JPS6268029A - Rectifier for no-break power source - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention provides an AC input side connected to an input transformer connected to an AC power supply, and a DC output side connected to a battery to be floatingly charged. Regarding uninterruptible power supply rectifiers,
In particular, the present invention relates to a rectifier n used as a DC voltage source for a constant voltage constant frequency inverter in an uninterruptible power supply.

[Conventional technology]

FIG. 2 is a circuit diagram showing a conventional embodiment of a rectifier for uninterruptible power supply. According to this, a three-phase autotransformer is used as the input transformer 1 connected to a three-phase AC power supply,
A rectifier 2 consisting of a three-phase bridge-connected thyristor is connected to an output tap which is a terminal tap of the autotransformer. A floating charging battery 3 is connected to the JM output side of the thyristor rectifier 2. This constitutes an uninterruptively heated DC voltage source, which is used, for example, as a DC input voltage gap for constant voltage constant frequency inverters and, as a whole, often
An uninterruptible power source device commonly known as

[The problem to be solved by the present invention] The battery 3 requires not only constant floating charging but also recovery charging after being discharged due to a power outage and periodic equal charging. During recovery charging and equalization charging, a high charging voltage is required which is about 10% higher than the voltage value for normal floating charging. For this reason, the rectifier 2 outputs an output according to the required charging voltage by controlling the firing angle, but when floating charging is always performed, the firing angle is increased to output a low voltage, so the input power factor The problem is that it gets worse. If AC input voltage fluctuations are taken into account when designing, the input power factor at all times will be about 0.75 (lag), for example.

In view of the above, an object of the present invention is to provide a rectifier for uninterruptible power supply with improved input power factor. In a rectifier for uninterruptible power supply, the AC input side is connected to the input transformer connected to the AC power supply, and the DC output side is connected to the battery to be charged in a floating manner.The rectifiers are connected in parallel with each other on the DC output side. Consisting of two connected rectifiers, the first rectifier is connected to the output tap on the low voltage side of the two sets of output taps of the autotransformer provided as the input transformer, and the second
The rectifier is connected to the output tap on the high voltage side of the autotransformer, the first rectifier operates for continuous battery floating charging, and the second rectifier operates for recovery charging after discharge or periodic equalization charging. This is achieved by driving for.

[Action and effect]

During floating charging, which requires a lower charging voltage than the charging voltage for recovery charging or equalization charging, the first rectifier connected to the low voltage side tap of the autotransformer is operated, In this case, the first rectifier operates within a small firing angle range to output the required floating charge voltage due to the low AC input voltage, resulting in a high input power factor.

〔Example〕

Hereinafter, the present invention will be explained in more detail with reference to the embodiment shown in FIG.

In FIG. 1, 10 is an input transformer, which is a three-phase autotransformer with one set of input taps and two sets of output taps. The input tap is connected to a three-phase AC power source. 2
A first rectifier 21 is connected to the output tap on the low voltage side of the set of output taps, and a second rectifier 22 is connected to the output tap on the high voltage side, which is a terminal tap, and both rectifiers are connected to the DC output side. are connected in parallel to the battery 3. Both rectifiers consist of three-phase bridge-wired silisks.

At all times, the first rectifier 21 is operated to perform floating charging of the battery 3 while supplying power to the load via an inverter (not shown). When a power outage occurs, the battery 3 discharges instead of the rectifier 21 to maintain power supply to the load.When power is restored, the second rectifier 22 is operated to recover and charge the battery, and the voltage is set to about 10e4 higher. Output. When the recovery charging is completed, the operation of the second rectifier 22 is stopped, and the operation of the first rectifier 2 is stopped.
1 operation is resumed, and constant floating charging is performed.

Furthermore, the battery 3 can be charged evenly by periodically operating the second rectifier 22.

Thus, depending on whether you want a low DC output voltage for floating charging or a high DC output voltage for recovery or equalization charging, the AC input voltage can be correspondingly lower or higher. Therefore, the input power factor can be kept high during operation of any rectifier.

Since both rectifiers 21 and 22 are not operated at the same time,
If the element cooling fins of both rectifiers are shared, the same cooling fins as the one outside the Korai rectifier will be sufficient.

Also, when the second rectifier 22 is operating, the first rectifier 21
The first rectifier 21 may be composed of a diode, since the rectifying element inside is reverse biased and does not conduct.

[Brief explanation of drawings]

FIG. 1 is a circuit diagram showing one embodiment of the present invention, and FIG. 2 is a circuit diagram showing a conventional embodiment. 10...Input transformer (autotransformer), 21...First
rectifier, 22... second rectifier, 3... battery.

Claims (1)

[Claims] 1) In a rectifier for uninterruptible power supply, the AC input side is connected to the input transformer connected to the AC power supply, and the DC output side is connected to the battery to be floatingly charged. Consisting of two rectifiers connected in parallel to each other, the first rectifier is connected to the output tap on the low voltage side of the two sets of output taps of the autotransformer provided as the input transformer, and the second A rectifier is connected to the output tap on the high voltage side of the autotransformer, the first rectifier operates for continuous battery floating charging, and the second rectifier operates for recovery charging after discharge or periodic equalization charging. 1. A rectifier for uninterruptible power supply, characterized in that the rectifier is operated for the purpose of operation.