KR101913784B1 - Ssd multipler and the storage system based on it - Google Patents

Abstract

In the present invention, a plurality of M.2 memory cards are vertically or horizontally arranged in a multistage arrangement in the same size as a 3.5-inch hard disk drive to replace a 3.5-inch hard disk drive in a 3.5-inch hard disk drive, To provide an MSD multi-plug that has a larger capacity of the M.2 memory card.
In particular, since the M.2 memory card is provided with various types of lengths in terms of the standard, it provides an environment that can be used corresponding to the length of the M.2 memory card.
In addition, the S-DIMMER of the present invention has an SFF-8639 connector that supports the PCI EXPRESS and SATA interfaces at the same time as the connector of the 3.5-inch hard disk drive, and is supported by the mounted M.2 memory card PCI EXPRESS interface or SATA interface is provided according to the type of interface and the RAID configuration method by the built-in controller.
In addition, a separate USB connector is provided to facilitate the use of the SAS de-multiplexer of the present invention as a portable storage device, thereby supporting a USB interface.
In particular, the present invention provides a dongle for a PCI EXPRESS interface in order to use a high-speed PCI EXPRESS interface while using the SAS de-multiplexer of the present invention as a portable device.
Finally, we provide a concise bus architecture and a storage system based on the M.2 multi-plug-mounted mass storage system of the present invention.

Description

[0001] SSD MULTIPLER AND THE STORAGE SYSTEM BASED ON IT [0002]

The present invention reduces the weight of a computer compared to the case where an M.2 memory card is used as a main storage of a notebook computer and uses a 2.5-inch SASd (SSD), and particularly mounts an M.2 memory card supporting a PCI EXPRESS interface To use the M.2 memory card as a single unit, it is possible to replace the 3.5-inch hard disk drive by mounting a plurality of M.2 memory cards in the same external shape as the 3.5-inch hard disk drive Or as a portable storage device.

In the conventional technique, there has been an attempt to mount a plurality of M.2 memory cards in the interior of a 3.5-inch hard disk drive. However, in the case of an M.2 memory card, , Various types of lengths such as 30, 42, 60, 80, and 110 (mm) are presented as standard.

In the present invention, since a plurality of M.2 memory cards are applied to the same outer shape as a 3.5 inch hard disk drive, but for the purpose of realizing storage of a larger capacity, among the M.2 memory cards of various lengths, Type M.2 memory card having a length of 60, 80 and 110 (mm).

In addition, when the M.2 memory card is arranged horizontally or vertically at regular intervals in a case of the same size as a 3.5-inch hard disk drive, the M.2 memory card is fixedly guided to a predetermined position .

In addition, the circuit connection method corresponding to the PCI EXPRESS interface or SATA interface supported by the M.2 memory card, the RAID support of the control part, or the interface method when the interface is not supported is described.

Meanwhile, the ESD multiflamer of the present invention is basically the same in appearance as a 3.5-inch hard disk drive, but in the case where it is arranged in the longitudinal direction according to the arrangement type of the M.2 memory card, It is easy to replace the M.2 memory card by opening the storage medium entrance cover but it is not possible to make the thickness thinner than the 3.5 hard disk drive while the M.2 memory card is kept horizontal with the printed circuit board In the case of the horizontal arrangement, the size of the casing in the horizontal and vertical directions is the same as that of the 3.5 inch hard disk drive, but the thickness can be made thinner than the 3.5 inch hard disk drive.

Accordingly, the SAS de-multiplexer of the present invention can be replaced with a 3.5-inch hard disk drive, and can be a high-performance portable storage system as such.

In addition to having a SFF-8639 connector at the same position as the connector of a 3.5-inch hard disk drive, the USB EXPRESS interface and the SATA interface support the USB connector And also provides a USB interface.

The present invention further provides a dongle for a PCI EXPRESS interface in order to smoothly support high-performance data input / output over a USB interface while using the SAS de-multiplexer as a portable storage medium.

The PCI EXPRESS dongle has a connector corresponding to the SFF-8639 connector and the USB connector of the MSD Multiplayer main body so that it can be coupled tightly to each other. The PCI EXPRESS dongle is connected to the PCI EXPRESS The connector is connected to a connector provided on the fixed bracket of the interface card provided as a PCI EXPRESS ADD-IN card type provided in the PCI EXPRESS slot on the motherboard connected to the commercial commercial PCI EXPRESS cable. Suggest a plan.

The 3.5-inch hard disk drive-type ASD multifuler 10 according to the related art has an M.2 connector 25, 27, 29 (see FIG. 1) to which the M.2 memory card 35, 2, the M.2 memory cards 35, 37, 39 are arranged in a state of being horizontal with respect to the printed circuit board .

The horizontal M.2 connector 51 corresponding to the M.2 connector 25, 27, 29 of FIG. 1 is fixed to a corresponding point on the printed circuit board according to a predetermined length of the M.2 memory card to be used And an interface signal constituting a PCI EXPRESS lane that branches from a 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, it is possible to internally configure only one type of M.2 memory card corresponding to the length of the M.2 memory card, The M.2 connectors 25, 27 and 29 need to be separately arranged on a separate printed circuit board since the arrangement positions of the M.2 connectors 25, 27 and 29 must be aligned with the M.2 memory cards of different lengths.

In addition, when the M.2 memory card is constituted only by 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 , And the M.2 memory card is configured to support the SATA interface, the SATA port of the SFF-8639 connector 11 and the first M.2 connector 25, the first SATA connector 25, (SATA) interface signal between the second M.2 connector 27, the second SATA connector 15, and the third M.2 connector 29 via a direct SATA interface signal.

16, the conventional multi-device bay 1 is connected to a PCIe slot 3-1 provided in the host computer 2 through a PC i-Express hub card 3-7, In the computer 2, each device is recognized.

The PCIe Express Hub card (3-7) is equipped with a PCIe Express switch (4), which is connected to the PCIe slot (3-1) via PCIe x16, and the PCIe x4 And a connecting port.

The PC I / E switch 4 has a separate control pin for adjusting the branching type of the PCIe signal to be connected to the outside.

18 shows an example in which the conventional scalable multi-device bays 1 are connected to an external PCIe hub 5 using an expandable multi-device bay and the external PCIe hub 5 is connected to a PCIe expansion card 3- 5).

FIG. 19 is a block diagram illustrating an external PCIe hub 5 incorporating a second PCIe hub card 7 mounted in a slide manner on the basis of a conventional expandable multi-device bay 1, 1) as a storage system, a RAID card 8 must be provided.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is a first object of the present invention to provide a 3.5-inch hard disk drive which is widely used by using a PCI EXPRESS interface or an M.2 memory card of SATA interface type, In which a plurality of M.2 memory cards are vertically or horizontally arranged at a high density to provide a mass storage device.

A second object of the present invention is to provide a memory card having a first vertical length in which an M.2 memory card is inserted so as to correspond to the lengths of various kinds of M.2 memory cards having the same width but different vertical width And to provide an MSD Multiplayer that can be used 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 a memory card comprising two second vertical connection boards on the left and right sides of a main printed circuit board to accommodate two lengths of M.2 memory cards, In which the first vertical connection board is coupled to the 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 provide a method of controlling a plurality of M.2 memory cards by forming a single or multi-volume logical storage through a RAID configuration in a controller, and, even if any M.2 memory card fails, And to replace only the M.2 memory card with the same M.2 memory card so that normal data can be recovered.

A fifth object of the present invention is to provide an MSD Multiplayer that supports a USB interface by providing a USB connector for connecting the MSD Multiplayer to any computer for easy portability.

A sixth object of the present invention is to provide a PCI EXPRESS dongle, which is separately provided to support high performance data transmission of a PCI EXPRESS interface while being used as a portable device, Which is exposed to a connector of a PCI EXPRESS ADD-IN card provided in a computer main body.

A seventh object of the present invention is to provide a large-capacity storage device, which is similar to the above-described M.2 memory card using a 2.5 inch SAS disk, which is generally used even if it is larger than the external shape of a 3.5 inch hard disk drive And to provide an ESD multi-plug that provides a means for providing an ESD.

According to an aspect of the present invention, there is provided an SAS demultiplexer including: a printed circuit board having a PCI EXPRESS or SATA interface connection means; A plurality of storage media in a PCI EXPRESS interface mode or a SATA interface mode; A control unit connected to the PCI EXPRESS or SATA interface connection means; A first vertical connection board arranged in a direction perpendicular to the printed circuit board and composed of at least one or more than one;

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

The printed circuit board may include at least one first vertical connection board lower connector at a lower end of the first vertical connection board, and the first vertical connection board lower connector may include at least one first vertical connection board lower connector, And the control unit is connected in a circuit.

A second vertical connection board connector connected to the control unit, the second vertical connection board connector being formed of one or two and arranged in the vertical direction on left and right sides of the printed circuit board; A second vertical connection board connected to the second vertical connection board connector and formed of one or two vertical members perpendicular to the printed circuit board; A first vertical connection board connector formed on one side of the second vertical connection board and corresponding to a length of the storage medium; And a first vertical connection board coupled to the first vertical connection board connector.

The printed circuit board may further include a USB interface connection unit to be connected to the control unit.

In addition, a storage media connector provided in a direction perpendicular to the first vertical connection board is provided in a direction perpendicular to the printed circuit board, and the storage medium is vertically coupled to the printed circuit board.

In addition, a storage medium connector provided in a direction perpendicular to the first vertical connection board is provided in a horizontal direction with respect to the printed circuit board, and the storage medium is coupled to the printed circuit board in a horizontal direction.

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

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

The second vertical connection board mounts one of the first vertical connection board connectors and mounts one of the first vertical connection board connectors at a position corresponding to the length of the storage medium, Connecting the second vertical connection board corresponding to the same length of the storage media to the second vertical connection board connector, respectively, and connecting the first vertical connection board to the second vertical connection board, The first vertical connection board connector on the connection board is 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 connection board.

In addition, when the length of the storage media is two, the first vertical connection board is provided in a divided form having a length corresponding to the number of the storage media, And connecting the first vertical connection boards to the first vertical connection board lower connectors, respectively, to connect storage media having different lengths to the respective first vertical connection boards.

In addition, when the length of the storage media is two, the first vertical connection board is provided in a divided form having a length corresponding to the number of the storage media, And connecting the first vertical connection boards to the second vertical connection boards, respectively, to connect storage media having different lengths to the respective first vertical connection boards.

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

Further, an upper cover, a lower cover, and an inlet cover of the storage medium are additionally provided at the upper and lower ends of the printed circuit board.

In addition, the side support and the upper cover are integrally structured.
Also, a guide structure having a concavo-convex structure that surrounds the printed circuit board exposed on the left / right of the storage medium is provided, and the storage medium is guided by the guide structure.

And a series of storage media guide protrusions protruding in a vertical direction from inner surfaces of the upper cover and the lower cover when the storage medium is drawn through the inlet of the storage medium inlet cover.

The guide protrusion is guided along the surface of the storage medium.

In addition, the storage media guide protrusion has a V-shaped inlet port for smooth guide.

Also, the storage media guide protrusion forms a 'V' shaped guide shape at the entrance of the first vertical connection board connector for accurate guide of the storage media.

In addition, an inner bottom guide structure is provided at a lower end 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 moved together.

The inner bottom guide structure may include at least one support protrusion at a lower end thereof.

In addition, at least one first vertical connection board fixing protrusion protruded from a lower end surface of the upper cover corresponding to a position where the first vertical connection board is moved according to the length of the storage medium.

In addition, if the storage medium is an M.2 memory card, the storage medium entrance cover may include a U-shaped protrusion on the inside of the storage medium entrance cover to prevent the storage media from being separated from the semi- As shown in Fig.

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

If the storage medium is a PCI EXPRESS interface, the controller is connected to the PCI EXPRESS interface side through the PCI EXPRESS or SATA connection means. If the storage medium is the SATA interface, the controller transmits the PCI EXPRESS Interface side or the SATA interface side.

The controller is 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 connection means through a PCI EXPRESS interface.

In addition, when the SAS demultiplexer is installed in a position where the 3.5 inch hard disk drive bay of the computer system is mounted, the interface card is connected to the interface card provided in the PCI Express slot of the computer system using a separate cable.

And an LED operated by an operation operation indicating LED signal outputted from the storage medium connector at the upper end of the printed circuit board in the vicinity of the opposite longitudinal end face of the storage medium at a position coupled to the storage media connector .

In addition, an LED operating according to an operation display LED signal output from the storage media connector may be provided at the lower end of the first vertical connection board, and the LEDs provided at the lower end of the first vertical connection board may be connected to the printed circuit board The PHOTO-TR is provided at the upper part to form the PHOTO COUPLER so that the operation display LED signal is output to the PHOTO-TR on the printed circuit board without passing through the separate connector.

And an LED operable by an error indication LED signal output from the control unit at an upper end of the printed circuit board in the vicinity of the opposite vertical section of the storage medium at a position coupled to the storage media connector.

Also, the SFF-8639 connector corresponding to the PCI EXPRESS or SATA interface connection means with a PIN-TO-PIN and the USB plug connector corresponding to the USB connector with a pin to pin are provided, An external interface having a connector for a PCI EXPRESS external interface circuitly connected to the SFF-8639 connector on one side of the printed circuit board and a USB connector in circuit connection with the USB plug connector, A dongle is additionally provided.

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

In addition, the upper cover has a nut groove for fixing the dongle in the vertical direction.

In addition, when the dongle is used, the dongle fixing nut for the dongle is composed of a nut support upper part, a nut, and a lower support part for a nut groove.

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

Also, a PC Eye Express expansion card connected to an external host computer; A PC iExpress switch connected to the PC iExpress expansion card and a PC iE interface signal; An ASD multifuller equipped with a control unit having a built-in RAID function and a plurality of ASD storage media connected thereto; And at least one ESD demultiplexer connected to the PCE Express interface signal branched to the PCE Express switch is installed to form a series of unit BAY-ROWs.

In addition, the storage system may include at least one or more unit storage arrays, each of which includes a PC iExpress expansion card, a PC iExpress switch, and a BAY-ROW

A first PCIe slot having the PCIe Express expansion card; A second PCIe slot in which the first PCIe slot and the pin-to-pin wiring are formed; Any other BAY-ROW consisting solely of M.2 Multiplexers ; And a hard disk drive. In the BAY-ROW configuration, the BAY-ROW provided with the M.2 multiplexer is connected to a PC interface signal that is branched to the PC I / O switch, For the BAY-ROW with the drive, a RAID card is additionally provided in the second PCIe slot to connect SATA or SAS interface signals input / output from the RAID card.

In addition, the storage media mounted on the SAS demultiplexer are arranged in a direction parallel to the direction of air flow leading from the front side to the rear side of the storage system.

Also, a PC Eye Express expansion card connected to an external host computer; A first PC iExpress switch connected to the PC iExpress expansion card via a PC i Eye interface signal; At least one or more BAY-ROWs including a second PC Eye Express switch that branches from the first PCA Express switch and is connected to a plurality of channels of PC Eye Express interface signals, respectively; And an ESD multi-splitter branched from the second PC I / O switch on the BAY-ROW and connected to the PC I / O interface signals of the plurality of channels, respectively.

In addition, the SAS de-multiplexer includes a controller incorporating a RAID function and a plurality of SAS storage media connected thereto.

In addition, the storage media mounted on the SAS demultiplexer are arranged in a direction parallel to the direction of air flow leading from the front side to the rear side of the storage system.

The ESD multiflamer according to the present invention is a case in which a case body in which a plurality of M.2 memory cards are built in a case of 3.5 inch hard disk drive size and a case body are used as a portable storage device, And a DONGLE that makes it easy to use the PCI EXPRESS interface.

The MS de-multiplexer of the present invention can cope with a case where the length of the M.2 memory card is 60 mm, 80 mm, or 110 mm, and with respect to the M.2 memory card of any one of the lengths, The position of the first vertical connection board provided in the demultiplexer is provided in the longest three kinds of lengths in such a manner as to be coupled to a corresponding position on the second vertical connection board according to the length of the M.2 memory card to be used Lt; RTI ID = 0.0 > M.2 < / RTI > memory card of any one of the M.2 memory cards.

In addition, if the user wishes to install two types of M.2 memory cards of the present invention on the MS de-multiplexer of the present invention, a first vertical connection board, which is separated into two for left and right sides, The first vertical connection board is connected to the vertical connection board connector at the corresponding position on the second vertical connection board provided on the left and right sides respectively corresponding to the length of each M.2 memory card, It is possible to install two types of M.2 memory cards of different lengths by inserting an M.2 memory card of the length.

On the other hand, if the M.2 memory card supports the SATA interface or supports the PCI EXPRESS interface, if the PCI Express X1 or X2 lane is supported, the second vertical connection board and the first vertical connection board Can be used.

If you want to support an M.2 memory card that supports the PCI EXPRESS X4 interface, you can configure two second vertical connection boards and one first vertical connection board to connect the PCI EXPRESS I / O interface signals to the left and right 2 vertical connection board connectors.

The SAS de-multiplexer of the present invention further includes a USB connector to provide a USB interface so that the MS de-multiplexer main body can be easily used as a portable storage device.

Lastly, even if a failure occurs in any M.2 memory card due to the RAID function provided by the controller used in the MS de-multiplexer of the present invention, the data of the storage configured by the MS de-multiplexer of the present invention is not lost It is possible to maintain the stable state. By simply replacing the M.2 memory card, which is identified through the LED at the lower inner side of the storage medium entrance cover of the translucent material, by simply replacing the memory card, the entire data management state can be restored to the state before the error through the execution of the REBUILD operation It is possible to restore.

FIG. 1 is a block diagram of a conventional 3.5-inch hard disk drive-type SAS demultiplexer.
2 is an M.2 memory card according to the prior art for connecting an M.2 memory card and a connector used in the present invention and a length coupled to the connector.
FIG. 3 is a block diagram of an ASD multiplexer according to the present invention.
Fig. 4 is an interface card to which the MS de-multiplexer according to the present invention is connected.
5 is a perspective view of an ASD multiflaver according to the present invention.
6 is a perspective view showing an internal structure of an ASD multifeller in which a top cover of an ASD multiflamer of the present invention is removed.
FIG. 7 is an exploded perspective view of the ASD multiflaver of the present invention. FIG.
8 is a perspective view of a storage media inlet cover according to an embodiment of the present invention.
9 is a plan view of an ASD multiflaver according to an embodiment of the present invention.
10 is a perspective view and a rear elevation view of an inner bottom guide structure according to an embodiment of the present invention.
FIG. 11 is a perspective view of a lower end connector to which another inner bottom guide structure and a first vertical connection board are coupled according to an embodiment of the present invention. FIG.
12 is a perspective view of a bottom cover according to an embodiment of the present invention.
13 is a perspective view of an upper cover according to an embodiment of the present invention.
FIG. 14 is a perspective view of a DONGLE for use with a PCI EXPRESS interface according to an embodiment of the present invention coupled to an ASD multifunctional device.
15 is an exploded perspective view of a mating connector surface of a dongle according to an embodiment of the present invention.
16 is a diagram illustrating a state in which conventional expandable multi-device bays are connected via an internal PCIe hub card installed in a computer of a user's computer.
FIG. 17 is a block diagram of a conventional embedded PCIe hub card used in FIG. 16. FIG.
FIG. 18 is a diagram illustrating a state in which conventional expandable multi-device bays are connected to an external PCIe hub using an expandable multi-device bay and an external PCIe hub is connected through a PCIe expansion card installed inside a host computer.
FIG. 19 is a block diagram illustrating an external PCIe hub having a second PCIe hub card mounted in a slide manner based on a conventional extended multi-device bay.
FIG. 20 is a view showing a rack-mount case type storage system on which an M.2 multifuler of the present invention is mounted, connected to PCIe expansion cards of respective PCIe slots provided on a host computer.
FIG. 21 shows a rack-mount case type storage system in which the M.2 multiplexer of the present invention is mounted is connected to each connection port of the storage expansion system, and the storage expansion system includes a PCIe expansion card Fig.
22 is a first block configuration diagram of a rack mount case type storage using the M.2 multi-plug or hard disk drive of the present invention as a unit storage medium.
23 is a second block configuration diagram of a rack-mount case type storage system using the M.2 multi-plug according to the present invention as a unit storage medium.
24 is a perspective view and a rear view of an embodiment of a rack-mount case type storage system equipped with an M.2 multi-plug of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a block diagram of a solid state disk (SSD) multifller according to the present invention.

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

The SFF-8639 connector 111 is a connector in which pins for the PCI EXPRESS X4 interface are disposed 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), the pins to form two SATA interfaces, and the power pins that supply + 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 to the SATA interface pins.

The power supply unit 115 receives power supplied from the outside through the SFF-8639 connector 111 and the USB connector 113, and generates various power supplies used in the MS de-multiplexer 100 of the present invention.

The control unit 117 may be provided in various forms according to the types of interfaces supported by the M.2 memory cards 151, 152, and 158 as storage media to be used.

That is, if the M.2 memory card 150 supports the SATA interface and supports the SATA interface as the external interface, the SATA port multiplexer is preferable as the IC for the controller 117. At this time, the SATA interface Pins are connected to the pins for the SATA interface on the SFF-8639 connector (111).

If the controller 117 configured using the SATA PORT MULTIPLIER supports the RAID function, the M.2 memory card 150 is connected as a single volume or as a storage represented by a plurality of volumes according to the format of the RAID configuration If the controller 117 does not support the RAID function, it functions as a simple PORT MULTIPLIER so that the individual M.2 memory cards 150 can be accessed from a connected computer system (not shown) .

If the M.2 memory card 150 supports the SATA interface and supports the PCI EXPRESS interface as an external interface, the PCI EXPRESS-TO-SATA conversion IC may be used for the control unit 117, The PCI EXPRESS interface pins of the SFF-8639 connector 117 are connected to and connected to the pins for the PCI EXPRESS interface on the SFF-8639 connector 111 on a signal-by-signal basis.

In this case, if the PCI EXPRESS-TO-SATA conversion IC used for the control unit 117 supports the RAID function as in the above example, the M.2 memory card 150 may be a single volume according to the format of the RAID configuration, or If the controller 117 does not support the RAID function, each M.2 memory card 150 is recognized by a computer system (not shown) connected to the M.2 memory card 150 as a storage that is displayed as a plurality of volumes, Is recognized as an individual store.

If the M.2 memory card 150 supports the PCI EXPRESS interface and also supports the PCI EXPRESS interface as an external interface, an IC for the PCI EXPRESS switch can be used for the control unit 117, The PCI EXPRESS interface pins of the SFF-8639 connector 117 are connected to and connected to the pins for the PCI EXPRESS interface on the SFF-8639 connector 111 on a signal-by-signal basis.

In this case, if the PCI EXPRESS switch IC used for the control unit 117 supports the RAID function, the M.2 memory card 150 may be divided into a single volume or a plurality of volumes according to the format of the RAID configuration If the controller 117 does not support the RAID function, each M.2 memory card 150 is recognized by a computer system (not shown) connected thereto as a displayed storage, .

The USB connector 113 is provided to easily connect to an arbitrary computer (not shown) when the MSD Multiplayer 100 of the present invention is used as a portable data storage device, It is connected to the USB port.

The second vertical connection board connector 119 may be provided with one or two connectors according to the interface type of the M.2 memory card 150 used as the storage medium and the configuration of the signal line LANE, On the left side and the right side of the control unit 117 on the right side.

That is, the connector used as the second vertical connection board connector 119 may be a vertical type connector like the other connectors used between the controller 117 and the M.2 memory cards 150 used in the present invention, M.2 connector is used. In the present invention, since the M.2 connector having a key is provided on one side only, the number of usable pins is 67 in total, whereas the M.2 memory card is used as a PCI Express X2 or PCI EXPRESS X4 The number of signal lines exceeds the number of pins of one second vertical connection board connector 119, so that the number of pins connected to one second vertical connection board connector 119 is insufficient To solve this problem, a second vertical connection board connector 119 is provided on the left / right side of the control unit 117, respectively.

On the other hand, when the M.2 memory cards 150 used as the storage medium support the SATA interface or the PCI Express X1 interface, only the pins provided from one second vertical connection board connector 119 Only one second vertical connection board connector 119 is provided on only one side of the control unit 117 as shown in FIG.

As described above, the second vertical connection board 127 may be used either singly or in combination, depending on the number of signal lines connected between the controller 117 and the M.2 memory card 150 used as the storage medium , And is coupled to the second vertical connection board connector (119).

3, the second vertical connection board 127 corresponds to the length of the M.2 memory cards 151, 152, and 158 used as the storage media, such as 60 mm, 80 mm, and 110 mm, A vertical end of the memory card provided with the fixing groove 31 is provided at a corresponding position on the second vertical connection board 127 on the basis of a position at which the end portion of the memory card provided with the fixing groove 31 is aligned at a designated position on the M.2 memory card inlet (not shown) A first vertical connection board connector 121 for a 110 mm, a first vertical connection board connector 123 for an 80 mm, and a first vertical connection board connector 125 for a 60 mm.

(Not shown) in which the second vertical connection board 127 is connected to the second vertical connection board connector 119 and the first vertical connection board connector connectors 121, Signal lines are connected between the pins corresponding to the same signals of the first and second vertical connection boards 123 and 125 using the inner / outer layer wiring space of the printed circuit board constituting the second vertical connection board 127.

The first vertical connection board 136 connects 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, In the vertical or horizontal direction.

The first storage media connector 141 to the eighth storage media connector 148 are arranged in a horizontal direction with respect to the printed circuit board 101 so that the multi- In this case, a high-density storage configuration is possible depending on how many M.2 connectors are arranged in the same column as one horizontally disposed connector.

As described above, the first vertical connection board 136 is connected to any one of the first vertical connection board connectors 121, 121 provided on the second vertical connection board 127 corresponding to the length of the M.2 memory card 150, 123, and 125, respectively.

If the length of the M.2 memory card 150 to be installed is two, the size of the M.2 memory card 150 may be a half size (HALF SIZE) or a different ratio Two first vertical connection boards 136 are provided on the second vertical connection board connector 119 and the second vertical connection board 127 provided on the left and right sides of the controller 117, It can be solved by connecting two first vertical connection boards 136 to corresponding connectors of the first vertical connection board connectors 121, 123 and 125 correspondingly to the length of the M.2 memory card 150 .

In this way, the first vertical connection board 136, which is provided in a half size, divides a signal input / output to / from the control unit 117 into a first vertical connection board 136, The length of the signal wiring for the storage medium located farthest from the control unit 117 is excessively long to prevent a signal delay from occurring.

The LED display units 161, 162 and 168 are constituted by an operation display LED 186 and an error display LED 187. The fixed part of the M.2 memory card 150 used as a storage medium is the ESD multi- (Not shown) of the storage medium 100 of the plug 100. As shown in FIG.

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 storage media are connected to the control unit 117 through the PCI EXPRESS X2 or PCI EXPRESS X4 interface, the number of pins of the connector used in the intermediate signal connection path In this case, the operation indication signal output from the first storage media connector 141 to the eighth storage media connector 148 may include an LED on the first vertical connection board, PHOTO-TR is provided at a corresponding position on the printed circuit board 101 to form a PHOTO COUPLER so that a separate connector is not passed through the signal path, thereby making it possible to additionally secure a connector pin on a connection path that is insufficient for signal wiring .

The error display LED 187 is directly driven by the signal output from the control unit 117. [

3, the fixing holes HH_A1, HH_B1, and HH_C1 of the 3.5-inch hard disk drive are provided at positions indicated by arrows.

4 is an interface card to which an MSD Multiplayer according to the present invention is connected. In FIG. 4, an interface card (not shown) provided in a personal computer system (not shown) And a PCI EXPRESS ADD-IN card 80 in which a PCI EXPRESS edge rejection 83 is inserted into an EXPRESS slot (not shown).

The configuration of the interface card 80 is as follows.

The PCI EXPRESS edge rejection 83 is intended to be connected 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 terminal provided on the PCI EXPRESS edge rejection 83, and generates various power sources used in the interface card 80.

The control unit 87 is constituted by a PCI EXPRESS switch and is connected to the PCI EXPRESS edge rejection 83 and the PCI EXPRESS interface signal. The PCI EXPRESS interface 83 is connected to the internal connection connector 91 and the external connection connector 93, Interface signal.

A +12 V power supplied through the power supply pins of the PCI EXPRESS edge rejecting unit 83 and the +5 V power generated through the power supply unit 85 by the power supply required by the MS de-multiplexer 100 of the present invention is connected to the + And may be connected to the power supply pins provided on the connector 91 and the connector 93 for external connection, respectively.

In some cases, only the signals necessary for the interface operation may be connected to the internal connection connector 91 and the external connection connector 93. In this case, the USB connector 113 May be connected to a USB connector of the computer system 100 through a separate cable and supplied with power from a power pin of the USB connector 113. [

If the PCI EXPRESS switch 87 used as the control unit 87 in the interface card 80 supports the RAID function, data input and output in units of a certain buffer memory size are temporarily stored in the cache memory unit 89 And reads the data from the cache memory unit 89 to perform the PARITY operation required for the RAID 5 or RAID 6 configuration and stores it in another designated area of the cache memory unit 89.

5 is a perspective view of an MSD Multifilar 100 according to an embodiment of the present invention, which shows a front portion having an SFF-8639 connector 111 and a rear portion having a storage medium inlet cover 173, respectively.

5, the appearance of the MS de-multiplexer 100 of the present invention is composed of the following elements.

The top cover 170 includes a front ventilation hole array 169 for ensuring air permeability, a dongle fixing nut 171 for fixing a PCI EXPRESS dongle, a USB A connector 113 and the like, and a storage medium inlet cover 173 and an inlet cover fixing protrusion and a separating knob 175 protruding from the storage medium inlet cover 173 are provided at the rear portion.

5, the lower cover 200 and the side support 180 are provided. 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, And the inner hard guide 177 is fixed to the side support 180 through a fixing means such as a screw bolt (not shown).

The inner hard guide 177 is slidably coupled to an outer hard guide (not shown) included in the mass storage system (not shown) to move the inner hard guide knob 178 to the outside hard guide (Not shown).

6 is a perspective view showing the internal structure of the MSD multiplexer 100 in which the top cover 170 of the MSD multi-plug 100 according to the present invention is removed. The second vertical connection board connector 119, a second vertical connection board 127, and a first vertical connection board 136. In this case,

Referring to FIG. 6, the length of the M.2 memory card 150 used as the storage medium of the present invention is 60 mm M.2 memory card 150-1, 80 mm M.2 memory card 150-2, It is assumed that the M.2 memory card 150-3 is mounted at the same time so that the first vertical connection board 136 is arranged according to the length of each M.2 memory card 150 and the M.2 memory card 150 ) Are superimposed on one another in a state of being described in more detail as follows.

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

On the second vertical connection board 127, a first vertical connection board connector 121 for 110 mm, a first vertical connection board connector 123 for 80 mm and a second vertical connection board connector 123 for 60 mm are provided at positions corresponding to the length of the M.2 memory card 150 And a first vertical connection board connector 125 are respectively provided.

The first vertical connection board 136 is positioned on the lower end with the inner bottom guide structure 195 in a state where it first seats according to the length of the M.2 memory card 150, The first vertical connection board connector 121 for the 110 mm, the first vertical connection board connector 123 for the 80 mm or the first vertical connection board connector 125 for the 60 mm.

A first storage media connector 141 to an eighth storage media connector 148 for directly inserting and circuitly connecting the M.2 memory card 150 are formed on the first vertical connection board 136, (173).

The M.2 memory cards 150 inserted into the storage media connectors 141, 142 and 148 are thus aligned on any straight line of the rear end of the printed circuit board 101 and the storage media inlet cover 173 Each M.2 memory card 150 is securely fixed (not shown) by fixing means (described later in FIG. 8) provided inside the storage medium entrance cover 173 when the M.2 memory card 150 is coupled to the side support 180. [ do.

Although FIG. 6 and the following drawings illustrate the M.2 memory card 150 inserted in the vertical direction, the first vertical connection board 136, 1 storage media connector 141 to the eighth storage media connector 148 in the horizontal direction while the first storage media connector 141 is disposed at the lower end of the second vertical connection board 136 in the horizontal direction, The storage media connectors 142 are arranged at the top of the first storage media connector 141 in such a manner that the M.2 memory cards 150 are stacked, The M.2 memory card 150 can be installed in a two-layer laminated structure as a whole.

When the M.2 memory card 150 is arranged in the horizontal direction, the side support 18 and the side surface of the top cover 170 are provided with a series of ventilation holes through the arrangement of the ventilation holes so that the M.2 multi- Smooth internal cooling can be achieved when mounted on the mount storage system 400. [

The storage media connectors 141, 142,..., And 148 are disposed in a two-layer laminated structure, but in some cases, the storage media connectors 141, 142, The second vertical connection board connector 119 to the first vertical connection board connectors 121, 123, and 125 are provided for reinforcing input / output signals and power pins corresponding to a greater number of memory cards. It is preferable to replace the connector used as the connector with a connector that provides more pins.

FIG. 7 is an exploded perspective view of the MS de-multiplexer 100 of the present invention, showing in detail the rear portion of the MS de-multiplexer 100 in which the M.2 memory cards 150 are installed.

7, the ESD multiflamer 100 of the present invention includes a side support 180 at both ends of the left and right sides of the printed circuit board 101. An inner hard guide 177 And the storage medium inlet cover 173 are fixed.

In other words, the inner hard guide 177 is fixed using a separate fixing means by aligning the inner hard guide fixing hole 179 and the side support guide fixing hole 181, and the storage medium inlet cover 173 is fixed to the storage medium inlet The inlet fixing projections 175 projecting inward from the left and right sides of the cover 173 are fixed in such a manner that they are engaged with the inlet fixing grooves 189 of the side support 180. [

The M.2 memory card 150 is pulled toward the storage media connectors 141, 142, 148 provided on the first vertical connection board 136 in a slidable manner with the storage medium entrance cover 173 removed The upper cover 170 and the lower cover 200 have the guide protrusions 201, 202, 182, and 185 which are opened in a V-shape in order to guide the M.2 memory card more stably. Will be described later with reference to Figs. 12 and 13.

On the printed circuit board 101 on the lower left and right sides of the M.2 memory card 150 inserted in the storage media connectors 141, 142 and 148 on the first vertical connection board 136, an operation display LED 186 and an error indication LED Respectively.

The lights of the operation display LED 186 and the error display LED 187 are able to monitor the operation status of each LED from the outside through a material such as a smoked acrylic of translucent material.

8 is a perspective view of a storage medium inlet cover 173 according to an embodiment of the present invention in which inlet inlet holes 174 are arranged in the first half and inlet inlet fixing protrusions 175 are arranged inward from both left and right sides And is provided in a protruded form.

The M.2 memory card fixing groove guide protrusions 191 are provided to prevent separation of the M.2 memory cards 150 inserted into the storage media connectors 141, 142 and 148 across the inside center of the storage media entrance cover 173. [ And an M.2 memory card fixing groove 193 engraved in a semicircular concave structure is provided in correspondence with each of the M.2 memory cards 150. As shown in FIG.

9 is a plan view of the AS de-multiplexer 100 according to the embodiment of the present invention. The shape of the inner bottom guide structure 195 and the bottom cover guide structure 194, which are not shown in the above- M.2 memory cards 150-1, 150-2, and 150-3.

The inner bottom guide structure 195 is moved together when the first vertical connection board 136 is to be moved corresponding to the length of the M.2 memory card 150 and the bottom cover guide structure 194 is moved together with the bottom cover & Since it is formed by the protrusions protruding from the inner surface of the body 200, it is always kept fixed.

10 is a perspective view and a rear elevation view of the inner bottom guide structure 195 according to the embodiment of the present invention. The bottom surface of the printed circuit board constituting the first vertical connection board 136 is connected to the first vertical connection board fixing groove Shaped guide groove formed by the inner right vertical guide protrusion 197 and the inner left vertical guide protrusion 199 when the M.2 memory card 150 is inserted. (Not shown) of the memory card 150 is guided and guided to be correctly inserted into the storage media connectors 141, 142, and 148.

The lower inner guide structure 195 is provided with an anti-slide protrusion 196 and a series of holes corresponding to the anti-slide protrusion 196 on the printed circuit board 101, 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 in the process of mounting the M.2 memory card 150 in the slide manner, the first vertical connection board 136 is inserted into the first vertical connection board fixing groove 198 So that the first vertical connection board 136 is not pushed backward by the anti-slide projection 196. [

FIG. 11 is a perspective view of a first vertical connection board lower end connector 190 to which a first vertical connection board 136 is coupled with another inner lower end guide structure according to an embodiment of the present invention. The first vertical connection board 136 is connected to the M.2 memory cards 150-1, 150-2, 150-3, and 150-3 without using the second vertical connection board 127 and the second vertical connection board connector 119 On the printed circuit board 101 at the lower end of the first vertical connection board 136 on a position corresponding to the length of each type of the first vertical connection board 136. [

  When the first vertical connection board lower end connector 190 is provided as described above, the first vertical connection board 136 is inserted into the first vertical connection board lower end connector 190 at the lower end to form a series connection (Not shown) that is provided with an edge fingering (not shown) or a separate connector (not shown) coupled with the first vertical connection board lower end connector 190.

Another type of inner bottom guide structure 195 shown in FIG. 11 is located in front of the first vertical connection board lower connector 190 and connects the incoming M.2 memory card to the storage media on the first vertical connection board 136 The role of guiding the connectors 141, 142 and 148 precisely is the same as the inner lower guide structure 195 shown in Fig.

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

When the M.2 memory card 150 is inserted, the edge fingers (not shown) of the M.2 memory card 150 are inserted into the lower cover left primary guide protrusion 182 and the lower cover right primary guide protrusion 185, Shaped guide groove formed by the M.2 memory card 150, and as the M.2 memory card 150 is gradually inserted inward, the storage memory elements 159 Is sequentially guided by the secondary cover left (right) side secondary guide projection 183 and the lower cover left (right) side tertiary guide projection 184.

The secondary cover left (right) side secondary guide projection 183 and the lower cover left (right) side tertiary guide projection 184 are smoothly curved in the vertical section for guiding the M.2 memory card.

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

13 is a perspective view of an upper cover 170 according to an embodiment of the present invention. Even when the first vertical connection board 136 is moved according to the length of the M.2 memory card 150, And first vertical connection board fixing protrusions 213, 215, and 217 for firmly supporting the first vertical connection board fixing protrusions 213, 215, and 217.

The upper cover (left) right guide protrusions 207, 209, and 211 are used to correspond to the inner lower guide structure 195 coupled to the first vertical connection board 136, And is provided on the inner surface of the top cover 170 corresponding to the length.

When the M.2 memory card 150 is inserted, the edge fingering (not shown) of the M.2 memory card 150 is performed by the upper cover right side primary guide projection 201 and the upper cover left side primary guide projection 202, Shaped guide groove formed by the M.2 memory card 150, and as the M.2 memory card 150 is gradually inserted inward, the storage memory elements 159 Is sequentially guided by the upper cover (left) right second guide protrusion 203 and the upper cover (left) right third guide protrusion 205.

The upper cover (left) right second guide protrusion 203 and the upper cover (left) right third guide protrusion 205 are curved in the longitudinal direction for guiding the M.2 memory card 150 smoothly.

A lower cover 200 provided on a lower end surface of the printed circuit board 101 is provided with an upper cover fixing support 212 for fixing the upper cover 170 to the printed circuit board 101, And are fixed together using separate fixing means inserted through the cover fixing hole 199.

Meanwhile, a dongle fixing nut 171 may be provided at the center of the front surface of the top cover 170.

If the user does not use the dongle 300, it is possible to maintain a neat appearance by removing the dongle fixing nut 171 and fitting the entire nut groove stopper 280. If the dongle is to be used, The upper cover 285, the dongle fixing nut 171 and the nut groove lower support 281 in this order to assemble the upper cover so that only the dongle fixing nut 171 is exposed to the outside.
13 and 14, the guide protrusions 182, 183, 184, 185, 201, and 201 protruding from the upper cover 170 and the lower cover 200, respectively, 202, 203, 205, 207, 209, and 211 to guide the outer surface of the unit storage memory device such as a NAND FLASH memory mounted on the printed circuit board of the M.2 memory card 150, Preferably, a guide structure of a concave-convex structure for covering a part of the printed circuit board exposed on the left / right outer side of the M.2 memory card 150 is provided in a protruding form from the top cover 170 and the bottom cover 200 The M.2 memory card 150 can be guided by such a guide that the unit storage memory element is mounted on only one end face of the M.2 memory card 150, In the case of the mounted type, the M.2 memory card 150 The guide structure protruding from the upper cover 170 and the lower cover 200 can be stably guided on the M.2 memory card 150 After the unit storage memory element is guided, the protruding guide structure hides the unit storage memory element, which can fundamentally obviate a factor of hindering the heat dissipation of the unit storage memory element.
Although FIGS. 12 and 13 illustrate the guide of the M.2 memory card 150 in the vertical direction, the M.2 memory card 150 may be mounted in the horizontal direction The method of guiding the printed circuit board exposed on the left and right outer side surfaces of the M.2 memory card 150 described above to the shape of wrapping the printed circuit board by the concave and convex structures can be applied equally.

FIG. 14 is a perspective view of a dongle 300 for use with a PCI EXPRESS interface according to an embodiment of the present invention coupled to an MSD Multiplier 100, FIG. 15 is a perspective view of only a Dongle 300 itself, The SFF-8639 receptacle connector 307 inserted in correspondence with 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 surface of the main body 100 through the dongle fixing bolt through hole 311. [

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

That is, the USB connector 305 is used only for supplying the auxiliary power. When the user intends to use the MS de-multiplexer 100 of the present invention as a USB interface, the user disconnects the dongle 300, The USB connector 113 provided on the front of the multi-plug 100 may be directly used.

20 shows a rack-mount case type storage system 400 on which the M.2 multi-plug 100 of the present invention is mounted is connected to a PCIe expansion card 400 of each PCIe slot 3-1 provided on the host computer 2. [ The number of storage systems 400 that can be extended is limited by the number of PCIe slots 3-1 provided on the host computer 2. [

FIG. 21 shows a rack-mount case type storage system 400 of the present invention on which the M.2 multi-plug 100 of the present invention is mounted is connected to each connection port of the storage expansion system 5, 5 of the host computer 2 are connected to a single PCIe expansion card 3-5 of the PCIe slot 3-1 provided on the host computer 2. The limited slot 3- 1 (PCIe Gen. 2 x 1) or for any storage system 400 that is useful on the storage expansion system 5 and which is always useful for mounting a greater number of storage systems 400 And can exhibit performance of at least 8 Gbps (PCIe Gen.3 x1).

22 is a first block configuration diagram of a rack mount case type storage system 400 using the M.2 multi-plug 100 or the hard disk drive of the present invention as a unit storage medium.

In general, the maximum number of the 3.5 inch hard disk drives arranged in the vertical direction is 15 in the width of the standard type 42U rack, and the remaining one hard disk drive, which is a multiple of 2, And is disposed at the top of the rear portion.

15 M.2 multiflators 100 disposed in place of the hard disk drive are arranged in the vertical direction to form a unit BAY-ROW board 370. The unit BAY-ROW board 370 is formed in a ROW- MAGAZINE 371 may be constructed.

ROW-MAGAZINE (371) is a U-shape in the direction of the figure, and is shaped like a box shape with the top of the shape of 'c' open. It keeps 15 bays separated from the main body It is also possible to separate the unit M.2 multifulse 100 from the ROW-MAGAZINE 371.

The ROW-MAGAZINE 371 is connected to the ROW-MAGAZINE 371 through a pair of PAIR storage media provided on the rear side of the storage system body 400, It can be stored in a state of being coupled with a separate mounting means on one side.

The first block diagram of FIG. 22 can be directly corresponded to the connection scheme shown in FIG. 22, but can also be applied on the storage expansion system 5 shown in FIG.

22 is a block diagram showing a configuration in which an interface connected to the host computer 2 is formed of PCIe x 16, a PC iExpress expansion card is provided in a PC i-Express first slot, a PC i-Xpress second slot is a PC i- And the pins of the two slots remain connected to the pin-to-pin wiring, respectively.

When the arbitrary BAY-ROW board 370 is composed of the M.2 multiplexer 100, the PCIe x1 is connected to the PCIe Express switch 352 connected to the PCIe first slot side equipped with the PCIe expansion card, Since the PCIe lanes are connected to the PCIe x16 interface at the front and rear ends of the PCE xpress switch 352, respectively, since the respective M.2 multiplexers 100 are connected to the PCE xpress signal branched to the PCIe xpress signal, There is a characteristic that no delay occurs.

At this time, the PC I / O signal input / output from the PC I / O 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 optional BAY-ROW board 370 is composed only of a hard disk drive, the PCIe Express first slot equipped with the PCIe Express expansion card and the PCIe Express second slot connector connected by the pin- And a SATA or SAS interface signal input / output from the RAID card is connected to the SATA or SAS port of the SFF-8639 connector of the BAY-ROW board 370.

23 is a second block configuration diagram of a rack-mount case type storage system 400 using the M.2 multi-plug 100 of the present invention as a unit storage medium, and the first block configuration of FIG. The PCIe expansion switch 350 and the unit BAY-ROW boards 380-1, 380-2, 380-3, and 380-4 are woven into a PC iExpress interface signal, It is a form to put.

The structure of FIG. 23 shows that when the rack-mount case type storage system 400 of the present invention is directly connected to the host computer 2, a limited number of PCIe slots 3-1 are utilized, And the interface performance is characterized by the performance of the PCIe x16 in front of the PCE Express switch 354.

Also, the block diagram of FIG. 23 can correspond to a connection port provided in the storage expansion system 5 of FIG. 21 at a ratio of 1: 1, which is useful for expanding a larger number of storage systems.

In order to apply the PCIe x16 expansion card 350 of FIG. 23 to the PCIe x8 port of the storage expansion system 5 of FIG. 21, the PCIe x16 configuration of the PCIe expansion card 350 of FIG. It can be solved by replacing the PCIe x8 with a card composed of two ports and connecting the lower PCIe x8 to the storage expansion system 5. [

FIG. 24 is a perspective view and a rear view of an embodiment of a rack-mount case type storage system 400 equipped with the M.2 multi-plug 100 of the present invention. The configuration of the rack-mount case includes a front panel 401, A panel 403 and a rear panel 405. The side panel 403 is formed of a slide rail 407 for mounting on 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 also shown in FIG.

In the rack mount case 400 of the present invention, the unit BAY-ROW board 370 for mounting the hard disk drive and / or the M.2 multi-plug may be equipped with fifteen 3.5-inch hard disk drives, (Not shown) has a built-in SFF-8639 standard connector (not shown) to support SATA interface for hard disk drive interface and PCIe x4 interface for M.2 multi-plug 100 interface.

The BAY-ROW board 370 can be configured in such a manner that a separate partition wall (not shown) is formed to fit the external shape of the 3.5-inch hard disk drive and a hard guide outer (HDD GUIDE OUTER) And the ROW-MAGAZINE 371 may be formed inside the partition wall as described above.

In FIG. 24, the BAY-ROW board 370 or the ROW-MAGAZINE 371 is shown as being composed of four ROWs, but it may be 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 lower end of the printed circuit board constituting the BAY-ROW board 370, and serves as a connection path for various cables and a path for air flow.

A series of internal cooling fans 419 for forming a flow of air are provided outside the partition walls on which the rear stage ROW-MAGAZINE 371 is fixed. The fan grilles 411, 415, The cooling fans are disposed on the inner side of the cooling fans 417 and 417, respectively.

A power switch 411 and an LCD 413 for displaying various operating states are disposed at a central upper end portion of the front panel.

A rear bay 423 is located on the upper left / right side of the rear portion, and one bay is added to the 15 bayes constituting each bay-row board 370 to form 16 bayes, which is a multiple of 2.

A power supply module 427 is disposed at the lower left and right sides of the rear bay 423 and a power supply unit 427 for powering the N + 1 redundant PSUs on the printed circuit board (not shown) Circuit constitutes a power source output by a single power source.

A PCIe slot hole 429 for mounting a PC i interface card is arranged at the center of the power module 427 on the left and right sides.

A base board (not shown) is provided at the inner center of the left and right power supply modules corresponding to the PCIe slot hole 429, and the first block diagram of FIG. 22 corresponds to the base structure of the base board Pin signal connection is formed between two PCIe slot connectors (not shown) on a BASE board (not shown) corresponding to two adjacent PCIe slot holes 429 from the left side.

The reason for this is that if all of the storage media mounted on one BAY-ROW board 370 is a hard disk drive, in order to secure the preservation of data even when one or two hard disk drives fail, For this purpose, a RAID card is mounted in one of the two PCIe slots, and a PCIe interface card is mounted in the other PCIe slot.

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

23, a PCIe slot 354 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 are used and each PCiExpress signal branched from the PCI Epxress switch 354 is connected to a lower end of the BAY-ROW board 370 via a separate cable or internal wiring through a port connector (not shown) (Not shown), which is also connected to each SFF-8639 connector (not shown) to which the M.2 multiplexer 100 is connected.

Therefore, the second block diagram of FIG. 23 can be kept available only to the M.2 multiplexer 100 having the control unit 117 internally having the RAID function as the storage medium.

Of course, unlike the M.2 multiplexer 100, an SSD supporting a PCIe x4 interface among a single SSD (not shown) can be mounted using a separate bracket (not shown) The RAID card 8 can not be installed internally in the storage system. Therefore, if a failure occurs in a certain SSD (not shown), the entire data may be lost.

That is, since the storage system 400 does not support RAID5 or RAID6 on its own, the storage medium itself is loaded with a plurality of storage media such as the M.2 multiplexer 100, and if the RAID function is not supported, The storage system 400 according to the second block diagram of FIG. 23, in which the RAID configuration through the mounting of the RAID card is difficult, is meaningless It can be said that there is no.

On the other hand, according to the first block configuration of FIG. 22 and the second block configuration 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 ), And may be displayed as a single volume or a plurality of volumes according to a configuration method through a software RAID configuration internally in the host computer 2, respectively.

Generally, in a software RAID configuration on the host computer 2, RAID 0 and RAID 1 have a simple bit operation for generating RAID configuration data, so that there is little difference in performance compared to a hardware type RAID configuration. However, in the case of a RAID 5 configuration The parity bit operation for generating the recovery bits is relatively inefficient compared with the hardware method.

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

In addition, since the RAID card 8 is removed in addition to the server (not shown) which has been conventionally used for the storage system configuration, the heat generated by the server (not shown) and the RAID (8) BAY-ROW board 370 or ROW-MAGAZINE 371 to replace a high-density / high-capacity storage medium.

In addition, since the server (not shown) and the RAID card 8 having a large amount of power consumption are removed, the power module 427 can be mounted in a smaller size and smaller capacity, There is an additional advantage of shrinking.

Although the M.2 memory card has been described as an example for the sake of simplicity, it is also possible to apply the 2.5-inch or 1.8-inch SASD (SSD), which is widely used in the same configuration as described above, in the same manner.

However, in the configuration based on the 2.5 inch or 1.8 inch SAS disk, the physical size of the external case of the SAS de-multiplexer 100 of the present invention becomes larger than that of the 3.5 inch hard disk drive.

 Although the preferred embodiments of the present invention have been described in detail, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope of the appended claims.

10: Prior art 3.5-inch hard disk drive replacement type PCI EXPRESS memory expansion card block diagram;
11, 111: SFF-8639 connector
13, 15: SATA 7PIN connector
16, 115:
19: PCI EXPRESS switch
17: Clock signal generator
21: FPGA (FIELD PROGRAMMABLE GATE ARRAY)
23: MCU (MICRO-CONTROLLER UNIT)
25: Connector for connection to the first storage media
27: Connector for connecting to 2nd storage media
29: Connector for connecting to 3rd storage media
30: M.2 memory card
31: M.2 Memory card retention groove
33: PEM nut
35: First storage medium
37: Second storage medium
39: Third storage medium
45, 161: a first LED indicator
47, 162: a second LED indicator
49, 168: Third LED display
51: Horizontal type M.2 Memory card connector for perspective view and entrance direction
53: Vertical M.2 View of connector for memory card connection
80: Interface card
81: Fixed bracket
83: PCI EXPRESS Edge Ping Refusal
85:
87:
89: Cache memory unit
91: Connector for internal interface
93: Connector portion for external interface
100: M.2 multiflexer of the present invention
101: printed circuit board
113: USB connector
117:
119: Second vertical connector board connector
121: 1st vertical connection board connector for 110mm
123: First vertical connection board connector for 80mm
First vertical connection board connector for 125: 60 mm
127: second vertical connection board
136: first vertical connection board
141: first storage media connector
142: Second storage media connector
148: Eighth storage media connector
150: M.2 memory card
150-1: 60mm M.2 memory card
150-2: 80mm M.2 memory card
150-3: 110mm M.2 memory card
151: first storage medium (or first M.2 memory card)
152: Second storage medium (or second M.2 memory card)
158: the eighth storage medium (or the eighth M.2 memory card)
159: storage memory element
161: first LED indicator
162: second LED indicator
168: the eighth LED indicator
169: Front vent hole array
170: TOP cover
171: Fixing nut for dongle
173: Inlet cover
174: inlet vent hole
175: Inlet cover fixing protrusion and detachable handle
177: inner hard guide
178: Inner hard guide knob
179: Inner hard guide fixing hole
180: Side support
181: Side support guide fixing hole
182: BOTTOM cover Left primary guide projection
183: Lower cover Second left guide protrusion
184: Lower cover left third guide protrusion
185: Lower cover Right side 1st guide protrusion
186: Operation indicator LED
187: Error LED
189: Inlet fixing groove
190: First vertical connection board bottom connector
191: M.2 Memory card retention groove guide projection
193: M.2 Memory card retention groove
194: Lower cover guide structure
195: Inner lower guide structure
196: protrusion protrusion
197: Hard disk drive bottom fixing hole
198: First vertical connection board fixing groove
199: Lower cover fixing hole
200: BOTTOM cover
201: Top cover (right) 1st guide protrusion
202: Top cover left primary guide projection
203: Upper cover right 2nd guide protrusion
205: Top cover right third guide protrusion
207: Upper cover right 4th guide guide projection
209: Top cover right 5th guide protrusion
211: Top cover right 6th guide protrusion
212: Top cover fixing support
213, 215, 217: first vertical connection board fixing projection
219: first vertical connection board side support projection
280: Whole nut groove
281: Nut groove bottom support
283: nut groove middle support
285: Nut groove upper support
300: DONGLE for PCI EXPRESS
301: Fixing bolt for dongle
303: PCI EXPRESS X4 connector
305: Dongle USB connector
307: SFF-8639 RECEPTACLE connector
309: USB plug connector
311: Through-hole fixing bolt hole
313: Dongle cover fixing bolt
HH-A1, -A2: Hard disk drive front side side fixing hole
HH-B1, -B2: Hard disk drive middle side fixing hole
HH_C1, -C2: Hard disk drive rear side side fixing hole
1: Multi-device bay
2: Host computer part
2-1: Host computer
3-1: PCIe Express (PCIe) slot connector
3-5, 350: PC Eye Express Expansion Card
3-7: Built-in PC EXPRESS HUB card
4, 352, 354: PC Eye Express Switch
5: External PC Eye Express Hub
6: Primary PCIe HUB
6-1: PCIe Switch
7: Second PCIe Hub Card
8, 351: RAID card
9: Device (storage media)
370: BAY-ROW board
371: BAY-MAGAZINE
380-1, 380-2, 380-3, 380-4: 16BAY ROW
400: Rackmount case storage system
401: front panel
403: side panel
405: rear panel
407: slide rail
409: Rail support
411: Left fan grill
412: Front power switch
413: Status display LCD
415: Central fan grill
417: Right fan grill
419: Cooling fan
423: rear bay
425: Rear pan grill
427: Power module
429: PCIe card hole

Claims (43)

A printed circuit board having a PCI EXPRESS or SATA interface connection means; A plurality of storage media in a PCI EXPRESS interface mode or a SATA interface mode; A control unit connected to the PCI EXPRESS or SATA interface connection means; A first vertical connection board disposed in a direction perpendicular to the printed circuit board, the first vertical connection board being composed of at least one or more; A storage media connector having at least one or more storage media disposed on one side of the first vertical connection board to which the storage media is connected; , ≪ / RTI &
An upper cover and a lower cover at upper and lower ends of the printed circuit board, respectively; And a storage media inlet cover,
Wherein the upper cover or the lower cover is provided with a guide structure having a concavo-convex structure that surrounds a part of the printed circuit board exposed on left and right sides of the storage medium, the storage medium being guided by the guide structure, And is connected to the storage media connector disposed on one side of the board. The method according to claim 1,
Wherein the printed circuit board has at least one or more first vertical connection board lower connectors at a lower end of the first vertical connection board,
Wherein the first vertical connection board lower connector connects the first vertical connection board and the control unit in a circuit manner. The method according to claim 1,
A second vertical connection board connector which is connected to the control unit, the second vertical connection board connector being composed of one or two and arranged in the 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 in one or two vertical directions with respect to the printed circuit board;
A first vertical connection board connector disposed on one side of the second vertical connection board and corresponding to a length of the storage medium, the first vertical connection board connector being composed of at least one or more of the first vertical connection board and the second vertical connection board; And a plurality of micro-mirrors. The method according to claim 1,
Wherein the printed circuit board further comprises a USB interface connection unit and is connected to the control unit. The method according to claim 1,
Wherein the storage media connector is vertically disposed with respect to the printed circuit board and the storage medium is vertically coupled to the printed circuit board. Multiplayer. The method according to claim 1,
Wherein the storage medium connector is provided in a direction perpendicular to the printed circuit board and the storage medium is vertically coupled to the printed circuit board. Multiplayer. The method according to claim 6,
Wherein the storage media connectors disposed on the first vertical connection board are horizontally arranged in at least one or more directions to connect the storage media in a multi-layer stacking manner. The method of claim 3,
Wherein the first vertical connection board is coupled to the first vertical connection board connector provided on the second vertical connection board by moving the first vertical connection board in the forward and backward directions corresponding to the length of the storage medium. The method of claim 3,
Wherein the second vertical connection board mounts one first vertical connection board connector at a position corresponding to the length of the storage medium and is provided for each length of the storage medium,
Connecting 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 is coupled to the first vertical connection board connector on the second vertical connection board in a manner corresponding to the length of the storage medium. 3. The method of claim 2,
If the length of the storage media is two, the first vertical connection board is divided into two types having a length corresponding to the number of the storage media,
And connecting the first vertical connection board to the first vertical connection board lower connector at a position corresponding to the length of the storage medium to connect the storage media having different lengths to the respective first vertical connection boards ESD multifullar to feature. The method of claim 3,
If the length of the storage media is two, the first vertical connection board is divided into two types having a length corresponding to the number of the storage media,
And connecting the first vertical connection boards to the second vertical connection boards at positions corresponding to the lengths of the storage media to connect the storage media having different lengths to the respective first vertical connection boards. DS Multiplayer. The method of claim 3,
The printed circuit board has side supports on the left and right sides, and the side supports are provided on the lower side and the outer side with holes corresponding to the fixing holes of the hard disk drive at the same positions as the hard disk drive ESD multifullar to feature. delete delete delete delete delete The method according to claim 1,
Wherein the guide structure of the concavo-convex structure has a V-shaped inlet port for smooth guiding. delete delete delete delete delete The method according to claim 1,
The storage medium inlet cover may include a U-shaped protrusion on the inside of the storage media inlet cover to prevent the storage media entrance from falling out in correspondence with the semicircular fixing hole of the M.2 memory card when the storage medium is an M.2 memory card. And a fixing groove which is formed in the upper surface of the housing. The method according to claim 1,
Wherein the controller supports a RAID function for the storage media coupled to the first vertical connection board so that the storage media are converted into at least one or more logical storage according to the user's designation. Multiplayer. 26. The method of claim 25,
If the storage medium is a PCI EXPRESS interface system, the controller is connected to the PCI EXPRESS interface side in the PCI EXPRESS or SATA interface connection means,
Wherein the controller is connected to the PCI EXPRESS interface or the SATA interface in the PCI EXPRESS or SATA interface connection unit when the storage medium is a SATA interface scheme. The method according to claim 1,
Wherein the controller is configured as a PCI EXPRESS switch and is connected to each of the storage media in a PCI Express x1, x2, or x4 lane configuration,
And the PCI EXPRESS interface connecting means is connected to the PCI EXPRESS interface. delete The method according to claim 5 or 6,
And an LED operative by an operation indicator LED signal output from the storage media connector at an upper end of the printed circuit board adjacent to a longitudinally opposite side of the storage medium at a location coupled to the storage media connector. Demultiplexer. delete The method according to claim 1,
And an LED operative by an error indication LED signal output from the control unit at an upper end of the printed circuit board adjacent to a longitudinally opposite end face of the storage medium at a location coupled to the storage media connector. Pl. The method according to claim 1,
An SFF-8639 connector corresponding to the PCI EXPRESS or the SATA interface connecting means in a pin-to-pin manner, and a USB plug connector corresponding to the USB connector with a pin to pin,
A printed circuit board capable of fixing the SFF-8639 connector and the USB plug connector; a PCI EXPRESS external interface connector in circuit connection with the SFF-8639 connector on one side of the printed circuit board; Further comprising a dongle for an external interface having the USB connector connected to the connector in a circuit manner. delete delete delete 33. The method of claim 32,
Wherein the dongle comprises a dongle top cover, a dongle bottom cover, and a dongle fixing bolt. A PC Eye Express expansion card connected to an external host computer; A PC iExpress switch connected to the PC iExpress expansion card and a PC iE interface signal; A controller having a built-in RAID function, and an ASD multifpler mounted with a plurality of ASD storage media connected thereto; And at least one MS de-multiplexer connected to the PC-I / O interface signal branched to the PC-I / O switch is mounted, and a series of units BAY-ROW; , ≪ / RTI &
Wherein the SAS demultiplexer comprises: a printed circuit board having a PCI EXPRESS or SATA interface connection means; A plurality of storage media in a PCI EXPRESS interface mode or a SATA interface mode; A control unit connected to the PCI EXPRESS or SATA interface connection means; A first vertical connection board disposed in a direction perpendicular to the printed circuit board, the first vertical connection board being composed of at least one or more; A storage media connector having at least one or more storage media disposed on one side of the first vertical connection board to which the storage media is connected; Lt; / RTI >
An upper cover and a lower cover at upper and lower ends of the printed circuit board, respectively; And a storage medium inlet cover, wherein the upper cover or the lower cover includes a guide structure having a concavo-convex structure that surrounds a part of the printed circuit board exposed on left and right sides of the storage medium. 39. The method of claim 37,
Wherein the storage system comprises at least one or more unit storage arrays comprising the PC I / O expansion card, the PC I / O switch, and the BAY-ROW. 39. The method of claim 38,
A first PCIe slot having the PCIe Express expansion card;
A second PCIe slot in which the first PCIe slot and the pin-to-pin wiring are formed;
Any other BAY-ROW consisting solely of M.2 Multiplexers; And
In an arbitrary BAY-ROW configuration consisting solely of a hard disk drive,
The BAY-ROW having the M.2 multifuler is connected to the PC interface signal branched from the PC I /
Wherein the BAY-ROW with the hard disk drive is additionally provided with a RAID card in the second PCIe slot, and the SATA or SAS interface signal input / output from the RAID card is connected. delete A PC Eye Express expansion card connected to an external host computer; A first PC iExpress switch connected to the PC iExpress expansion card via a PC i Eye interface signal; At least one or more BAY-ROWs including a second PC Eye Express switch branched from the first PC Eye Express switch and connected to the PC Eye Express interface signals of a plurality of channels, respectively; An MS demultiplexer branched from a second PC I / O switch on the BAY-ROW and connected to the PC I / F interface signals of a plurality of channels, respectively; Respectively,
Wherein the SAS demultiplexer comprises: a printed circuit board having a PCI EXPRESS or SATA interface connection means; A plurality of storage media in a PCI EXPRESS interface mode or a SATA interface mode; A control unit connected to the PCI EXPRESS or SATA interface connection means; A first vertical connection board disposed in a direction perpendicular to the printed circuit board, the first vertical connection board being composed of at least one or more; A storage media connector having at least one or more storage media disposed on one side of the first vertical connection board to which the storage media is connected; Lt; / RTI >
An upper cover and a lower cover at upper and lower ends of the printed circuit board, respectively; And a storage medium inlet cover, wherein the upper cover or the lower cover includes a guide structure having a concavo-convex structure that surrounds a part of the printed circuit board exposed on left and right sides of the storage medium. 42. The method of claim 41,
Wherein the SAS de-multiplexer includes the controller having the RAID function and a plurality of the storage media connected thereto. delete

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