KR20170003130A - Battery backup unit - Google Patents

Abstract

The present invention relates to a battery backup unit capable of monitoring a main control unit and detecting a power failure of an external power supply using a watchdog built in a main control unit (MCU).
For example, a battery backup unit connected to a power supply line of a server operated by receiving power from an external power source and supplying power to the server when an external power source is out of power, the battery backup unit comprising at least one battery cell Battery; A charging element for charging the battery; a discharging element for discharging the battery; And a battery management system for controlling the charging and discharging of the battery, wherein the battery management system includes a main control unit having a watchdog that monitors an internal voltage supplied to the main control unit and monitors a power failure of the external power supply .

Description

A battery backup unit

The present invention relates to a battery backup unit.

 In general, a data storage system and devices for storing a large amount of data, such as a server, include a battery backup unit that provides a backup power in case the main power is cut off. Such a battery back-up unit includes a battery consisting of one or more battery cells charged by a main power source.

The battery backup unit supplies power to the server through the charged battery to prevent data loss when the main power supplied to the server fails to supply power to the server due to power failure or the like. Therefore, the battery backup unit quickly detects a situation where the main power is cut off and supplies power to the server. On the other hand, the battery backup unit may use a separate voltage detect IC to detect a situation where the main power is cut off. However, such a voltage detect IC has a problem that the accuracy is somewhat lower and the cost is increased.

The present invention provides a battery backup unit that monitors a main control unit using a watchdog built in a main control unit (MCU) and can detect a power failure of an external power source.

A battery backup unit connected to a power supply line of a server operated by an external power supply according to the present invention to supply power to the server when an external power supply is interrupted, the battery backup unit comprising at least one battery cell Batteries included; A charging element for charging the battery; a discharging element for discharging the battery; And a battery management system for controlling the charging and discharging of the battery, wherein the battery management system includes a main control unit having a watchdog that monitors an internal voltage supplied to the main control unit and monitors a power failure of the external power supply .

Also, the battery management system may include a charging / discharging control unit for controlling the charging device and the discharging device; A voltage detector for detecting a voltage of the battery; A current detector for detecting a current of the battery; A power supply unit for converting the external power supply to an internal voltage necessary for the main control unit and supplying the internal power supply to the main control unit; A reset control unit for resetting the battery management system; And a main control unit for controlling the charge / discharge control unit and the reset control unit.

The watchdog may also be electrically connected to the positive terminal of the external power source via a distribution resistor.

The watchdog may further include an internal power supply monitoring unit monitoring an internal voltage supplied from the power supply unit to monitor whether the main control unit operates normally or not; An external power monitoring unit monitoring an external voltage of an external power source input through the distribution resistor to monitor a power failure of the external power source; A timer for setting a first reference time for comparing the duration of the output signal of the internal power monitoring unit and a second reference time for comparing the duration of the output signal of the external power monitoring unit; A reset signal generator for receiving information from the internal power monitoring unit and the timer and generating a reset signal; And a discharge signal generator for receiving the information from the external power monitoring unit and the timer and generating a discharge signal.

The internal power monitoring unit may compare an internal voltage input to the main control unit with a first reference voltage, and may transmit an output signal to the reset signal generating unit if the internal voltage is less than a first reference voltage.

The reset signal generator may determine that the main controller does not operate normally if the duration of the output signal received from the internal power monitor is greater than the first reference time and may generate a reset signal and transmit the reset signal to the reset controller have.

The reset control unit may reset the battery management system when the reset signal is received from the reset signal generating unit.

The external power monitoring unit may compare an external voltage input through the distribution resistor with a second reference voltage and may transmit the output signal to the discharge signal generating unit if the external voltage is less than the second reference voltage.

When the duration of the output signal from the external power monitoring unit is greater than the second reference time, the discharge signal generating unit may determine that the external power supply is out of order, generate a discharge signal, and transmit the generated discharge signal to the charge / discharge control unit .

When the discharge signal is received from the discharge signal generator, the charge / discharge controller turns on the discharge element to discharge the battery, and the server can receive power from the battery.

The battery backup unit according to an embodiment of the present invention includes a main control unit with a watchdog, and the watchdog is electrically connected to a plus terminal of an external power source through a distribution resistor. Accordingly, the battery backup unit according to an embodiment of the present invention monitors the internal voltage supplied to the main control unit and the voltage of the external power supply at the same time, monitors whether or not the main control unit normally operates, Can be monitored.

1 is a block diagram illustrating a state in which a battery backup unit according to an embodiment of the present invention is connected to a server.
2 is a block diagram illustrating a battery backup unit according to an embodiment of the present invention.
3 is a block diagram illustrating the watchdog shown in FIG.
4 is a diagram showing a method of operating the watch dog.
5A and 5B are flowcharts illustrating a method of operating a watchdog.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

Here, parts having similar configurations and operations throughout the specification are denoted by the same reference numerals. In addition, when a part is electrically connected to another part, it includes not only a direct connection but also a case where the other part is connected to the other part in between.

1 is a block diagram illustrating a state in which a battery backup unit according to an embodiment of the present invention is connected to a server. 2 is a block diagram illustrating a battery backup unit according to an embodiment of the present invention. 3 is a block diagram illustrating the watchdog shown in FIG. 4 is a diagram showing a method of operating the watch dog. 5A and 5B are flowcharts illustrating a method of operating a watchdog.

1 to 4, a battery backup unit 100 according to an embodiment of the present invention includes a battery 110, a charging device 120, a discharging device 130, a sensor resistor 140, (BMS: Battery Management System) 150. The battery backup unit 100 according to an embodiment of the present invention is an auxiliary power supply unit and is connected to the server 10 as shown in FIG. Here, the server 10 refers to a computer in which a plurality of computers are connected to a single computer by a communication line, and information stored in common is stored, or programs in which a large amount of computer resources are used are collected. The server 10 is normally operated by receiving power from the external power source 20 and can receive power from the battery backup unit 100 when a power failure occurs to prevent data from being lost. Here, the external power source 20 may be a DC power source. That is, when a problem occurs in the external power source 20 connected to the power source line of the external power source 30 and supplying power to the server 10, the battery backup unit 100 according to an embodiment of the present invention may include a server 10 to prevent data from being lost.

The battery 110 may include at least one battery cell B1, B2, and B3 and may be charged or discharged at a constant voltage. The battery 110 has a plus terminal B + and a minus terminal B-. The number of battery cells and the connection relationship (serial or parallel) of the battery cells are not limited to the number of the battery cells B1, B2, and B3, As shown in FIG. The battery 110 is charged with power supplied from an external power source 20. The battery 110 supplies power to the server 10 and the battery management system 150 when an external power source 20 connected to the server 10 is out of order. The battery 110 is connected to an external power source 20. The positive terminal B + of the battery 110 is connected to the positive terminal P + of the external power source 20 and the negative terminal B- of the battery 110 is connected to the negative terminal of the external power source 20. [ (P-). The charging device 120 and the discharging device 130 are connected between the positive terminal B + of the battery 110 and the positive terminal P + of the external power source 20.

The charging device 120 and the discharging device 130 are connected in series between the positive terminal B + of the battery 110 and the positive terminal P + of the external power source 20 to charge or discharge the battery 110 . Each of the charging device 120 and the discharging device 130 includes a field effect transistor (FET) and a parasitic diode (D). That is, the charging element 120 includes FET1 and D1, and the discharging element 130 includes FET2 and D2. The connection direction between the source and the drain of the field effect transistor FET1 of the charging element 120 is set in the opposite direction to the field effect transistor FET2 of the discharging element 130. [ The field effect transistor FET1 of the charging element 120 is connected to limit the current flow from the external power source 20 to the battery 110 while the field effect transistor FET2 of the discharging element 130 is connected to the battery 110. [ To limit the flow of current from the server (20) to the server (20). That is, when the charging device 120 is turned on, the external power source 20 is supplied to the battery 110 to charge the battery 110. When the discharging device 130 is turned on, the battery 110 is discharged And supplies power to the server (20). Here, the field effect transistors (FET1 and FET2) of the charging element 120 and the discharging element 130 are switching elements, and the electric elements performing other kinds of switching functions can be used.

The sensor resistor 140 is connected between the negative terminal B- of the battery 110 and the negative terminal P- of the external power supply 20. Both ends of the sensor resistor 140 are connected to the current detection unit 180 of the battery management system 150. Accordingly, the current detector 180 can detect the charge / discharge current of the battery 110 by checking the voltage value at both ends of the sensor resistor 140 and the resistance value of the sensor resistor 140. Therefore, the sensor resistor 140 transmits information on the charging current or the discharging current of the battery 110 to the current detector 180.

The battery management system 150 includes a charge / discharge control unit 160, a voltage detection unit 170, a current detection unit 180, a power supply unit 190, a reset control unit 200, and a main control unit (MCU) .

The charge and discharge control unit 160 is connected to the charging device 120 and the discharging device 130 and operates the charging device 120 and the discharging device 130 under the control of the main control unit 210. For example, when the external power supply 20 is being supplied to the server 10, the charging / discharging control unit 160 turns on the charging device 120 according to a command of the main control unit 210 to charge the battery 110 Can be charged. When the external power supply 20 has a problem such as a power failure, the charge / discharge control unit 160 turns on the discharge element 130 according to a command of the main control unit 210 to discharge the battery 110, 10).

The voltage detector 170 is connected to the battery cells B1, B2 and B3 to detect the voltage of the battery 110 and transmit the detected voltage to the main controller 210. [ The current detector 180 is connected to the sensor resistor 140 to detect a charging / discharging current of the battery 110, and transmits the detected charging / discharging current to the main controller 210.

The power supply unit 190 supplies power to the main control unit 210. The power supply unit 190 is connected to the plus terminal P + of the external power supply 20 and supplies power to the main control unit 210 through the positive terminal P + V _MCU ) and supplies it to the main control unit 210. The power supply unit 190 may be a regulator.

The reset controller 200 resets the battery management system 150 in response to an instruction from the main controller 210. The reset controller 200 resets the battery management system 150 when the battery management system 150 does not operate normally so that the battery management system 150 can maintain normal operation.

The main controller 210 receives the voltage and current information of the battery 110 from the voltage detector 170 and the current detector 180 and commands the charge and discharge controller 160 to charge the charge element 120 and the discharge element Lt; RTI ID = 0.0 > 130 < / RTI >

In addition, the main control unit 210 includes a watchdog 220 for monitoring whether the main control unit 210 is operating properly. The watchdog 220 monitors the internal voltage V _MCU supplied to the main control unit 210 and monitors the external power supply 10 supplied to the server 10. Generally, a watchdog is one of the functions built in the main control unit, and monitors the operation of the main control unit. In addition, to monitor the power failure of the external power source, a separate detect IC was used to monitor the status of the external power source. However, in the present invention, the watchdog 220 is connected to the positive terminal P + of the external power supply 20 through the distribution resistors R1 and R2 to monitor the main control unit 210, It was also possible to monitor the power failure.

3, the watchdog 220 includes an internal power monitoring unit 221, an external power monitoring unit 222, a timer 223, a reset signal generating unit 224, and a discharge signal generating unit 225 .

The internal power supply monitoring unit 221 monitors whether the internal voltage V _MCU supplied from the power supply unit 190 is properly supplied to the main control unit 210. [ More specifically, referring to Figure 4, the internal power monitoring unit 221 by comparing the internal voltage (V _MCU) and a first reference voltage (V _REF1) to be supplied to the main control unit 210, the internal voltage (V _MCU Is less than the first reference voltage V _REF1 , the output signal is transmitted to the reset signal generator 224. [ Here, the first reference voltage V _REF1 is stored in advance in the internal power monitoring unit 221.

The external power monitoring unit 222 monitors whether the external power supply 20 is properly supplied to the server 10. That is, the external power monitoring unit 222 monitors the external power source 20 for power failure. The external power monitoring unit 222 is electrically connected to the positive terminal P + of the external power source 20 through the distribution resistors R1 and R2. That is, the external power source 20 is not directly input to the external power source monitoring unit 222, but the external voltage P _in is divided by the distribution resistors R1 and R2. For example, when an external power supply 20 is abnormally generated, such as a power failure, an external voltage P _in distributed by the distribution resistors R1 and R2 is also anomaly. 4, the external power monitoring unit 222 compares the divided external voltage P _in with the second reference voltage V _{REF2 to} determine whether the divided external voltage P _in is greater than or equal to the second reference voltage V _REF2 , (V _REF2 ), it is transmitted to the discharge signal generating unit 225. [ The second reference voltage V _REF2 is preset in the external power supply monitoring unit 222. Here, the second reference voltage V _REF2 may be set by a user.

The timer 223 is used to determine how long the internal voltage V _MCU supplied from the internal power monitoring unit 221 to the main control unit 210 is less than the first reference voltage V _REF1 A first reference time is set. The internal voltage V _MCU supplied to the main controller 210 may be instantaneously lowered below the first reference voltage V _REF1 and returned to the original state. However, if a reset signal is generated in such a case, the battery management system 150 operates inefficiently. Therefore, a first reference time is set in the timer 223 to prevent this.

A second reference time for determining whether the distributed external voltage P _in is less than the second reference voltage V _REF2 is set _in the timer 223. The divided external voltage P _in may instantaneously be lower than the second reference voltage V _REF2 and then return to its original state. However, if the battery 110 is discharged due to a power failure, the battery backup unit 100 operates abnormally. Therefore, a second reference time is set in the timer 223 to prevent this. Here, the first reference time and the second reference time may be set by the user.

The reset signal generator 224 receives information from the internal power monitoring unit 221 and the timer 223 and generates a reset signal. Specifically, the reset signal generator 224 generates a reset signal for a period of time during which the internal voltage V _MCU supplied from the internal power monitoring unit 221 to the main controller 210 remains less than the first reference voltage V _REF1 (t1) is longer than the first reference time set in the timer 223, the main controller 210 determines that the main controller 210 does not normally operate, generates a reset signal, and transmits the reset signal to the reset controller 200. [

The discharge signal generator 225 receives information from the external power monitor 222 and the timer 223 and generates a discharge signal. Specifically, the discharge signal generating unit 225 generates a discharge signal having a time t2 during which the external voltage P _in , which is distributed from the external power monitoring unit 222, is less than the second reference voltage V _REF2 , If it is longer than the second reference time, it is determined that it is a blackout, and a discharge signal is generated and transmitted to the charge / discharge control unit 160.

A method of operating the watchdog 220 of the main control unit 210 in the battery management system 150 will now be described.

5A, the internal power monitoring unit 221 compares the internal voltage V _MCU input to the main control unit 210 with the first reference voltage V _REF1 (S1) _MCU ) is less than the first reference voltage (V _REF1 ), the output signal is transmitted to the reset signal generator 224. When the reset signal generator 224 receives the output signal from the internal power monitor 221, the reset signal generator 224 generates a reset signal for a time t1 during which the internal voltage V _MCU remains lower than the first reference voltage V _REF1 , 223) (S2). ≪ / RTI > The reset signal generator 224 operates normally if the time t1 during which the internal voltage V _MCU remains below the first reference voltage V _REF1 is greater than the first reference time It generates a reset signal and transmits it to the reset control unit 200 (S3). The reset controller 200 receives the reset signal and resets the battery management system 150 (S4).

5B, the external power monitoring unit 222 compares the external voltage P _in distributed through the distribution resistors R1 and R2 with the second reference voltage V _REF2 (S11) And transmits the output signal to the discharge signal generating unit 225 when the external voltage P _in is smaller than the second reference voltage V _REF2 . The discharge signal generator 225 receives the output signal from the external power monitoring unit 222 and outputs the discharge signal to the discharge signal generating unit 225 at a time t2 during which the divided external voltage P _in is maintained to be less than the second reference voltage V _REF2 , Is greater than a second reference time set in the timer 223 (S12). The discharge signal generator 225 determines that a power failure has occurred when the time t2 during which the distributed external voltage P _in is less than the second reference voltage V _REF2 is greater than the second reference time, And transmits the signal to the charge / discharge control unit 160 (S13). The charge / discharge control unit 160 receives the discharge signal and turns on the discharge element 130 (S14). Accordingly, the battery 110 is discharged to supply power to the server 10 and the battery management system 150.

As described above, the battery backup unit 100 according to an embodiment of the present invention includes a main control unit 210 having a watchdog 220 therein, and the watchdog 220 is connected to the distribution resistors R1 and R2 To the positive terminal (P +) of the external power supply (20). The watchdog 220 simultaneously monitors the internal voltage V _MCU supplied to the main control unit 210 and the voltage P _in of the external power supply 20 to determine whether the main control unit 210 operates normally The external power supply 20 can be monitored for the presence or absence of a power failure.

It is to be understood that the present invention is not limited to the above-described embodiment, and that various modifications and changes may be made without departing from the scope of the present invention as defined in the appended claims. 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.

10: Server 20: External power source
100: Battery backup unit (BBU) 110: Battery
120: charging element 130: discharging element
140: Sensor resistance 150: Battery management system (BMS)
160 charge / discharge control unit 170 voltage detection unit
180: current detection unit 190:
200: reset control unit 210: main control unit (MCU)
220: Watchdog 221: Internal power monitoring unit
222: External power monitoring unit 223: Timer
224: Reset signal generator 225: Discharge signal generator

Claims (10)

A battery back-up unit connected to a power line of a server which receives power from an external power source and supplies power to the server when the external power source is out of power,
The battery backup unit
A battery comprising at least one battery cell;
A charging element for charging the battery; a discharging element for discharging the battery; And
And a battery management system for controlling charging and discharging of the battery,
Wherein the battery management system includes a main control unit having a watchdog to monitor an internal voltage supplied to the main control unit and to monitor a power failure of the external power supply. The method according to claim 1,
The battery management system
A charging / discharging control unit for controlling the charging device and the discharging device;
A voltage detector for detecting a voltage of the battery;
A current detector for detecting a current of the battery;
A power supply unit for converting the external power supply to an internal voltage necessary for the main control unit and supplying the internal power supply to the main control unit;
A reset control unit for resetting the battery management system; And
And a main control unit for controlling the charge / discharge control unit and the reset control unit. 3. The method of claim 2,
Wherein the watchdog is electrically connected to a positive terminal of the external power source via a distribution resistor. The method of claim 3,
The watchdog
An internal power monitoring unit monitoring an internal voltage supplied from the power supply unit to monitor whether the main control unit operates normally;
An external power monitoring unit monitoring an external voltage of an external power source input through the distribution resistor to monitor a power failure of the external power source;
A timer for setting a first reference time for comparing the duration of the output signal of the internal power monitoring unit and a second reference time for comparing the duration of the output signal of the external power monitoring unit;
A reset signal generator for receiving information from the internal power monitoring unit and the timer and generating a reset signal; And
And a discharge signal generator for receiving the information from the external power monitoring unit and the timer and generating a discharge signal. 5. The method of claim 4,
Wherein the internal power monitoring unit compares an internal voltage input to the main control unit with a first reference voltage and transmits an output signal to the reset signal generating unit when the internal voltage is less than a first reference voltage. unit. 6. The method of claim 5,
The reset signal generator determines that the main controller does not operate normally if the duration of the output signal from the internal power monitor is greater than the first reference time and generates a reset signal and transmits the reset signal to the reset controller A battery backup unit. The method according to claim 6,
Wherein the reset control unit resets the battery management system when receiving a reset signal from the reset signal generation unit. 5. The method of claim 4,
Wherein the external power monitoring unit compares an external voltage input through the distribution resistor with a second reference voltage and transmits an output signal to the discharge signal generating unit when the external voltage is less than a second reference voltage. Backup unit. 9. The method of claim 8,
Wherein the discharge signal generator determines that the external power source is out of order if the duration of the output signal received from the external power source monitoring unit is greater than the second reference time and generates a discharge signal and transmits the generated discharge signal to the charge / Battery backup unit. 10. The method of claim 9,
The charge / discharge control unit, when receiving the discharge signal from the discharge signal generation unit, turns on the discharge element to discharge the battery,
Wherein the server receives power from the battery.

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