JPH10285830A - Uninterruptible power supply unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To attain miniaturization in a power supply unit and improved power conversion efficiency by using a common power conversion transformer for both the commercial input and the chargeable battery input due to power failure. SOLUTION: A device uses a back boost method in which the winding direction of the third winding of a power conversion transformer is made opposite to that of the first winding. In on ordinary operation, power to load is supplied form a commercial AC power supply unit 1, converted into direct current by a rectifying circuit 3 after noise is removed by a filter 2, smoothed by a capacitor C1, and switched on/off by a switching element S11, so that high-frequency AC is generated in the third winding N21 side of the power conversion transformer T. In case of power failure, if the output voltage EB of a chargeable battery 5 is on/off-controlled by a switching element S12, and the second winding N12 of the power conversion transformer T is driven through a counter-current preventing diode D12, the high frequency AC is generated in the third winding N21. By using the common power conversion transformer, it is possible to reduce the size of the device and improve the power supply conversion efficiency.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an uninterruptible power supply, and more particularly, to an improvement of an uninterruptible power supply using a DC / DC converter system.

[0002]

2. Description of the Related Art In recent years, a power supply device used for a computer system, a communication device, and the like employs a system in which a commercial AC power supply is usually used and power is supplied from a battery at the time of a power failure in order to avoid a state in which the power supply is stopped. doing.

FIG. 9 is a diagram showing a first example of a conventional multi-input / single-output power supply circuit. This example shows a buck-boost system in which the winding directions of a primary winding and a secondary winding of a power conversion transformer are reversed and a choke coil (reactor) used in a secondary-side power supply voltage generation circuit is not required. . In this buck-boost method, when the primary switching element is on, energy is stored in the core of the power conversion transformer, and when the primary switching element is turned off, the energy stored in this core is converted to secondary energy. It is designed to be released to the side.

(1) During Normal Operation During normal operation, power to the load is supplied from the commercial AC power supply 1. The commercial AC voltage enters a noise filter (harmonic filter) 2. The noise filter 2 is for preventing noise generated by the switching circuit from leaking to the commercial side. The output of the noise filter 2 is a rectifier circuit 3
And is converted to direct current. The output of the rectifier circuit 3 is smoothed by the smoothing capacitor C1 and becomes a DC having flat characteristics.

The DC voltage smoothed by the smoothing capacitor C1 is turned on / off by a switching element S11. The switching element S11 is connected to the primary winding N of the first transformer T1 via a backflow prevention diode D11.
The DC voltage E11 applied to the capacitor C1 is turned on / off by the switching element S11, so that a high-frequency AC is generated on the secondary winding N21 side of the first transformer T1.

The high-frequency AC is supplied to a rectifying diode D2.
After being rectified by DC and converted to DC, it is smoothed by a smoothing capacitor C2 to be a flat DC. The secondary winding N21, the rectifying diode D21, and the smoothing capacitor C2 constitute a first power supply voltage generating circuit.

The voltage E01 applied to the smoothing capacitor C2 at this time becomes the output voltage of the power supply. In this case, the conduction time of the switching element S11 depends on the output voltage E
Pulse width control (PWM control) so that 01 becomes a constant value
Is done.

On the other hand, the first power conversion transformer T1 includes:
A third winding N2B is provided, and high-frequency AC is generated in the third winding N2B by switching on the primary side. At this time, the switch S is on,
The DC voltage rectified by the rectifier diode D2B is smoothed by the smoothing capacitor C3.

The voltage E0B applied to the smoothing capacitor C3 is connected to the constant current circuit 4. The constant current circuit 4 receives the voltage E0B, generates a constant current, and charges a rechargeable battery 5 (a battery, for example, a secondary battery). At this time, the switching element S12 connected to the rechargeable battery 5 is off, and the rechargeable battery 5 is charged with energy.

(2) At the time of a power outage If the commercial AC voltage is not supplied due to the power outage, charging is possible.
Output voltage E of the active battery 5 _BWith the switching element S12
On / off control, and the primary winding N1 of the second transformer T2.
2 is driven via a backflow preventing diode D12. This
As a result, the secondary winding N22 of the second transformer T2 has:
High frequency alternating current is generated.

The high-frequency alternating current is supplied to a rectifying diode D2.
After being rectified by DC and converted to DC, it is smoothed by a smoothing capacitor C4 to be a flat DC. The secondary winding N22, the rectifying diode D22, and the smoothing capacitor C4 constitute a second power supply voltage generating circuit.

The voltage E02 applied to the smoothing capacitor C4 at this time becomes the output voltage of the power supply. In this case, the conduction time of the switching element S12 depends on the output voltage E
Pulse width control (PWM control) so that 02 becomes a constant value
Is done. At this time, the switch S is off.

The outputs of the first power supply voltage generation circuit and the second power supply voltage generation circuit are respectively connected to a diode D0.
1, or OR-coupled via D02 to supply power to the load. That is, power is supplied to the load from the first power supply voltage generation circuit via the diode D01 during normal operation, and power is supplied to the load from the second power supply voltage generation circuit via the diode D02 during a power failure.

The following are examples of circuits of various types of conventional power supply devices. FIG. 10 is a diagram showing a first example of a conventional multi-input / multi-output power supply circuit. The same components as those in FIG. 9 are denoted by the same reference numerals. This example is also a buck-boost uninterruptible power supply like the example shown in FIG. In this example, a power supply voltage generation circuit having the same configuration as that of the power supply voltage generation circuit including the secondary winding N21, the rectifying diode D21, and the smoothing capacitor C2 is provided to configure a multi-output power supply device. That is, the secondary winding N21 ', the rectifying diode D21', and the smoothing capacitor C2 'constitute a power supply voltage generating circuit.

On the other hand, two power supply circuits for generating an output voltage from the rechargeable battery 5 are also provided. In this example, a power supply voltage generation circuit having the same configuration as the power supply voltage generation circuit including the secondary winding N22, the rectifying diode D22, and the smoothing capacitor C4 is provided. That is, the secondary winding N
The power supply voltage generating circuit is composed of the rectifying diode 22 ', the rectifying diode D22', and the smoothing capacitor C4 '.

The output of the first power supply voltage generation circuit of the power conversion transformer T1 and the first
And the output of the power supply voltage generating circuit
01 and D02, and the outputs of the second power supply voltage generation circuit of the power conversion transformer T1 and the output of the second power supply voltage generation circuit of the power conversion transformer T2 are diodes D01 'and D02', respectively. Is OR-bonded.

In the circuit thus configured, during normal operation, the first and second power supply voltage generating circuits of the power conversion transformer T1 generate output voltages by PWM control of the switching element S11. Is turned on to charge the rechargeable battery 5 by the charging circuit.

At the time of a power failure, P of switching element S12
The first and second power conversion transformers T2 are controlled by the WM control.
To generate an output voltage. The details of the operation of each circuit are the same as those described in FIG.

FIG. 11 is a diagram showing a second example of a conventional multi-input / single-output power supply circuit. The same components as those in FIG. 9 are denoted by the same reference numerals. In this example, the power conversion transformer 1
This figure shows a forward method in which a choke coil (reactor) is provided in a secondary-side rectifying / smoothing circuit in which the winding directions of a secondary winding and a secondary winding are the same.

In this forward method, when the primary-side switching element is on, energy is stored in a choke coil (reactor) provided in the secondary-side smoothing circuit, and when the primary-side switching element is turned off. The energy stored in the choke coil is released to the load side.

In the figure, L1 is a choke coil provided in the first power supply voltage generation circuit, and L2 is a choke coil provided in the second power supply voltage generation circuit. D3
1 is a diode that forms a full-wave rectifier circuit together with D21, and D32 is a diode that forms a full-wave rectifier circuit together with D22.

In the circuit thus configured, during normal operation, the output voltage is generated in the power supply voltage generation circuit of the power conversion transformer T1 by the PWM control of the switching element S11, during which the switch S is turned on to turn on the charging circuit. To charge the rechargeable battery 5.

At the time of a power failure, P of switching element S12
By the WM control, an output voltage is generated in the power supply voltage generation circuit of the power conversion transformer T2. The details of the operation of each circuit are the same as those described in FIG.

FIG. 12 is a diagram showing a second example of a conventional multi-input / multi-output power supply circuit. 10 and 11 are denoted by the same reference numerals. In this example, the secondary winding N2
1, a power supply voltage generation circuit having the same configuration as the power supply voltage generation circuit including the full-wave rectification diodes D21 and D31, the choke coil L1, and the smoothing capacitor C2 is provided.
It constitutes a multi-output power supply. That is, the secondary winding N2
1 ', the full-wave rectifier diodes D21' and D31 ', the choke coil L1', and the smoothing capacitor C2 'constitute a power supply voltage generating circuit.

On the other hand, two power supply circuits for generating an output voltage from the rechargeable battery 5 are also provided. In this example, a power supply voltage generation circuit having the same configuration as the power supply voltage generation circuit including the secondary winding N22, the diodes D22 and D32 for full-wave rectification, the choke coil L2, and the smoothing capacitor C4 is provided. That is, the secondary winding N22 ', the diodes D22' and D32 'for full-wave rectification, the choke coil L
A power supply voltage generating circuit is constituted by 2 'and the smoothing capacitor C4'.

The output of the first power supply voltage generation circuit of the power conversion transformer T1 and the first
And the output of the power supply voltage generating circuit
01 and D02, and the outputs of the second power supply voltage generation circuit of the power conversion transformer T1 and the output of the second power supply voltage generation circuit of the power conversion transformer T2 are diodes D01 'and D02', respectively. Is OR-bonded.

In the circuit thus configured, during normal operation, an output voltage is generated in the first and second power supply voltage generating circuits of the power conversion transformer T1 by PWM control of the switching element S11, and during this time, the switch S Is turned on to charge the rechargeable battery 5 by the charging circuit.

At the time of a power failure, the switching element S12
By the WM control, power is supplied from the rechargeable battery 5 and the first and second power supply voltage generation circuits of the power conversion transformer T2 generate output voltages. The details of the operation of each circuit are the same as those described in FIG.

FIG. 13 is a diagram showing a third example of a conventional multi-input / single-output power supply circuit. In this example, a primary winding of a power conversion transformer is divided into two parts, and each winding is alternately turned on / off by a switching element (push-pull method).

In the first power conversion transformer T1, N
11A and N11B are primary windings divided into two, N21
A and N21B are secondary windings divided into two. The output of the rectifier circuit 3 is connected to the middle point between the primary windings N11A and N11B. The primary winding N11A is ON / OFF controlled by the switching element S11A, and the primary winding N11A is controlled.
B is on / off controlled by the switching element S11B.

By this on / off control, a high-frequency alternating current is generated on the secondary side of the power conversion transformer T1, but the two-side winding is also divided into N21A and N21B, and the midpoint of these windings is set as a common potential. Rectifier diodes D21, D31
Full-wave rectification of the AC generated at In this example, since the forward method is adopted, the choke coil L1 is provided in the secondary-side power supply voltage generation circuit.

Such a configuration is the same for the second power conversion transformer T2. In the second power conversion transformer T2, N12A and N12B are divided into two parts 1
The secondary windings N22A and N22B are secondary windings divided into two. The anode of the rechargeable battery 5 is connected to the middle point between the primary windings N12A and N12B. Primary winding N12A
Is turned on / off by a switching element S12A, and the primary winding N12B is turned on / off by a switching element S12B.

In the first power conversion transformer T1, 2
The secondary winding is divided into two parts N21A and N21B, and the middle point is a common line for the secondary power supply output. The high-frequency AC generated in the secondary winding is full-wave rectified by rectifier diodes D21 and D31, and the output of the rectifier circuit is connected to a smoothing capacitor C2 via a choke coil L1. Then, the voltage applied to the capacitor C2 becomes the output of the first power supply voltage generation circuit.

In the second power conversion transformer T2, 2
The secondary winding is divided into N22A and N22B, and the middle point is a common line for the secondary power supply output. The high-frequency AC generated in the secondary winding is full-wave rectified by rectifier diodes D22 and D32, and the output of the rectifier circuit is connected to a smoothing capacitor C4 via a choke coil L2. Then, the voltage applied to the capacitor C4 becomes the output of the second power supply voltage generation circuit.

The outputs of the first power supply voltage generation circuit and the second power supply voltage generation circuit are respectively connected to a diode D0.
1, or OR-coupled via D02 to supply power to the load. That is, power is supplied to the load from the first power supply voltage generation circuit via the diode D01 during normal operation, and power is supplied to the load from the second power supply voltage generation circuit via the diode D02 during a power failure.

On the other hand, the winding on the charging circuit side is also divided into N2BA and N2BB, and the middle point is a common line of the charging circuit. The high-frequency alternating current generated in the winding is full-wave rectified by the diodes D2B and D3B, and its output is smoothed by the choke coil L3 and the capacitor C3 to become a flat DC voltage. The output of this charging circuit charges the rechargeable battery 5 via the switch S and the constant current circuit 4.

In the circuit thus configured, during normal operation, an output voltage is generated in the power supply voltage generation circuit of the power conversion transformer T1 by PWM control in which the switching elements S11A and S11B are alternately turned on / off. Then, the switch S is turned on to charge the rechargeable battery 5 via the constant current circuit 4 by the charging circuit.

At the time of a power failure, power is supplied from the rechargeable battery 5 by PWM control for alternately turning on / off the switching elements S12A and S12B, and an output voltage is generated in the power supply voltage generation circuit of the power conversion transformer T2. The details of the operation of each circuit are the same as those described in FIG.

FIG. 14 is a diagram showing a third example of a conventional multi-input / multi-output power supply circuit. 12 and 13 are denoted by the same reference numerals. In this example, the secondary winding N2
1AN21B, full-wave rectifier diodes D21, D31,
A power supply voltage generation circuit having the same configuration as that of the power supply voltage generation circuit including the choke coil L1 and the smoothing capacitor C2 is provided to configure a multi-output power supply device. That is, the secondary windings N21A 'and N21B, the full-wave rectifier diode D2
1 ', D31', choke coil L1 ', and smoothing capacitor C2' constitute a power supply voltage generating circuit.

On the other hand, two power supply voltage generating circuits for generating an output voltage from the rechargeable battery 5 are also provided. In this example, a power supply voltage generation circuit having the same configuration as the power supply voltage generation circuit including the secondary windings N22A and N22B, the diodes D22 and D32 for full-wave rectification, the choke coil L2, and the smoothing capacitor C4 is provided. . That is, the secondary windings N22A 'and N22B', the full-wave rectifier diode D2
2 ', D32', choke coil L2 ', and smoothing capacitor C4' constitute a power supply voltage generation circuit.

The output of the first power supply voltage generation circuit of the power conversion transformer T1 and the first
And the output of the power supply voltage generating circuit
01 and D02, and the outputs of the second power supply voltage generation circuit of the power conversion transformer T1 and the output of the second power supply voltage generation circuit of the power conversion transformer T2 are diodes D01 'and D02', respectively. Is OR-bonded.

In the circuit thus configured, during normal operation, the switching elements S11A and S11B
The first and second power conversion transformers T1 are controlled by the WM control.
The power supply voltage generating circuit generates an output voltage. During this time, the switch S is turned on to charge the rechargeable battery 5 by the charging circuit.

At the time of a power failure, the switching elements S12A,
By the PWM control in S12B, power is supplied from the rechargeable battery 5 and the first and second power conversion transformers T2
To generate an output voltage. The details of the operation of each circuit are the same as those described in FIG.

[0044]

The above-mentioned conventional uninterruptible power supply has the following problems. Separate power conversion transformers were required for commercial operation and rechargeable battery operation, and two output rectifier circuits were required. Therefore, there is a problem that the shape of the power supply device becomes large. Since the output of the power supply device needs to be OR-coupled with a diode, there is a problem that when a current is supplied to a load, the power supply conversion efficiency is deteriorated due to a forward voltage drop of the diode.

The present invention has been made in view of such problems, and it is an object of the present invention to provide an uninterruptible power supply capable of reducing the size of a power supply and improving power conversion efficiency. The purpose is.

[0046]

[Means for Solving the Problems]

(1) FIG. 1 is a principle block diagram of the present invention. The same components as those in FIG. 9 are denoted by the same reference numerals. The device shown in the figure is an uninterruptible power supply that normally receives an AC input voltage and obtains a DC voltage by a DC / DC converter method, and receives a DC input voltage of a rechargeable battery and obtains a DC voltage by a DC / DC converter method during a power failure. Make up the device.

In the figure, 1 is an AC power supply, and 3 is a rectifier circuit for converting the output of the AC power supply 1 into a DC voltage. T is a power conversion transformer, one of which is provided. 10 is a first switching circuit that switches the output of the primary side rectifier circuit 3 to drive the first winding of the power conversion transformer T;
Reference numeral 20 denotes a second switching circuit that switches the output of the rechargeable battery 5 to drive the second winding of the power conversion transformer T.

Reference numeral 30 denotes a power supply voltage generating circuit for rectifying and smoothing the AC generated on the third winding side of the power conversion transformer T to generate an output voltage, and 40 generates a power supply voltage on the fourth winding side of the power conversion transformer T. A charging circuit for rectifying the alternating current to be charged and charging the rechargeable battery 5 with the rectified DC voltage;
A constant current circuit that receives the output voltage of 0 and charges the rechargeable battery 5 with a constant current.

According to the configuration of the present invention, at the time of commercial input,
By using the same power conversion transformer when a rechargeable battery is input due to a power failure, the shape of the power supply device can be reduced. Also, since only one power conversion transformer is needed, only one output rectifier circuit is required, and the OR coupling of the diodes is not required, so that the power conversion efficiency can be improved.

(2) In this case, the third winding of the power conversion transformer is wound in the opposite direction to the first winding, and one power supply voltage generating circuit is provided. It is characterized by supplying output power.

According to the configuration of the present invention, the back-boost method in which the third winding of the power conversion transformer is wound in the reverse direction to the first winding is adopted, so that the power supply voltage generating circuit is choked. A single-output uninterruptible power supply that does not require a coil can be provided.

(3) A plurality of third windings of the power conversion transformer are wound in a direction opposite to that of the first winding, and a plurality of power supply voltage generating circuits are provided. It is characterized by supplying.

According to the structure of the present invention, the buck-boost system in which the winding direction of the plurality of third windings of the power conversion transformer is wound in the opposite direction to the first winding is adopted.
A multiple output uninterruptible power supply that does not require a choke coil in the power supply voltage generation circuit can be provided.

(4) The third power conversion transformer
The winding direction of the winding is wound in the same direction as the first winding,
It is characterized in that one power supply voltage generating circuit is provided to supply a single output power to a load.

According to the configuration of the present invention, by adopting the forward system in which the winding direction of the third winding of the power conversion transformer is wound in the same direction as the first winding, the shape is small and the power conversion efficiency is low. A good single output uninterruptible power supply can be provided.

(5) A plurality of third windings of the power conversion transformer are wound in the same direction as the first winding, and a plurality of the power supply voltage generating circuits are provided. It is characterized by supplying.

According to the configuration of the present invention, the power conversion transformer employs a forward method in which the winding directions of the plurality of third windings are wound in the same direction as the first winding, so that the power conversion transformer has a small shape and the power conversion. An efficient multiple-output uninterruptible power supply can be provided.

(6) Further, the first switching circuit has a push-pull configuration, and one power supply voltage generating circuit is provided to supply a single output power to a load.

According to the configuration of the present invention, a single output uninterruptible power supply having a small shape and high power conversion efficiency can be provided by using a push-pull configuration for the first switching circuit.

(7) Further, the first switching circuit has a push-pull configuration, a plurality of power supply voltage generating circuits are provided, and a multi-output power supply is supplied to a load.

According to the configuration of the present invention, by providing the first switching circuit with a push-pull configuration, it is possible to provide a multiple output uninterruptible power supply having a small shape and high power conversion efficiency.

[0062]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 2 is a circuit diagram showing a first embodiment of the present invention. 1 and 9 are denoted by the same reference numerals. This example uses a buck-boost in which the winding direction of the third winding of the power conversion transformer is made opposite to the winding direction of the first winding, and the choke coil (reactor) used in the secondary-side power supply voltage generation circuit becomes unnecessary. The method is shown. In this buck-boost method, when the primary switching element is on, energy is stored in the core of the power conversion transformer, and when the primary switching element is turned off, the energy stored in this core is converted to secondary energy. It is designed to be released to the side.

In the figure, 1 is an AC power supply for generating commercial AC, 2 is a noise filter for preventing noise generated in the switching circuit from leaking to the commercial side, and 3 is an AC voltage receiving the output of the noise filter 2 and converting the AC voltage to DC. It is a rectifier circuit for converting to a voltage. As the rectifier circuit 3, for example, a full-wave rectifier circuit or a bridge rectifier circuit is used.

C1 is a smoothing capacitor connected to the output of the rectifier circuit 3, and S11 is a switching element for switching the voltage E11 applied to the smoothing capacitor C1. D11 is a backflow prevention diode connected in series with the switching element S11. T is a single power conversion transformer, N11 is a first winding, and N12 is a second winding.
, N21 is a third winding, and N2B is a fourth winding.

The diode D11 is connected to the first winding N11.
And the other end of the first winding is connected to a common line. The first switching circuit 10 includes the smoothing capacitor C1, the switching element S11, and the diode D11.

Reference numeral 5 denotes a rechargeable battery, for example, a secondary battery, a large capacity capacitor, an electric double layer capacitor, or the like. S12 is a switching element connected to the anode of the rechargeable battery 5, D12 is a reverse current blocking diode connected in series with the switching element S12, N12 is a second winding connected to the diode D12, and the other end. Is connected to a common line (the cathode side of the rechargeable battery 5). Then, the switching element S12 and the diode D1
2 together form a second switching circuit 20.

D21 is a diode for rectifying high-frequency AC generated in the third winding N21, and C2 is the diode D2.
This is a smoothing capacitor connected between 1 and the common line. The rectifier diode D21 and the smoothing capacitor C2 constitute the power supply voltage generation circuit 30.

D2B is a diode for rectifying the high-frequency AC generated in the fourth winding N2B, S is a switch connected in series with the rectifying diode D2B, and C3 is a smoothing connected between the switch S and the common line. It is a capacitor for use. The charging circuit 40 includes the rectifying diode D2B, the switch S, and the smoothing capacitor C3. Reference numeral 4 denotes a constant current circuit that receives the output of the charging circuit and charges the rechargeable battery 5 with a constant current. The operation of the circuit thus configured will be described as follows.

(1) During Normal Operation During normal operation, power to the load is supplied from the commercial AC power supply 1. After the commercial AC voltage enters the noise filter 2 to remove noise, it enters the rectifier circuit 3 and is converted to DC. The output of the rectifier circuit 3 is a smoothing capacitor C
The DC is smoothed at 1 and has a flat characteristic.

The DC voltage smoothed by the smoothing capacitor C1 is turned on / off by the switching element S11. The switching element S11 is connected to the primary winding N of the first transformer T1 via a backflow prevention diode D11.
The DC voltage E11 applied to the capacitor C1 is turned on / off by the switching element S11 to thereby control the third winding N21 of the power conversion transformer T.
A high-frequency alternating current is generated on the side.

This high-frequency AC is supplied to the rectifying diode D2
After being rectified by DC and converted to DC, it is smoothed by a smoothing capacitor C2 to be a flat DC. The voltage E01 applied to the smoothing capacitor C2 at this time becomes the output voltage of the power supply device. In this case, the conduction time of the switching element S11 is subjected to pulse width control (PWM control) so that the output voltage E01 has a constant value. Here, the output voltage E01 of the power supply voltage generation circuit is obtained by setting the conduction time of the switching element S11 to T _on1 , one cycle to Ts, and setting the number of turns of the first winding N11 to N11 without changing the number of turns of the third winding N21. Assuming that N21 is used as it is, it is approximately expressed by the following equation.

E01 = (T _on1 / Ts) × (N21 / N11) × E11 (1) Power is supplied to the load from the output voltage E01. On the other hand, the power conversion transformer T is provided with a fourth winding N2B, and high-frequency AC is generated in the fourth winding N2B by switching on the primary side. At this time, the switch S is on and the rectifying diode D2B
The DC voltage rectified by is smoothed by the smoothing capacitor C3.

At this time, the output voltage E0B of the charging circuit when the switch S is turned on is N as the number of turns of the fourth winding N2B.
If 2B is used as it is, it is approximately expressed by the following equation.

[0074] _{E0B = (T on1 / Ts)} × (N2B / N11) × E11 (2) Then, the voltage e0b according to the smooth capacitor C3 is connected to the constant current circuit 4. The constant current circuit 4 receives the voltage E0B, generates a constant current, and
(For example, a secondary battery). At this time, the switching element S12 connected to the rechargeable battery 5 is off, and the rechargeable battery 5 is charged with energy.

(2) At the time of power outage If the commercial AC voltage is not supplied due to the power outage, charging is possible.
Output voltage E of the active battery 5 _BWith the switching element S12
On / off control, and the second winding N1 of the power conversion transformer T
2 is driven via a backflow preventing diode D12. This
As a result, in the third winding N21 of the power conversion transformer T,
High frequency alternating current is generated.

This high-frequency AC is supplied to the rectifying diode D2
After being rectified by DC and converted to DC, it is smoothed by a smoothing capacitor C2 to be a flat DC. The voltage E01 applied to the smoothing capacitor C2 at this time becomes the output voltage of the power supply device. In this case, the conduction time of the switching element S12 is subjected to pulse width control (PWM control) so that the output voltage E01 has a constant value. At this time, the switch S is off.

[0077] The output voltage E01 at this time, the output voltage of the rechargeable battery 5 and E _B, the conduction time of the switching element S12 T _on2, 1 cycle Ts, the N12 as a number of turns of the second winding N12 as If used, it is approximately expressed by the following equation.

E01 = (T _on2 / Ts) × (N21 / N12) × E _B (3) Power is supplied to the load from the output voltage E01. According to this embodiment, the shape of the power supply device can be reduced by using the same power conversion transformer at the time of commercial input and at the time of input of a rechargeable battery due to a power failure. Also, since only one power conversion transformer is needed, only one output rectifier circuit is required, and the OR coupling of the diodes is not required, so that the power conversion efficiency can be improved.

Further, by employing a buck-boost method in which the third winding of the power conversion transformer is wound in the reverse direction to the first winding, a single choke coil is not required in the power supply voltage generating circuit. A one-output uninterruptible power supply can be provided.

FIG. 3 is a circuit diagram showing a second embodiment of the present invention. 1 and 11 are denoted by the same reference numerals. This example corresponds to the third power conversion transformer T.
The winding direction of the winding N21 is wound in the same direction as the first winding N11, and a choke coil (reactor) is provided in the smoothing circuit of the power supply voltage generation circuit.

In this forward system, when the switching element S11 is on, energy is stored in a choke coil (reactor) provided in the power supply voltage generating circuit, and when the switching element S11 is turned off, the choke coil is turned off. The stored energy is released to the load side.

In the figure, L1 is a choke coil provided in the power supply voltage generating circuit. D31 is a diode that forms a full-wave rectifier circuit together with D21. In the circuit configured as described above, during normal operation, the switching element S11 is obtained from the DC voltage obtained from the AC power supply.
, The output voltage is generated in the power supply voltage generation circuit of the power conversion transformer T. During this time, the switch S is turned on to charge the rechargeable battery 5 by the charging circuit.

At the time of a power failure, P of switching element S12
Energy is supplied from the rechargeable battery 5 by the WM control, and the power supply voltage generation circuit of the power conversion transformer T generates an output voltage. Details of the operation of each circuit are as described with reference to FIG. 2, and a description of the detailed operation will be omitted.

According to this embodiment, by adopting the forward system in which the third winding of the power conversion transformer is wound in the same direction as the first winding, the shape is small and the power conversion efficiency is small. A single-output uninterruptible power supply with good performance can be provided.

FIG. 4 is a circuit diagram showing a third embodiment of the present invention. 3 and 10 are denoted by the same reference numerals. In this embodiment, a buck-boost system in which a plurality of third windings of a power conversion transformer are wound in a direction opposite to the first winding N11 is provided, a plurality of power supply voltage generating circuits are provided, and a load is provided. To supply a multi-output power supply.

In this embodiment, the third winding N21,
A power supply voltage generation circuit having the same configuration as that of the power supply voltage generation circuit including the rectifying diode D21 and the smoothing capacitor C2 is provided to configure a multi-output power supply device. That is,
The third winding N21 ', the rectifying diode D21', and the smoothing capacitor C2 'constitute a power supply voltage generating circuit.

The configurations of the second switching circuit and the charging circuit are the same as those shown in FIG. In the circuit configured as described above, during normal operation, the PW of the switching element S11 is calculated from the DC voltage obtained from the AC power supply.
By the M control, an output voltage is generated in a power supply voltage generation circuit provided in each of the plurality of third windings of the power conversion transformer T. During this time, the switch S is turned on to charge the rechargeable battery 5 by the charging circuit. .

At the time of a power failure, P of switching element S12
By the WM control, energy is supplied from the rechargeable battery 5 and an output voltage is generated in a power supply voltage generation circuit provided in each of the plurality of third windings of the power conversion transformer T.
The details of the operation of each circuit are the same as those described in FIG.

According to this embodiment, the power supply voltage is generated by employing the buck-boost method in which the winding directions of the plurality of third windings of the power conversion transformer are wound in the opposite direction to the first winding. A multiple output uninterruptible power supply that does not require a choke coil in the circuit can be provided.

FIG. 5 is a circuit diagram showing a fourth embodiment of the present invention. 3 and 12 are denoted by the same reference numerals. In this embodiment, the power conversion transformer has a forward system in which the winding directions of a plurality of third windings are wound in the same direction as the first winding N11. It supplies multiple output power.

In this embodiment, the third winding N21,
Rectifier diodes D21, D31, choke coil L
1, a power supply voltage generation circuit having the same configuration as that of the power supply voltage generation circuit including the smoothing capacitor C2 is provided to configure a multi-output power supply device. That is, the third winding N21 ′,
The rectifying diodes D21 'and D31' and the smoothing capacitor C2 'constitute a power supply voltage generating circuit.

The configurations of the second switching circuit and the charging circuit are the same as those shown in FIG. In the circuit configured as above, during normal operation, the PW of the switching element S11 is obtained from the DC voltage obtained from the AC power supply.
By the M control, an output voltage is generated in a power supply voltage generation circuit provided in each of the plurality of third windings of the power conversion transformer T. During this time, the switch S is turned on to charge the rechargeable battery 5 by the charging circuit. .

At the time of a power failure, P of switching element S12
By the WM control, energy is supplied from the rechargeable battery 5 and an output voltage is generated in a power supply voltage generation circuit provided in each of the plurality of third windings of the power conversion transformer T.
The details of the operation of each circuit are the same as those described in FIG.

According to this embodiment, by adopting the forward system in which the winding directions of the plurality of third windings of the power conversion transformer are wound in the same direction as the first winding, the shape is reduced and the power is reduced. A multiple output uninterruptible power supply with high conversion efficiency can be provided.

FIG. 6 is a circuit diagram showing a fifth embodiment of the present invention. 3 and 13 are denoted by the same reference numerals. In this embodiment, a forward system in which the winding directions of a plurality of third windings of the power conversion transformer are wound in the same direction as the first winding N11 is provided, a power supply voltage generating circuit is provided, and a single load is provided. It supplies one output power.

Then, the first winding of the power conversion transformer T is divided into two parts, and the respective windings are alternately turned on / off by respective switching elements (push-pull method).

N11A and N11B are divided first windings, and N21A and N21B are divided third windings. The output of the rectifier circuit 3 is connected to the first windings N11A and N1A.
It is connected to the midpoint of 1B. The primary winding N11A is turned on / off by a switching element S11A, and
ON / OFF of the secondary winding N11B is controlled by the switching element S11B. Switching elements S11A, S1
1B and the first windings N11A and N11B constitute a first switching circuit.

The switching element S11A
And the on / off control of S11B, a high-frequency AC is generated on the third winding side of the power conversion transformer T. The third winding is also divided into N21A and N21B, and the midpoint of these windings is Rectifying diodes D21 and D3 as potentials
The alternating current generated in 1 is full-wave rectified. In this example, since the forward system is adopted, the power supply voltage generating circuit is provided with the choke coil L1.

N12A and N12B are second windings divided into two. The second winding N12A is connected to the switching element S
On / off control is performed by 12A, and winding N12B is controlled on / off by switching element S12B. Switching elements S12A, S12B and second winding N1
2A and N12B constitute a second switching circuit.

On the other hand, the winding on the charging circuit side is also divided into N2BA and N2BB, and the middle point is the common line of the charging circuit. The high-frequency alternating current generated in the fourth winding is full-wave rectified by diodes D2B and D3B, and its output is smoothed by choke coil L3 and capacitor C3 to become a flat DC voltage. The output of this charging circuit is supplied to a chargeable battery 5 via a switch S and a constant current circuit 4.
Charge.

In the circuit thus configured, during normal operation, the power supply voltage of the power conversion transformer T is generated by PWM control in which the switching elements S11A and S11B are alternately turned on / off from the DC voltage obtained from the AC power supply. An output voltage is generated in the circuit, during which the switch S is turned on to charge the rechargeable battery 5 via the constant current circuit 4 by the charging circuit.

At the time of a power failure, energy is supplied from the rechargeable battery 5 by PWM control for alternately turning on / off the switching elements S12A and S12B, and the power supply voltage generation circuit of the power conversion transformer T generates an output voltage. The details of the operation of each circuit are the same as those described in FIG.

According to this embodiment, a single output uninterruptible power supply having a small shape and high power conversion efficiency can be provided by using a push-pull configuration for the first switching circuit.

FIG. 7 is a circuit diagram showing a sixth embodiment of the present invention. 3, FIG. 6, and FIG. 14 are denoted by the same reference numerals. In this embodiment, the winding direction of the plurality of third windings of the power conversion transformer is changed to the first winding N.
11 is a forward type wound in the same direction as that of FIG. 11, a plurality of power supply voltage generating circuits are provided, and a multi-output power supply is supplied to a load.

Then, the first winding of the power conversion transformer T is divided into two, and the respective windings are alternately turned on / off by respective switching elements (push-pull system).

In this embodiment, the third winding N21
A, N21B, full-wave rectifier diodes D21, D31,
A power supply voltage generation circuit having the same configuration as that of the power supply voltage generation circuit including the choke coil L1 and the smoothing capacitor C2 is provided to configure a multi-output power supply device. That is, the third
N21A ', N21B, full-wave rectifier diode D
21 ', D31', choke coil L1 ', and smoothing capacitor C2' constitute a power supply voltage generating circuit.

The configurations of the charging circuit and the second switching circuit are the same as in FIG. In the circuit thus configured, during normal operation, output voltages are generated in a plurality of power supply voltage generation circuits by PWM control of the switching elements S11A and S11B from a DC voltage obtained from an AC power supply, and the switch S is turned on during this time. Turn on to charge the rechargeable battery 5 by the charging circuit.

At the time of power failure, the switching elements S12A,
By the PWM control in S12B, energy is supplied from the rechargeable battery 5, and an output voltage is generated by a plurality of power supply voltage generation circuits. The details of the operation of each circuit are the same as those described in FIG.

According to this embodiment, by providing the first switching circuit with a push-pull configuration, it is possible to provide a multiple-output uninterruptible power supply having a small shape and high power conversion efficiency.

FIG. 8 is a diagram showing a specific configuration example of the constant current circuit used in the above embodiment. The same components as those in FIG. 2 are denoted by the same reference numerals. In the figure, the secondary side (fourth winding) output of the power conversion transformer T is rectified by a rectifying diode D2B to DC, and this diode D2B
Is smoothed by the smoothing capacitor C3, and is a flat DC voltage E0B, which is a voltage output (output of the charging circuit).

R1 is a resistor connected in series with the charging circuit,
TR1 is a transistor whose emitter is connected to the resistor R1, TR2 is a transistor whose emitter is connected to the output of the charging circuit, R2 is a resistor connected between the base of the transistor TR2 and the emitter of the transistor TR1,
Reference numeral 3 denotes a resistor connected between the base of the transistor TR1 and the common line. The collector of the transistor TR2 is connected to the base of the transistor TR1. The resistors R1 to R3 and the transistors TR1 and TR2 form a constant current circuit 4.

In the circuit thus configured, the base of the transistor TR1 is grounded, and the transistor TR2 drives the transistor TR1. In such a grounded base transistor circuit, the output resistance is extremely high, so that a constant current circuit can be formed. That is, assuming that the output impedance of the constant current circuit 4 is Z1 and the impedance on the load side is Z2, the output current I of the constant current circuit is expressed by the following equation.

I = E0B / (Z1 + Z2) (4) Here, the output impedance Z1 is extremely large, and Z1
>> Assuming that Z2, the equation (4) is simplified to I = E0B / Z1 (5), and the constant current I is independent of the impedance on the load side.
Is output.

In the above embodiment, the case where a field effect transistor (FET) is used as a switching element is taken as an example. However, the present invention is not limited to this, and other switching elements such as a bipolar transistor may be used. Can be used.

Further, in the above-described embodiment, the case of two outputs is taken as an example of a multi-output power supply circuit. However, the present invention is not limited to this, and a power supply circuit of three or more outputs can be realized. it can.

[0116]

As described in detail above, according to the present invention, (1) a DC voltage is normally obtained by a DC / DC converter system by receiving an AC input voltage, and a DC input of a rechargeable battery is provided during a power failure. In an uninterruptible power supply that receives a voltage and obtains a DC voltage by a DC / DC converter system, a single power conversion transformer and a first winding of the power conversion transformer by switching an output of a primary rectifier circuit , A second switching circuit that switches the output of the rechargeable battery to drive a second winding of the power conversion transformer, and a first switching circuit that is generated on the third winding side of the power conversion transformer. A power supply voltage generating circuit for rectifying and smoothing the alternating current to generate an output voltage, and rectifying the alternating current generated on the fourth winding side of the power conversion transformer, and charging the rechargeable battery with the rectified DC voltage. And a constant current circuit that receives the output voltage of the charging circuit and charges the rechargeable battery with a constant current. By using a power supply unit, the size of the power supply unit can be reduced, and only one power conversion transformer is required. Therefore, only one output rectifier circuit is required, and OR coupling of diodes is not required. Conversion efficiency can be improved.

(2) In this case, the third winding of the power conversion transformer is wound in a direction opposite to that of the first winding, and one power supply voltage generating circuit is provided. A choke coil is required in the power supply voltage generating circuit by adopting a buck-boost method in which the third winding of the power conversion transformer is wound in the opposite direction to the first winding by supplying output power. And a single-output uninterruptible power supply that does not have a single output.

(3) A plurality of third windings of the power conversion transformer are wound in the opposite direction to the first winding, and a plurality of power supply voltage generating circuits are provided. By using a buck-boost method in which the winding direction of the plurality of third windings of the power conversion transformer is wound in the opposite direction to the first winding, a choke coil is required in the power supply voltage generation circuit. A multiple output uninterruptible power supply can be provided.

(4) The third power conversion transformer
The winding direction of the winding is wound in the same direction as the first winding,
By providing one power supply voltage generating circuit and supplying a single output power to a load, a forward method is adopted in which the third winding of the power conversion transformer is wound in the same direction as the first winding. Thus, a single-output uninterruptible power supply having a small shape and high power conversion efficiency can be provided.

(5) A plurality of third windings of the power conversion transformer are wound in the same direction as the first winding, and a plurality of power supply voltage generating circuits are provided. By employing a forward system in which the winding directions of the plurality of third windings of the power conversion transformer are wound in the same direction as the first winding, a plurality of outputs having a small shape and high power conversion efficiency are provided. Can be provided.

(6) In addition, the first switching circuit has a push-pull configuration, and one power supply voltage generating circuit is provided to supply a single output power to a load. With the push-pull configuration, a single-output uninterruptible power supply having a small shape and high power conversion efficiency can be provided.

(7) Further, the first switching circuit has a push-pull configuration, a plurality of the power supply voltage generating circuits are provided, and a multi-output power supply is supplied to the load, so that the first switching circuit has a push-pull configuration. With this configuration, it is possible to provide a multiple output uninterruptible power supply having a small shape and high power conversion efficiency.

As described above, according to the present invention, it is possible to provide an uninterruptible power supply capable of reducing the size of the power supply and improving the power conversion efficiency.

[Brief description of the drawings]

FIG. 1 is a principle block diagram of the present invention.

FIG. 2 is a circuit diagram showing a first embodiment of the present invention.

FIG. 3 is a circuit diagram showing a second embodiment of the present invention.

FIG. 4 is a circuit diagram showing a third embodiment of the present invention.

FIG. 5 is a circuit diagram showing a fourth embodiment of the present invention.

FIG. 6 is a circuit diagram showing a fifth embodiment of the present invention.

FIG. 7 is a circuit diagram showing a fifth embodiment of the present invention.

FIG. 8 is a diagram showing a specific configuration example of a constant current circuit used in the present invention.

FIG. 9 is a diagram showing a first example of a conventional multi-input / single-output power supply circuit.

FIG. 10 is a diagram showing a first example of a conventional multi-input / multi-output power supply circuit.

FIG. 11 is a diagram showing a second example of a conventional multi-input / single-output power supply circuit.

FIG. 12 is a diagram showing a second example of a conventional multi-input / multi-output power supply circuit.

FIG. 13 is a diagram showing a third example of a conventional multi-input / single-output power supply circuit.

FIG. 14 is a diagram showing a third example of a conventional multi-input / multi-output power supply circuit.

[Explanation of symbols]

 Reference Signs List 1 AC power supply 3 Rectifier circuit 4 Constant current circuit 5 Rechargeable battery 10 First switching circuit 20 Second switching circuit 30 Power supply voltage generation circuit 40 Charging circuit T Power conversion transformer

──────────────────────────────────────────────────の Continuation of the front page (51) Int.Cl. ⁶ Identification code FI H02M 7/06 H02M 7/06 A (72) Inventor Kazuki Muniyasu 4-1-1 1-1 Uedanaka, Nakahara-ku, Kawasaki City, Kanagawa Prefecture Fujitsu Inside (72) Inventor Atsushi Kuwahara 4-1, 1-1 Uedanaka, Nakahara-ku, Kawasaki City, Kanagawa Prefecture Inside (72) Inventor Jun Junda 4-1-1, Kamiodanaka, Nakahara-ku, Kawasaki City, Kanagawa Prefecture Fujitsu Limited (72) Inventor Minoru Hirahara 4-1-1 Kamikadanaka, Nakahara-ku, Kawasaki City, Kanagawa Prefecture Fujitsu Limited

Claims (7)

[Claims] 1. Normally, a DC / DC signal is received by receiving an AC input voltage.
An uninterruptible power supply unit that obtains a DC voltage by a converter system and receives a DC input voltage of a rechargeable battery at the time of a power failure to obtain a DC voltage by a DC / DC converter system. A first switching circuit for switching an output of the circuit to drive a first winding of the power conversion transformer, and a second switching for switching an output of the rechargeable battery to drive a second winding of the power conversion transformer. A switching circuit, a power supply voltage generating circuit for rectifying and smoothing an AC generated on a third winding side of the power conversion transformer to generate an output voltage, and rectifying an AC generated on a fourth winding side of the power conversion transformer A charging circuit that charges the rechargeable battery with the rectified DC voltage; and a constant current circuit that receives the output voltage of the charging circuit and charges the rechargeable battery with a constant current. Uninterruptible power supply, characterized in that the. 2. A power supply transformer, wherein a third winding of the power conversion transformer is wound in a direction opposite to that of the first winding, and one power supply voltage generating circuit is provided to supply a single output power to a load. The uninterruptible power supply according to claim 1, wherein: 3. A plurality of third windings of the power conversion transformer are wound in a direction opposite to the first winding, and a plurality of power supply voltage generating circuits are provided to supply a multi-output power supply to a load. The uninterruptible power supply according to claim 1, wherein: 4. The power conversion transformer has a third winding wound in the same direction as the first winding, and one power supply voltage generating circuit is provided to supply a single output power to a load. The uninterruptible power supply according to claim 1, wherein: 5. A plurality of third windings of the power conversion transformer are wound in the same direction as the first winding, and a plurality of power supply voltage generating circuits are provided to supply a multi-output power supply to a load. The uninterruptible power supply according to claim 1, wherein: 6. The uninterruptible power supply according to claim 1, wherein the first switching circuit has a push-pull configuration, one power supply voltage generation circuit is provided, and a single output power supply is supplied to a load. Power supply. 7. The uninterruptible power supply according to claim 1, wherein the first switching circuit has a push-pull configuration, a plurality of the power supply voltage generation circuits are provided, and a multi-output power supply is supplied to a load. .