JP2005287175A - Uninterruptible power supply device and its control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the pattern cut or fuse blow within an uninterruptible power supply device 12 even if a commercial power source 1 is cut off in case that there is a setting error in a setter for load 6. <P>SOLUTION: A detector 13 is provided between the secondary winding 4b and the output terminal 5 of a transformer 4 within the uninterruptible power supply device 12, and the voltage supplied from the load 6 connected to an output terminal 5 to the uninterruptible power supply device 12 is detected. A comparator 18 compares the maximum value of the absolute voltage of the load 6 supplied from the detector 13 with the specified value, and in case that the maximum value of the absolute voltage of load 6 is larger than the specified voltage, this device controls an inverter 11 into nonoperation when the commercial power source 1 is cut off. Moreover, an alarm part 14 outputs an alarm by the control signal of the controller 19. When the user installs the uninterruptible power supply device 12, the user can detect a setting error in a setter for the load 6. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  In the present invention, while receiving commercial power, the commercial power is stepped down and supplied to the load, and the battery is charged by the charger. When a power failure occurs, the DC power of the storage battery is converted to AC power by the inverter. The present invention relates to an uninterruptible power supply device to be supplied to a power supply and a control method thereof.

  FIG. 1 shows a conventional uninterruptible power supply. AC power from the commercial power source 1 is supplied from the input terminal 2 into the uninterruptible power supply 12. When the breaker 17 is provided between the input terminal 2 and the cutoff part 3 and the breaker 17 is turned on, AC power is supplied to the primary winding 4 a of the transformer 4 through the breaker 17 and the cutoff part 3. The AC power supplied to the primary winding 4 a of the transformer 4 is stepped down to 60 V, for example, and then supplied to the output terminal 5 connected to the secondary winding 4 b of the transformer 4. It is supplied as operating power to the load 6 connected to the output terminal 5.

The control unit 19 is connected between the breaker 17 and the blocking unit 3. When the power failure detection unit 7 in the control unit 19 detects the reception of AC power from the commercial power source 1, the control unit 19 supplies the charger 8. Due to the control signal, the charger 8 connected to the tertiary winding 4c of the transformer 4 is in an operating state, and the storage battery 9 is charged. A backflow prevention diode 10 is inserted in series between the charger 8 and the storage battery 9. When the commercial power source 1 fails, a power failure of the commercial power source 1 is detected by the power failure detection unit 7, and the cutoff unit 3 is activated by a control signal from the control unit 19 to the cutoff unit 3. Is interrupted by the interrupting unit 3. Thereafter, the control signal from the control unit 19 to the inverter 11 causes the inverter 11 to be in an operating state, the DC power stored in the storage battery 9 is converted into AC power by the inverter 11, and the AC power is transformed by the transformer connected to the inverter 11. The quaternary winding 4d of the device 4 is supplied as operating power to the load 6 through the secondary winding 4b.

Moreover, the charger 8 is controlled to a non-operation state by the power failure detection of the commercial power source 1 of the power failure detection unit 7. Although not shown, a fuse is provided inside the inverter 11. When a large current flows inside the inverter 11, the fuse 11 is prevented from being destroyed by the fuse. (For example, see FIG. 4 of Patent Document 1.)

  FIG. 2A is an example in which a plurality of loads 6 </ b> A to 6 </ b> E are connected to the output terminal 5 of the uninterruptible power supply 12. When a plurality of loads are connected to the uninterruptible power supply 12, the number of loads connected to the uninterruptible power supply 12 depends on the allowable output power of the uninterruptible power supply 12. It is limited by the voltage drop due to the shielded wire 15 connecting the, and the power consumption of the load. When the number of loads 6 connected to the uninterruptible power supply 12 is large and the uninterruptible power supply 12 is overloaded, abnormal heat generation of the board in the uninterruptible power supply 12 and power at which the load can operate normally Such as inability to supply. Therefore, the uninterruptible power supply 12 is provided with a protection function that stops the output of the uninterruptible power supply 12 when the overload state continues for a predetermined time.

Although not shown, the load is provided with a plurality of connection terminals for connecting to the shielded wire 15 and a setting unit, and by switching the setting unit, a connection terminal for inputting the operating power of the load, and the load The connection terminal that outputs the operating power can be switched. In FIG. 2A, the arrows of the connection portions of the loads 6A to 6E and the shielded wire 15 indicate that the load setting portions are set so that the operating power is supplied in the direction of the arrows, and all of the loads 6A to 6E are not present. Operating power is supplied from the power failure power supply device 12.

  When a load is newly connected to the uninterruptible power supply 12 to which a plurality of loads are connected and operating power is supplied to all the loads from the uninterruptible power supply 12, the uninterruptible power supply 12 may be overloaded. . In this case, in order to prevent overload, an uninterruptible power supply is newly installed and connected to the added load. For example, as shown in FIG. 2B, loads 6F-6I and uninterruptible power supply 12 'are newly connected to the connection network in which uninterruptible power supply 12 and loads 6A-6E of FIG. The setting unit of each load is switched so that the uninterruptible power supply 12 and 12 'can supply operating power to each load without being overloaded. Since the loads 6A to 6E connected to the uninterruptible power supply 12 are already operating, it is desirable not to cause a power failure when connecting the loads 6F to 6I and the uninterruptible power supply 12 '. Therefore, the wiring contractor cuts the power supply path only for a specific load and performs wiring work, or performs wiring work so that the loads 6A to 6E do not cause a power failure. Hereinafter, each element constituting the uninterruptible power supply 12 'will be described by adding a dash (') to the reference numeral.

For example, the load 6B and 6F, 6D and 6H, 6E and 6G, 6H and 6I, 6I and the uninterruptible power supply 12 ′ are newly connected by the shield line 15 by the wiring contractor. After the connection, operating power is supplied to the loads 6A, 6B, 6C, 6E, 6F, and 6G from the existing uninterruptible power supply 12, and operating power is supplied to the loads 6D, 6H, and 6I from the newly installed uninterruptible power supply 12 '. The setting to be performed is performed in the setting unit of each load.
Japanese Utility Model Publication No. 3-11342

  By the way, the load 6C and the load 6D are originally connected by the shield wire 15, and the setting unit is set so that the load 6D supplies operating power from the uninterruptible power supply 12. However, after the uninterruptible power supply 12 ′ is added, the load 6D changes the setting of the setting unit to supply the operating power from the uninterruptible power supply 12 ′, and stops the supply of the operating power of the uninterruptible power supply 12. There is a need. However, there is a case where the wiring contractor mistakes the setting of the setting unit of the load 6D, and the load 6D is supplied with operating power from both the uninterruptible power supply 12 and the uninterruptible power supply 12 '. In this case, the output terminals of the uninterruptible power supply devices 12 and 12 'are connected through the load 6D.

  In the above state, when a load other than the load 6D is ignored, the load 6D is connected in parallel with the output terminals of the uninterruptible power supply units 12 and 12 '. As shown in FIGS. 3A and 3B, when the uninterruptible power supply units 12 and 12 ′ both receive AC power from the commercial power source 1, the voltage waveforms at the output terminals of the uninterruptible power supply units 12 and 12 ′ are as shown in FIG. As shown in FIG. 3D, the voltage waveforms are the same and there is no phase shift. In this case, the voltage waveform supplied to the load 6D becomes FIG. 3G because the load 6D is connected in parallel with the output terminals of the uninterruptible power supply devices 12 and 12 ′, and the voltage waveforms shown in FIGS. 3C and 3D The same and no phase shift. Thus, when AC power having the same waveform and the same phase is supplied as operating power from both uninterruptible power supply units 12 and 12 ′, the uninterruptible power supply units 12 and 12 ′ operate normally and load Also works fine. Therefore, the wiring contractor does not notice that the setting of the load setting unit is wrong.

  On the other hand, as shown in FIG. 3E, when the commercial power supply 1 to the uninterruptible power supply 12 ′ fails, that is, when the AC power reception of the commercial power supply 1 stops at point a, The power failure detection unit 7 ′ detects a power failure. After power failure detection by the power failure detection unit 7 ′, the AC power reception is blocked by the cutoff unit 3 ′ by the control signal from the control unit 19 ′ to the cutoff unit 3 ′, and the control unit 19 ′ controls the inverter 11 ′. The DC power stored in the storage battery 9 ′ is converted into AC power by the inverter 11 ′ by the signal, and the AC power is supplied to the load as operating power through the transformer 4 ′. (Hereinafter referred to as inverter operation.) Since the inverter operation is started from the time point (b) when the power failure detection unit 7 ′ detects the power failure, the uninterruptible power supply 12 ′ that performs the inverter operation after the commercial power source 1 fails. The voltage waveform of the output terminal (FIG. 3F) of the uninterruptible power supply 12 ′ with respect to the voltage waveform (FIG. 3C) of the uninterruptible power supply 12 that received AC power from the commercial power supply 1 ) After that, the phase of the voltage waveform is shifted from the time (b point) when the inverter operation is started. In order to clarify the phase shift of the voltage waveform at the output terminal, both voltage waveforms of FIGS. 3D and 3F are shown in FIG. 3H.

  For example, it is assumed that the output terminals of the uninterruptible power supply units 12 and 12 ′ are connected by a coaxial cable having a length of 100 (m), and the resistance value of the used coaxial cable is 1 (Ω) / 100 (m). When the potential difference E between the output terminals of the uninterruptible power supply units 12 and 12 ′ is assumed to be about 60 (V) at the point c in FIG. 3H and the voltage drop due to the load is ignored, the uninterruptible power supply units 12 and 12 ′ The current flowing between the output terminals is about 60 (A) from current = voltage / resistance. This large current flows from the output terminal to the uninterruptible power supply side (in this case, the 12 side) on the low potential side. The circuit pattern between the transformer 4 and the output terminal 5 in the uninterruptible power supply can withstand this large current for a short time. However, if this large current continues to flow for a longer time, a pattern cut between the transformer 4 and the output terminal 5 will be caused. In addition, since this large current flows into the inverter 11, the fuse in the inverter 11 is blown.

  Thus, when the commercial power supply 1 fails, a large current flows into the uninterruptible power supply 12, causing a pattern break between the secondary winding 4b of the transformer 4 and the output terminal 5 and a fuse blow in the inverter 11. Therefore, there is a problem that it is impossible to supply operating power to the load 6. As a result, even if the commercial power source 1 recovers, there is a problem that the operating power cannot be supplied to the load 6 because the pattern is cut off at the time of a power failure. Further, when the uninterruptible power supply 12 'is installed, the uninterruptible power supply 12, 12' and the load operate normally, so that it is impossible for the wiring contractor to notice the setting error of the load setting unit. was there.

  Therefore, the present invention can prevent the occurrence of a pattern break between the secondary winding 4b of the transformer 4 and the output terminal 5 and a fuse blow in the inverter 11 even when the commercial power source 1 is cut off. Another object of the present invention is to provide an uninterruptible power supply device and a control method for the wiring supplier that can detect a setting error in the setting unit of the load 6 when installing the uninterruptible power supply device.

In order to achieve the above object, an uninterruptible power supply device according to claim 1 of the present invention comprises:
A power failure detection unit that detects commercial power reception or power failure,
A shut-off unit that cuts off the reception of the commercial power;
A charger for charging the storage battery while receiving the commercial power;
When the commercial power fails, an inverter that converts the DC power of the storage battery into AC power;
A transformer for stepping up or stepping down AC power supplied from the commercial power or AC power supplied from the inverter and supplying the load to the load;
In the uninterruptible power supply with
A detection unit for detecting the output voltage of the load;
A comparison unit that compares the maximum value of the absolute value of the output voltage detected by the detection unit with a predetermined voltage;
A storage unit for storing data corresponding to the comparison result by the comparison unit;
A determination unit that determines whether or not the inverter can be operated based on a comparison result by the comparison unit;
A storage unit for storing a predetermined time (T) until the power is received again after the output voltage of the load is detected by the detection unit after the commercial power is cut off by the operation of the cut-off unit;
A time measuring unit that measures the time until the power is received again after detecting the output voltage of the load by the detecting unit after blocking the commercial power reception by the operation of the blocking unit;
Is provided.

Moreover, in addition to the uninterruptible power supply device described in claim 1, the uninterruptible power supply device described in claim 2
A storage unit that stores a predetermined time (t) from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit;
A time measuring unit that measures the time from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit;
Is provided.

Moreover, in addition to the uninterruptible power supply device described in claim 1, the uninterruptible power supply device described in claim 3
A storage unit that stores a predetermined period (Lt) from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit;
A period measuring unit that measures a period from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit;
Is provided.

Moreover, in addition to the uninterruptible power supply device described in any one of Claims 1 to 3, the uninterruptible power supply device described in Claim 4 includes:
Provided alarm means for issuing an alarm when the maximum value of the absolute value of the output voltage detected by the detection unit is greater than a predetermined voltage,
It is characterized by that.

Moreover, the control method of the uninterruptible power supply according to claim 5 is a control method for controlling the uninterruptible power supply according to any one of claims 1 to 4,
Shutting off the reception of the commercial power by the blocking unit during the reception of the commercial power;
After detecting the output voltage of the load, stopping the interruption of the reception of AC power by the interruption unit;
Detecting the output voltage of the load within a predetermined time (T) from when the commercial power is cut off to when the cut off of the incoming power is stopped;
Comparing the maximum value of the absolute value of the output voltage detected by the detection unit with a predetermined voltage;
Storing data corresponding to the comparison result between the maximum value of the absolute value of the output voltage of the load and a predetermined voltage;
When the maximum value of the absolute value of the output voltage detected by the detection unit is larger than a predetermined voltage, when the commercial power fails, the inverter operation is not performed,
In the case where the maximum value of the absolute value of the output voltage detected by the detection unit is equal to or lower than a predetermined voltage, when the commercial power fails, an inverter operation is performed.
It is characterized by comprising.

Moreover, in addition to the control method of the uninterruptible power supply described in claim 5, the control method of the uninterruptible power supply described in claim 6 includes:
Detecting the output voltage of the load within a predetermined time (T) from when the commercial power is cut off to when the cut off of the incoming power is stopped;
Comparing the maximum value of the absolute value of the output voltage detected by the detection unit with a predetermined voltage;
The step of storing the data corresponding to the comparison result between the maximum value of the absolute value of the output voltage of the load and the predetermined voltage,
Start after the predetermined time (t) has elapsed after detection of receiving the commercial power.
The method for controlling an uninterruptible power supply according to claim 5.

Moreover, in addition to the control method of the uninterruptible power supply described in claim 5, the control method of the uninterruptible power supply described in claim 7 is:
Detecting the output voltage of the load within a predetermined time (T) from when the commercial power is cut off to when the cut off of the incoming power is stopped;
The step of comparing the maximum value of the absolute value of the output voltage detected by the detection unit with a predetermined voltage, and the data corresponding to the comparison result between the maximum value of the absolute value of the output voltage of the load and the predetermined voltage are stored. What is a stage?
It is repeatedly executed every predetermined period (Lt) after detecting the reception of the commercial power.
The method for controlling an uninterruptible power supply according to claim 5.

Moreover, in addition to the control method of the uninterruptible power supply according to any one of claims 5 to 7, the control method of the uninterruptible power supply according to claim 8 includes:
In the step of detecting the output voltage of the load within a predetermined time (T) from when the commercial power is cut off until the cutoff of the incoming power is stopped,
The relationship between the time T (seconds) from when the commercial power reception is cut off until the cutoff is stopped and the frequency f (Hz) of the commercial AC power is 1 / (2f) ≦ T ≦ 1 / f. is there,
It is characterized by that.

According to the uninterruptible power supply described in claim 1,
The detection unit can detect an output voltage of a load that has not been detected conventionally. Further, the comparison unit can compare the maximum value of the absolute value of the output voltage of the load detected by the detection unit with a predetermined voltage. Further, the storage unit stores data corresponding to the comparison result by the comparison unit and a predetermined time (T) from when the commercial power is cut off by the operation of the cut-off unit until the power is received again. Can do. The determination unit can determine whether or not the inverter can be operated based on a comparison result by the comparison unit. Further, the time measuring unit can measure the time from when the commercial power is received by the operation of the cutoff unit until the commercial power is received again.

According to the uninterruptible power supply described in claim 2, in addition to the effect of the uninterruptible power supply described in claim 1,
The storage unit can store a predetermined time (t) from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit. Further, the time measuring unit can measure the time from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit.

According to the uninterruptible power supply device described in claim 3, in addition to the effect of the uninterruptible power supply device described in claim 1,
The storage unit can store a predetermined period (Lt) from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit. Further, the period measurement unit can measure a period from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit.

According to the uninterruptible power supply device described in claim 4, in addition to the effects of the uninterruptible power supply device described in any of claims 1 to 3,
The alarm means can issue an alarm when the maximum value of the absolute value of the output voltage detected by the detector is greater than a predetermined voltage.

According to the uninterruptible power supply control method according to claim 5,
Since the load output voltage is detected within a predetermined time (T) from when the commercial power is cut off to when the cut-off of the power is stopped, an accurate load output voltage can be detected. In addition, after storing data corresponding to a comparison result obtained by comparing the maximum value of the absolute value of the output voltage of the load detected by the detection unit with a predetermined voltage, when the commercial power fails, the detection is performed. If the maximum value of the absolute value of the output voltage detected by the control unit is greater than the predetermined voltage, the inverter operation is not performed, and if the maximum value of the absolute value of the output voltage of the load is less than the predetermined value, the inverter operation Therefore, it is possible to determine whether or not to perform the inverter operation according to the magnitude of the absolute value of the output voltage detected by the detection unit.

According to the control method of the uninterruptible power supply device described in claim 6, in addition to the effect of the control method of the uninterruptible power supply device described in claim 5,
Within a predetermined time (t) after the detection of the reception of the commercial power, the output voltage of the load is detected and the interruption of the reception is stopped, and then the absolute value of the output voltage of the load detected by the detection unit The maximum value is compared with a predetermined voltage. As a result, when the wiring contractor finishes the installation work of the uninterruptible power supply and turns on the breaker, whether the setting means of the load setting unit connected to the uninterruptible power supply is set or not is detected within the predetermined time. You can know by operation. This predetermined time is normally set within several tens of seconds. It includes t = 0 seconds.

According to the control method of the uninterruptible power supply described in claim 7, in addition to the effect of the control method of the uninterruptible power supply described in claim 5,
After detecting the receipt of the commercial power, the commercial power is cut off every predetermined period (Lt), the output voltage of the load is detected and the cut-off of the power is stopped, and then detected by the detection unit. The maximum value of the absolute value of the output voltage of the load is compared with a predetermined voltage. Even when the wiring contractor newly connects another uninterruptible power supply apparatus that does not have the function of the present invention to the load in parallel, the setting error of the load setting unit can be known by the operation of the alarm means. This operation is repeated every predetermined period (Lt).

According to the control method of the uninterruptible power supply device according to claim 8, in addition to the effect of the control method of the uninterruptible power supply device according to any of claims 5 to 7,
The relationship between the time T (seconds) from when the commercial power is received until the cutoff is released and the frequency f (Hz) of the commercial AC power is defined as 1 / (2f) ≦ T ≦ 1 / f. It was. By setting 1 / (2f) ≦ T, it is possible to secure one half of the period, which is the minimum time required to detect the maximum value of the output voltage of the load. Moreover, by setting T ≦ 1 / f, the load connected to the uninterruptible power supply device does not stop during a power failure of the commercial power supply, and the operation can be continued normally.

  According to the uninterruptible power supply apparatus and the control method thereof of the above invention, while receiving the commercial power, the commercial power is cut off, the load output voltage is detected, and the absolute value maximum value and the predetermined voltage are set. In comparison, if the predetermined voltage is larger than the maximum absolute value of the output voltage, the pattern between the secondary winding of the transformer and the output terminal is cut off in order to control the inverter to the non-operating state at the time of commercial power failure. Thus, it is possible to prevent occurrence of blown fuses in the inverter. In addition, when the predetermined voltage is larger than the maximum value of the absolute value of the output voltage, an alarm is output. Therefore, when installing the uninterruptible power supply, the wiring contractor may detect a setting error in the load setting unit. it can.

  FIG. 4 shows an embodiment of the present invention, and parts corresponding to those in FIG. A detector 13 is provided between the secondary winding 4 b of the transformer 4 and the output terminal 5, and a voltage (output of the load 6) supplied from the load 6 connected to the output terminal 5 to the uninterruptible power supply 12. Voltage) is detected. The detection unit 13 is connected to the control unit 19 and supplies the detected output voltage of the load 6 to the control unit 19. In addition to the power failure detection unit 7, the control unit 19 includes a comparison unit 18, a determination unit 22, a storage unit 21, and a timer unit 20, and the alarm unit 14 is connected to the control unit 19.

The comparison unit 18 compares the maximum value Vm of the output voltage of the load 6 detected by the detection unit 13 (hereinafter referred to as an absolute value voltage) with a predetermined voltage Vc. In the determination unit 22, it is determined whether to perform the inverter operation based on the result of the comparison performed by the comparison unit 18.

The storage unit 21 includes the predetermined voltage Vc, a predetermined time t from when the power failure detection unit 7 detects the reception of the commercial power 1 to when the power reception is interrupted by the interruption unit 3, and the interruption unit 3 for commercial use. A predetermined time T from when the power supply 1 is cut off until the power supply is stopped is stored in advance. In addition, a determination flag a corresponding to the comparison result by the comparison unit 18 is stored. That is, when the maximum value Vm of the absolute value voltage of the load 6 is larger than the predetermined voltage Vc, the control unit 19 sets the determination flag a to a = 0, and the maximum value Vm of the absolute value voltage of the load 6 is the predetermined voltage Vc. In the following cases, the determination flag a is set to a = 1 and stored in the storage unit 21.

The timer unit 20 is turned on at the same time that the power failure detection unit 7 detects the reception of the commercial power 1, measures the time until the power reception is interrupted by the interruption unit 3, and is turned off when a predetermined time t has elapsed. Become. Further, when the power receiving of the commercial power source 1 is interrupted by the interrupting unit 3, the power is turned on at the same time, and the time until the power receiving is stopped is measured again, and the power is turned off when a predetermined time T elapses.

  The alarm unit 14 is connected to the control unit 19. When the maximum value Vm of the absolute value voltage of the load 6 is larger than the predetermined voltage Vc, that is, when the determination flag a is a = 0, the alarm unit 14 is connected to the alarm unit 14. Output a control signal.

  Next, operation | movement of the uninterruptible power supply 12 is demonstrated using FIG. After the uninterruptible power supply 12 and the load 6 are connected and installed, when the breaker 17 of the uninterruptible power supply 12 is turned on by the wiring contractor (S1), the AC power of the commercial power supply 1 is received via the breaker 17. Supplied to the power failure detection unit 7. When the power failure detection unit 7 detects the reception of AC power from the commercial power source 1 (S2), the control unit 19 reads out the predetermined voltage Vc, the predetermined time t, and the predetermined time T from the storage unit 21, and at the same time other initial values. Setting is performed (S3), and operating power is supplied to the load 6 through the transformer 4 (S4).

  When a predetermined time t has elapsed after the power failure detection unit 7 detects the reception of the AC power from the commercial power supply 1 (S5), the power reception is interrupted by the interrupting unit 3 by the control signal of the control unit 19 (S6). ). The predetermined time t is normally stored in the storage unit 21 in advance within a few tens of seconds. Further, the time measurement up to the predetermined time t is executed by the ON-OFF operation of the timer unit 20.

  Thereafter, the detection unit 13 detects the output voltage of the load 6 based on the control signal of the control unit 19 (S7), and the output voltage of the load 6 detected by the detection unit 13 is supplied to the comparison unit 18. The control unit 19 continues to detect the output voltage of the load 6 from the detection unit 13 until the predetermined time T elapses after the power reception is interrupted by the interruption unit 3 (S8—No). At the same time, the detection is terminated (S8-Yes), and the interruption of power reception by the interruption unit 3 is stopped (S9). Note that the time measurement up to the predetermined time T is executed by the ON-OFF operation of the timer unit 20.

After stopping the interruption of power reception, the control unit 19 causes the comparison unit 18 to compare the maximum value Vm of the absolute value voltage of the load 6 supplied from the detection unit 13 with the predetermined voltage Vc (S10). When the maximum value Vm of the absolute value voltage of the load 6 is larger than the predetermined voltage Vc, the control unit 19 sets the determination flag to a = 0 and stores it in the storage unit 2 (S11). When the maximum value Vm of the absolute value voltage of the load 6 is equal to or lower than the predetermined voltage Vc, the determination flag is set to a = 1 and stored in the storage unit 2 (S12), and the alarm unit 14 outputs an alarm (S13). Thereafter, charging of the storage battery 9 by the charger 8 is started (S14).

When the commercial power source 1 fails, the power failure detection unit 7 detects a power failure (S15), and the control signal from the control unit 19 blocks the AC power from the commercial power source 1 in the cutoff unit 3 (S16). Charging of the storage battery 9 by the charger 8 is stopped (S17). Thereafter, the control unit 19 determines the determination flag a value in the determination unit 22 (S18). If the determination flag is a = 1, the control unit 19 controls the inverter 11 to be in an operating state (S19). If a = 0, the non-operating state is controlled (S20).

  Next, the predetermined time T will be described. Conventionally, the switching time until the inverter operation is started after the power failure detection unit 7 detects the AC power failure of the commercial power source 1 is 1 of the AC waveform of the commercial power source 1 when the power frequency of the commercial power source 1 is 50 Hz. It is set to a period or less, that is, 20 ms or less. This is because even if the commercial power source 1 is out of power, the load 6 is not stopped for a short time of one cycle or less of the AC waveform, so that the operation can be continued normally. It is. Further, the cycle of the AC voltage waveform of the commercial power supply 1 and the output voltage waveform of the load 6 are the same, and the minimum time required to detect the maximum value of the output voltage is one half of this cycle.

Therefore, for the reason described above, the predetermined time T is determined to be not less than a half cycle of the input waveform and not more than one cycle. That is, when the frequency of the AC power of the commercial power source 1 is f (Hz), one cycle of the AC power of the commercial power source 1 is 1 / f (second). Further, since the half cycle of the AC power of the commercial power supply 1 is 1 / (2f) (seconds), the predetermined time T (seconds) is expressed by the equation (1).
1 / (2f) ≦ T ≦ 1 / f (1)

  Next, the predetermined voltage Vc will be described. The rated output voltage of the uninterruptible power supply 12 is AC60 (V). For example, when the commercial power supply 1 has an amplitude of 20% less than the rated voltage AC100 (V) due to the influence of a voltage drop or the like and becomes AC80 (V), the output voltage is AC48 (V). As described above, the AC voltage of the commercial power source 1 may decrease in amplitude by 20% at the maximum. Therefore, when the voltage value of AC48 (V) or higher is set to the predetermined voltage Vc, the comparison unit 18 sets the voltage value of 48 (V) or higher detected for reducing the amplitude of the voltage of the commercial power supply 1 to the absolute value of the load 6. There is a risk of erroneous detection with the value voltage. Moreover, it is necessary to consider the voltage drop between the connected load 6 and the uninterruptible power supply 12 and the shield wire 15. Furthermore, when a power failure occurs, the energy stored in the transformer 4 may be temporarily added to the output voltage waveform. Therefore, if the predetermined voltage Vc is set low, this voltage may be detected. Therefore, for example, AC 40 (V) is set as a value that is not affected by the energy stored in the transformer 4 when a power failure occurs and is not affected by the voltage drop of the commercial power supply 1 or the like.

(Effects and effects of this embodiment)
In the present embodiment, since the detection unit 13 is provided, it is possible to detect the output voltage of the load 6 that could not be detected conventionally. Further, since the comparison unit 18 is provided, the maximum value Vm of the absolute value voltage of the load 6 detected by the detection unit 13 can be compared with the predetermined voltage Vc. In addition, since the determination unit 22 is provided, it is possible to determine whether or not the inverter can be operated based on the comparison result by the comparison unit 18. Further, since the storage unit 21 is provided, data corresponding to the comparison result by the comparison unit 18, that is, the determination flag a can be stored. In addition, since the timer unit 20 is provided, it is possible to measure the time from when the power failure detection unit 7 detects power reception until the interruption unit 3 cuts off the reception of commercial power, and to receive commercial power by the interruption unit 3. It is possible to measure the time from when the power is shut off until power is received again. Instead of the timer unit 20, the time can be measured by calculating the time from a clock (not shown) connected to the outside of the control unit 19. Further, since the alarm unit 14 is provided, when the maximum value Vm of the absolute value voltage of the load 6 is larger than the predetermined voltage Vc, a control signal is output to the alarm unit 14 and the setting unit of the load 6 is set to the wiring contractor. Can inform you of mistakes.

  In addition, while receiving the commercial power source 1, the cutoff unit 3 cuts off the commercial power source 1 (S 6) and detects the output voltage of the load 6 (S 7), so that the accurate load output voltage can be detected. it can. In addition, after detecting the output voltage of the load 6 (S7), the interruption of the AC power reception by the interruption unit 3 is stopped (S9), so that the operating power can be supplied to the load 6. In addition, since a predetermined time T is set from the time when the commercial power supply 1 is cut off (S6) to the time when the power supply is stopped (S9), the timer unit 20 sets the time at the same time as turning off the power. When the measurement time reaches a predetermined time T, the interruption of power reception can be stopped.

Further, when the maximum value Vm of the absolute value voltage of the load 6 is compared with the predetermined voltage Vc (S10), and the maximum value Vm of the absolute value voltage of the load 6 is larger than the predetermined voltage Vc, the commercial power is When the power failure occurs, the inverter operation is not performed (S20), and when the maximum value Vm of the absolute voltage of the load is equal to or lower than the predetermined voltage Vc, the inverter operation is performed when the commercial power is interrupted (S19). Whether or not to perform inverter operation can be determined based on the magnitude of the output voltage detected by the detection unit 13.

Further, the interruption (S6) of the AC power reception of the commercial power source 1 by the interruption unit 3 is executed within a predetermined time t after the power failure detection unit 7 detects the reception of the commercial power source 1 (S2). When the wiring contractor turns on the breaker, the wiring contractor can quickly know whether there is a setting error in the setting unit of the load connected to the uninterruptible power supply 12. This predetermined time t is normally set within several tens of seconds. Therefore, the wiring contractor can know whether or not the load is set erroneously after several tens of seconds after the installation work of the uninterruptible power supply is completed and the breaker is turned on. In addition, t = 0 second may be sufficient, and at the same time as the commercial power source 1 receives power, the power receiving unit 3 cuts off power reception. In this case, the steps of detecting power reception (S2) and initial setting (S3) are set before the start of charging the storage battery (S14).

  Further, the relationship between the time T (seconds) from the interruption of the AC power reception of the commercial power supply 1 (S6) to the stop of the interruption (S9), and the frequency f (Hz) of the commercial AC power is The cycle of the AC power of the power source 1 and the output voltage of the load is the same, and the minimum time required to detect the maximum value of the output voltage is 1/2 of this cycle, that is, 1 / (2f) ≦ T Set to In addition, since the load 6 connected to the uninterruptible power supply 12 does not stop at the time of a power failure of the commercial power supply 1 and the normal operation can be continued is 1 / f (second) or less, T ≦ 1 / f is set.

According to the above embodiment, while the commercial power source 1 is receiving power, the AC power is cut off (S6), the output voltage of the load is detected (S7), and the maximum value Vm of the absolute value voltage of the load is set to a predetermined value. The voltage Vc is compared (S10), and if the maximum value Vm of the absolute value voltage of the load is larger than the predetermined voltage Vc, the inverter is controlled to the non-operating state at the time of commercial power failure (S20). It is possible to prevent the pattern breakage between the secondary winding and the output terminal and the fuse blown in the inverter. In this case, since an alarm is output (S13), when installing the uninterruptible power supply 12, the wiring contractor can detect a setting error in the load setting unit.

(Application examples)
The present invention is not limited to the above-described embodiments, and various applications are possible. The alarm unit 14 can be informed to the wiring company by an alarm sound by providing a speaker inside. In addition, an alarm display unit such as a high-intensity LED can be provided to notify the wiring contractor by an alarm display. Further, a communication unit (not shown) connected to the control unit 19 may be provided, and along with an alarm from the alarm unit 14, an abnormality may be automatically reported to the management center or the like by the output of the communication unit. By automatic notification, it is possible to notify an erroneous setting of the load setting unit before the AC power failure of the commercial power supply 1. If there is no alarm unit 14, it is impossible to notify the setting error of the load setting unit, but at least the pattern breakage between the secondary winding of the transformer and the output terminal and the fuse in the inverter are blown. It is possible to prevent the occurrence.

  Further, the steps S6 to S13 may be performed every predetermined period Lt. When the new uninterruptible power supply 12 'does not have the function of the present invention, it is impossible to detect a setting error in the load setting unit when the new uninterruptible power supply 12' is turned on. However, for every predetermined period Lt, the interruption unit 3 cuts off the reception of the AC power of the commercial power source 1, detects the output voltage of the load 6 from the detection unit 7, and is supplied from the detection unit 7 in the comparison unit 18. When the maximum value Vm of the absolute value voltage of the load 6 is compared with the predetermined voltage Vc, and the maximum value Vm of the absolute value voltage is larger than the predetermined voltage Vc, in order to control the inverter 11 to be non-operation during a power failure, Together with the uninterruptible power supply 12 having the function of the present invention, it is possible to prevent the pattern breakage and the fuse blow of the uninterruptible power supply 12 having no function of the present invention at the time of the power failure of the commercial power supply 1. For example, one week, one month, one year, or the like is set as the predetermined period Lt. In addition, the timer 20 and the above-mentioned timepiece can be used for the period measurement of the predetermined period.

  Further, as shown in FIG. 6, the transformer 4 may not be provided between the blocking unit 3 and the output terminal 5. This is effective when the same voltage as that of the commercial power source 1 is supplied to the load 6. If a voltage different from that of the commercial power source 1 is supplied to the load 6, an ascending (falling) voltage circuit (not shown) is provided between the blocking unit 3 and the detecting unit 13.

Further, as shown in FIG. 7, the transformer 4 is provided between the cutoff unit 3 and the changeover switch 16, and the changeover switch 16 is controlled by the control signal of the control unit 19 and supplied to the load 6 in accordance with the state of the commercial power source 1. The power may be switched between the commercial power side and the storage battery 9 side. This is effective when the direct-current voltage of the storage battery 9 and the operating voltage of the load are substantially the same and greatly differ from the commercial voltage. In this case, an ascending (falling) voltage circuit (not shown) may be provided between the storage battery 9 and the inverter 11 depending on the relationship between the voltage value of the storage battery 9 and the output voltage, as in FIG.

  For example, when a voltage greater than the predetermined voltage Vc is detected in step S10 in FIG. 5, the control unit 19 outputs a control signal to the alarm unit 14. An alarm is output from the alarm unit 14, and then the interrupting unit 3 is interrupted by the control signal of the control unit 19, and the AC power of the commercial power source 1 is received by the interrupting unit 3 until the disconnection release switch is manually operated. The blocking may be continued. If the cutoff release switch is not operated, the cutoff of the AC power reception of the commercial power supply 1 by the cutoff unit 3 is not released, so that the wiring contractor can always know the abnormality.

It is a block diagram which shows the outline | summary of the conventional uninterruptible power supply. It is a figure which shows the example of a connection of an uninterruptible power supply and load. It is a figure which shows the input waveform and output waveform of an uninterruptible power supply. It is a block diagram which shows the uninterruptible power supply device of this Embodiment. It is a processing flow figure of this Embodiment. It is a block diagram of another example of the uninterruptible power supply of this embodiment. It is a block diagram of another example of the uninterruptible power supply according to the present embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Commercial power source, 2 ... Input terminal, 3 ... Shut-off part, 4 ... Transformer, 4a ... Transformer primary winding, 4b ... Transformer secondary winding 4c: tertiary winding of transformer, 4d: quaternary winding of transformer, 5 ... output terminal, 6 ... load, 7 ... (in existing uninterruptible power supply) ) Power failure detection unit, 7 '... Power failure detection unit of the new uninterruptible power supply, 8 ... Charger, 9 ... Storage battery (in the existing uninterruptible power supply), 9' ... A storage battery of a new uninterruptible power supply, 10 ... a diode for preventing backflow, 11 ... an inverter (in the existing uninterruptible power supply), 11 '... an inverter of a new uninterruptible power supply, 12 ... uninterruptible power supply (existing uninterruptible power supply), 12 '... new uninterruptible power supply, 13 ... detection unit, 14 ... alarm unit, 15 ... Yield line, 16 ... changeover switch, 17 ... breaker, 18 ... comparison unit, 19 ... control unit (within existing uninterruptible power supply), 19 '... new uninterruptible power supply Control unit of apparatus, 20 ... timer unit, 21 ... storage unit, 22 ... determination unit

a ... determination flag, E ... potential difference, t ... predetermined time, T ... predetermined time, Lt ... predetermined period, Vm ... maximum value of absolute value voltage, Vc ... predetermined Voltage

Claims (8)

A power failure detection unit that detects commercial power reception or power failure,
A shut-off unit that cuts off the reception of the commercial power;
A charger for charging the storage battery while receiving the commercial power;
When the commercial power fails, an inverter that converts the DC power of the storage battery into AC power;
A transformer for stepping up or stepping down AC power supplied from the commercial power or AC power supplied from the inverter and supplying the load to the load;
In the uninterruptible power supply with
A detection unit for detecting the output voltage of the load;
A comparison unit that compares the maximum value of the absolute value of the output voltage detected by the detection unit with a predetermined voltage;
A storage unit for storing data corresponding to the comparison result by the comparison unit;
A determination unit that determines whether or not the inverter can be operated based on a comparison result by the comparison unit;
A storage unit for storing a predetermined time (T) until the power is received again after the output voltage of the load is detected by the detection unit after the commercial power is cut off by the operation of the cut-off unit;
A time measuring unit that measures the time until the power is received again after detecting the output voltage of the load by the detecting unit after blocking the commercial power reception by the operation of the blocking unit;
An uninterruptible power supply. A storage unit that stores a predetermined time (t) from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit;
A time measuring unit that measures the time from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit;
The uninterruptible power supply apparatus according to claim 1, wherein: A storage unit that stores a predetermined period (Lt) from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit;
A period measuring unit that measures a period from when the commercial power is received by the power failure detection unit to when the commercial power is cut off by the operation of the cutoff unit;
The uninterruptible power supply apparatus according to claim 1, wherein: Provided alarm means for issuing an alarm when the maximum value of the absolute value of the output voltage detected by the detection unit is greater than a predetermined voltage,
The uninterruptible power supply according to any one of claims 1 to 3. A control method for controlling the uninterruptible power supply according to any one of claims 1 to 4,
Shutting off the reception of the commercial power by the blocking unit during the reception of the commercial power;
After detecting the output voltage of the load, stopping the interruption of the reception of AC power by the interruption unit;
Detecting the output voltage of the load within a predetermined time (T) from when the commercial power is cut off to when the cut off of the incoming power is stopped;
Comparing the maximum value of the absolute value of the output voltage detected by the detection unit with a predetermined voltage;
Storing data corresponding to the comparison result between the maximum value of the absolute value of the output voltage of the load and a predetermined voltage;
When the maximum value of the absolute value of the output voltage detected by the detection unit is larger than a predetermined voltage, when the commercial power fails, the inverter operation is not performed,
In the case where the maximum value of the absolute value of the output voltage detected by the detection unit is equal to or lower than a predetermined voltage, when the commercial power fails, an inverter operation is performed.
An uninterruptible power supply control method comprising: Detecting the output voltage of the load within a predetermined time (T) from when the commercial power is cut off to when the cut off of the incoming power is stopped;
Comparing the maximum value of the absolute value of the output voltage detected by the detection unit with a predetermined voltage;
The step of storing the data corresponding to the comparison result between the maximum value of the absolute value of the output voltage of the load and the predetermined voltage,
Start after the predetermined time (t) has elapsed after detection of receiving the commercial power.
The method for controlling an uninterruptible power supply according to claim 5. Detecting the output voltage of the load within a predetermined time (T) from when the commercial power is cut off to when the cut off of the incoming power is stopped;
The step of comparing the maximum value of the absolute value of the output voltage detected by the detection unit with a predetermined voltage, and the data corresponding to the comparison result between the maximum value of the absolute value of the output voltage of the load and the predetermined voltage are stored. What is a stage?
It is repeatedly executed every predetermined period (Lt) after detecting the reception of the commercial power.
The method for controlling an uninterruptible power supply according to claim 5. In the step of detecting the output voltage of the load within a predetermined time (T) from when the commercial power is cut off until the cutoff of the incoming power is stopped,
The relationship between the predetermined time T (seconds) from when the commercial power is cut off to when the cutoff is stopped and the frequency f (Hz) of the commercial AC power is 1 / (2f) ≦ T ≦ 1 / f Is,
The control method of the uninterruptible power supply according to any one of claims 5 to 7.

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