JP4951476B2 - Uninterruptible power system - Google Patents

Description

  The present invention relates to an uninterruptible power supply having a DC / DC converter for charging / discharging and a converter for converting an AC voltage into a DC voltage using a controllable switching element such as an IGBT (Insulated Gate Bipolar Transistor). Relates to the device.

  The mission of the uninterruptible power supply is to supply power to the load as a stable voltage source even when the commercial power supply is abnormal. That is, when an abnormality occurs in the commercial power supply, the converter is immediately stopped, and the storage battery is discharged instead of the commercial power supply to supply power to the load. When the commercial power supply is normal, it is necessary to charge the storage battery in preparation for the storage battery discharge at the time of abnormality. There are various configurations of the charging circuit and the discharging circuit relating to the storage battery.

  In many conventional uninterruptible power supply devices, a storage battery is arranged in a rectified DC voltage section. In a storage battery arranged in this way, in order to be able to output a rated voltage from an inverter at the end of discharge, the storage battery It is necessary to increase the number of series. Moreover, since the storage battery voltage has a large difference between full charge and discharge end, the rated voltage of the switching element to be selected needs to be larger than the rated voltage selected from the AC voltage.

  On the other hand, in many uninterruptible power supply devices in recent years, a configuration in which a smoothing capacitor is disposed between a converter and an inverter and a direct current voltage is supplied to the storage battery via a DC-DC converter is often employed. As a method for charging the storage battery in this case, many means for stepping down the DC voltage using a DC-DC converter are employed. And in this system, there are roughly two types of storage battery discharge operation methods when the commercial power supply is abnormal.

  The first method is a method in which a DC-DC converter is configured as a bidirectional DC-DC converter circuit for charging and discharging, and a charge / discharge circuit is used in common. In this method, by using a diode reversely connected to the switching element, two switching elements operated in the step-down mode and the step-up mode can be configured by, for example, the same IGBT module, and the reactor is also used in common. There is an advantage that it can be performed (for example, refer to Patent Document 1).

  The second method is a method of switching the input connection destination of the converter to a storage battery or a commercial power source. In this method, when the commercial power supply is abnormal, the input of the converter is instantaneously switched to the storage battery, and the converter is operated as a switching circuit of the step-up chopper, thereby supplying DC power to the inverter. This discharge method is adopted in an uninterruptible power supply using a half-bridge or full-bridge converter. However, in the case of this method, it is necessary to provide a separate charging circuit (see, for example, Patent Documents 2 and 3).

Japanese Patent Laid-Open No. 10-248246 JP-A-8-65920 JP 11-234923 A

  However, as the storage battery continues to discharge, its voltage decreases and the discharge current increases. On the other hand, the rated current and rated loss of the switching element used in the discharge circuit must satisfy the maximum discharge current. In addition, when the number of storage battery cells is small, or when the storage battery is a three-phase uninterruptible power supply, the discharge current may be relatively larger than the input / output alternating current. Furthermore, since the discharge current is a direct current, the average current is larger than the alternating current, causing a problem that the loss of the switching element is increased.

  That is, it is necessary to select and use a switching element used in the charge / discharge DC-DC converter having a predetermined characteristic according to the specification during discharge. For this reason, it is necessary to select a switching element having a larger rating such as current and loss than a switching element in a range that can be selected based on the specifications of the converter and the inverter. As a result, the switching element becomes expensive. Moreover, when using the switching element of a DC-DC converter in the same module containing 6 elements including the switching element used for a converter or an inverter, you must select an element from the specification by discharge current. Don't be. Furthermore, it is necessary to select the reactor used for the DC-DC converter in consideration of the maximum discharge current.

  The present invention has been made in view of such problems. The object of the present invention is to reduce the discharge current flowing in the charge / discharge DC-DC converter of the storage battery, thereby reducing the cost and space. It is to provide a possible uninterruptible power system.

In order to solve the above-described problems and achieve the object of the present invention, an uninterruptible power supply apparatus of the present invention includes an AC-DC converter that converts commercial power to DC, and a DC voltage converted by the AC-DC converter. a capacitor for smoothing, when converting the smoothed DC voltage by the smoothing capacitor into an AC voltage comprises an inverter for supplying power to a load, the power from the commercial power source is supplied normally, AC-DC converter When the DC voltage converted in step 1 is supplied to the inverter and power is normally supplied from the commercial power supply, the DC voltage converted by the AC-DC converter is stepped down to charge the storage battery, causing the commercial power supply to malfunction. In this state, a DC-DC converter for charging / discharging that supplies DC power to the inverter by boosting and discharging the power of the storage battery charged when the commercial power supply is normal. In the uninterruptible power supply having a data, in front of the AC-DC converter, a switching means for supplying power of the battery to the AC-DC converter provided, when the commercial power source is abnormal state, the commercial power supply side of this switching means Is switched to the storage battery side, the power of the storage battery is supplied to the AC-DC converter , and the AC-DC converter is operated as a DC-DC converter by boosting the power of the storage battery by the switching element constituting the AC-DC converter. Furthermore, power monitoring means for monitoring the output power is provided, and when the power monitoring means detects that the value of the output power exceeds the threshold value, the AC-DC converter is operated as a discharging DC-DC converter. A plurality of discharge DC-DC converters are arranged in the discharge path .

  Furthermore, as a preferred embodiment of the present invention, in the above-described uninterruptible power supply, when the commercial power supply is in an abnormal state, the switching cycle of the charge / discharge DC-DC converter and the AC- The ripple current of the DC voltage supplied to the smoothing capacitor is reduced by shifting the switching period of the DC converter.

  Further, as a further preferred embodiment, a separating means for separating the charging / discharging path may be provided between the charging / discharging DC-DC converter and the storage battery, and an additional reactor may be provided in the charging direction path.

  According to the present invention, an AC-DC converter that converts alternating current to direct current when the commercial power supply is normal operates as a discharge DC-DC converter when the commercial power supply is abnormal. The current can be reduced. Thereby, size reduction of the reactor used for a DC-DC converter is attained. Moreover, since the selection range of the switching element used for a DC-DC converter becomes wide, use of a low-cost switching element is attained.

  The present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a configuration of an uninterruptible power supply according to an embodiment of the present invention.

  In FIG. 1, one end of the alternating current from the commercial power source 1 is connected to the connection midpoint of the switching elements 21 and 22 connected in series constituting the converter 2 through the switch 13 and the reactor 81. Further, the other end of the alternating current from the commercial power source 1 is connected to a connection midpoint of the switching elements 23 and 24 connected in series constituting the converter 2. These switching elements 21 and 22 and switching elements 23 and 24 are driven by signals from the control circuit 100. A smoothing capacitor 6 is connected between both ends of the switching elements 21 and 22 and the switching elements 23 and 24.

  Further, both ends of the capacitor 6 are connected to both ends of the switching elements 31 and 32 and the switching elements 33 and 34 that are connected in series to constitute the inverter 3. The switching elements 31 and 32 and the switching elements 33 and 34 are also driven by signals from the control circuit 100. The connection midpoints of the switching elements 31 and 32 and the switching elements 33 and 34 are connected to the load 4 through the low-pass filter 10. Further, the output (voltage and current) of the low-pass filter 10 is supplied to the power discriminating circuit 101 that switches the operation of the control circuit 100.

  On the other hand, both ends of switching elements 51 and 52 connected in series constituting the DC-DC converter 5 are connected between both ends of the capacitor 6. The switching elements 51 and 52 are also driven by a signal from the control circuit 100. And the connection midpoint of these switching elements 51 and 52 is connected to the storage battery 7 through the circuit of the reactors 9 and 14 and the diode 11 which were connected in series, and the discharge operation switch 12 connected in parallel to the reactor 14 and the diode 11. . Further, the storage battery 7 is connected to the switcher 13. These discharge operation switch 12 and switch 13 are also driven by signals from the control circuit 100.

  In the uninterruptible power supply having the above configuration, converter 2 converts the alternating current of commercial power supply 1 into a direct current. The direct current is further inversely converted into alternating current by the inverter 3, and power is supplied to the load 4 through the low-pass filter 10. The capacitor 6 is provided for smoothing the DC voltage converted by the converter 2. The DC voltage of the capacitor 6 is made larger than the voltage of the storage battery 7.

  Further, the charging / discharging DC-DC converter 5 operates as a step-down chopper circuit to charge the storage battery 7 when the commercial power source 1 is normal. Further, when the commercial power source 1 is abnormal, the charge / discharge DC-DC converter 5 operates as a step-up chopper circuit and supplies DC power from the storage battery 7 to the inverter 3. The charging current at the time of charging the storage battery flows to the storage battery 7 via the reactors 9 and 14 and the diode 11. At the time of discharging, the discharge operation switch 12 is turned on, and from the storage battery 7 to the capacitor 6 via the discharge operation switch 12 and the reactor 9. Current to

  Since the discharge operation switch 12 is used in a DC circuit and may be a latch type, it is appropriate to use a thyristor. Converter reactor 81 is a part of a filter for removing harmonics generated from converter 2. Further, the switching device 13 is switched to connect the converter 5 and the commercial power source 1 when the commercial power source 1 is normal, and to connect the converter 5 and the storage battery 7 when abnormal.

  Therefore, in the above-described uninterruptible power supply, when the commercial power supply 1 is normal, the DC-DC converter 5 is controlled to operate as a step-down chopper circuit in order to charge the storage battery 7 as described above. The step-down chopper circuit at this time is composed of a DC-DC converter 5, a diode 11, a storage battery 7, and a diode reversely connected to the switching element 52 using the DC voltage of the capacitor 6 as a power source. At this time, only the switching element 51 needs to be switched.

  When the commercial power source 1 becomes abnormal, the switching element 51 is stopped and the discharge operation switch 12 is turned on. Soon after the switching element 51 is stopped, all the energy of the reactor 9 is released, the charging current disappears, and the diode 11 is turned off. At this time, the booster chopper circuit is configured using the storage battery 7 as a power source, and the switching element 52 is operated.

  When the switching element 52 is turned on, the voltage of the storage battery 7 is applied to the DC-DC converter reactor 9, the energy is accumulated in the direction opposite to that during charging, and the discharge current 15 flows. When the switching element 52 is off, the discharge current 15 flows through the capacitor 6 through the diode reversely connected to the switching element 51.

  As described above, the DC-DC converter 5 operates as a so-called bidirectional DC-DC converter. Here, the step-up chopper circuit using the DC-DC converter reactor 9 that operates when the commercial power supply is abnormal will be referred to as a dedicated chopper.

  Next, the operation of the converter 2 will be described. First, when the commercial power supply is normal, converter control is performed to shape the reactor current 16 into a sine wave in order to keep the DC voltage of the capacitor 6 constant and increase the input power factor. At this time, the reactor 81 not only suppresses the harmonic current generated in the converter 2 but also functions to boost the voltage of the commercial power source 1.

  On the other hand, when an abnormality occurs in the commercial power source 1, the converter 2 is stopped and the switch 13 switches the connection destination of the converter 2 to the storage battery 7. Here, the circuit configuration including the storage battery 7, the reactor 81, and the switching elements 21 and 22 is the same as the step-up chopper circuit including the reactor 9, the switching elements 51 and 52, and the storage battery 7, and the switching element 22 is described above. By performing the same operation as that of the switching element 52, the storage battery voltage can be boosted and discharged.

  That is, when the commercial power supply is normal and abnormal, the switching elements 21 and 22 are driven as shown in the waveform diagram of FIG. 2, for example.

  Here, FIGS. 2A and 2B are waveform diagrams when the commercial power supply is normal, and the alternating current is converted into direct current by driving the switching elements 21 and 22 with pulses that are PWM-modulated in accordance with the input alternating current waveform. 2C and 2D are waveform diagrams in the case where an abnormality occurs in the commercial power source 1. The switching element 21 is stopped and the switching element 22 is driven as shown in FIG. 2D to boost the storage battery voltage. Can be discharged. The step-up chopper circuit configured using the converter reactor 81 in this way is referred to as a combined chopper.

  When the commercial power source 1 returns to the normal state, the operation of the switching element 22 is stopped, and the switcher 13 switches the connection destination of the converter 2 to the commercial power source 1. The converter 2 including the switching element 22 returns to the operation of the forward converter that performs AC-DC conversion again, and is supplied with power from the commercial power source 1. As a result, even if a commercial power supply abnormality occurs, stable power supply to the inverter 3 can be continued, and since the booster chopper circuit for discharging the storage battery has two configurations, the current flowing through one booster chopper circuit is reduced. The first object of the present invention is achieved.

  Furthermore, the uninterruptible power supply of the present invention can be implemented in a device applied to a half-bridge converter as shown in FIG. 3 or a three-phase uninterruptible power supply as shown in FIGS.

  That is, in the apparatus of FIG. 3, the converter 2 is configured with a half bridge composed of switching elements 21 and 22, and the inverter 3 is composed of a half bridge composed of switching elements 31 and 32. In such a half-bridge configuration, an uninterruptible power supply similar to the full-bridge configuration in FIG. 1 can be configured.

  Further, in the apparatus of FIG. 4, the converter 2 is configured by a half bridge composed of switching elements 21-22, 23-24, and 25-26 for each of the three-phase inputs, and the inverter 3 is switched for each of the three-phase outputs. It is composed of a half bridge consisting of -32, 33-34, and 35-36. Thus, a three-phase uninterruptible power supply can be configured.

  Further, in the apparatus of FIG. 5, the converter 2 is configured by a half bridge composed of switching elements 21-22 and 23-24 for the two-phase input of the three phases, and the inverter 3 is switched for each three-phase output. A half bridge composed of 31-32, 33-34, and 35-36 is used, and one of the three-phase outputs of the low-pass filter 10 is connected to the remaining one of the three-phase inputs. This also makes it possible to configure a three-phase uninterruptible power supply.

  Among such uninterruptible power supply units, the AC circuit has three phases in the configurations of FIGS. 4 and 5, and therefore the difference between the discharge current from the storage battery 7 and the magnitude of the AC current is compared with that of a single-phase machine. Become bigger. On the other hand, in the present invention, the discharge current flowing through the charge / discharge DC-DC converter 5 can be reduced. In particular, in FIG. 4, by providing the switching unit 18, the number of phases that can be operated with the converter 2 serving as the dual chopper becomes two, and three DC-DC converters for discharging are arranged in parallel. Therefore, the discharge current flowing per unit is further reduced.

  Furthermore, in this case, the DC-DC converter 5 can use a switching element equivalent to the switching element used for the converter 2 or the inverter 3. Alternatively, the parallel number of switching elements used in the DC-DC converter 5 can be reduced, and cost reduction and space saving can be realized.

  3 and 5, the number of switching elements related to the capacitor 6 is three or six. Therefore, when each switching element is one parallel, the use of a module product containing six elements is used. And the number of parts can be reduced. Since these circuits also reduce the current flowing through the switching element 52 according to the present invention, the rated specifications of the module can be lowered and the cost can be reduced.

  By the way, when the commercial power supply is abnormal, it is not necessary to always operate the two boost chopper circuits of the dedicated chopper and the combined chopper. This is based on, for example, performing a power failure operation using only the dedicated chopper, and the dual-purpose chopper can be operated when the output power of the inverter 3 exceeds a preset threshold value. Although there are various methods for setting the threshold, it is appropriate to determine the threshold value of the output power at which the dedicated chopper can operate alone as the threshold.

  As a result, when the output power of the inverter 3 exceeds the threshold value when the commercial power supply is normal, the dual chopper is operated from the moment of switching to the power failure operation. Otherwise, the output power is set to the threshold value during the power failure operation. The dual-use chopper is operated from the time when the value is exceeded. However, the switching device 13 is switched to the storage battery 7 side regardless of the operation of the dual-purpose chopper.

  In the embodiment shown in FIG. 4, since the discharge boost chopper circuit has three configurations, the operation based on output power monitoring can be performed in three stages. Thereby, the effect that the efficiency of the whole DC-DC converter in a light load becomes high is acquired. Such operation control can be performed by monitoring the output power of the low-pass filter 10 by the power discrimination circuit 101 and switching the operation of the control circuit 100 based on the discrimination output.

  Furthermore, in the uninterruptible power supply of the present invention, the ripple current flowing from the storage battery 7 to the capacitor 6 can be reduced by shifting the switching cycle of the plurality of boost chopper circuits when the commercial power supply is abnormal.

  That is, FIGS. 6 and 7 show discharge current ripples in the embodiment of the uninterruptible power supply device shown in FIG. 1 when the switching periods are aligned (FIG. 6) and when the switching periods are shifted (FIG. 7). A waveform diagram is shown. Here, when the switching periods of the switching elements 52 and 22 are aligned as shown in FIGS. 6B and 6D, the waveforms of the discharge current 15 shown in FIG. 6A and the discharge current 16 shown in FIG. The total discharge current shown in FIG.

  On the other hand, when the switching periods of the switching elements 52 and 22 are shifted by half as shown in FIGS. 7B and 7D, the waveforms of the discharge current 15 shown in FIG. 7A and the discharge current 16 shown in FIG. Thus, the total discharge current shown in FIG. In this case, the peak value of the total discharge current is reduced to one third, and the ripple frequency is doubled. Note that such control for shifting the switching cycle by a half cycle is performed by the control circuit 100.

  Therefore, the peak value of the ripple current of the total discharge current of the storage battery 7 is reduced, and the electrolytic capacitor used in the capacitor 6 is less affected by the internal temperature rise as the ripple current becomes higher. This is effective in extending the life of the capacitor 6. The waveform diagrams shown in FIGS. 6 and 7 correspond to the case where the inductances of the converter reactor 81 and the DC-DC converter reactor 9 have the same value.

  Further, in FIGS. 8 and 9, in the embodiment of the three-phase uninterruptible power supply device shown in FIG. 4, the switching periods are aligned (FIG. 8) and the one-third period is shifted (FIG. 8). The ripple waveform figure of the discharge current of 9) is shown. Here, when the switching periods of the switching elements 52, 22, and 24 are aligned as shown in FIGS. 8B, 8D, and 8F, the discharge current 15 shown in FIG. 8A, the discharge current 16 shown in FIG. 8C, and FIG. The waveform of the discharge current 17 shown in FIG. 8 matches, and the total discharge current shown in FIG. 8G increases.

  On the other hand, when the switching periods of the switching elements 52, 22, and 24 are shifted by one third as shown in FIGS. 9B, 9D, and 9F, the discharge current 15 shown in FIG. The discharge current 16 shown in FIG. 8 and the waveform of the discharge current 17 shown in FIG. 8E shift, and the total discharge current shown in FIG. 8G becomes smaller. In this case, the peak value of the total discharge current is reduced by a factor of nine and the ripple frequency is tripled. The control circuit 100 performs such control that shifts the switching period by one-third period.

  Accordingly, even in this case, the peak value of the ripple current of the total discharge current of the storage battery 7 is reduced, and the electrolytic capacitor used in the capacitor 6 is less affected by the internal temperature rise as the ripple current is higher. Therefore, the temperature rise of the capacitor 6 can be reduced, and the life of the capacitor 6 can be extended. The waveform diagrams shown in FIGS. 8 and 9 are for the case where the inductances of converter reactors 81 and 82 and DC-DC converter reactor 9 have the same value.

  Further, the waveform diagrams shown in FIGS. 6 to 9 are cases where the on-duty of the drive waveform is 25%, but the ripple reduction rate varies depending on the DUTY. That is, the above values are on condition that the on-duty is 25%, the step-up chopper operation is in the continuous mode, and the inductance values of the reactors are equal.

  In the above-described configuration, the reduction rate increases as the on-duty approaches 50%. That is, in the case of the two switching elements, the ripple disappears when the ON duty is 50%. Further, in the case of the two switching elements, it can be reduced to 1/6 when ON DUTY is 40%, and can be reduced to about 1/4 (1 / 3.5) when ON DUTY is 30%. Furthermore, it can be reduced to one third with ON duty 25%.

  In the above-described configuration, the inductance of the converter reactor 81 and the DC-DC converter reactor 9 have the same value. For example, in the embodiment shown in FIG. In some cases, the inductance value needs to be considerably smaller than the inductance of the DC-DC converter reactor 9. In that case, for example, a circuit as shown in FIG. 10 may be configured.

  That is, in FIG. 10, a discharge operation reactor 84 is mounted between the switch 13 and the storage battery 7 for the boost chopper circuit. In this case, a reactor whose sum with the converter reactor 81 corresponds to the reactor 9 for the DC-DC converter may be selected as the reactor 84. Thus, the inductances of converter reactors 81 and 84 and DC-DC converter reactor 9 can be made equal.

  Further, regarding the control, when there is a difference between the impedances of the dedicated chopper and the dual-purpose chopper, the discharge current 15 and the reactor current 16 are unbalanced only by the control targeting the DC voltage of the capacitor 6. Therefore, it is better to add current control that makes the magnitudes of the discharge current 15 and the reactor current 16 an arbitrary ratio in the control of the dedicated chopper and the combined chopper.

  Here, since the circuit impedance is usually small, the pulse adjustment amount for balancing the current is very small with respect to the pulse width. Therefore, for example, as shown in FIG. 11, the dedicated chopper is controlled only by the DC voltage control of the capacitor 6, and the dual-purpose chopper adds a current control amount for making the current an arbitrary ratio to the duty necessary for the DC voltage control. With the ratio coefficient 93 in FIG. 11, the discharge current 15 and the reactor current 16 can be set to an arbitrary ratio.

  Further, since the control amount of the current balance control is very small, the limiter 94 may be about one-tenth of the control amount of the DC voltage AVR 92. By performing the current balance control, a constant current ratio can be realized even when the element values of the reactor 81 and the reactor 9 are varied or the inductance value is different, for example, when the inductance ratio is 1: 2. .

  As is clear from the description of each of the above embodiments, according to the uninterruptible power supply disclosed in the present invention, the discharge current flowing through the DC-DC converter 5 is reduced, so that the switching element and the reactor can be reduced. The price and size can be reduced, and the uninterruptible power supply can be reduced in cost and space.

  That is, according to the uninterruptible power supply disclosed in the present invention, the reactor used for the DC-DC converter can be downsized. Moreover, since the selection range of the switching element used for a DC-DC converter spreads, a low-cost switching element can be used.

  Furthermore, the present invention makes it possible to use a switching element of a DC-DC converter in the same module as a switching element used in a converter or an inverter, particularly in a small and medium capacity uninterruptible power supply. Moreover, in a large-capacity uninterruptible power supply device, the parallel number of the switching elements used for a DC-DC converter can be made small. Thus, according to the uninterruptible power supply device of the present invention, the number of parts can be reduced and the size can be reduced, so that the work process can be reduced and the space can be saved.

  The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the claims.

It is a simple circuit diagram which shows the structure of the uninterruptible power supply which concerns on one embodiment of this invention. 4 is a waveform diagram of switching drive when the power supply is normal and abnormal with respect to the switching elements 21 and 22 constituting the converter 2. FIG. It is a simple circuit diagram of an embodiment of the uninterruptible power supply device of the present invention applied to a half-bridge converter. It is a simplified circuit diagram of an example of an embodiment of an uninterruptible power supply of the present invention applied to a general three phase machine. It is a simplified circuit diagram of an embodiment of the uninterruptible power supply device of the present invention applied to a three-phase machine having a common input / output phase. It is a relationship figure showing the ripple of a storage battery discharge current in case the switching period and timing of two step-up chopper circuits which operate | move at the time of a commercial power supply abnormality correspond. It is a related figure showing the ripple of a storage battery discharge current at the time of shifting the switching period of two step-up chopper circuits which operate | move at the time of a commercial power source abnormality by a half cycle. It is a relationship figure showing the ripple of a storage battery discharge current in case the switching period and timing of three boost chopper circuits which operate | move at the time of a commercial power supply abnormality correspond. It is a relationship figure showing the ripple of a storage battery discharge current at the time of shifting the switching period of the 3 step-up chopper circuits which operate at the time of abnormality in commercial power supply by 1/3 period. It is the simple circuit diagram which showed a part of uninterruptible power supply which concerns on the other embodiment of this invention in case the inductance applied to the reactor for converters at the time of alternating current operation and direct current operation differs. It is a simple block diagram showing an example of the control method for implement | achieving the balance of the electric current which flows into two boost choppers.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Commercial power source, 2 ... Converter, 3 ... Inverter, 4 ... Load, 5 ... DC-DC converter, 6 ... Capacitor, 7 ... Storage battery, 81-83 ... Converter reactor, 84 ... Reactor for discharge operation, 9 ... DC -DC converter reactor, 10 ... low pass filter, 11 ... diode, 12 ... discharge operation switch, 13, 18 ... switch, 14 ... reactor, 15 ... discharge current, 16, 17 ... reactor current, 21-26, 31 ˜36, 51, 52... Switching element, 91... DC voltage AVR, 92 .. ACR for current balance, 93... Ratio factor, 94.

Claims (3)

An AC-DC converter that converts commercial power into direct current;
A capacitor for smoothing the DC voltage converted by the AC-DC converter;
An inverter that converts the DC voltage smoothed by the smoothing capacitor into an AC voltage and supplies power to a load, and when the power is normally supplied from the commercial power supply, the DC converted by the converter Supplying voltage to the inverter;
When power is normally supplied from the commercial power source, the DC voltage converted by the converter is stepped down to charge the storage battery. When the commercial power source is in an abnormal state, the power of the charged storage battery is by boosting to be discharged, in the uninterruptible power supply having a charge discharging DC-DC converter that to supply DC power to the inverter,
Switching means for supplying the power of the storage battery to the AC-DC converter is provided in the front stage of the AC-DC converter,
Wherein when the commercial power source is abnormal state, by switching the switching means to the storage battery side from the commercial power supply side to supply the power of the storage battery before Symbol AC-DC converter, the switching elements constituting the AC-DC converter wherein by boosting the power of the storage battery to operate the AC-DC converter as a DC-DC converter by,
Furthermore, a power monitoring means for monitoring the output power is provided,
When the power monitoring means detects that the value of the output power exceeds a threshold value, the AC-DC converter is operated as a discharge DC-DC converter, and the discharge DC-DC converter is used as a discharge path. An uninterruptible power supply characterized by arranging a plurality of units . In the uninterruptible power supply according to claim 1,
When the commercial power supply is in an abnormal state, the smoothing capacitor is shifted by shifting the switching cycle of the charge / discharge DC-DC converter and the switching cycle of the AC-DC converter that also serves as the discharge DC-DC converter. Reduced ripple current of DC voltage supplied to
An uninterruptible power supply. In the uninterruptible power supply according to claim 1 or 2,
Separating means for separating a charging / discharging path is provided between the charging / discharging DC-DC converter and the storage battery, and an additional reactor is provided in the charging direction path.
An uninterruptible power supply.

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