hard disk drive as a unit storage medium.

In general, the maximum number that can be accommodated by placing a 3.5-inch hard disk drive vertically in the width of a standard 42U rack (RACK) is 15, and the other hard disk drive that is a multiple of 2 is as shown in FIG. It is located at the top of the rear part.

15 M.2 multiplexers 100, which are replaced by hard disk drives, are arranged in a vertical and vertical direction to form a unit BAY-ROW board 370, and the row-row is accommodated in a detachable case. MAGAZINE 371 may be configured.

ROW-MAGAZINE (371) is a 'U' shape in the direction and 'C' shape is a box shape with the top open, and it is to keep 15 bays separated from the main body. It is also possible to separate the unit M.2 multiplexer 100 from the ROW-MAGAZINE 371.

When the ROW-MAGAZINE 371 is separated from the storage system main body 400 and stored, the ROW-MAGAZINE 371 is provided with the PAIR storage media provided in the rear part of the storage system main body 400 in order. It can be stored in a combined state by using a separate mounting means on one side.

The first block diagram of FIG. 22 may directly correspond to the connection method as shown in FIG. 22, but may also be applied to the storage expansion system 5 illustrated in FIG. 21.

In the block diagram of FIG. 22, the interface connected to the host computer 2 is formed of PCIe x16, the PCI Express expansion card is provided in the PCI Express first slot, and the PCI Express second slot is PCI Express. It is provided in a position adjacent to the first slot, the pins of the two slots are maintained in the state connected with the pin-to-pin wiring, respectively.

If any BAY-ROW board 370 is configured as an M.2 multiplexer 100, each PCIe x1 from the PCI Express switch 352 connected to the PCI Express first slot side with the PCI expansion card is provided. Since each M.2 multiplexer 100 is connected to the PC-I Express signal branched to the PCI-E Express switch 352, the PCIe Lane is matched with the PCIe x16 interface before and after the PC-I Express Switch 352, so the signal is connected. There is a characteristic that no delay occurs.

At this time, the PC-I Express signal input and output from the PC-I Express Switch 352 is connected to the PCI Express interface port on the SFF-8639 connector (not shown) provided on the BAY-ROW board 370.

If the other BAY-ROW board 370 is configured only with a hard disk drive, the PCI Express second slot connector connected to the PCI Express first slot including the PCI Express expansion card and connected by pin-to-pin wiring may be used. A RAID card is provided on the board, and a SATA or SAS interface signal input and output from the RAID card is connected to the SATA or SAS port of the SFF-8639 connector of the BAY-ROW board 370.

FIG. 23 is a second block diagram of a rackmount case type storage system 400 using the M.2 multiplexer 100 of the present invention as a unit storage medium, and the first block diagram of FIG. PC Express Express switch 354 to connect one PCIe expansion card 350 and unit BAY-ROW boards 380-1, 380-2, 380-3, and 380-4 to the PCI Express interface signal. It is a form.

The structure of FIG. 23 utilizes a limited number of PCIe slots 3-1 when the rackmount case type storage system 400 of the present invention is directly connected on the host computer 2, while maintaining high capacity without degrading interface performance. It can be configured, the interface performance is characterized by the performance of PCIe x16 in front of the PCX Express switch 354.

In addition, the block diagram of FIG. 23 may correspond to a connection port provided in the storage expansion system 5 of FIG. 21 in a 1: 1 ratio, and thus may be usefully applied to expand a larger number of storage systems.

For reference, in order to apply the PCIe x16 expansion card 350 of FIG. 23 to the PCIe x8 port provided in the storage expansion system 5 of FIG. 21, the PCIe x16 configuration of the PCIe expansion card 350 of FIG. This can be solved by connecting the lower PCIe x8 to the storage expansion system (5) by replacing it with a two-port PCIe x8 card.

24 is a perspective view and a rear view of an embodiment of a rackmount case type storage system 400 equipped with the M.2 multiplexer 100 of the present invention. The rackmount case may include a front panel 401 and a side view. The panel 403 and the rear panel 405, the side panel 403 is composed of a slide rail 407 for mounting in a 42U rack (not shown).

A rail support 409, which is part of the 42U rack component for securing the slide rail 407 to the 42U rack, is shown together in FIG.

Rack mount case 400 of the present invention is a unit for mounting a hard disk drive and / or M.2 multiplexer BAY-ROW board 370 may be equipped with 15 3.5-inch hard disk drive, the interface connector The SFF-8639 standard connector (not shown) includes a SATA interface for a hard disk drive interface and a PCIe x4 interface for an M.2 multiplexer 100 interface at the same time.

The configuration of the BAY-ROW board 370 can be configured by forming a separate partition wall (not shown) to fit the external appearance of the 3.5-inch hard disk drive and fixing the hard guide outers therein. As mentioned above, the ROW-MAGAZINE 371 may be configured inside the partition wall.

In FIG. 24, the BAY-ROW board 370 or the ROW-MAGAZINE 371 is illustrated as being configured with four ROWs. However, the BAY-ROW board 370 or the ROW-MAGAZINE 371 may be additionally extended in units of the BAY-ROW board 370 or the ROW-MAGAZINE 371.

A space of 1U height (44.45mm) is provided at the bottom of the printed circuit board constituting the BAY-ROW board 370 to serve as a connection passage for various cables and a passage for air flow.

Outside the partition to which the rear row ROW-MAGAZINE 371 is fixed, a series of inner cooling fans 419 are provided to form a flow of air, and the fan grills 411, 415, which are provided on the front panel 401 are provided. 417) Cooling fans are also disposed inside.

The power switch 411 and the LCD 413 which display various operation states are arrange | positioned at the upper center part of a front panel.

The rear bay 423 is located at the upper left / right side of the rear part, and one BAY is added to 15 BAYs constituting each BAY-ROW board 370 to form 16 BAYs, which are multiples of two.

A power module 427 is located at the bottom left and right of the rear bay 423, respectively, and internally constitutes an N + 1 REDUNDANT PSU on a printed circuit board (not shown) connecting the two power modules 427. It configures the power output by the circuit as a single power supply.

In the center of the left and right power supply module 427, a PCIe slot hole 429 for mounting the PCI Express interface card is arranged.

A base board (not shown) is provided at an inner center of the left / right power module corresponding to the PCIe slot hole 429, and the first block diagram of FIG. 22 is based on a configuration method of the base board (not shown). In this case, a pin-to-pin signal connection is formed between two PCIe slot connectors (not shown) on a BASE board (not shown) corresponding to two PCIe slot holes 429 adjacent from the left side.

For this reason, if all of the storage media mounted on any one BAY-ROW board 370 are hard disk drives, RAID configuration is provided to ensure data preservation even if any one or two hard disk drives fail. For this purpose, a RAID card is mounted in any one of two PCIe slots, and a PCIe interface card is mounted in the other PCIe slot.

If all of the BAY-ROW boards 370 are mounted only with a hard disk drive, the RAID card and the PCIe interface card are connected in circuit by using two adjacent PCIe slots as a pair.

Meanwhile, in the case of the storage system according to the second block diagram of FIG. 23, a PCIe slot hole corresponding to a specific PCIe slot connector (not shown) to which a PCI Express switch 354 on a BASE board (not shown) is connected ( 429) is used, and each PC Express signal branched from the PCI Epxress switch 354 is connected to the bottom of the BAY-ROW board 370 through a separate cable or internal wiring through a connected port connector (not shown). It is connected to a corresponding connector (not shown) provided in the connector, which is in turn connected to each SFF-8639 connector (not shown) to which the M.2 multiplexer 100 is connected.

Accordingly, the second block diagram of FIG. 23 may be maintained only for the M.2 multiplexer 100 having the controller 117 having a RAID function as a storage medium.

Of course, unlike the M.2 multiplexer 100, the SSD that supports the PCIe x4 interface may be mounted using a separate bracket (not shown), even in a single SSD (not shown). Because the RAID card 8 is a structure that cannot be mounted internally in the storage system, if any one SSD (not shown) fails, the entire data may be lost.

That is, since the storage system 400 itself is not supported by RAID5 or RAID6, when the storage media itself is equipped with a plurality of storage media such as the M.2 multiplexer 100 and does not support RAID function, data preservation is performed. The storage system 400 according to the first block diagram of FIG. 22 presented in the present invention, in particular, the second block diagram of FIG. 23, which is difficult to configure a RAID by mounting a RAID card, has a meaning because of problems in stability of the image. You can say no.

Meanwhile, according to the first block diagram of FIG. 22 and the second block diagram of FIG. 23, the M.2 multiplexer 100 mounted on the BAY-ROW 370 without using a separate RAID card is connected to the host computer 2. Recognized as M.2 multiplexer 100 storage unit, and can be represented as a single volume or a plurality of volumes according to the configuration method through the RAID configuration of the software method internally in the host computer (2).

Generally, due to the software RAID configuration on the host computer (2), RAID0 and RAID1 have little bit operation for generating RAID configuration data, so there is no significant difference in performance compared to the hardware RAID configuration. It is not used well because the degree of delay is larger than the hardware method for parity bit operation for recovery bit generation.

The storage system 400 of the present invention according to the block diagram shown in FIG. 22 and FIG. 23 does not have a separate server internally configured for the storage system, and thus the configuration of the system is simple.

In addition, since the RAID card 8 is removed together with the server (not shown) which is conventionally used for the storage system configuration, the heat generation is less, and the space occupied by the server (not shown) and the RAID (8) card are reduced. It is possible to replace the BAY-ROW board 370 or ROW-MAGAZINE (371) with high density / capacity storage media.

In addition, since the server (not shown) with large power consumption and the RAID card 8 are removed, it is possible to mount a power module 427 which is lighter and simpler and has a smaller capacity, thereby increasing its own heat and volume of the power module 427. There is an additional reduction advantage.

In the above description, for the sake of convenience, the M.2 memory card has been described as an example. However, the same configuration as described above may be applied to the 2.5-inch or 1.8-inch SDS which are generally used.

However, when the 2.5-inch or 1.8-inch SD-based configuration, the problem that the physical size of the outer case of the SSD multiplexer 100 of the present invention becomes larger than the 3.5-inch hard disk drive is inevitable.

 In the above, a preferred embodiment according to the present invention has been described in detail, but those skilled in the art can carry out various modifications and modifications within the scope of the claims.

Claims (43)

1. A printed circuit board having PCI EXPRESS or SATA interface connection means;

   A plurality of storage media of the PCI EXPRESS interface method or the SATA interface method;

   A control unit connected to the PCI EXPRESS or SATA interface connecting unit;

   A first vertical connection board disposed in a vertical direction with respect to the printed circuit board and configured of at least one or more;

   A storage media connector comprising at least one or more disposed on one side of the first vertical connection board;

   An SD multiplexer characterized in that the storage medium is connected to the storage medium connector;
2. The method of claim 1,

   The printed circuit board includes at least one or more first vertical connection board lower connectors at a lower end of the first vertical connection board, and the lower connector of the first vertical connection board is the first vertical connection board and the controller. SSD multiplexer, characterized in that for connecting the circuit.
3. The method of claim 1,

   A second vertical connection board connector connected to the control unit and configured as one or two and disposed in a vertical direction on left and right sides of the printed circuit board;

   A second vertical connection board coupled to the second vertical connection board connector and configured as one or two perpendicular to the printed circuit board;

   A first vertical connection board connector configured on at least one side of the second vertical connection board and configured to correspond to the length of the storage media; And

   SSD multiplexer, characterized in that consisting of a first vertical connection board coupled to the arbitrary first vertical connection board connector.
4. The method of claim 1,

   The printed circuit board further comprises a USB interface connecting means to be connected to the control unit SSD multiplexer.
5. The method of claim 1,

   A storage media connector provided in the vertical direction on the first vertical connection board is provided in a vertical direction with the printed circuit board so that the storage media is coupled in a vertical direction with respect to the printed circuit board. .
6. The method of claim 1,

   A storage media connector provided in the vertical direction on the first vertical connection board is provided in a horizontal direction with the printed circuit board so that the storage media is coupled in a horizontal direction with respect to the printed circuit board. .
7. The method of claim 6,

   The storage media connectors arranged on the first vertical connection board is arranged at least one or more horizontally so that the storage media are coupled in a multi-stacked manner.
8. The method of claim 3, wherein

   And the first vertical connection board corresponding to the length of the storage medium is coupled to the first vertical connection board connector provided on the second vertical connection board in a forward / backward direction to be coupled.
9. The method of claim 3, wherein

   The second vertical connection board mounts the first vertical connection board connector and mounts the first vertical connection board connector at a position corresponding to the length of the storage medium. 2 vertical connection boards, respectively

   Coupling the second vertical connection board corresponding to the same length of the storage medium to the second vertical connection board connector,

   And the first vertical connection board coupled to the length of the storage medium in such a manner as to be coupled to the first vertical connection board connector on the second vertical connection board.
10. The method of claim 2,

    When the length of the storage media is two types, the first vertical connection boards are each provided in a bisected form having a length corresponding to the number of the two types of storage media, and the first vertical connection board is provided at a position corresponding to the length of the storage media. 1 S multiplexer, characterized in that the vertical connection board can be coupled to the lower connector of the first vertical connection board, respectively, the storage media of different lengths can be coupled to each of the first vertical connection board.
11. The method of claim 3,

    When the length of the storage media is two types, the first vertical connection boards are each provided in a bisected form having a length corresponding to the number of the two types of storage media, and the first vertical connection board is provided at a position corresponding to the length of the storage media. 1 S multiplexer, characterized in that by coupling the vertical connection board to the second vertical connection board, respectively, the storage media of different lengths can be coupled to each of the first vertical connection board.
12. The method of claim 1,

    The printed circuit board is provided with side supports on the left and right sides, respectively, and the side supports are provided with holes corresponding to the fixing holes of the hard disk drive on the lower side and the outer surface at the same position as the hard disk drive. SD multiplier made with.
13. The method of claim 12,

    And a top cover, a bottom cover, and an inlet cover of the storage medium, on top and bottom of the printed circuit board.
14. The method according to claim 12 and 13,

    S side multiplexer characterized in that the side support and the top cover is an integral structure.
15. The method according to claim 5 or 6,

    And a guide structure having a concave-convex structure surrounding a printed circuit board exposed at left and right sides of the storage medium, wherein the storage medium is guided by the guide structure.
16. The method according to claim 5 and 13,

    When the storage medium is introduced through the inlet of the storage media inlet cover, SD multi-providing a series of storage media guide projections protruding vertically from the inner surface of the top cover and the bottom cover Plug.
17. The method of claim 16,

    And the guide protrusion is guided along the surface of the storage medium.
18. The method of claim 16,

    The storage media guide protrusion has a shape of the inlet is 'V' shaped for smooth guide SSD multiplexer.
19. The method of claim 16,

    And the storage media guide protrusion forms a 'V' shaped guide shape at an inlet of the first vertical connection board connector for accurate guide of the storage media.
20. The method of claim 2 or 3,

    S multiplexer characterized in that to form a guide shape of the 'V' shape by providing a lower inner guide structure on the bottom of the first vertical connection board.
21. The method of claim 20,

    And the inner bottom guide structure is moved together as the position of the first vertical connection board is moved in correspondence with the length of the storage medium.
22. The method of claim 20,

    The inner bottom guide structure has an SD multiplexer having at least one support protrusion at the bottom.
23. The method according to claim 1 and 13,

    The at least one first vertical connection board fixing protrusion protruding from the bottom surface of the top cover corresponding to the position where the first vertical connection board is moved according to the length of the storage media Plug.
24. The method according to claim 1 and 13,

    The storage media inlet cover is fixed to form a U-shaped protrusion inside the storage media inlet cover when the storage media is an M.2 memory card to prevent separation from the semi-circular fixing hole of the M.2 memory card. Ss multiplexer characterized by having a groove.
25. The method of claim 1,

    The controller supports a RAID function for the storage media coupled to the first vertical connection board, so that the storage media is converted into at least one or more logical storages according to a user's designation. Plug.
26. The method of claim 25,

    The control unit is connected to the PCI EXPRESS interface side in the PCI EXPRESS or SATA connection means when the storage media is a PCI EXPRESS interface method, and the control unit is the PCI EXPRESS interface side in the PCI EXPRESS or SATA connection means when the storage media is a SATA interface. Or SSD multiplexer, characterized in that connected to the SATA interface side.
27. The method of claim 1,

    The control unit is configured as a PCI EXPRESS switch, corresponding to each of the storage media PCI EXPRESS x1, x2 or x4 lane configuration, characterized in that connected to the PCI EXPRESS interface to the PCI EXPRESS interface connection means Multiplier.
28. The method of claim 25 or 26,

    When the SD Multi-Plug is installed at a location where the 3.5-inch hard disk drive bay of the computer system is mounted, the SD Multi-connector is connected to the interface card provided in the PCI Express slot of the computer system using a separate cable. Plug.
29. The method according to claim 5 or 6,

    And an LED operated by an operation operation indication LED signal output from the storage media connector at an upper end of the printed circuit board in the vicinity of the opposite end surface of the storage media at a position coupled to the storage media connector. Ssd multiplexer.
30. The method of claim 29,

    An LED operated by an operation indication LED signal output from the storage media connector is provided at the bottom of the first vertical connection board, and corresponding to the LED provided at the bottom of the first vertical connection board. And a PHOTO COUPLER formed so that the operation indicator LED signal is output to the PHOTO-TR on the printed circuit board without going through a separate connector.
31. The method according to claim 1 and 5 or 6,

    SSD multi-characterized by an error indication LED signal output from the controller on the upper end of the printed circuit board in the vicinity of the opposite end surface of the storage media in the position coupled to the storage media connector Plug.
32. The method according to claim 1, 4 and 13,

    SFF-8639 connector corresponding to pin-to-pin (PIN-TO-PIN) and USB plug connector corresponding pin-to-pin to the USB connector, and the connector can be fixed to the PCI EXPRESS or SATA interface connecting means A printed circuit board, a dongle for an external interface having a connector for a PCI Express external interface that is connected to the SFF-8639 connector on one side of the printed circuit board and a USB connector that is connected to the USB plug connector S-D multiplexer further comprises (DONGLE).
33. The method of claim 32,

    An SD plug between the USB connector and the USB plug connector has a circuit connection formed only with respect to a power pin.
34. The method of claim 13,

    The top cover is a SD multiplexer, characterized in that the front portion has a dongle fixing nut groove in the vertical direction.
35. The method of claim 34,

    The dongle fixing nut groove is composed of a nut groove upper support, a nut, a nut groove lower support when the dongle is used, and an entire nut groove plug when the dongle is not used.
36. The method of claim 32,

    The dongle is a SD multiplexer, characterized in that consisting of the dongle top cover, the dongle bottom cover and the dongle fixing bolt.
37. A PCI Express expansion card connected to an external host computer;

    A PC-I Express switch connected to the PC-I Express expansion card and a PC-I Express interface signal;

    An SD multiplier equipped with a control unit having a RAID function and a plurality of SD storage media connected thereto; And

    Storage system, characterized in that a series of unit BAY-ROW is configured by mounting at least one or more SD multiplexer connected to the PCI Express interface signal branched to the PCI Express switch.
38. The method of claim 37,

    The storage system is a storage system, characterized in that to form a unit storage array consisting of the PCI Express expansion card, PCI Express switch and BAY-ROW in at least one or more arrays.
39. The method of claim 38,

    A first PCIe slot provided with the PCi Express expansion card;

    A second PCIe slot in which pin-to-pin wiring is formed;

    Any other BAY-ROW configured only with SSD multiplier; And

    In the configuration of any BAY-ROW composed only of the hard disk drive,

    The BAY-ROW equipped with the M.2 multiplexer is connected to the PCI Express interface signal branched to the PCI Express switch, and the RAID is installed in the second PCIe slot for the BAY-ROW equipped with the hard disk drive. Storage card, characterized in that additionally provided with a SATA or SAS interface signal input and output from the RAID card.
40. The method of claim 38,

    Storage media mounted on the SD multiplexer is arranged in a direction parallel to the direction of the air flow from the front portion to the rear portion of the storage system.
41. A PCI Express expansion card connected to an external host computer;

    A first PC Express switch connected to the PC Express expansion card and a PCI Express interface signal;

    At least one or more BAY-ROWs that include a second PCX Express switch branched from the first PCA Express switch and connected to a plurality of PCX Express interface signals, respectively;

    And a SD multiplexer which is branched from the second PC Express switch on the BAY-ROW and connected to a plurality of PCI Express interface signals, respectively.
42. 42. The method of claim 41 wherein

    The SSD multiplexer includes a control unit having a RAID function and a plurality of SSD storage media connected thereto.
43. The method of claim 42,

    Storage media mounted on the SD multiplexer is arranged in a direction parallel to the direction of the air flow from the front portion to the rear portion of the storage system.

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