KR20140088393A - Interface board for power supply - Google Patents

Abstract

Disclosed is an interface board to supply power. The interface board includes: an input unit receiving DC power from an external power supply device which converts AC power to DC power and a supply unit which supplies the received DC power to a server arranged in a rack. The interface board to supply power can be connected to a plurality of servers arranged in rack units respectively.

Description

Power supply interface board {INTERFACE BOARD FOR POWER SUPPLY}

Embodiments of the present invention relate to a power supply interface board for directly supplying DC power from an external power supply to each server installed in a rack.

In recent years, as large data centers have emerged, research is underway to change data centers based on alternating current (AC) power delivery to a data center based on high efficiency direct current (DC) power delivery Is in progress.

In this connection, Korean Patent Laid-Open Publication No. 10-2011-003035 (published on Jan. 11, 2011) discloses a "DC power supply system" in which a DC power supply system receives AC power and outputs it from a rectifier that generates DC power DC power is directly supplied to a plurality of servers.

However, in such a conventional power supply system, power supply units (PSUs) are individually used for each server. Therefore, when a power supply problem occurs due to overload, power failure, or power supply failure, There is a problem that an influence occurs. In addition, there has been a problem in that the efficiency of the power source varies depending on the state of the power source device used individually for each server, so that it is difficult to obtain the maximum effect.

Accordingly, there is a demand for a method capable of preventing data loss due to overload, power failure, faulty power supply, and the like, and maintaining the best efficiency of the power supply.

There is provided a power supply interface board that can prevent data loss due to defective, power failure, and overload of a PSU (Power Supply Unit).

There is provided a power supply interface board capable of preventing a voltage increase phenomenon due to an inrush current generated in a server upon initial power-on.

A power supply interface board capable of supplying power according to characteristics of the server is provided.

There is provided a power supply interface board capable of providing auxiliary power longer than the time kept by the existing PSU.

The interface board includes an input unit for receiving a DC power from an external power supply unit for converting AC power into DC power, and a supply unit for supplying the input DC power to a server arranged in a rack. And may be connected to the plurality of servers, respectively.

According to an aspect of the present invention, the apparatus may further include an inrush current protector for preventing a voltage increase due to an inrush current generated in the server when initial power is applied to the server.

According to another aspect of the present invention, the inrush current protector may include a fuse for blocking current when a current higher than the inrush current is input.

According to another aspect, the apparatus may further include a switch for shutting off power when a current is input through the supply unit.

According to another aspect of the present invention, the power supply unit may further include a power conversion unit converting the DC power supplied from the external power supply unit into a predetermined voltage.

According to another aspect, the rear surface of the interface board may include an epoxy-based conductive material.

DC power required for driving the server from the external power supply unit is directly supplied to the server. Thus, it is possible to prevent data loss due to failure, power failure, and overload of the PSU (Power Supply Unit).

By including the inrush current protection circuit, it is possible to prevent the voltage increase phenomenon from occurring due to the inrush current generated in the server when the initial power is applied.

And a constant voltage circuit that converts the DC power supplied from the external power supply unit to a predetermined voltage, so that DC power can be supplied according to the characteristics of each server.

Each of the servers is provided with an auxiliary power source to be supplied to each server, so that the auxiliary power source can be supplied for a longer time than the conventional PSU maintains.

1 is a block diagram illustrating a power supply in an embodiment of the present invention.
FIG. 2 is a diagram for explaining an operation procedure of a power supply device in an embodiment of the present invention.
3 is a diagram showing a detailed configuration of a power supply device according to an embodiment of the present invention.
4 is a diagram illustrating a process of switching power supply to a second source when an unstable power source is input from a first source in the embodiment of the present invention.
5 and 6 are circuit diagrams showing an instantaneous power supply unit according to an embodiment of the present invention.
7 is a graph showing a load amount of the DC power source and a movable capacity of the AC power source in the embodiment of the present invention.
8 is a diagram for explaining a process of supplying DC power to a plurality of servers provided in a rack in a power supply apparatus according to an embodiment of the present invention.
9 is an exemplary view showing a state in which a power supply device is installed in a rack according to an embodiment of the present invention.
10 is a perspective view showing a power supply unit in an embodiment of the present invention.
11 is a circuit diagram showing an interface board in an embodiment of the present invention.
12 is a perspective view showing an interface board according to an embodiment of the present invention.
13 is a flowchart showing a power supply method in an embodiment of the present invention.

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

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram illustrating an example of a power supply apparatus according to an embodiment of the present invention. FIG.

The power supply apparatus 100 according to the present invention is designed to supply a stable direct current power in units of racks arranged in a data center and maintain the efficiency of the power supply in the best condition. And may include a monitoring unit 110, a relay 120, a DC power supply unit 130, and a controller 140.

If the power is unstably supplied to the rack due to overload, power failure, etc., data written to the server may be lost. In order to prevent this, the power supply apparatus 100 receives AC power from a plurality of different source sources and multiplexes them, and converts the multiplexed AC power into DC power and supplies the AC power to a plurality of racks.

For example, a high-voltage AC power source may be input to the power supply apparatus 100 from a first source and a second source. At this time, the power supply apparatus 100 selectively turns on / off the AC power input from the first source source and the second source source using the relay 120, It is possible to multiplex the input AC power.

The monitoring unit 110 monitors the AC power input to the power supply apparatus 100. For example, the monitoring unit 110 senses the voltage and current of the AC power source input from the first source and the voltage and current of the AC power source input from the second source, respectively, and outputs the sensed value to the controller 140).

The relay 120 switches the AC power input to the power supply unit 100 to either the first source or the second source according to the switching signal transmitted from the controller 140. The relay 130 may be, for example, a solid state relay (SSR).

The DC power supply unit 130 converts AC power supplied through the relay 120 into AC power and supplies the DC power to a plurality of servers arranged in the rack. For example, the direct current power supply unit 130 may convert a 220V AC power supplied to the power supply unit 100 into a direct current power of 12V / 100A. At this time, the DC power supply unit 130 may include a plurality of PSUs (Power Supply Units) for converting the supplied AC power into DC power. The PSUs may be connected in parallel to supply DC power in units of a rack.

For example, if one rack contains 20 servers with a power capacity of 20A, the rack requires a total power capacity of 400A. Therefore, when 20 servers included in one rack are operated, the DC power supply unit 130 includes five PSUs providing a DC power capacity of 200 A, so that even when one of the PSUs malfunctions, the remaining four PSUs So that an efficient power supply can be supplied to the rack.

The control unit 140 generates a switching signal for switching the supply of the AC power to either the first source source or the second source source according to the monitoring result received from the monitoring unit 110 and transmits the switching signal to the relay 120. For example, when an unstable AC power source is input from the first source source for a predetermined time or longer (for example, 50 ms or more), the control unit 140 switches the supply of the AC power source from the first source circle to the second source circle . Similarly, when an unstable AC power source is input from the second source source for a predetermined time or more, the control unit 140 may switch the supply of the AC power source from the second source circle to the first source circle.

In another embodiment, the control unit 140 includes a function of monitoring an AC power supplied from the plurality of source sources to the power supply apparatus 100, and supplies the AC power to the first source source and the second source source, And may be switched to any one of the second source sources.

When the supply of the AC power is switched by the control unit 140, the instantaneous input voltage is interrupted and the PSU stops operating, causing a voltage drop phenomenon (Dip phenomenon) in the output power supply. In order to prevent this, the power supply apparatus 100 may further include a momentary power supply unit (350 in FIG. 3) for supplying DC power to a plurality of servers installed in the rack when the AC power is switched.

As an example, the instantaneous power supply may include at least one of a capacitor and a lithium polymer battery. In this case, the instantaneous power supply unit can supply the DC power charged to the capacitor or the lithium polymer battery when the AC power is switched. Capacitors, lithium polymer batteries, etc. may be influenced by the DC power supplied to the PSU. To prevent this, the instantaneous power supply unit may use at least one of a diode and a field effect transistor (FET).

The control unit 140 can maintain the switched state for a predetermined time (for example, 5 minutes to 10 minutes) after switching the AC power, and monitor the supplied AC power. When the AC power is normally input from the source to which the unstable AC power is supplied as a result of the monitoring, the controller 140 may switch the power again to the original state.

DC power supplied from the DC power supply unit 130 may be integrated and distributed through an integrator (360 in FIG. 3), and may be supplied to each of the servers through a connection with the corresponding interface board (820 in FIG. 7). The interface board can prevent a voltage increase due to an inrush current generated in a server when an initial power is applied, and can be applied to a data center based on conventional DC power transmission. For example, the interface board according to the present invention may be implemented in a removable (modular) manner, and may be coupled to a space of the existing server minus the PSU.

The power supply apparatus 100 further includes a remote power monitoring unit for monitoring an operation state of the plurality of servers installed in the rack and for activating or deactivating the plurality of PSUs included in the DC power supply unit according to the operating state of the server It is possible. The remote power monitoring unit may include a camera, a temperature sensor, and the like to remotely monitor an operation state and an output state of the server.

FIG. 2 is a diagram for explaining an operation procedure of a power supply device in an embodiment of the present invention. Hereinafter, a case where the first AC power source and the second AC power source are input from two source sources will be described with reference to FIG.

The monitoring unit 110 senses each AC power source using a first C / T sensing voltage and current of the first AC power source and a second C / T sensing voltage and current of the second AC power source, To the control unit 140. [0031] FIG.

If both of the first AC power and the second AC power are stable, the first AC power and the second AC power may be supplied to the DC power supply 130 through the relay 120. [

The DC power supply unit 130 may include a plurality of PSUs (first to eighth PSUs) as shown in FIG. Each PSU is used in parallel so as to have a constant current distribution, so that the heat generation can be minimized and the problem caused by the failure of the PSU can be prevented in advance. In addition, since the conventional power supply unit is implemented in such a manner that AC power is applied to each PSU of each server to operate independently, data loss occurs in the server when an unstable power supply such as power failure or overload is input. The power supply unit supplies the first AC power and the second AC power of different source sources to each PSU through the relay 120 to control the relay 120 when an unstable power is applied due to a power failure, The power can be transferred to the stable side.

To this end, the relay 120 may include, for example, first to fourth relays for switching the first AC power supply, fifth to eighth relays and ninth to twelfth relays for switching the second AC power, Relay. ≪ / RTI > The relay 120 may switch the AC power supplied to the DC power supply unit 130 to one of a first source and a second source according to a switching signal transmitted from the controller 140.

The control unit 140 may monitor the first AC power supply and the second AC power supplied to the DC power supply unit 130 based on the sensing value from the monitoring unit 110. [ At this time, if the first AC power source is unstable, the control unit 140 switches the first to fourth relays and the ninth to twelfth relays so that only the second AC power is supplied to the DC power supply unit 130, If the AC power source is unstable, the fifth to eighth relays and the thirteenth to sixteenth relays may be switched so that only the first AC power is supplied to the DC power supply unit 130.

The control unit 140 continuously monitors the first AC power and the second AC power while the input voltage is switched, and when the AC power is normally input from the source to which the AC power supplied with the unstable power is input, So that the input of the AC power source can be transferred to the original state. In order to prevent the voltage drop phenomenon (Dip phenomenon) from occurring, the capacitor 140 or the lithium polymer battery having the DC power supply must have a charging time. Therefore, the control unit 140 has a delay of about 30 seconds, Can be transferred to the original state.

FIG. 3 is a diagram illustrating a detailed configuration of a power supply apparatus according to an embodiment of the present invention. FIG. 4 is a schematic diagram of a power supply apparatus according to an embodiment of the present invention. In FIG. 3, when an unstable power supply is input from a first source, And Fig.

In case the power supply is unstable due to overload, power failure, etc., data recorded in the server may be lost. To prevent this, the power supply unit may receive AC power from different sources. In FIG. 3, the input power is shown as a first AC power source and a second AC power source.

When the first AC power source and the second AC power source are supplied, the monitoring unit 110 uses the first C / T 310 and the second C / T 320 to generate the first AC power and the second AC power, Senses the voltage and the current, and transmits the sensed value to the control unit 140.

3, the relay 120 is implemented by a plurality of contactless relays (Relay 1 to Relay 16), and each of the PSUs (PSU 1 to PSU 8) included in the DC power supply unit 130 is connected to the first AC power source 2 Transmits AC power. 3, the first AC power is supplied from the first relay through the fourth relay and the ninth relay through the twelfth relay to the first PSU through the eighth PSU, and the second AC power is supplied from the fifth relay through the eighth relay Relay, and the thirteenth relay through the sixteenth relay to the first PSU through the eighth PSU, the number of the relay and the PSU may be modified as necessary.

When both the first AC power and the second AC power are stable, the first AC power and the second AC power may be supplied to the DC power supply 130 through the relay 120 as shown in FIG. 4 (a) have. However, when the first AC power is not stable as shown in FIG. 4 (b), the first to fourth relays and the ninth to twelfth relays are connected to the DC power supply The first AC power supplied to the first AC power supply 130 may be switched to the second AC power.

For this, the control unit 140 generates a switching signal for switching the supply of the AC power to either the first source source or the second source circle based on the sensing value received from the monitoring unit 110 and transmits the switching signal to the corresponding relay .

For example, when an unstable AC power source is input from the first source source for a predetermined time or longer (for example, 50 ms or more), the control unit 140 switches the supply of the AC power source from the first source circle to the second source circle . Similarly, when an unstable AC power source is input from the second source source for a predetermined time or more, the control unit 140 may switch the supply of the AC power source from the second source circle to the first source circle.

When the supply of the AC power is switched by the control unit 140, the instantaneous input voltage is interrupted and the PSU stops operating. As the load instantaneously rises, a voltage drop phenomenon (Dip phenomenon) occurs in the output power source, The power supply unit 350 supplies the DC power to the rack when the AC power supplied to the DC power supply unit 130 is switched to prevent this. For example, when the AC power supplied to the DC power supply unit 130 is switched, the instant power supply unit 350 may supply the DC power charged in the capacitor or the lithium polymer battery to the rack.

The instantaneous power supply unit 350 may include a rectifying circuit for rectifying the DC power supply and a constant voltage circuit for maintaining the rectified DC power supply at a constant voltage. It may also include a diode or FET to block the impact of the PSU upon charging a capacitor or a lithium polymer battery. Accordingly, the instantaneous power supply unit 350 can charge the capacitor or the lithium polymer battery with a normal power source even if a problem occurs in any one of the input AC power sources. The reason for using a separate power source instead of charging the capacitor or the lithium polymer battery by the DC power source is that when the output is directly connected, the power output of the PSU is short-circuited This is because the same phenomenon occurs and the output is not output normally. To compensate for this, the instantaneous power supply unit 350 uses an electric switch between the charged material and the PSU output to charge the charged material to a certain level through an AC power source. can do.

The controller 140 monitors the states of the first PSU through the eighth PSU included in the DC power supply 130 using the third C / T 330, and activates each PSU according to the server operating capacity Or deactivate the power supply to maintain the efficiency of the power supply at all times. The display unit 340 connected to the controller 140 may display information on the first AC power, the second AC power, and the first PSU through the eighth PSU. In addition, the controller 140 may transmit information about the first AC power, the second AC power, and the first PSU to the eighth PSU to the remote power monitoring apparatus, or may receive the switching signal from the remote power monitoring apparatus.

The control unit 140 maintains the switched state for a predetermined time (for example, 5 minutes to 10 minutes) when the AC power supplied to the DC power supply unit 130 is transferred, Power can be monitored. If the AC power is normally input from the source to which the unstable AC power is input as the monitoring result, the controller 140 can switch the power to the original state again.

The DC power supplied from the DC power supply unit 130 may be supplied to each server installed in the rack after being integrated through the integrator 360.

Conventional power supply units use individual power supply for each server, and when the power supply unit has a problem, it is configured to have a serious effect on the operation of the server. The efficiency of the PSU depends on the state of the power supply unit used individually And the efficiency is fluctuated so that the maximum effect is not obtained. However, as described above, the power supply apparatus according to the present invention can minimize the heat generation by using a plurality of PSUs (first PSU through eighth PSU) in parallel to achieve a constant current distribution. As a result, The occurrence of a problem can be prevented in advance. In addition, by using the remote power monitoring unit, each PSU can be activated or deactivated according to the operation state of the server, so that the power supply can always be maintained in the best state.

In addition, the conventional power supply apparatus is implemented in such a manner that AC power is applied to each PSU of each server to operate independently, and there is no countermeasure against an unstable input power source such as a power failure. However, When the unstable power source such as a power failure is applied by causing two source power sources (the first AC power source and the second AC power source) of the source one to be supplied to the respective PSU via the relay 120, The input power can be switched to the safe side according to the switching signal from the monitoring unit and the input power is monitored while maintaining the switching for a predetermined time (for example, 5 to 10 minutes) It is possible to switch the power source back to the original state.

Meanwhile, the instantaneous power supply unit 350 may include a lithium polymer battery or a capacitor to supply DC power instantaneously when the input power is switched. When a DC power is supplied using a general battery, periodical inspection is required due to the volume problem and its short life due to charge, discharge or natural discharge, and the maintenance and management cost can not be ignored after a certain period of time. In addition, a general battery has a characteristic that a voltage is instantaneously discharged to a certain voltage because it has a nominal voltage due to characteristics. To compensate for this, charging the battery up to the nominal voltage causes the battery life to be shortened. A phenomenon may occur in which the voltage of the battery is discharged to the instantaneous nominal voltage and the server is reset. Therefore, by using a capacitor that can be used semi-permanently, it is possible to reduce the maintenance cost and the maintenance cost, and it is possible to use up to the charged voltage without fail, and the charging time can be shortened compared with the battery.

In addition, the power supply apparatus according to the present invention can perform real-time management by using a control unit or a remote power monitoring unit, and can reduce unnecessary power consumption by activating or deactivating each PSU according to server usage amount. If the input voltage is unstable, the input power of the relay is switched and the input voltage is monitored for a certain period of time after the change. When the relay is returned to the normal state, the transferred power is returned to the original state.

FIG. 5 is a circuit diagram showing an instantaneous power supply unit according to an embodiment of the present invention. FIG. 6 is a detailed circuit diagram of an instantaneous power supply unit. FIG. Fig.

As shown in FIG. 5, for example, the instant power supply unit 350 may be connected in series with a supercapacitor. Alternatively, the instant power supply unit 350 may be detachably connected to a package having a predetermined capacity to facilitate a replacement operation. Since the super capacitor can be burned out when the output voltage is higher than the magnetic voltage proof, the super capacitor can be connected in series to be higher than the output voltage. Meanwhile, the instantaneous power supply unit 350 may include a diode or FET 510 to prevent the PSU from affecting the charging of the supercapacitor.

5, the instantaneous power supply unit 350 includes a separate rectifying circuit for charging the super capacitor with the direct current power and a rectifying circuit and a constant voltage circuit for rectifying the direct current power from the alternating current power supply, can do. Accordingly, the instantaneous power supply unit 350 can charge the normal capacitor to the supercapacitor even if a problem occurs in any one of the input AC power supplies. The reason for using a separate power source instead of charging the super capacitor by the DC power source is that the characteristics of the supercapacitor has a short value at the time of initial power-on, so if the output is directly connected, the phenomenon that the power output of the PSU is short- And the output is not normally output. In order to compensate for this, the instantaneous power supply unit 350 uses the electric switch between the supercapacitor and the PSU output to charge the supercapacitor to a certain level through the ac power supply. can do.

On the other hand, when the input power is switched, a load phenomenon instantaneously occurs as in the D region of the graph shown in FIG. 7, resulting in a dip phenomenon. In order to compensate for this, the instantaneous power supply unit may instantaneously supply the DC power supplied from the lithium polymer battery or the capacitor instead of the DC power supply when the input power is switched.

8 is a diagram for explaining a process of supplying DC power to a plurality of servers provided in a rack in a power supply apparatus according to an embodiment of the present invention.

The 220 V AC power input from the plurality of source sources to the power supply apparatus 100 may be multiplexed through the relay 120 and supplied to the DC power supply unit 130. The relay 120 may selectively control ON / OFF of a plurality of AC power inputs or may multiplex an AC power input using a switching method.

The DC power supply unit 130 converts the AC power supplied through the relay 120 to DC power. For example, the DC power supply 130 may convert the AC power to a DC power of approximately 12V / 100A. The DC power supply unit 130 may include a plurality of PSUs that convert AC power to DC power.

The integrator 360 integrates the converted DC power from the DC power supply 130. For example, the integrator 360 may be connected to the DC power supply 130 through a bus bar, Lt; / RTI > Meanwhile, the integrator 360 may distribute the DC power supplied from the DC power supply 130 to a DC power source of approximately 24 V or 12 V for stable power supply.

The rack 800 may include at least one server 810 provided with DC power supplied through the integrator 360. The server 810 may be connected to the power supply 100 through an interface board 820 as shown in FIG.

The interface board 820 supplies the DC power provided through the integrator 360 to the server 810, which can simplify a connection line such as a cable. The integrator 360 and the interface board 820 may be directly connected by a one-to-one cable.

Also, since the interface board 820 includes an inrush current protection circuit, it is possible to prevent a voltage enhancement phenomenon due to an inrush current generated in the server 810 upon initial power application, Can be applied.

On the other hand, the interface board 820 may include a noise removing circuit.

For example, the power supply apparatus 100 according to the present invention can supply DC power to a plurality of servers 810 installed in the rack 800 using an interface board 820 suitable for each server 810 . That is, the power supply apparatus 100 according to the present invention can directly supply DC power to a general server due to the use of the interface board 820, so that various kinds of servers 810 are provided in the rack 800 Can be added.

The rear surface of the interface board 820 may include an insulator such as an epoxy series. The insulator (not shown) of the interface board 820 serves as a kind of cover for securing safety against high current and guides the interface board 820 to be connected to an inner main board (not shown) of the server 810 So that the interface board 820 can be securely and accurately connected.

Meanwhile, the power supply apparatus 100 according to the present invention may include an instantaneous power supply unit (not shown for convenience, but 350 of FIG. 3). As described above, the instantaneous power supply unit may be implemented as a supercapacitor connected to the DC power supply unit 130. The instantaneous power supply unit 350 can be charged with DC power and can supply power to each server 810 in an emergency.

Specifically, the instantaneous power supply unit is generated when the load of the DC power supply unit 130 instantaneously rises so that the DC power supply unit 130 can not immediately respond to the instantaneous change, DIP phenomenon can be compensated. At this time, the instantaneous power supply unit may supply DC power to the interface board 820 to ensure stable power supply.

In addition, the instantaneous power supply unit may be configured in such a manner that, when a failure occurs in any one of the AC power sources supplied from a plurality of source sources, the alternating current power supply unit may generate a stable alternating- DC power can be supplied in response to instantaneous power failure due to the switching time delay. That is, if an abnormal power supply such as a momentary power failure occurs, the instantaneous power supply unit can supply the power to the server 820 in an emergency and stabilize the power supply.

FIG. 9 is an exemplary view showing a state where a power supply device is installed in a rack according to an embodiment of the present invention, and FIG. 10 is a perspective view showing a power supply device according to an embodiment of the present invention.

As shown in FIG. 9, one power supply 100 may be stored in one rack 800. The power supply 100 may include a relay 120, a DC power supply 130, an integrator 360, and the like, and the integrator 360 may be connected to the DC power supply 130 DC power can be supplied to each server 810 installed in the rack 800 through the interface board 820. [

At this time, the power supply apparatus 100 may be located at the upper portion or the central portion of the rack 800. For example, when the power supply air apparatus 100 is located at the center of the rack, as shown in FIG. 9, between the top of the plurality of servers 810 installed in the rack 800 and the servers located at the bottom of the rack, A voltage drop of ~ 0.3V may occur. To compensate for this, the DC power supply 130 may increase the output of the DC power supply by 0.3V.

Meanwhile, when one rack 800 includes 20 servers 810 having a power capacity of 20A, the rack 800 needs a total power capacity of 400A. Accordingly, when the 20 servers 810 are initially operated, they can operate at an 80% line of 500A, which is the capacity of the DC power supply supplied from the DC power supply unit 130. [ For example, if the DC power supply 130 includes five PSUs providing a DC power capacity of 200 A, even if one of the PSUs malfunctions, the remaining four PSUs may provide a DC power capacity of 400 A So that power can be stably supplied to the server 810. Further, in a normal operation state, assuming that one of the plurality of servers 810 is about 12A, 20 servers 810 are required to have a DC power capacity of about 240A, so that the DC power supply 130 Even when the DC power supply capacity of 400 A is supplied, a load operation of about 60% is possible. Therefore, the power supply device according to the present invention can secure the stability of the power supply due to such a configuration.

10, a power supply device according to the present invention may include a relay 120, a DC power supply 130, a controller 140, a momentary power supply 350, And can be stored in a rack, respectively.

11 is a circuit diagram showing an interface board in an embodiment of the present invention.

The interface board supplies the DC power to the server while controlling the inrush current generated from the server to be minimized when the initial power is applied to the server to prevent the dip phenomenon from occurring due to the inrush current, .

For this, as shown in FIG. 11, a switch may be added to the input terminal so that the power is cut off when a trouble occurs at the final output terminal. In addition, a power conversion unit may be added so that an auxiliary power source (for example, 3.3V or the like) may be further stably supplied to the server.

The interface board connector can be connected to the server.

12 is a perspective view showing an interface board according to an embodiment of the present invention.

12, the interface board includes an input unit 1210 for receiving a DC power from an external power supply for converting an AC power to a DC power, and an input unit 1210 for receiving the input DC power from a server And may be directly connected to each of the servers arranged in a rack unit instead of the conventional PSU. At this time, the interface board can be manufactured differently depending on the DC capacity of the server and the connection method with the server.

The interface board may include an inrush current protector 1230 for preventing a voltage enhancement phenomenon due to an inrush current generated in the server when initial power is applied to the server. In this case, the inrush current protection unit 1230 may include a fuse for blocking current when a current higher than the inrush current is input.

Although not shown in FIG. 12, the interface board may include a switch that cuts off power when a current is input through the supply unit 1220. In addition, the interface board may include a power conversion unit for converting the DC power supplied from the external power supply unit into a predetermined voltage, so that the auxiliary power may be further stably supplied to the server.

On the other hand, the interface board may include a bus bar 1240 for ensuring heat dissipation and ground (GND) assurance of the inrush current prevention circuit, and the back surface of the interface board may be formed of an epoxy series heat conductor. The interface board may also include a status indicator LED to check and adjust the power to the server.

13 is a flowchart showing a power supply method in an embodiment of the present invention.

The power supply unit supplies stable DC power in units of racks arranged in the data center and receives AC power from a plurality of different source sources and multiplexes them in order to maintain the power efficiency at the best condition (1310).

At this time, the monitoring unit of the power supply apparatus monitors the AC power supplied from the source (1320). For example, when the input power of the power supply unit is duplicated by the first AC power and the second AC power, the monitoring unit senses the voltage and current of the first AC power and the voltage and current of the second AC power respectively, And transmit the sensing value to the control unit.

If the control unit of the power supply unit detects that a power failure occurs in the first AC power or the second AC power based on the sensing value received from the monitoring unit (1330), the control unit of the power supply unit switches the supply of the AC power to the source of the normal operation Generates a switching signal and transmits it to the relay so that the AC power is supplied stably (1340). The relay switches the AC power supplied from the AC power supply unit to either the first source or the second source according to the switching signal transmitted from the control unit, and may be a non-contact relay, for example.

For example, when an unstable AC power source is input from the first source source for a predetermined time or longer (for example, 50 ms or longer), the control unit of the power source supply unit switches the supply of the AC power source from the first source circle to the second source circle And when the unstable AC power source is inputted from the second source circle for a predetermined time or more, the supply of the AC power source can be switched from the second source circle to the first source circle.

If the AC power supply is switched, the instantaneous input voltage is interrupted and the PSU stops operating, causing a dip phenomenon in the output power supply. In order to prevent this, the instant power supply of the power supply unit may supply the DC power charged to the capacitor or the lithium polymer battery to the server when the supply of the AC power is switched. A capacitor, a lithium polymer battery, or the like may be influenced by a DC power supplied to the PSU, the instantaneous power supply unit may use at least one of a diode and a field effect transistor (FET).

On the other hand, the control unit can maintain the switched state for a predetermined time (for example, 5 minutes to 10 minutes) after switching the supply of the AC power, and monitor the AC power supplied from the AC power supply unit. If it is confirmed that AC power is normally input again from the source source from which the unstable AC power is input as a result of the monitoring, the control unit can switch the power supply to the original state again.

The AC power supplied through the above process may be converted into DC power through the DC power supply unit and supplied to a plurality of servers arranged in the rack (1350). At this time, the DC power supply unit may include a plurality of PSUs that convert the supplied AC power into DC power. The PSUs may be connected in parallel to supply DC power to a plurality of servers.

The DC power supplied from the DC power supply unit may be distributed and supplied to a plurality of servers arranged in the rack after being integrated through the integrator. The interface board that connects the power supply unit and the server can prevent the voltage increase due to the inrush current generated in the server when the initial power is applied, thereby supplying power to each component of the server. The interface board may be applied to a server based on conventional DC power transmission.

On the other hand, the operation status of a plurality of servers installed in the rack can be monitored by using the remote power monitoring unit. The remote power monitoring unit may activate or deactivate a plurality of PSUs included in the DC power supply unit, depending on the operating state of the server.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

Claims (6)

An input unit for receiving DC power from an external power supply unit for converting AC power to DC power; And
A supply unit for supplying the input DC power to a server arranged in a rack,
Lt; / RTI >
An interface board connected to a plurality of servers arranged in a rack unit. The method according to claim 1,
Further comprising an inrush current protector for preventing a voltage increase due to an inrush current generated in the server when initial power is applied to the server. 3. The method of claim 2,
Wherein the inrush current protector comprises:
And a fuse for blocking current when a current higher than the inrush current is input. The method according to claim 1,
Further comprising a switch for shutting off power when a current is inputted through the supply unit. The method according to claim 1,
Further comprising: a power conversion unit converting the DC power supplied from the external power supply unit to a predetermined voltage. The method according to claim 1,
Wherein the back surface of the interface board includes an epoxy-based conductive material.

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