JP2010088211A - Backup power supply of blade server - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To use a backup power supply conveniently by setting it instead of power supply units or blades in an enclosure of a blade server which is not specially designed to set the backup power supply. <P>SOLUTION: The backup power supply 20 is set instead of a plurality of blades 50 and power supply units 60 in the enclosure 40, into which a plurality of power supply units 60 that supply electric power to the blades 50 are set detachably. The backup power supply 20 includes an outer case 21 and a connection portion 22, which can be set in the enclosure 40 detachably. The outer case 21 accommodates a plurality of batteries 31, DC-DC converter 32, which converts the output of the batteries 31 into a voltage that can be supplied to the power supply line 53 of the blades 50; and a charge/discharge control circuit 33, which, in a state set in the enclosure 40, charges the batteries 31 with input electric power and supplies the output of the batteries 31 to the power supply line 53 of the blades 50 at power failure. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a backup power supply that can be set in place of a power supply unit in a blade server enclosure in which a plurality of blades are detachably set.

  Blade servers need to guarantee normal operation during power outages. In order to realize this, a backup battery containing a lead storage battery installed outside the enclosure has been developed. This backup power supply supplies power to the blade server in place of the AC commercial power supply in the event of a power failure. Therefore, this backup power source is connected to the input side of the blade server's commercial power source, and changes to the commercial power source in the event of a power failure and outputs AC power. For this reason, when detecting a power failure, this backup power supply converts the output of the lead storage battery into an alternating current having the same voltage as that of the commercial power supply by a DC / AC inverter and outputs it. In the event of a power failure, the power output from the lead storage battery is converted to alternating current by the DC / AC inverter of the backup power source, and the input alternating current is converted to direct current of a predetermined voltage by the power supply circuit built in the blade server. Supply to each blade. According to this circuit configuration, since the output of the lead storage battery is supplied to each blade via the DC / AC inverter and the power supply circuit, there is a drawback that the utilization efficiency of the power output from the lead storage battery is lowered. Further, since this backup power supply is installed outside the enclosure, there is a disadvantage that it cannot be used conveniently. In order to eliminate this drawback, a backup power source that can be set at the bottom of an enclosure in which a plurality of blades are set has been developed. (See Patent Document 1)

The backup power supply of Patent Document 1 converts a power charged in a built-in battery into a predetermined DC voltage by a DC / DC converter without converting the power into AC, and outputs it. Therefore, the output of the DC / DC converter can be directly supplied to the power supply line of the blade server to increase the battery utilization efficiency. However, since this backup power supply is set in a dedicated storage space provided at the bottom of the enclosure, it is necessary to design the enclosure exclusively for setting the backup power supply. Therefore, there is a drawback that it cannot be set in a general-purpose blade server that is not designed to set a backup power source.
JP 2003-309935 A

  The present invention was developed to solve the above drawbacks, and an important object of the present invention is to replace a power supply unit or blade in a blade server enclosure that is not specifically designed for setting backup power. It is to provide a backup power source of a blade server that can be used very conveniently.

Means for Solving the Problems and Effects of the Invention

  The backup power supply according to claim 1 of the present invention is an enclosure 40 in which a plurality of blades 50 can be detachably set and a plurality of power supply units 60 and 80 for supplying power to the blades 50 can be detachably set. Are backup power supplies 20 and 70 of the blade server. The backup power supply 20 includes exterior cases 21 and 71 and connection portions 22 and 72 that can be detachably set in the enclosure 40 in place of the power supply units 60 and 80. The exterior cases 21 and 71 can be charged with a plurality of charges. Battery 31, DC / DC converter 32 that converts the output of battery 31 to a voltage that can be supplied to power supply line 53 of blade 50, and input in the state where it is set in place of power supply units 60 and 80 in enclosure 40. And a charge / discharge control circuit 33 that supplies the output of the battery 31 to the power line 53 of the blade 50 via the DC / DC converter 32 in the event of a power failure.

  The backup power supply according to claim 2 of the present invention is an enclosure 40 in which a plurality of blades 50 can be detachably set, and a plurality of power supply units 60 and 80 for supplying power to the blades 50 can be detachably set. Is a backup power supply 10 for a blade server. The backup power source 10 includes an exterior case 11 and a connection portion 12 that can be detachably set in the enclosure 40 in place of the blade 50, and a plurality of batteries 31 that can be charged inside the exterior case 11, The DC / DC converter 32 that converts the output to a voltage that can be supplied to the power supply line 53 of the blade 50 and the battery 31 are charged with the input power while being set in the enclosure 40 in place of the blade 50. And a charge / discharge control circuit 33 for supplying the output of the battery 31 to the power line 53 of the blade 50 via the DC / DC converter 32.

  The backup power supply according to claim 1 or claim 2 can be used very conveniently by being set in place of a power supply unit or in place of a blade in an enclosure of a blade server not specifically designed for setting the backup power supply. There are features. In addition, the above backup power supply does not convert the battery output to AC, but converts it to a DC voltage that can be supplied to the power supply of each blade by a DC / DC converter and outputs it. Can supply. This realizes a very important feature that lengthens the operating time of the blade server relative to the charge capacity of the battery.

  The backup power supply of the blade server of the present invention can be set in place of the power supply unit 60 set at the lower part of the enclosure 40 or the power supply unit 80 set at the back of the enclosure 40.

  The backup power supply of the blade server of the present invention can set the output voltage of the DC / DC converter 32 to 12 ± 1V.

The backup power supply for the blade server of the present invention can be provided with cooling fans 24 and 74 on the front surfaces of the outer cases 21 and 71.
Since the above backup power supply can be ventilated and cooled from the front of the outer case to the outside of the enclosure with a cooling fan, the built-in heating element can be efficiently cooled.

  The backup power supply of the blade server of the present invention can be provided with lock levers 27 and 77 set in a locked state in the enclosure 40 on the front surface of the outer cases 21 and 71.

In the backup power source of the blade server of the present invention, the battery 31 housed in the outer case 11, 21, 71 can be a nickel metal hydride battery or a lithium ion battery.
The above backup power supply can be set in place of the blade and the power supply unit, and the operation time of the blade battery during a power failure can be extended. This is because the charge capacity with respect to the volume of the secondary battery can be increased while limiting the size so that the outer case can be set in place of the blade or the power supply unit.

  Embodiments of the present invention will be described below with reference to the drawings. However, the embodiments described below exemplify the backup power supply of the blade server for embodying the technical idea of the present invention, and the present invention does not specify the structure or circuit configuration of the backup power supply as follows. .

  Further, in this specification, in order to facilitate understanding of the scope of claims, numbers corresponding to the members shown in the examples are indicated in the “claims” and “means for solving problems” sections. It is added to the members. However, the members shown in the claims are not limited to the members in the embodiments.

  The backup power supplies 10 and 20 shown in FIG. 1 are set in place of the blade 50 of the blade server or set in place of the power supply unit 60 to supply power to the blade 50 in the event of a power outage. Hold in operation. The time for which the backup power supplies 10 and 20 hold the blade server in an operating state after a power failure is longer than the time during which the blade server can be normally terminated, for example, 2 to 10 minutes.

  The blade server set so that the backup power sources 10 and 20 can be attached / detached can detachably set a plurality of blades 50, and further, a plurality of power supply units 60 for supplying power to each blade 50 can be installed below the blades 50. An enclosure 40 is provided as a storage case that can be detachably set. The illustrated enclosure 40 accommodates the blades 50 in a plurality of stages, that is, two stages, so that the blades 50 can be accommodated in a plurality of rows in each stage, and in the figure, eight rows. Furthermore, the enclosure 40 shown in the figure has a structure in which the power supply units 60 can be stored in six rows below the blades 50 in the horizontal direction.

  The enclosure 40 can set 16 blades 50 so as to be detachable. However, since the blade server does not always use 16 sets of blades 50, the backup power supply 10 is set in place of the blades 50 in a portion where the blades 50 are not set.

  Further, the enclosure 40 shown in the figure has a structure in which six rows of power supply units 60 can be detachably set. However, since six sets of power supply units 60 are not always used, the power supply unit 60 is not attached to a portion where the power supply units 60 are not set. Instead, the backup power source 20 is set.

  The backup power supplies 10 and 20 include exterior cases 11 and 21 and connection portions 12 and 22 that can be detachably set in the enclosure 40 in place of the blade 50 or in place of the power supply unit 60. The outer case 11 of the backup power supply 10 that is set in place of the blade 50 has an outer shape that can be removably inserted into a portion to which the blade 50 is connected. The outer case 21 of the backup power supply 20 set in place of the power supply unit 60 has an outer shape that can be detachably inserted into a portion where the power supply unit 60 is set.

  Further, as shown in FIG. 2, the enclosure 40 includes a connect bay 41 provided with a bus line, a communication line, a power supply line, and the like connected to the blade 50 and the power supply unit 60 to be set. The blade 50 and the power supply unit 60 set at a fixed position of the enclosure 40 are provided with connection portions 52 and 62 including connection terminals and connectors connected to the connect bay 41 in a state of being set at a fixed position. It is connected to the connect bay 41 via the connection parts 52 and 62. Accordingly, the backup power supplies 10 and 20 that are set in place of the blade 50 and the power supply unit 60 are also provided with the connecting portions 12 and 22 that are connected to the connect bay 41 in a state where they are set at fixed positions of the enclosure 40.

  FIG. 3 shows a block diagram of the blade server. The blade server shown in this figure includes a power supply unit 60 that supplies input commercial power to the power supply line 53 of the blade 50. The power supply unit 60 converts an input commercial power source into an AC / DC conversion circuit 63 that converts direct current into direct current, and DC that converts the direct current output from the AC / DC conversion circuit 63 into a voltage supplied to the power supply line 53 of the blade 50. / DC converter 64. The blade server in this figure has a power circuit 54 built in the blade 50 and a sub DC / DC converter 55 that converts the DC voltage supplied from the power unit 60 into an optimum voltage for the internal circuit. . In the illustrated blade server, the voltage supplied from the power supply unit 60 to the power supply line 53 of the blade 50 is 12V, and the blade 50 has a built-in sub DC / DC converter 55 that converts the 12V into 5V, 3.3V, and 1V. ing.

  The backup power supplies 10 and 20 include a plurality of batteries 31 that can be charged, a DC / DC converter 32 that converts the output voltage of the batteries 31 into a DC voltage that can be supplied to the power supply line 53 of the blade 50, and the batteries 31 with the input power. A charging / discharging control circuit 33 that controls charging of the power supply 53 of the blade 50 via the DC / DC converter 32 by detecting a power failure and charging.

  The battery 31 is composed of a plurality of nickel metal hydride batteries, and the plurality of nickel metal hydride batteries are connected in series to increase the output voltage, or connected in series and in parallel to increase the output voltage and output current. The battery 31 incorporated in the backup power sources 10 and 20 is set to a capacity that can output 400 W to 2 kW of power continuously for 2 to 10 minutes, for example. As the battery 31, a lithium ion battery can be used instead of the nickel metal hydride battery. Lithium ion batteries can have a larger capacity with respect to volume than nickel metal hydride batteries.

  The DC / DC converter 32 is set to a voltage at which the charging voltage of the battery 31 can be supplied to the power supply line 53 of the blade 50, for example, 11.5 V in FIG. The output voltage of the DC / DC converter 32 is set in a range of 12V ± 1V so that DC power can be supplied to the power supply line 53 of the blade 50. In the illustrated backup power supplies 10 and 20, a diode 34 that prevents backflow is connected to the output side of the DC / DC converter 32. Since the backup power supplies 10 and 20 do not cause a current to flow backward from the power supply unit 60 to the backup power supplies 10 and 20, the DC / DC converter 32 is always in an operating state, and the battery 31 passes through the DC / DC converter 32 during a power failure. Can supply power to the power line 53. The DC / DC converter 32 in the operating state consumes power, but this power is not supplied from the battery 31, and the power supply circuit 35 that converts the power input to the backup power supplies 10 and 20 into the charging voltage of the battery 31. Can be supplied from. The backup power supplies 10 and 20 can supply power to the power supply line 53 of the blade 50 without time delay at the time of a power failure, that is, without interrupting the voltage input to the power supply line 53. Here, the backup power sources 10 and 20 in FIG. 3 use the input power as an AC power source that is a commercial power source. Therefore, the backup power supplies 10 and 20 shown in the figure use the power supply circuit 35 as an AC / DC converter 35A to convert the input AC power to DC and supply it to the charge / discharge control circuit 33.

  The charge / discharge control circuit 33 detects the remaining capacity of the battery 31 and charges it with a direct current input from the power supply circuit 35 so as to keep the battery 31 at a predetermined remaining capacity. For example, the charge / discharge control circuit 33 controls the charging of the battery 31 such that the remaining capacity of the battery 31 is maintained at 80% to 100%. Further, the charge / discharge control circuit 33 stops the operation of the DC / DC converter 32 and stops the discharge of the battery 31 when the remaining capacity of the battery 31 is reduced to the minimum capacity in order to prevent the battery 31 from being overdischarged. .

  The charge / discharge control circuit 33 can also supply power from the battery 31 to the power supply line 53 of the blade 50 through the diode 34 at the time of a power failure while the DC / DC converter 32 is always in an operating state. It is also possible to switch the DC / DC converter 32 to the operating state. The charge / discharge control circuit 33 detects the voltage of the input commercial power supply, determines that a power failure occurs when the commercial power supply voltage becomes lower than the set value, switches the DC / DC converter 32 to the operating state, Power is supplied from 31 to the power supply line 53 of the blade 50 via the DC / DC converter 32. Since the voltage of an AC commercial power supply changes with time, it takes 1/2 cycle time to detect an AC voltage and detect a power failure.

Although not shown, the charge / discharge control circuit 33 converts the alternating current of the commercial power supply into a phase-shifted signal that is 90 degrees out of phase with the commercial power supply using an integrating circuit or a differential circuit. Both of the input signals to be input are separately squared by the squaring circuit, and the output of each squaring circuit is added by the adding circuit, so that a power failure of the commercial power supply can be detected in a time shorter than ½ cycle.
This circuit, when an input signal input from the commercial power source and omega, to achieve the following equation, and outputs a DC voltage of A ^2. That is, alternating current is input and direct current is output. In this equation, A is the peak voltage of the commercial power supply.
(Asin ω) ² + (A cos ω) ² = A ² holds.
In this circuit, the addition circuit outputs a constant DC voltage (A ² ) in a state where commercial power is input. However, when a power failure occurs, this output voltage changes immediately and a power failure can be detected. That is, it is instantaneously determined whether or not the input commercial power source changes along a sine curve that becomes a predetermined voltage at a predetermined cycle.

  The backup power supplies 10 and 20 that detect the power failure of the commercial power supply and set the DC / DC converter 32 in the operating state are set in the operating state before the voltage of the power line 53 of the blade 50 decreases to the set value due to the power failure. Power is supplied to the power line 53. Since the power supply line 53 of the blade 50 is connected to a large-capacity electrolytic capacitor 56, the voltage does not drop instantaneously even if a power failure occurs. The electrolytic capacitor 56 causes the DC / DC converter 32 to be in an operating state before the voltage of the power supply line 53 is lowered to the set voltage, that is, the lowest voltage at which the blade 50 can be normally operated. Electric power is supplied to keep the blade 50 in an operating state even when a power failure occurs. After the blade server performs predetermined processing such as termination processing with the power supplied from the battery 31 to the power line 53 and shuts off the power, the charge / discharge control circuit 33 stops the operation of the DC / DC converter 32, Discharging the battery 31 is stopped.

  Further, FIG. 4 shows backup power supplies 10 and 20 in which the input power is not an AC power supply but a DC power supply. The backup power supplies 10 and 20 shown in the figure are input from the power supply line 53 of the blade 50 using the DC power output from the power supply unit 60 as input power. The backup power supplies 10 and 20 in the figure use an output line 36 that is supplied from the DC / DC converter 32 to the power supply line 53 of the blade 50 in combination with an input line 37 for charging the battery 31. In the illustrated backup power supplies 10 and 20, a diode 34 that prevents backflow is connected to the output side of the DC / DC converter 32, and the output side of this diode is branched and connected to the power supply circuit 35. With this structure, the output line 36 and the input line 37 can be integrated into one line. Since the backup power supplies 10 and 20 use the input power as a direct current, the power supply circuit 35 is used as a DC / DC converter 35B to convert the input direct current into a charge voltage for the battery 31 and supply it to the charge / discharge control circuit 33. is doing.

  The charge / discharge control circuit 33 detects the remaining capacity of the battery 31 and charges it with a direct current input from the power supply circuit 35 so as to always keep the battery 31 at a predetermined remaining capacity. Electric power is supplied to the power supply line 53 of the blade 50 by discharging. The charge / discharge control circuit 33 can also supply power from the battery 31 to the power supply line 53 of the blade 50 through the diode 34 when the DC / DC converter 32 is always in an operating state. The DC / DC converter 32 can be switched to the operating state. For example, the charge / discharge control circuit 33 can detect a voltage of the input power supply line 53 and determine that a power failure occurs when the voltage of the power supply line 53 becomes smaller than a set value, or a communication line (not shown). A power failure can be detected by a signal from the connect bay 41 connected through the communication line 41). When the power failure is detected, the charge / discharge control circuit 33 switches the DC / DC converter 32 to the operating state and supplies power from the battery 31 to the power supply line 53 of the blade 50 via the DC / DC converter 32.

  5 and 6 show the backup power supply 20 set in place of the power supply unit 60. FIG. These backup power sources 20 have a DC / DC converter 32 and a battery 31 built in before and after the outer case 21. The charge / discharge control circuit is mounted on a built-in circuit board 23. Further, as shown in FIG. 1, the backup power source 20 is set in place of the power unit 60 set at the lower portion of the enclosure 40. The backup power source 20 is provided with a cooling fan 24 on the front surface of the outer case 21 and is used as a heat generating component built in the cooling fan 24, for example, a switching element FET of the DC / DC converter 32, a rectifying diode, a battery 31 or the like. Cool with forced air. The outer case 21 is provided with a large number of through holes 26 in the front panel 25 through which air sucked or exhausted by the cooling fan 24 on the front face passes.

  Further, the exterior case 21 shown in the figure is provided with a lock lever 27 set in a locked state on the enclosure 40 on the front surface. The lock lever 27 is made of an elastic metal plate, and a locking hook 28 is elastically projected on the side surface of the outer case 21. The locking hook 28 is locked by a locking portion (not shown) provided in the enclosure 40 and prevents the backup power source 20 from being disconnected. The backup power source 20 can be detached from the enclosure 40 by operating the lock lever 27 to remove the locking hook 28.

  7 and 8 show the backup power supply 10 used in the enclosure 40 in place of the blade 50. FIG. The backup power supply 10 can accommodate a large number of batteries 31 to increase the charging capacity. For this reason, many blades 50 with large power consumption at the time of a power failure can be continuously maintained in an operating state for a long time. The backup power supply 10 also has a charge / discharge control circuit mounted on a circuit board (not shown) that realizes the DC / DC converter 32.

  The backup power supplies 10 and 20 are provided in the enclosure 40 instead of the blade 50 or in place of the power supply unit 60 and provided with connection portions 12 and 22 connected to a connect bay 41 provided in the enclosure 40. Yes. The connection parts 12 and 22 are provided in the inner part of the outer cases 11 and 21 and are connected to the connect bay 41 in a state of being set in the enclosure 40. The blade server can be kept in an operating state for a predetermined time during a power failure by setting the backup power supplies 10 and 20 in place of the blade 50 or in place of the power supply unit 60. The blade server can set a plurality of backup power supplies 10 and 20 and supply power from the backup power supplies 10 and 20 to the power supply line 53 of the blade 50 in the event of a power failure, thereby maintaining the operating state.

  In the above embodiment, the blade server has the power supply unit 60 set in the lower part of the enclosure 40. However, the blade server is located at the back of the enclosure 40 and above and below the connect bay 41 as shown in FIG. The power supply unit 80 can also be installed in the spaces 42, 42. The power supply unit 80 is provided with a connection portion 82 composed of a connection terminal and a connector connected to the connect bay 41 in a state of being set at a fixed position, and is connected to the connect bay 41 via the connection portion 82. . In this blade server, a power supply unit 80 can be detachably set in a space 42 on the back surface, and a backup power supply 70 can be set in place of the power supply unit 80.

FIGS. 10 and 11 show a backup power supply 70 that is set in place of the power supply unit 80 in the space 42 above and below the connect bay 41 on the rear surface of the enclosure 40. This backup power source 70 has a DC / DC converter 32 and a battery 31 built in before and after an outer case 71. The charge / discharge control circuit is mounted on a built-in circuit board 73. Further, the backup power source 70 is provided with a cooling fan 74 on the front surface of the outer case 71 (the back side of the enclosure 40), and a heat generating component built in with the cooling fan 74, for example, a FET of a switching element of the DC / DC converter 32, It cools by forcibly blowing air to the diode for rectification, the battery 31 and the like. The exterior case 71 is provided with a through hole 76 in the front panel 75 through which air sucked by the front cooling fan 74 or air exhausted is passed.
When the circuit shown in the block diagram of FIG. 3 is used on the circuit board 73, electronic components corresponding to the DC / DC converter 32, the charge / discharge control circuit 33, the diode 34, the AC / DC converter 35A of the power supply circuit 35, etc. Will be implemented. On the circuit board 73, when the circuit of the block diagram of FIG. 4 is used, it corresponds to the DC / DC converter 32, the charge / discharge control circuit 33, the diode 34, the DC / DC converter 35B of the power supply circuit 35, and the like. Electronic components will be mounted.

  Further, the exterior case 71 shown in the figure is provided with a lock lever 77 set on the front surface in a locked state on the enclosure 40. The lock lever 77 is made of an elastic metal plate, and a locking hook 78 is elastically projected on the upper surface of the exterior case 71. The locking hook 78 is locked by a locking portion (not shown) provided in the enclosure 40 and prevents the backup power source 70 from being disconnected. The backup power source 70 can be detached from the enclosure 40 by operating the lock lever 77 to remove the locking hook 78.

The backup power supply 70 is also provided with a connection portion 72 connected to the connect bay 41 in a state where the backup power supply 70 is set at a fixed position of the enclosure 40 instead of the power supply unit 80. The connection portion 72 is provided in the back of the outer case 71 and is connected to the connect bay 41 while being set in the enclosure 40. The blade server can hold the backup power supply 70 in place of the power supply unit 80, and can maintain the operation state for a predetermined time during a power failure. The blade server can set a plurality of backup power supplies 70 and supply power from each backup power supply 70 to the power supply line 53 of the blade 50 in the event of a power outage, thereby maintaining the operating state.
10 and 11, in a box-shaped backup power source having a thick plate shape, one side is disposed on the lower side, but one plane (the rear surface in FIG. 11) is disposed on the lower side. In other words, the space 42 can be set in a state rotated by 90 degrees from the states of FIGS.

It is a perspective view which shows an example of the blade server by which the backup power supply concerning one Example of this invention is set. FIG. 2 is a vertical sectional view of the blade server shown in FIG. 1. It is a block diagram of the blade server shown in FIG. It is a block diagram which shows another example of a blade server. It is a perspective view of the backup power supply concerning one Example of this invention. It is the disassembled perspective view which looked at the backup power supply shown in FIG. 5 from the back surface. It is a perspective view of the backup power supply concerning the other Example of this invention. It is the disassembled perspective view which looked at the backup power supply shown in FIG. 7 from the back surface. It is a vertical sectional view showing a blade server to which a backup power supply according to another embodiment of the present invention is set. It is a perspective view of the backup power supply concerning the other Example of this invention. It is the disassembled perspective view which looked at the backup power supply shown in FIG. 10 from the back surface.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Backup power source 11 ... Exterior case 12 ... Connection part 20 ... Backup power source 21 ... Exterior case 22 ... Connection part 23 ... Circuit board 24 ... Cooling fan 25 ... Front panel 26 ... Through-hole 27 ... Lock lever 28 ... Locking hook 31 ... Battery 32 ... DC / DC converter 33 ... Charge / discharge control circuit 34 ... Diode 35 ... Power supply circuit 35A ... AC / DC converter
35B ... DC / DC converter 36 ... Output line 37 ... Input line 40 ... Enclosure 41 ... Connect bay 42 ... Space 50 ... Blade 52 ... Mounting part 53 ... Power supply line 54 ... Power supply circuit 55 ... Sub DC / DC converter 56 ... Electrolytic capacitor DESCRIPTION OF SYMBOLS 60 ... Power supply unit 62 ... Mounting part 63 ... AC / DC conversion circuit 64 ... DC / DC converter 70 ... Backup power supply 71 ... Exterior case 72 ... Connection part 73 ... Circuit board 74 ... Cooling fan 75 ... Front panel 76 ... Through-hole 77 ... Lock lever 78 ... Hook hook 80 ... Power supply unit 82 ... Mounting part

Claims (7)

An enclosure (40) can be set in which a plurality of blades (50) can be detachably attached and a plurality of power supply units (60), (80) for supplying power to the blade (50) can be set detachably. A backup power supply for the blade server,
In place of the power supply unit (60), (80), it is provided with an outer case (21), (71) and a connecting portion (22), (72) that can be detachably set in the enclosure (40). A DC / DC converter that converts a plurality of rechargeable batteries (31) and a voltage that can be supplied to the power supply line (53) of the blade (50) into the rechargeable batteries (31) inside the (21) and (71) (32) and charging the battery (31) with the input power while being set in place of the power supply unit (60), (80) in the enclosure (40), and at the time of power failure, the battery (31) A backup power supply for a blade server, comprising: a charge / discharge control circuit (33) for supplying an output to a power supply line (53) of the blade (50) via a DC / DC converter (32). An enclosure (40) can be set in which a plurality of blades (50) can be detachably attached and a plurality of power supply units (60), (80) for supplying power to the blade (50) can be set detachably. A backup power supply for the blade server,
It is provided with an outer case (11) and a connecting portion (12) that can be detachably set in the enclosure (40) instead of the blade (50), and a plurality of rechargeable batteries (31 ), A DC / DC converter (32) that converts the output of the battery (31) into a voltage that can be supplied to the power line (53) of the blade (50), and the blade (50) in the enclosure (40). In this state, the battery (31) is charged with the input power, and the output of the battery (31) is supplied to the blade (50) power line (53) via the DC / DC converter (32) in the event of a power failure. A backup power supply for a blade server, comprising a charge / discharge control circuit (33) for supplying power to the blade server.   The backup power supply of a blade server according to claim 1, wherein the backup power supply unit is set in place of a power supply unit (60) set in the lower part of the enclosure (40) or a power supply unit (80) set in the back. .   The backup power supply for the blade server according to claim 1 or 2, wherein an output voltage of the DC / DC converter (32) is 12 ± 1V.   The blade server backup power supply according to claim 1 or 2, wherein cooling fans (24), (74) are provided in front of the outer cases (21), (71).   The blade server according to claim 1 or 2, wherein a lock lever (27), (77) set in a locked state in the enclosure (40) is provided on a front surface of the outer case (21), (71). Backup power supply.   The blade server backup power supply according to claim 1 or 2, wherein the battery (31) accommodated in the outer case (11), (21), (71) is a nickel metal hydride battery or a lithium ion battery.

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