[DESCRIPTION] [Invention Title]

UNINTERRUPTIBLE POWER SUPPLY WATCHDOG SYSTEM AND AUTO RECOVERY METHOD USING THE SAME

[Technical Field]

The present invention relates to the Uninterruptible Power Supply (UPS), more particularly, to the UPS watchdog system and auto recovery method using the same, which determines whether a failure is temporary or not in case a power supply path is switched to a bypass line due to an unusual condition of UPS, and rapidly recovers the disabled power supply path to the normal power line in case a corresponding failure is temporary.

[Background Art]

Typically, the UPS is designed with a view to steadily supplying the power having a constant voltage and frequency to a load even when a power failure is occurred in the common power source without notice or an input power is not constant. Fig. 1 is a drawing that shows the configuration of an uninterruptible power supply (UPS) of the related art.

In a normal mode, in case an alternating current (AC) power is inputted to UPS through a switch CBl, the inputted alternating current

(AC) power is transformed from a rectifier 1 to a direct current (DC) power, and then, it is supplied to an inverter 2 and is charged in a

battery 3. The inverter 2 converts again the output power of the rectifier 1 into the alternating current to provide to a load. At this time, an output breaker CB3 is ON, while the switch STS, CB4 of a bypass module 4 is OFF. At this time, in case the input power is blocked due to the power failure, the DC power which is charged in the battery 3 is transformed into the AC power by the inverter 2 and the transformed AC power is supplied to a load. The path in which the input power or the DC power of the battery 3 is supplied through the inverter 2 is called as normal power line. However, in case a malfunction of the inside of UPS or a momentary short circuit of the outside of UPS is generated while the input power is normally inputted, the electric power supply through the normal power line may be impossible. In this case, the control means (not shown) of the UPS blocks off the normal power line by making the output breaker CB3 to be OFF. The control means (not shown) changes the power supply path from the normal power line to the bypass line by making the switch STS, CB4 of the bypass module 4 to be ON. Accordingly, the input power is immediately supplied to a load through the bypass line. At this time, the switch CB4 of the bypass module 4 is applied with ON signal simultaneously with the static switch STS, and immediately being turned on after the static switch STS is turned on.

In case the power supply path is switched to the bypass line, a user checks out the unusual condition of UPS. When the check out is completed, the electric power supply is manually changed as 'inverter

first ¹ . Therefore, the power is supplied again to a load through the normal power line.

In case of conventional UPS, an artificial operation of a user is required in order that the power supply path is switched again to the normal power line after switching to the bypass line.

Of course, the switching to the bypass line in the UPS can be generated when a really important failure is generated in the normal power line. However, it also can be generated by a temporary control failure of the inside of UPS or a temporary external load short circuit. After the switching to the bypass line, the process of checking out by a user and manual switching to the normal power line should be completed. Therefore, there is a problem in that too much time is required for the recovery procedure even when a temporary control failure or a temporary external load short circuit is occurred. Furthermore, if the failure of the bypass line is generated during such recovery procedure, there is a problem that the power supply for the load is completely blocked.

[Disclosure] [Technical Problem]

Accordingly, an object of the present invention is to solve at least the problems and disadvantages of the related art. The object of the present invention is to provide a UPS apparatus capable of steadily supplying power by rapidly recovering to a normal power path in case a power supply path is switched to a bypass line due to a temporary

failure of UPS.

[Technical Solution]

In order to accomplish the object, according to an aspect of the present invention, provided is an UPS watchdog system that compulsively recovers a power supply path to a normal power line as much as a preset number, in case the power supply path of UPS is switched from the normal power line to a bypass line.

According to another aspect of the present invention, provided is an UPS watchdog system comprising an inverter-on generating unit that generates an inverter-on signal for turning on an inverter of an

UPS in case a bypass signal is generated; a recovery signal generating unit that generates a recovery signal for changing the power supply path from the bypass line to the normal power line according to the bypass signal, the inverter-on signal and a recovery stop signal; a counter unit that outputs an accumulation count signal of the magnitude corresponding to the number of occurrence of the recovery signal; a counting comparison unit that generates a counting comparison signal in case the magnitude of the accumulation count signal is greater than a preset reference value; and a recovery stop unit that controls the generation of a reset signal for stopping the recovery stop signal and the counting of the counter unit according to the counting comparison signal and the accumulation count signal.

According to still another aspect of the present invention, provided is an UPS auto recovery method comprising a first step of

determining whether a power supply path of an UPS is switched from a normal power line to a bypass line; a second step of turning on an inverter of UPS and switching again the power supply path to the normal power line, in case the power supply path is switched to the bypass line; and a third step of repeatedly performing the first and the second step until the number of switching to the bypass line reaches a preset number.

[Advantageous Effects] The present invention is to provide a UPS apparatus capable of steadily supplying power by rapidly recovering to a normal power path in case a power supply path is switched to a bypass line due to a temporary failure of UPS.

[Description of the Drawings]

Fig. 1 is a diagram showing the configuration of an uninterruptible power supply (UPS) of the related art.

Fig. 2 is a diagram showing the configuration of an UPS watchdog system according to the present invention. Fig. 3 is a timing diagram showing the auto recovery operation according to the present invention, in case the failure of UPS is temporary.

Fig. 4 is a timing diagram showing the auto recovery operation process according to the present invention, in case the recovery signal SRECO is consecutively generated three times.

Fig. 5 is a timing diagram showing the auto recovery operation process according to the present invention, in case the recovery signal SRECO is consecutively generated five times.

[Best Mode]

The embodiment of the present invention will be illustrated in detail with reference to attached drawings.

Fig. 2 is a diagram showing the configuration of an UPS watchdog system according to the present invention. The UPS watchdog system of Fig. 2 provides an inverter-on generating unit 10, a recovery signal generating unit 20, a counter unit 30, a counting comparison unit 40 and a recovery stop unit 50.

The inverter-on generating unit 10 outputs the inverter-on signal SINV- _O N for turning-on the inverter 2 when a preset given time elapses, in case a bypass signal S _UB for switching the power supply path from a normal power line to a bypass line is generated when the

UPS has a failure. That is, in case the power supply path is switched from the normal power line to the bypass line, the inverter-on generating unit 10 automatically generates an inverter-on signal S _IN V- _ON when the bypass signal Srre is generated in order to confirm whether such switching is caused by a temporary abnormal occurrence.

The recovery signal generating unit 20 outputs the recovery signal S _RE C _O for returning the power supply path from the bypass line to the normal power line according to the bypass signal S _UB , the inverter-on SINV-ON and the recovery stop signal SS _T OP which will be

mentioned later. Such recovery signal generating unit 20 includes a AND gate having the bypass signal S _UB , the inverter-on signal S _I NV- _O N and a recovery stop signal S _STOP as input signal.

The counter unit 30 outputs the accumulation count signal ScouN _T that counts the output signal of the recovery signal generating unit 20, that is, the number of occurrence of the recovery signal S _RECO and has the magnitude corresponding to the number of generating the recovery signal S _RE C _O - In the present embodiment, the up-counter is used as counter unit 30. The counter unit 30 increases the magnitude of the accumulation count signal S _COUNT as much as a predetermined amount (for example, IV) to output whenever the recovery signal S _RE CO is generated. For example, the counter unit 30 outputs the accumulation count signal S _CO U _NT which has the magnitude of IV when the recovery signal SREC _O is once generated, thereafter, when the recovery signal S _REC O is again generated, it outputs the accumulation count signal S _CO UNT which has the magnitude of 2 V (IV + IV). The counter unit 30 is to be reset when a normal operation signal SN _OR or a reset signal S _R S _T from the recovery stop unit 50 is applied, and discontinues a count. The counting comparison unit 40 outputs the counting comparison signal SCOU _NT - _COMP in case the magnitude of the accumulation count: signal SCOU _NT becomes larger than a reference value V _REF by comparing the magnitude of the accumulation count signal SCOUNT with a preset reference value V _REF - At this time, the magnitude of the reference value V _REF is settled depending on how

many times the watchdog system of the present invention implements repair operation in UPS in the abnormal occurrence. That is, since the magnitude of the accumulation count signal SCOUN _T is increased in proportion to the number of occurrence of the recovery signal S _RECO/ in case the reference value V _REF is set up between 2V ~ 3V, the counting comparison signal SCOUNT-CO _MP is generated when the recovery signal S _RECO is generated three times. This counting comparison unit 40 includes a comparator COMPl that outputs the counting comparison signal SCOUNT-CO _MP by comparing the magnitude of the accumulation count signal SCOUNT with the preset reference value V _REF , and a delay unit 42 that makes a time delay of the output signal SCOUNT-CO _MP of the comparator COMPl to output to the recovery stop unit 50.

The recovery stop unit 50 selectively stops the auto recovery operation of the present invention and the counting operation of the counter unit 30 according to the counting comparison signal S _COU N _T - _COMP - That is, when the counting comparison signal SCOUN _T -C _OMP is generated, the recovery stop unit 50 determines that the failure of UPS is not a temporary failure but a serious failure, and generates the recovery stop signal SSTOP- The recovery stop signal SSTOP is applied to the recovery signal generating unit 20 and stops the occurrence of the recovery signal S _RE CO- Further, the recovery stop unit 50 outputs the signal of high level to one of input terminal of the OR-gate and generates the reset signal S _RST - Furthermore, in case the recovery signal SRECO is not generated as much as the preset times for a predetermined time (for example, three minutes), the recovery stop

unit 50 determines this as a normal state and generates the reset signal SRST to stop the counting operation of the counter unit 30. This recovery stop unit 50 provides a J/K flip flop 52 that outputs the differential signal( β, ^Q ) according to the counting comparison signal Scou _NT -coMP _/ a comparator COMP2 that senses the generation of the accumulation count signal SCOUNT and changes it into a rectangular wave to output, a delay unit 54 that delays the output signal of the comparator COMP2 for a given time, and a OR-gate that outputs the reset signal S _RS τ when at least one signal is generated among any one differential signal(β) of J/K flip flop 52 and a delay count signal S _CO UNT- DLY from the delay unit 54.

Fig. 3 to Fig. 5 are a timing diagram showing the operation of watchdog system according to the present invention.

Fig. 3 is a timing diagram showing the auto recovery operation according to the present invention, in case the failure of UPS is temporary.

As mentioned in Fig. 1, in case the malfunction of the inside of

UPS or the external momentary short circuit is generated, the power supply through the normal power line may be impossible. In this case, the control means of UPS (not shown) blocks off the normal power line by turning off the output breaker CB3. Additionally, the control means (not shown) generates the bypass signal SUB in order to change the power supply path from the normal power line to the bypass line by turning on the switch STS, CB4 of the bypass module 4. In the meantime, the generated disorder is so serious that it

may require an additional check-out or step by a user. However, sometimes, it can be just a temporary problem (for example, the temporary disconnection of a temperature sensor, the temporary fan disorder, and so on), that it can be automatically restored sooner or later.

Therefore, in case the power supply path is switched to the bypass line, the watchdog system of the present invention firstly performs the automatic recovery operation of the present invention which will be explained in the below. Additionally, in case the auto recovery is not performed, the check-out and manual recovery by a user can be performed like a related art.

Hereinafter, the automatic recovery operation of the present invention will be described.

In case the bypass signal S _n - _B is generated, the inverter-on generating unit 10 generates the inverter-on signal SINV-ON immediately or after a predetermined time to turn on again the inverter 2. At this time, the bypass signal SUB and the inverter-on signal SINV-ON are also inputted to the recovery signal generating unit 20.

In case the inverter-on signal SINV-ON is generated, the inverter 2 performs the operation for the electric power supply, after being turned on again and passing through the initialization process. Such operation of the inverter 2 is identical with the operation when the inverter 2 is turned on again by the manual operation of the user of the related art. At this time, since the counting comparison signal SCOUNT-COMP is

not yet generated (low level), another input signal S _ST OP of the recovery signal generating unit 20 maintains the high level state as shown in Fig. 3.

Therefore, the recovery signal generating unit 20 generates the recovery signal S _RECO for changing again the power supply path from the bypass line to the normal power line with a high level since three input signals are all applied with a high level. UPS recovers the power supply path from the bypass line to the normal power line by the recovery signal S _RECO outputted in the recovery signal generating unit 20. And the recovery signal S _R E _CO is applied to the counter unit 30.

The counter unit 30 generates the accumulation count signal ScouNT having the magnitude of IV since the recovery signal SRECO was generated for the first time. As the accumulation count signal ScouNT having the magnitude of IV is smaller than the reference value SREF (for example, 2.5V), the counting comparison signal SCOUN _T -COM _P still maintains the low level state. Therefore, the recovery stop signal SS _T O _P still maintains the high level state. However, since the bypass signal S _UB is switched to the low level due to the generation of the recovery signal S _RE C _O , the recovery signal SR _E C _O is switched again to the low level. And the delay count signal S _C OUN _T - _DLY still maintains the low level state for the delay time by the delay unit 54, although the accumulation count signal SC _O UN _T is generated.

Like this, in case the disorder generated in the inverter 2 is still maintained although the inverter 2 is compulsively turned on again by the inverter on signal S _IN V- _ON and the power supply path is restored

again to the normal power line by the recovery signal S _RE CO, the UPS switches again the power supply path to the bypass line by generating again the bypass signal Srre-

And then, as described above, the inverter-on generating unit 10 generates again the inverter-on signal S _I NV-ON, and, accordingly, as shown in Fig. 3, the recovery signal generating unit 20 generates again the recovery signal SRECO- That is, the recovery signal S _RE co is generated twice.

As the recovery signal S _RE co is generated again, the counter unit 30 increases the magnitude of the accumulation count signal S _COUNT to

2V and outputs. However, being the accumulation count signal S _CO U _NT of 2V is also smaller than the reference value S _REF (for example, 2.5V), the counting comparison signal S _COUNT - _COMP still maintains the low level state. Accordingly, the recovery stop signal SS _T O _P still maintains the high level state. However, since the bypass signal S _UB is switched to the low level due to the generation of the recovery signal S _RECO/ the recovery signal S _RE co is switched again to the low level.

At this time, in case the disorder generated in the UPS is temporary and is automatically restored, the UPS normally operates again. For example, in Fig. 2, in case the contact signal S _NOR of the temperature sensor is normally generated again, the counter unit 30 is reset by the contact signal S _NOR and the counting operation is interrupted.

In Fig. 2, the counter unit 30 is reset in case the contact signal SNO _R of the temperature sensor is generated. However, in case the

power supply through the normal power line is possible although the contact signal SN _OR of the temperature sensor is not continuously generated, the counting operation does not need to be continued. That is, by applying the accumulation count signal SCOUN _T to the OR gate after making a time delay of the accumulation count signal S _COUNT , the delay unit 54 resets the counter unit 30 in case the bypass signal S _UB is not generated again within a predetermined time. Accordingly, the accumulation count signal S _CO U _NT is transitted to a low level.

Thereafter, the watchdog system of the present invention discontinues the automatic recovery operation until a disorder is generated again in UPS and the bypass signal SITB is generated.

In Fig. 2, the counter unit 30 made to be reset according to the contact signal SN _OR of the temperature sensor, however, it is just an embodiment of the present invention. By using the experience or the statistics, an application by the user is possible for the temperature sensor and/or the instrument to which a temporary disorder is expected.

Fig. 4 is a timing diagram showing the auto recovery operation process according to the present invention, in case the recovery signal SRECO is consecutively generated three times. That is, the automatic recovery operation according to the present invention is shown in case that the disorder of the UPS is not temporary.

In Fig. 3, it is described that the recovery signal SRECO is generated only two times and, thereafter, the bypass signal S _γγB is not generated again, so that the recovery operation is not performed any

more. However, in spite of the recovery operation of two times, the bypass signal S _γγB can be generated again.

That is, in case the disorder generated in the inverter 2 is still maintained even when the inverter 2 is compulsively turned on twice since the inverter-on signal S _I NV-ON and the recovery signal S _RECO has been generated twice, the UPS generates again the bypass signal SUB-

And then, the inverter-on generating unit 10 once again generates the inverter-on signal S _INV - _ON/ and accordingly, the recovery signal generating unit 20 once again generates the recovery signal SRECO- That is, the recovery signal SRECO is generated three times.

Like this, in case the recovery signal S _R E _CO is generated three times, the counter unit 30 generates the accumulation count signal SCOUNT of 3V. Accordingly, the comparator COMPl generates the counting comparison signal SCOUN _T - _COM P with a high level to output. And the counting comparison signal SCOUN _T - _C O _MP is time-delayed by the delay unit 42 and applied to the J/K flip flop 52.

Any one of differential signal ( ^Q ) of the J/K flip flop 52, that is, the recovery stop signal SSTOP is switched to the low level as the counting comparison signal SCOUN _T - _COMP is switched to the high level. Accordingly, the recovery signal generating unit 20 generates the recovery signal SRECO with the low level. At the same time, since another differential signal ( ^Q ) of the J/K flip flop 52 is outputted with the high level, the reset signal S _RST is generated and the counting operation of the counter unit 30 is interrupted. That is, in the present embodiment, in case the power supply

path is switched to the bypass line, firstly the auto recovery operation is consecutively performed three times. Nevertheless, in case the recovery has not been performed, it is determined that the UPS has an important disorder, so that the recovery operation is not performed any more. In this case, the manual recovery by a user is performed like a related art.

Fig. 5 is a timing diagram showing the auto recovery operation process according to the present invention, in case the recovery signal S _RE CO is consecutively generated five times. Compared with Fig. 4, this embodiment shows that the automatic recovery operation is paused in case the recovery signal S _RE CO is consecutively generated five times during a given time by enhancing the reference value V _REF of the counting comparison unit 40, for example, to 4.5V. That is, the number of the automatic recovery operation can be controlled by controlling the reference value V _REF .

The description of the auto recovery principles of this embodiment is omitted since it is identical with Fig. 4.