TWI598609B - Server Management Control System - Google Patents

Description

Server management control system

The present invention relates to a server management system, and more particularly to a server management control system for testing operations.

Generally, in the Burn-in and Run-in Test process, a large number of servers to be tested are automatically sent into the test area in one direction, and each servo is manually and one by one. Connected to the power supply and connected to the test signal line, and the server is connected to the central test server, and the central test server issues a test command to the server, and the server executes the test command and Conduct a test operation to verify the performance of the software and hardware of the server. However, manually connecting the server to the power supply and the test signal line is very time consuming and labor intensive. Furthermore, it usually takes a long time to perform the burn-in test, and since the server is sent to the test area in one batch, it is necessary to wait for all the servers to be tested before sending the test area in batches, although the central test server The test status of the server can be monitored, but if a server with a test error or verification failure is found or the wiring error cannot be tested due to human error, the manager cannot remove the server from which the test failed. Test space and instant processing, still need to wait for other servers to complete the test, not cost-effective and time-consuming, and need to explore improvements.

Accordingly, it is an object of the present invention to provide a server management control system that effectively improves test efficiency.

Thus, the server management control system of the present invention is applied to a working system. The working system includes a working platform, a first conveying unit disposed on the working platform, two test racks disposed on the working platform and located on opposite sides of the first conveying unit, and two sets the test rack The second transport unit on. Each test rack includes multiple test spaces. Each of the second conveying units includes a plurality of second transmission modules disposed on the corresponding test racks and located in the test space.

The server management control system includes a plurality of server devices, a plurality of carrier devices for transporting the server device, and a reading device disposed on the working platform for reading the identification unit of the server device a device, a plurality of power supply devices disposed on the test frame and respectively located in the test space, a plurality of detection devices disposed on the test frame and respectively located in the test space, and a A central server control device that controls the operation of the operating system and manages the server device.

Each server device includes a server unit and an identification unit disposed on the server unit. Each of the loading devices is movably disposed on the first conveying unit, and includes a mechanism for receiving the server unit and being movably disposed at the first transmission a carrier board on the sending unit, a first connecting unit disposed on the carrying board for electrically connecting the server unit, and two disposed on opposite sides of the carrying board and adjacent to each other a second connecting unit extending in the direction of the test rack, and a conductive unit disposed in the passenger board and electrically connecting the first connecting unit and the second connecting unit. Each of the carrier plates is movably disposed on the first conveying unit and is movable by the first conveying unit to move to any of the second transmission units of the second conveying unit, and is correspondingly second The drive module is driven to move into the corresponding test space.

Each power supply device is located in the corresponding test space and can be combined with any second connection unit of each of the passenger devices to form an electrical connection. Each detecting device is configured to detect a riding device in the corresponding test space.

The central server control device includes a control unit for controlling movement of the first transmission unit and the second transmission module of the second delivery unit, and a processing unit electrically coupled to the control unit.

The processing unit is communicably coupled to the detecting device and the reading device, and the server devices are respectively placed on the carrier board and sequentially placed on the first conveying unit of the working system. . When each of the carrier boards moves closer to the reading device, the reading device reads the data of the identification unit of each server device and transmits the data read by the identification unit to the processing unit, and the The processing unit generates a distribution mode according to the data of each identification unit and the data of the detecting device, and transmits the distribution mode to the control unit, where the delivery mode has a test space corresponding to each server unit. The The control unit executes the distribution mode and sequentially controls the first conveying unit to drive each of the carrier plates to move to the second transmission module of the corresponding second conveying unit, and controls the corresponding second transmission module to correspond to the test. The direction of the space moves to move each of the carrier plates to the corresponding test space, and one of the second connection units of each of the carrier devices is combined with the corresponding power supply device, so that each of the first connection units can supply power to Corresponding to the server unit, at this time, the processing unit is communicably coupled to the first connection unit of each of the carrier devices, and the processing unit transmits a test command via the first connection unit to the corresponding server unit, thereby Each server unit can execute the test command in a corresponding test space.

The effect of the present invention is that the control unit performs the delivery mode and sequentially controls the first transport unit to drive each of the carrier plates to move to the second transmission module of the corresponding second transport unit, and control the corresponding The second transmission module moves in the direction of the corresponding test space and combines one of the second connection units of each of the carrier devices with the corresponding power supply device, and can automatically distribute each carrier board and achieve Each server device is independently fed into or out of the corresponding test space. Furthermore, each of the power supply devices can be combined with any second connection unit of each of the carrier devices to form a modular design of the electrical connection, so that the first connection unit can supply power to the corresponding server unit and each The server unit can execute the test instruction in the corresponding test space, and does not require complicated complicated wiring work, thereby saving time and improving test efficiency.

10‧‧‧Working system

11‧‧‧Working platform

12‧‧‧First conveyor unit

121‧‧‧Input section

122‧‧‧Executive paragraph

123‧‧‧Output segment

124‧‧‧First conveyor module

125‧‧‧Second transport module

13‧‧‧Test stand

131‧‧‧Test space

14‧‧‧Second transport unit

141‧‧‧Second drive module

142‧‧‧Rotator

15‧‧‧stop unit

151‧‧‧stops

20‧‧‧Server Management Control System

2‧‧‧Server device

21‧‧‧Server unit

211‧‧‧Power supply connection

212‧‧‧ Signal serial connection

22‧‧‧ Identification unit

3‧‧‧Carriage device

31‧‧‧Travel board

32‧‧‧First connection unit

321‧‧‧First connection

322‧‧‧Second connection

323‧‧‧Wireless signal receiver

33‧‧‧Second connection unit

34‧‧‧Conducting unit

341‧‧‧Power connectors

342‧‧‧Signal connector

4‧‧‧Reading device

5‧‧‧Power supply unit

51‧‧‧ combination unit

52‧‧‧Power transmission unit

53‧‧‧Signal transmission unit

6‧‧‧Detection device

7‧‧‧Central server control unit

71‧‧‧Control unit

72‧‧‧Processing unit

8‧‧‧Wireless transmission

Other features and effects of the present invention will be apparent from the following description of the drawings, wherein: FIG. 1 is a block diagram illustrating a first embodiment of the server management control system of the present invention applied to a working system. FIG. 2 is a schematic top view, and FIG. 3 is an enlarged schematic view showing a combination of a server device and a carrier device in the first embodiment; FIG. 4 is a front view showing In the first embodiment, the server device and the carrier device cooperate with the transmission relationship of the working system; FIG. 5 is a front view, which is an explanatory view of FIG. 4; FIG. 6 is a front view showing the first embodiment. The server device and the carrier device cooperate with the transmission relationship of the working system; and FIG. 7 is a block diagram showing the second embodiment of the server management control system of the present invention applied to the working system.

Referring to Figures 1, 2 and 3, a first embodiment of the server management control system 20 of the present invention is applied to a working system 10. The working system 10 includes a working platform 11 , a first conveying unit 12 disposed on the working platform 11 , and two test racks 13 disposed on the working platform 11 and located on opposite sides of the first conveying unit 12 . And the second conveying unit 14 on the test frame 13 is disposed. Each test rack 13 includes a plurality of test spaces 131. The first transport unit 12 includes an input section 121 , an execution section 122 , an output section 123 , a plurality of first transport modules 124 , and a plurality of second transport modules 125 . The first transport module 124 is controlled to rotate from the input segment 121 to the output segment 123, and the second transport module 125 is controllably movable to the direction of any of the second transport units 14. The test spaces 131 of the test rack 13 are respectively located on opposite sides of the execution section 122 of the first transport unit 12. Each of the second transmission units 14 includes a plurality of second transmission modules 141 disposed on the corresponding test racks 13 and located in the test space 131 . Each of the second transmission modules 141 has a plurality of rotators 142 .

Each of the loading plates 31 is sequentially disposed on the input section 121 of the first conveying unit 12, and the first conveying module 124 drives each of the loading plates 31 to the execution section via the reading device 4. 122 moves, before each of the loading plates 31 moves to the corresponding test space 131, the control unit 71 sequentially controls the second conveying module 125 of the first conveying unit 12 to drive each of the loading plates 31 to move to Corresponding to the second transmission module 141 of the second conveying unit 14 and controlling the corresponding second transmission module 141 to rotate in the direction of the corresponding test space 131 to move each of the loading plates 31 to the corresponding test space 131 And one of the second connecting units 33 of each of the carrying devices 3 is combined with the corresponding power supply device 5.

The server management control system 20 includes a plurality of server devices 2, a plurality of carrier devices 3 for transporting the server device 2, and a working platform 11 a reading device 4 for reading the identification unit 22 of the server device 2, a plurality of power supply devices 5 disposed on the test frame 13 and respectively located in the test space 131, and a plurality of The detecting device 6 on the test rack 13 and located in the test space 131, and a central server control device 7 for controlling the working system 10 to operate and manage the server device 2.

Each server device 2 includes a server unit 21 and an identification unit 22 disposed on the server unit 21. Each server unit 21 has a power supply serial port 211 and a signal serial port 212.

Each of the loading devices 3 is movably disposed on the first conveying unit 12, and includes a loading plate 31 for receiving the server unit 21 and movably disposed on the first conveying unit 12, a first connecting unit 32 disposed on the carrier board 31 for electrically connecting the server unit 21, and two disposed on opposite sides of the carrying board 31 and respectively adjacent to the test rack 13 A second connecting unit 33 extending in a direction, and a conductive unit 34 disposed in the carrier board 31 and electrically connecting the first connecting unit 32 and the second connecting unit 33.

Each of the carrier plates 31 is movably disposed on the first conveying unit 12 and can be driven by the first conveying unit 12 to move to any of the second transmission modules 141 of the second conveying unit 14 and The corresponding second transmission module 141 is driven to move into the corresponding test space 131. Each of the first connecting units 32 has a first connecting portion 321 which can be combined with the power supply serial port 211 of any one of the server units 21, and one of which can be used for any The signal of the server unit 21 is connected in series with the second connection portion 322 of the combination 212. The conductive unit 34 of each of the loading devices 3 has a power connector 341 connecting the first connecting portion 321 and the second connecting unit 33, and a connecting the second connecting portion 322 and the second connecting unit 33. Signal connector 342.

Each power supply device 5 is located in the corresponding test space 131 and can be electrically connected with any of the second connection units 33 of each of the carrier devices 3, and includes a combination unit 51 coupled to the second connection unit 33, A power transmission unit 52 disposed on the combining unit 51, and a signal transmission unit 53 disposed on the combining unit 51 and communicatively coupled to the processing unit 72 of the central server control device 7. Each detecting device 6 is configured to detect the loading device 3 in the corresponding test space 131. In this embodiment, each detecting device 6 is in the form of a light-shielding sensor, and each detecting device 6 detects the carrier board of the carrying device 3 in the corresponding test space 131, but Without limitation, each detecting device 6 can detect whether each server device 2 and the corresponding carrier device 3 are in each test space.

The central server control device 7 includes a control unit 71 and a processing unit 72 electrically coupled to the control unit 71. The control unit 71 is configured to control the rotation of the first transport module 124, the second transport module 125, and the second transport module 141 of the second transport unit 14 of the first transport unit 12. The processing unit 72 can be communicatively coupled to the detecting device 6 and the reading device 4.

Referring to FIG. 1 , FIG. 2 and FIG. 4 , in use, the power supply serial port 211 of each server unit 21 and the signal serial port 212 are respectively coupled to the first connection portion of each of the carrier devices 3 . 321 and the second connecting portion 322, so that each server device 2 is combined with the corresponding carrying device 3. Then, each of the carrier boards 31 is sequentially placed on the input section 121 of the first transport unit 12 of the working system 10, and the first transport module 124 sequentially drives each of the passenger boards 31 to the read section. Moving in the direction of the device 4, when each of the carrier plates 31 moves closer to the reading device 4, the reading device 4 reads the data of the identification unit 22 of each server device 2 and will read the The data of the identification unit 22 is transmitted to the processing unit 72, and the processing unit 72 generates a delivery mode according to the data of each of the identification units 22 and transmits the data to the control unit 71. In this embodiment, the delivery mode has a test space 131 corresponding to each server unit 21. In detail, the processing unit 72 is communicatively coupled to the detection device 6 to learn that the server device is available. 2, the position of the test space 131 is moved in, and the order of the server device 2 is known in cooperation with the reading device 4, and the processing unit 72 schedules the delivery mode to be transmitted to the control unit 71. Subsequent delivery operations.

Then, the control unit 71 executes the delivery mode and sequentially controls the first conveying module 124 of the first conveying unit 12 to drive each of the loading plates 31 to move to the execution segment 122, and when each carrier plate The control unit 71 sequentially controls the second transport module 125 of the first transport unit 12 to drive each of the passenger carriers 31 to the corresponding second transport unit 14 before moving to the corresponding test space 131. Move in direction Move to the corresponding second transmission module 141. Referring to FIG. 1 , FIG. 2 and FIG. 5 , the control unit 71 controls the rotator 142 of the corresponding second transmission module 141 to move in the direction of the corresponding test space 131 to move each of the loading plates 31 . Into the corresponding test space 131, one of the second connection units 33 of each of the carrier devices 3 is combined with the corresponding power supply device 5. In this embodiment, the first transport module 124, the second transport module 125, and the rotator 142 are in the form of a rotating wheel, and can move each of the loading plates 31, but not Limited.

Referring to FIG. 1 , FIG. 2 and FIG. 4 , it is to be noted that the working system 10 further includes a stopping unit 15 disposed on the working platform 11 and controlled by the control unit 71 of the central server control device 7 . . The stop unit 15 includes a plurality of stops 151 that are controllable to pass through the execution section 122 of the first transport unit 12 and to block movement of the passenger board 31. In this embodiment, each server device 2 is sequentially moved into the execution segment 122, and the control unit 71 executes the delivery mode to sequentially control the first delivery module 124 to drive each multiplication. The movement of the carrier 31 moves the corresponding server device 2 to the test space 131 that needs to be entered. At this time, the control unit 71 controls the stopper 151 to pass through the first conveying unit 12 and respectively block the current entry. The carrier board 31 of the test space 131 is moved forward to the carrier board 31 of the corresponding test space 131. Then, the control unit 71 controls the second transport module 125 of the first transport unit 12 to rotate to the corresponding second transport unit 14, and drives the carrier board 31 to enter the corresponding test space 131 to move to Corresponding to the second transmission module 141 of the second conveying unit 14. Then, the corresponding second transmission module 141 is rotated in the direction of the corresponding test space 131 to move the carrier board 31 to the corresponding test space 131, and one of the second connection units of the carrier device 3 is moved. 33 is combined with the combining unit 51 of the corresponding power supply unit 5. Then, the control unit 71 controls the corresponding second transport module 125 and the corresponding second transmission mold that have been rotated to stop rotating, and retracts the stopper 151 to make the first transport The module 124 rotates to move the carrier board 31 to be moved to the corresponding test space 131 forward.

Then, when the combining unit 51 of each power supply device 5 is combined with the corresponding second connecting unit 33 to form an electrical connection, the processing unit 72 transmits a signal connection of the test command from the signal transmitting unit 53 to the corresponding conductive unit 34. The 342 is connected to the corresponding server unit 21 via the second connecting portion 322 of the first connecting unit 32 and the corresponding signal, so that each server unit 21 can execute the corresponding test space 131. Test instructions. By integrating the modular unit 51 of each power supply unit 5 and the second connection unit 33 of each of the loading units 3, the corresponding server unit 21 can be powered up and coupled with each other. The processing unit 72 of the central server control device 7 achieves a network communication connection and executes the test command, eliminating the need for manual complicated wiring operations, simplifying the operation process and saving manpower. In this embodiment, the processing unit 72 transmits the test command through the network communication link to the baseboard management controller (Baseboard) of the corresponding server unit 21 via the corresponding signal serial port 212. The Management Controller (BMC) (not shown) performs subsequent test operations. In this embodiment, the processing unit 72 performs communication connection in a wireless or wired network manner, and the drawings are not labeled and distinguished.

Referring to FIG. 1, FIG. 2 and FIG. 6, then, each server unit 21 is executed when each server unit 21 performs the completion of the test command or when each server unit 21 performs the test command is not completed and an error occurs. A message is sent and transmitted from the corresponding signal string 212 to the signal transmitting unit 53 via the corresponding second connecting unit 322 to the processing unit 72 of the central server control unit 7. The processing unit 72 generates a corresponding output mode and passes to the control unit 71. The output mode has a test space 131 corresponding to the server unit 21 that is required to be removed. The control unit 71 executes the output mode and controls the second transmission module 141 of the corresponding second transport unit 14 to drive the corresponding carrier board 31. Moving in the direction of the first conveying unit 12, the coupling unit 51 of the power supply device 5 is separated from the corresponding second connecting unit 33, and the carrier plate 31 is moved to the first conveying unit 12, and then The first transport module 124 drives the carrier board 31 to move in the direction of the output section 123, thereby moving the carrier device 3 and the corresponding server device 2 out of the working platform 11. At this time, the administrator can combine the subsequent server device 2 to be tested with the corresponding carrier device 3, and place it on the input segment 121 of the first transport unit 12, and then according to the above-mentioned distribution process method. The automatic complement is sent to the corresponding test space 131, and the flow and details of the distribution have been described in detail, and will not be further described herein.

In other words, when each server unit 21 performs the completion of the test command to indicate that the test job has ended or when each server unit 21 executes the test command is not completed and an error indicates that the test job has been interrupted, the two cases Each server unit 21 corresponding to the next sends the removal message to the processing unit 72, and lets the processing unit 72 know the server device 2 that needs to be removed and the processing unit 72 cooperates with the data of the delivery mode. The position of the test space 131 of the server device 2 that needs to be removed. Then, the processing unit 72 further generates a corresponding output mode and transmits the corresponding output mode to the control unit 71. The control unit 71 executes the output mode and controls the corresponding second conveying unit 14 and the first conveying unit 12 to further the loading. The device 3 and the corresponding server device 2 are moved out of the work platform 11. To be simple, the server device 2 generates a corresponding output mode and the control unit 71 outputs the output mode through the processing unit 72 if there is a test completion or a test failure results in the end of the test interruption. By controlling the operation of the second transport unit 14 and the first transport unit 12, the server device 2 that needs to be removed can be removed from the work platform 11, and the server device 2 to be tested is immediately added. Save time and increase test efficiency.

The control unit 71 executes the delivery mode and sequentially controls the first transport unit 12 to drive each of the carrier plates 31 to move to the second transmission module 141 of the corresponding second transport unit 14, and control the corresponding The two transmission modules 141 are moved in the direction of the corresponding test space 131 and one of the second connection units 33 of each of the carriers 3 In combination with the corresponding power supply unit 5, each of the carrier boards 31 can be automatically distributed, and it is achieved that each of the server units 2 can be independently moved out of the corresponding test space 131.

Furthermore, the combining unit 51 of each power supply unit 5 can be combined with any second connecting unit 33 of each of the carrying devices 3 to form a modular design of electrical connection, so that the first connecting unit 32 can supply power to Corresponding server unit 21 and each server unit 21 can execute the test command in the corresponding test space 131, without manual complicated wiring work and avoiding human error, saving time and improving test efficiency.

It should be particularly noted that the server management control system 20 further includes a plurality of wireless transmission devices 8 respectively disposed on the server device 2, and each wireless transmission device 8 is configured to store a test of the corresponding server unit 21. The data is passed to the processing unit 72 of the central server control unit 7. The data of the test instruction executed by each server unit 21 is stored in the corresponding wireless transmission device 8, so that the administrator can manage and analyze the data later, and each wireless transmission device 8 can communicate with the processing unit 72, so that The processing unit 72 can effectively control the test situation and the result of each server device 2, and of course, the designation of the removal message sent by each server unit 21 can be transmitted to the processing unit through the corresponding wireless transmission device 8 according to actual requirements. 72 and subsequent removal operations. In this embodiment, the wireless transmission device 8 is a USB access device, but is not limited thereto.

Referring to FIG. 2 and FIG. 7, the second embodiment of the server management control system 20 of the present invention is substantially the same as the first embodiment, and the difference lies in: each servo The server unit 21 of the device 2 has a power supply serial port 211 and a signal serial port 212. The first connection unit 32 of each of the carrier devices 3 has a power supply connection for any of the server units 21. The first connection portion 321 combined with the 211, and a wireless signal receiver 323 connectable to the signal serial port 212 of any of the server units 21 and communicably coupled to the processing unit 72 of the central server control device 7 . The conductive unit 34 of each of the carrying devices 3 has a power connecting member 341 connecting the first connecting portion 321 and the second connecting unit 33. Each power supply device 5 includes a second connecting unit 33 combined with any of the second connecting units 33. The combining unit 51 and a power transmission unit 52 disposed on the combining unit 51.

When the combining unit 51 of each power supply unit 5 is combined with the corresponding second connecting unit 33 to form an electrical connection, the processing unit 72 transmits the test command to the corresponding server via the wireless signal receiver 323 of the first connecting unit 32. The unit 21, in turn, causes each server unit 21 to execute the test command in the corresponding test space 131. Specifically, the wireless signal receiver 323 of the first connecting unit 32 of each of the carrying devices 3 is coupled to the signal serial port 212 of the corresponding server unit 21 and communicably coupled to the processing unit 72. The design, without the need to additionally configure the physical signal transmission mechanism, can receive the test command issued by the processing unit 72 through each wireless signal receiver 323, and cause the corresponding server unit 21 to execute the test command without additional configuration entity. The signal transmission mechanism effectively simplifies the physical installation operation of the server management control system 20. Of course, each server unit 21 performs the completion of the test command or when each servo When the test unit 21 performs the test command and the error occurs, the corresponding wireless signal receiver 323 can transmit the corresponding removal message to the processing unit 72. In this embodiment, each of the wireless signal receivers 323 is a wireless network receiving accessor, and is connected to the processing unit 72 by a Wi-Fi signal, but is not limited thereto. The first connection unit 32 of each of the passenger devices 3 can also be designed with a power line communication function (HomePlug AV device) according to the actual use requirements, thereby simplifying the hardware configuration operation.

In summary, the server management control system 20 of the present invention controls the first transport unit 12 to move each of the carrier plates 31 to the corresponding second transmission module 141 by the control unit 71, thereby enabling automatic distribution. Each of the carrier boards 31 is completed, and each server device 2 can be independently fed into or out of the corresponding test space 131. Furthermore, each power supply device 5 can be combined with any second connection unit 33 of each of the carrier devices 3 to form a modular design of electrical connection, and can be supplied to each server unit 21 and correspondingly tested. The test instruction is executed in the space 131, and the complicated complicated wiring operation is not required, thereby effectively saving time and improving test efficiency.

However, the above is only the embodiment of the present invention, and the scope of the invention is not limited thereto, and all the equivalent equivalent changes and modifications according to the scope of the patent application and the patent specification of the present invention are still The scope of the invention is covered.

10‧‧‧Working system

11‧‧‧Working platform

12‧‧‧First conveyor unit

124‧‧‧First conveyor module

125‧‧‧Second transport module

14‧‧‧Second transport unit

141‧‧‧Second drive module

20‧‧‧Server Management Control System

2‧‧‧Server device

21‧‧‧Server unit

211‧‧‧Power supply connection

212‧‧‧ Signal serial connection

22‧‧‧ Identification unit

3‧‧‧Carriage device

31‧‧‧Travel board

32‧‧‧First connection unit

321‧‧‧First connection

322‧‧‧Second connection

33‧‧‧Second connection unit

34‧‧‧Conducting unit

341‧‧‧Power connectors

342‧‧‧Signal connector

4‧‧‧Reading device

5‧‧‧Power supply unit

51‧‧‧ combination unit

52‧‧‧Power transmission unit

53‧‧‧Signal transmission unit

6‧‧‧Detection device

7‧‧‧Central server control unit

71‧‧‧Control unit

72‧‧‧Processing unit

8‧‧‧Wireless transmission

Claims (8)

A server management control system is applied to a working system, the working system comprises a working platform, a first conveying unit disposed on the working platform, two disposed on the working platform and located at the first conveying unit a test rack on the opposite side, and a second transport unit on the test rack, each test rack includes a plurality of test spaces, and each of the second transport units includes a plurality of test racks disposed on the corresponding test racks a second transmission module in the test space, the server management control system comprising: a plurality of server devices, each server device comprising a server unit, and an identification unit disposed on the server unit; a carrier device for transporting the server device, each of the carrier devices being movably disposed on the first transport unit, and including a device for receiving the server unit and movably disposed at the first a carrier board on the transport unit, a first connecting unit disposed on the board and configured to electrically connect the server unit, and two disposed on opposite sides of the carrier board a second connecting unit extending in the direction of the adjacent test rack, and a conductive unit disposed in the carrying board and electrically connecting the first connecting unit and the second connecting unit, each of the carrying boards Movably disposed on the first conveying unit and movable by the first conveying unit to move to any of the second transmission modules of the second conveying unit, and driven by the corresponding second transmission module Moving to the corresponding test space; a reading device disposed on the working platform and configured to read the identification unit of the server device; a plurality of being disposed on the test frame and respectively located in the test space a power supply device, each power supply device is located in a corresponding test space and can be combined with any second connection unit of each of the carrier devices to form an electrical connection; a plurality of the power supply devices are disposed on the test frame and are respectively located in the test space a detecting device for detecting a carrier device in a corresponding test space; and a central server control device for controlling operation and management of the server device a control unit for controlling movement of the second transmission module of the first transport unit and the second transport unit, and a processing unit electrically coupled to the control unit, the processing unit and the detecting device And the reading device is communicatively coupled, the server device is respectively coupled to the carrier board and sequentially moved on the first conveying unit of the working system, when each carrier board moves close to the When the device is read, the reading device reads the data of the identification unit of each server device and transmits the data read by the identification unit to the processing unit, and the processing unit according to the information of each identification unit Generating a delivery mode to the control unit in conjunction with the data of the detecting device, the delivery mode having a test space corresponding to each server unit, the control unit executing the delivery mode and sequentially controlling the first delivery The unit drives each of the carrier plates to move to the second transmission module of the corresponding second conveying unit, and controls the corresponding second transmission module to move in the direction of the corresponding test space and each carrier Moving the board to the corresponding test space, and combining one of the second connecting units of each of the carrying devices with the corresponding power supply device, so that each of the first connecting units can supply power to the corresponding server unit, at this time, The processing unit is communicably coupled to the first connection unit of each of the carrier devices, and the processing unit transmits a test command to the corresponding server unit via the first connection unit, so that each server unit can be tested correspondingly Execute the test instruction in space. The server management control system of claim 1, wherein the server unit of each server device has a power supply serial port and a signal serial port, and the first connection unit of each of the carrier devices has a a first connecting portion that can be connected to the power supply string of any one of the server units, and a second connecting portion that can be combined with the signal serial port of any one of the server units, and the conductive unit of each of the carrying devices has a a power connector connecting the first connecting portion and the second connecting unit, and a signal connecting member connecting the second connecting portion and the second connecting unit, each power supply device including a second connecting unit a combined combination unit, a power transmission unit disposed on the combination unit, and a signal transmission unit disposed on the combination unit and coupled to the processing unit of the central server control device, when the combination unit of each power supply unit Correspondingly, the second connecting unit is combined to form an electrical connection, and the processing unit transmits the test command from the signal transmitting unit to the signal connecting component of the corresponding conductive unit and passes through the first connection list The second connection portion of the element is connected to the corresponding server unit in series with the corresponding signal, so that each server unit can execute the test instruction in the corresponding test space. The server management control system of claim 1, wherein the server unit of each server device has a power supply serial port and a signal serial port, and the first connection unit of each of the carrier devices has a a first connection portion that can be connected to the power supply of any one of the server units, and a signal connection port connectable to any of the server units and communicatively coupled to the processing unit of the central server control unit The wireless signal receiver has a power connection unit connecting the first connection portion and the second connection unit, and each power supply device includes a combination with any second connection unit. a unit, and a power transmission unit disposed on the combining unit, when the combining unit of each power supply unit is combined with the corresponding second connecting unit to form an electrical connection, the processing unit can transmit the test command via the first connecting unit The wireless signal receiver is connected to the corresponding server unit, so that each server unit can execute the test command in the corresponding test space. The server management control system according to claim 2 or 3, wherein, when each server unit executes the test instruction, and sends a message to the processing unit of the central server control device, the processing unit Generating a corresponding output mode and transmitting to the control unit, the output mode having a test space corresponding to the server unit to be removed, the control unit executing the output mode and controlling the second transmission mode of the corresponding second conveying unit The group drives the corresponding carrier plate to move in the direction of the first conveying unit to separate the power supply device from the corresponding second connecting unit, and moves the carrier plate to the first conveying unit to further the carrying device Corresponding server device moves out of the working platform; when each server unit executes the test command is not completed and an error occurs, the removal message is sent to the processing unit of the central server control device, and the processing unit generates the output And transmitting to the control unit, the control unit executing the output mode and controlling the second transmission module of the corresponding second conveying unit Moving the corresponding carrier plate to move in the direction of the first conveying unit and separating the power supply device from the corresponding second connecting unit, and moving the carrier plate to the first conveying unit to further correspond to the carrying device The server device moves out of the working platform. The server management control system of claim 2 or 3, further comprising a plurality of wireless transmission devices respectively disposed on the server device, each wireless transmission device configured to store test data of the corresponding server unit and Transfer to the processing unit of the central server control unit. The server management control system of claim 4, wherein the first transport unit comprises an input segment, an execution segment, an output segment, a plurality of first delivery modules, and a plurality of second delivery modules. The first transport module is controlled to rotate from the input segment to the output segment, and the second transport module is controllably movable to the direction of any second transport unit, the test rack is tested The space is respectively located on opposite sides of the execution section of the first conveying unit, and the second transmission modules of each second conveying unit respectively have a plurality of rotators for driving the movement of each of the carrier plates, each of which is multiplied The carrier board is sequentially placed on the input section of the first conveying unit, and the first conveying module drives each of the loading boards to move through the reading section to the execution section, when each carrier board moves Before the corresponding test space, the control unit sequentially controls the second transport module of the first transport unit to drive each of the transport plates to move to the second drive module of the corresponding second transport unit, and control Corresponding to the rotator of the second transmission module Each of the carrier plates is moved to the corresponding test space by the rotation of the corresponding test space, and one of the second connection units of each of the carrier devices is combined with the corresponding power supply device. The server management control system according to claim 6, wherein the processing unit generates a corresponding one when each of the server units performs the completion of the test instruction and each of the server units executes the test instruction is not completed and an error occurs. The output mode is transmitted to the control unit, and the control unit executes the output mode and controls the second transmission module of the second conveying unit to drive the corresponding carrier board to move toward the first conveying unit and the power supply device Separating from the corresponding second connecting unit, and moving the carrier board to the execution section of the first conveying unit, the control unit simultaneously controlling the rotation of the first conveying module of the first conveying unit to drive the corresponding The carrier board is moved from the execution segment to the output segment to move the carrier device and the corresponding server device out of the working platform. The server management control system of claim 6, the working system further comprising a stop unit disposed on the work platform and controlled by a control unit of the central server control device, the stop unit comprising a plurality of Controlly, a stop for the first transport unit and a stop for blocking the movement of the carrier plate can be passed.