TWI505097B - Server - Google Patents

Description

Server system

The present invention relates to a server system, and more particularly to a server system that can continuously store information by managing power supply when power is off.

With the rapid advancement of technology, the development of the Internet has made various electronic devices full of people's lives, and the devices needed to construct the network are servers. In general, existing servers need to back up data, but when When the server is powered off, it is necessary to prepare the data by the preliminary power. However, since the storage data of the server is huge, if there is no good power management system, it is easy to cause insufficient supply of the supply. The problem that the data cannot be reliably reserved during the power outage, therefore, the existing technology still has room for improvement.

In view of the poor power management performance of existing server systems, there is generally a problem that data backup cannot be performed reliably. Accordingly, the present invention provides a server system that mainly charges a power storage unit when the server system is powered on, and when the server system is powered off, the power storage unit starts and re-powers, thereby solving the problems of the prior art.

Based on the above purpose, the main technical means adopted by the present invention provides a The server system comprises a storage control module, a power supply unit, a power storage unit and a power switching unit. The storage control module is electrically connected to a storage device for controlling the storage device. The storage control module includes a cache storage unit for storing data and control information of the storage device and the storage control module. The power supply unit outputs a first power source, and the power storage unit is electrically connected to the power supply unit, receives the first power source, and outputs a second power source. The power switching unit is electrically connected to the power supply unit, the power storage unit and the storage control module, receives the first power source and the second power source, and outputs a third power source, and the third power source supplies power to the storage control module, and the power switching unit is isolated first. Direct conduction of the power supply to the second power source to prevent leakage current.

Wherein, when the server system is powered on, the first power source charges the power storage unit, and the power switching unit receives the first power source to output the third power source. When the server system is shut down, the power storage unit starts and outputs the second power source, and the power source switches. The unit receives the second power source to output the third power source, and the storage control module controls the cache unit to store the data and control information of the storage device and the storage control module, and after the server system is powered on again, the storage control module is The information stored in the cache unit continues to work.

In a preferred embodiment of the above-mentioned server system, the server system further includes a connector, and the power storage unit is electrically connected to the connector, and is electrically connected to the power supply unit and the power switching unit through the connector. The power storage unit can be plugged and unplugged through the connector, and the power storage unit is a Megacell module. In addition, the power storage unit includes a battery management module, An input power management module, an output power management module, and a battery pack, the battery management module manages charging and discharging of the power storage unit, and the input power management module is configured to charge the first power source of the power storage unit The power is managed to prevent overcharging, and the output power management module is used to control the battery management module to turn on and off the output second power source, and the battery pack is used to store the power.

In a preferred embodiment of the above-mentioned server system, when the server system is powered on, the battery management module controls the charging of the battery pack by the first power source according to the power of the battery pack, and the battery pack is charged. The temperature is monitored. When the server system is shut down, the battery management module controls the output power management module to output the second power according to a power storage unit startup signal, and the power storage unit startup signal is invalid when the server system is powered on. Status, in the active state when the server system is shut down. In addition, the server system further includes a substrate management controller electrically connected to the power storage unit, wherein the battery management module detects the temperature of the battery pack to obtain a temperature information, and transmits the temperature information through a communication. The signal is sent to the substrate management controller, and the substrate management controller manages the battery management module through the communication signal. In addition, when the power storage unit is inserted through the connector, the power storage unit sends an effective power storage unit insertion signal to the base management controller to facilitate the substrate management controller to monitor the state of the power storage unit.

After the main technical means of the server system used in the present invention, the power storage unit is charged when the server system is powered on, and the power storage unit is powered on and then powered when the server system is powered off. The system can still back up data efficiently when the system is powered off and powered off.

In addition, since the power storage unit is a very large battery unit by the auxiliary technical means of the server system used in the present invention, even if a huge amount of data needs to be backed up during power failure, the stored power can be effectively The supply can effectively back up the above information.

The specific embodiments of the present invention will be further described by the following examples and drawings.

1‧‧‧Server system

11‧‧‧Storage Control Module

111‧‧‧cache unit

12‧‧‧Power supply unit

13‧‧‧Power storage unit

131‧‧‧Battery Management Module

132‧‧‧Input power management module

133‧‧‧Output power management module

134‧‧‧Battery Pack

14‧‧‧Power switching unit

15‧‧‧Connector

16‧‧‧Base Management Controller

2‧‧‧Storage equipment

S1‧‧‧first power supply

S2‧‧‧second power supply

S3‧‧‧ third power supply

S4‧‧‧ Effective power storage unit insertion signal

S5‧‧‧ communication signal

S6‧‧‧Power storage unit start signal

1 is a block diagram showing a server system in accordance with a preferred embodiment of the present invention; and a second diagram showing a circuit diagram of a power storage unit and a power switching unit in accordance with a preferred embodiment of the present invention.

Since the server system provided by the present invention has a combination of implementations, it will not be repeated here, and only a preferred embodiment will be specifically described.

Referring to the first and second figures, the first figure shows a block diagram of a server system according to a preferred embodiment of the present invention, and the second figure shows a power storage unit and a power switching unit according to a preferred embodiment of the present invention. Schematic diagram of the circuit. As shown in the figure, the server system 1 of the preferred embodiment of the present invention includes a storage control module 11, a power supply unit 12, a power storage unit 13, a power switching unit 14, a connector 15, and a substrate management. Controller 16.

The storage control module 11 is, for example, a hard disk, but the storage control module 11 is electrically connected to a storage device 2, for example, but the storage device 2 is, for example, a hard disk. In other embodiments, other devices having the ability to store data may be substituted. In addition, the memory control module 11 includes a cache memory unit 111. For example, the cache memory unit 111 is a flash memory inside the memory control module 11, but is not limited thereto. The power supply unit 12 is, for example, a power supply unit (PSU), but is not limited thereto.

The power storage unit 13 is, for example, a Megacell module and is electrically connected to the power supply unit 12. Specifically, the power storage unit 13 includes a battery management module 131, an input power management module 132, an output power management module 133, and a battery pack 134 (may be multiple in other embodiments), and a battery management module. The group 131 can be a processor having a processing function. The input power management module 132 is electrically connected to the power supply unit 12, and the output power management module 133 is electrically connected to the input power management module 132 and the battery management module 131. The battery pack 134 is electrically connected to the battery management module 131, the input power management module 132, and the output power management module 133.

The power switching unit 14 is electrically connected to the storage control module 11, the power supply unit 12, and the power storage unit 13, and the power switching unit 14 can be a switch composed of two transistors.

The connector 15 is, for example, a connector including a male connector and a female connector (such as a USB interface and an SPI interface connector, but is not limited thereto). The connector 15 is electrically connected to the power storage unit 13, the power supply unit 12, and the power supply. cut The power storage unit 13 is electrically connected to the power supply unit 12 and the power switching unit 14 through the connector 15, and the power storage unit 13 can be inserted and removed through the connector 15.

The baseboard management controller (BMC) is electrically connected to the power storage unit 13, and is further electrically connected to the battery management module 131.

The storage control module 11 is configured to control the storage device 2, and the cache storage unit 111 is configured to store data and control information of the storage device 2 and the storage control module 11, and the power supply unit 12 can output a first power source S1. The source of the first power source S1 may be a commercial power, and the power storage unit 13 receives the first power source S1 and outputs a second power source S2. The power switching unit 14 receives the first power source S1 and the second power source S2 and outputs a third power source S3. The third power source S3 is powered by the storage control module 11, and the power source switching unit 14 isolates the first power source S1 and the second power source S2. Direct conduction to prevent leakage current (as shown in the second figure).

In addition, the battery management module 131 manages the charging and discharging of the power storage unit 13, and the input power management module 132 manages the power of the first power source S1 charged by the power storage unit 13 to prevent overcharging and output power. The management module 133 is configured to be controlled by the battery management module 131 to turn on and off the output second power source S2, and the battery pack 134 is configured to store the power provided by the first power source S1.

When the server system 1 is powered on, the first power source S1 is powered by the power source storage unit 13, thereby charging the power storage unit 13, and the power switching unit 14 also receives the first power source S1 and outputs the third power source. S3, so that the storage control module 11 can be executed by using the third power source S3. The data and control information of the storage device 2 and the storage control module 11 are stored.

In addition, when the power storage unit 13 is inserted through the connector 15, the power storage unit 13 issues an effective power storage unit insertion signal S4 to the substrate management controller 16 to facilitate the substrate management controller 16 to perform the state of the power storage unit 13. Monitoring, that is, when the server system 1 is powered on, the battery management module 131 controls the charging of the battery pack 134 by the first power source S1 according to the amount of power of the battery pack 134, and monitors the temperature of the battery pack 134. Specifically, the battery management module 131 detects the temperature of the battery pack 134 to obtain a temperature information, and sends the temperature information to the substrate management controller 16 through a communication signal S5, so that the substrate management controller 16 transmits the communication signal S5 according to the communication signal S5. The temperature information manages the battery management module 131, that is, the substrate management controller 16 enables the battery management module 131 to control the temperature of the battery pack 134 not to be too high.

Wherein, when the server system 1 is turned off (may also be referred to as power off), the power storage unit 13 is activated and outputs the second power source S2 (that is, the amount of power stored in the battery pack 134) via the connector 15, and further, battery management The module 131 controls the output power management module 133 to turn on and output the second power S2 according to a power storage unit startup signal S6, and the power switching unit 14 receives the second power S2 to output the third power S3, and the storage control module 11 controls the cache. The unit 111 stores the data and control information of the storage device 2 and the storage control module 11 (that is, backup). After the server system 1 is powered on again, the storage control module 11 uses the information stored by the cache unit 111. Continue to work.

In addition, the power storage unit start signal S6 is powered on the server system 1. When the server system 1 is in an inactive state, it is in an active state when the server system 1 is powered off. Specifically, the power storage unit start signal S6 can be pulled up to the first power source S1 through a resistor (not shown), so that the first When the power supply S1 is powered off, it will be in an active working state (low effective); it can also be controlled by a power good signal (not shown) outputted by the power supply unit 12, for example, when the power good signal is valid, the power storage unit The start signal S6 is invalid, and when the power good signal is invalid, the power storage unit start signal S6 is valid, and can also be realized by a device having an inversion function (such as an inverter).

In summary, after the main technical means of the server system provided by the present invention is adopted, since the power storage unit is charged when the server system is powered on, and the power storage unit is powered on and then powered when the server system is powered off, When the server system is powered off and power is off, the data can still be backed up and the work can be continued when the power is turned on again. In addition, since the power storage unit is a very large battery unit, even if a huge amount of data needs to be backed up in the event of a power failure, the stored power can be efficiently supplied and the above data can be effectively backed up.

The features and spirit of the present invention will be more apparent from the detailed description of the preferred embodiments. On the contrary, the intention is to cover various modifications and equivalents within the scope of the invention as claimed.

1‧‧‧Server system

11‧‧‧Storage Control Module

111‧‧‧cache unit

12‧‧‧Power supply unit

13‧‧‧Power storage unit

131‧‧‧Battery Management Module

132‧‧‧Input power management module

133‧‧‧Output power management module

134‧‧‧Battery Pack

14‧‧‧Power switching unit

15‧‧‧Connector

16‧‧‧Base Management Controller

2‧‧‧Storage equipment

S1‧‧‧first power supply

S2‧‧‧second power supply

S3‧‧‧ third power supply

S4‧‧‧ Effective power storage unit insertion signal

S5‧‧‧ communication signal

Claims (9)

A server system includes: a storage control module electrically connected to a storage device for controlling the storage device, the storage control module comprising: a cache storage unit for storing the storage device and the Storing data and control information of the control module; a power supply unit, outputting a first power source; a power storage unit electrically connecting the power supply unit through a connector, receiving the first power source and outputting a second power source; And a power switching unit electrically connected to the power supply unit, the power storage unit and the storage control module, receiving the first power source and the second power source, and outputting a third power source, wherein the third power source provides the storage control Powering the module, the power switching unit isolating direct conduction between the first power source and the second power source to prevent leakage current; wherein, when the server system is powered on, the first power source charges the power storage unit, the power source The switching unit receives the first power source to output the third power source, and when the server system is powered off, the power storage unit starts and outputs the second power The power switching unit receives the second power source to output the third power source, and the storage control module controls the cache memory unit to store data and control information of the storage device and the storage control module, where the server system After being powered on again, the storage control module continues to work according to the information stored in the cache unit. The server system of claim 1, wherein the power storage The storage unit is electrically connected to the connector, and is electrically connected to the power supply unit and the power switching unit through the connector, and the power storage unit can be inserted and removed through the connector. The server system of claim 1, wherein the power storage unit is a Megacell module. The server system of claim 2, wherein the power storage unit comprises: a battery management module for managing charging and discharging of the power storage unit; and an input power management module for the power supply The power of the first power source charged by the storage unit is managed to prevent overcharging; an output power management module is configured to be turned on and off by the control of the battery management module; and a battery Group to store power. The server system of claim 4, wherein when the server system is powered on, the battery management module controls the first power source to charge the battery pack according to the power of the battery pack, and The temperature of the battery pack is monitored. When the server system is shut down, the battery management module controls the output power management module to turn on and output the second power according to a power storage unit startup signal. The server system of claim 5, wherein the power storage unit activation signal is in an inactive state when the server system is powered on, and is in an active state when the server system is powered off. The server system of claim 5, wherein the server system further comprises a baseboard management controller, the baseboard management controller being electrically connected to the power storage unit. The server system of claim 7, wherein the battery management module detects the temperature of the battery pack to obtain a temperature information, and sends the temperature information to the baseboard management controller through a communication signal. The substrate management controller manages the battery management module through the communication signal. The server system of claim 7, wherein the power storage unit sends an effective power storage unit insertion signal to the baseboard management controller to facilitate the insertion of the power storage unit through the connector. The baseboard management controller monitors the status of the power storage unit.