DE2061120B2 - DC power supply system with first static converter - has rectifier and standby battery, and has second converter between battery and load - Google Patents

Abstract

The d.c. power supply system has the emergency standby battery (3) charged from a static converter (2) coupled to the main rectifier's (1) output. The main rectifier is connected to the normal a.c. supply network. The static converter consists of a static inverter followed by a rectifier, and is controlled by the battery terminal voltage. A second static converter (4) connects the battery to the load (5) and can be shorted out by a switch (6) if it fails. The second converter also consists of a static inverter and a rectifier, and is controlled by the voltage across the load. The supply system can be coupled to a single or polyphase network.

Description

The invention relates to a circuit arrangement for the uninterrupted supply of power to a consumer with constant DC voltage from the single or multi-phase AC network with an unregulated Main rectifier, with a reserve battery and with additional rectifiers to keep the Charge or float charge voltage for the battery and the voltage for the consumer.

In particular, the invention relates to such a DC power supply system, in which for feeding both mains and battery operation are provided for the consumer.

Direct current supply systems are already known in which a consumer is fed from the alternating current or three-phase network via a rectifier and in which a battery is provided to supply the consumer in the event of a power failure. The requirement here is that not only the output DC voltage that feeds the consumer is kept as constant as possible, but that an uninterrupted switchover to the battery takes place even in the event of a power failure and that the battery is kept at its state of charge or, when the mains is restored, to its full charge being charged. In order to satisfy these conditions, it has advantages in addition to a main rectifier usually still an additional rectifier "<" h _P n which serves to increase the voltage of the main Vhters ^g f 5 for charging the battery. In addition, directions of regulation are required, by means of which the output voltage becomes constant in the event of mains voltage fluctuations or fluctuations in the load. with _{controllable Such} controllable semiconductor rectifiers known can be switched to the neutral state by control pulses and a regulation can be carried out by shifting the phase of the pulses Make rectifier. Such controllable rectifiers are already available for fairly large currents and the required control energy is relatively small ^ "In order to reduce the cost of the control devices, one has switched to providing an additional compensation device. .

For example, DT-AS 11 21 692 describes a power supply system in which a tensile stress is added to the battery voltage in the event of a network-2-i failure ^; rd which rigidly from a compensation device consisting of an inverter and a rectifier. Apart from the fact that in t _he ser known arrangement, the compensation device only, ο is effective after power failure, an additional rectifier for charging the battery is still required, and effects on the supply system are not on that account avoided because the main rectifier is a controlled rectifier.

A compensation device, which is used to maintain the voltage and voltage setting in a direct current network is described in DT-AS 12 27 128 This compensation device consists of an inverter and a controlled converter and generates a positive or negative additional voltage to the voltage of the direct current network.

In the journal ETZ-B, Volume 21, (1969), Issue 5, is on pages 123 to 126 describes a static compensation device that works with medium frequency and is in can deliver real power in both directions, d. H. a corresponding one for the existing DC voltage Voltage added or subtracted from this. In contrast to the present invention, however, here also gone from a regulated power rectifier. .

However, in all of these cases there may be repercussions the AC supply network has not been taken into account and the ones used have not been taken into account Means, in particular regulated rectifiers, a system perturbation cannot be avoided, so that repercussions on the AC or three-phase supply network are unavoidable. In increasing The AC grids are used by the electricity supply companies for tax purposes, by superimposing control pulses on the mains current, for example to control public Serving lighting systems. Therefore, the electricity consumer from the Sfomversorgungsunternehmen Strict conditions made regarding the suppression of disturbances caused by electricity supply systems have an effect on the feeding AC or three-phase network. The risk of such network perturbations is particularly high when using

The use of controlled semiconductor rectifiers is very large, since the current that is passed through such a controlled Rectifier flows, the ignition rises very steeply. The effort to suppress such However, network perturbations are disproportionately high and therefore for the Sirom consumer in many cases no longer portable.

From DT-AS 10 90 296 is a circuit arrangement for power supply devices. known at which via one or more main and additional rectifiers to the consumer direct current as well as the DC charging current for a battery is generated from a three-phase network. When power is supplied from the Three-phase network is operated by an unregulated. Main rectifier generated consumer voltage by a first regulated additional rectifier and the charging or charging unit generated by the main rectifier. The float charge voltage for the battery is kept constant by a second regulated additional rectifier. If the three-phase network fails, the main rectifier and the second additional rectifier are deactivated switched off and a converter fed by the battery generates the three-phase current for the first auxiliary rectifier.

Network perturbations are largely avoided by such a circuit arrangement. From Compensating devices formed by additional rectifiers can only increase the charging voltage or the consumer voltage. This has the disadvantage that the battery only with less Degree of utilization can be operated.

The invention is therefore based on the object of providing a circuit arrangement for uninterruptible Supplying a consumer with constant direct voltage from the single or multi-phase alternating current network to create, in which not only strong repercussions on the voltage of the feeding network can be avoided, but also the battery can be operated with the highest degree of utilization. Included is intended to ensure the uninterrupted supply of the consumer with constant DC voltage even in the event of a power failure be assured.

The object is achieved according to the invention in such a way that between the main rectifier and the Battery one from an inverter with downstream! Rectifier formed by the battery voltage influenced and, if necessary, positive or negative output voltage supplying, first compensation device is connected and that between the main rectifier and the consumer a similar, however, influenced by the consumer voltage, the second equalizing device is connected.

Contrary to the tendency to provide controllable rectifiers for rectifying the alternating current, In the invention, an unregulated rectifier is deliberately provided, since such a rectifier is only minimal Has repercussions on the feeding AC or three-phase network. The repercussions on the dining Network are very large, especially with multiphase regulated circuits. As the equalizing voltage such an unregulated rectifier in the event of mains voltage fluctuations or changes in load changes, but a constant DC voltage is to be achieved at the consumer, is a compensation device provided, through which an additional voltage is added to the DC voltage of the rectifier or from the DC voltage of the A voltage is subtracted from the rectifier to give the constant DC output voltage at the consumer obtain. The use of such compensation devices to achieve a constant output voltage is known per se In addition, a second such compensation device is used, to keep the battery charged or to fully recharge it after it has been discharged. The Charging can be carried out according to any program and the voltage required for this in each case is only achieved by adding or subtracting the voltage of the equalizer. Depending on the desired Charging characteristics of the battery, the usual fluctuations in the mains voltage and the usual Load fluctuations, the output equal voltage d? «Unregulated rectifier is dimensioned so that during most of the operating time the voltage to be added or subtracted by the compensation devices remains as low as possible. In this way it is achieved that on the one hand a minimum of Network perturbations are achieved and, on the other hand, the battery is operated with the highest degree of utilization will. The second compensation device mainly supplies a positive compensation voltage.

The compensation device consists of a known per se Way from the combination of an inverter and a rectifier, preferably a static one Inverter is used.

Embodiments of the invention are explained in more detail below with reference to the figures.

Fig.! shows schematically a circuit arrangement according to the invention;

F i g. 2 schematically shows another embodiment of the invention:

F1 g. 3 shows schematically the structure of a compensation device, as used in the invention.

The circuit arrangement according to FIG. 1 consists of an unregulated rectifier 1. the example is fed from the three-phase network. Via a compensation device 2, which is a predominantly positive Additional voltage to the output voltage of the unregulated Rectifier 1 supplies, the battery 3 is charged or kept on its charge. By the arrow it should be indicated that the additional voltage supplied by the compensating device 2 comes from the battery voltage being affected. Another compensation device 4, which a positive or negative additional voltage can deliver is arranged between the battery 3 and the consumer 5. The compensation device 4 is influenced by the voltage at the consumer 5 in such a way that it is always positive or negative additional voltage provides that the voltage at the consumer 5 remains constant. As a result of that the consumer 5 is not fed directly from the rectifier 1 but from the battery 3, too Load fluctuations at the consumer are absorbed so that they cannot affect the three-phase network. Despite the feeding of the battery 3 from the unregulated mains rectifier t and the feeding of the consumer 5 from the battery 3 are the voltages on the battery and on the consumer from each other independent and are determined by the compensation devices 2 and 4. It is therefore possible that the Battery 3 is charged with a different voltage than that supplied by the rectifier 1, and that the consumer 5 is fed with a different voltage than that applied to the battery 3 or from the rectifier 1 is delivered. To avoid the network perturbations caused by the

However, to keep compensating devices as small as possible, all parts will of course be dimensioned in this way. that, as a rule, no or only a small additional voltage is supplied by the compensation devices must become.

In order to still have a power supply for the consumer in the event of a failure of the compensation device 4 5 ensure, it is advantageous to provide a short circuit switch 6 through which the compensation device 4 is bypassed. The consumer 5 is then fed directly from the battery 3.

F i g. 2 schematically illustrates another embodiment of the invention. In this case, both the battery 3 and the consumer 5 are supplied with power from the unregulated mains rectifier 1, and via the associated compensation devices 2 and 4, which in turn depend on the voltage on the battery 3 or be influenced by the voltage at the consumer 5. This circuit arrangement has the advantage that in mains operation the compensating device 4 only the voltage deviations at the mains rectifier 1 must compensate and not the voltage fluctuations on the battery 3. With this circuit arrangement a short-circuit switch 7 is expediently provided in order to short-circuit the compensating device 2, if the mains voltage fails. In this case, the consumer 5 is then removed from the battery 3 via the compensation device 4 fed as in the case of FIG. 1.

In Fig. 3 is a schematic of the structure of a compensation device as shown in FIGS. 1 and 2 with the reference numerals 2 and 4 are shown. The input terminals of the compensation device according to FIG. 3 are denoted by 8 and 9 and the output terminals by 10 and It. The compensation device essentially contains an inverter 12, which is fed via the input terminals 8 and 9 and a downstream rectifier 13, which provides a positive or negative additional voltage to that at the terminals 8 and 9 supplies lying DC voltage. The arrow is intended to indicate that the inverter 12 is influenced, namely in the case of the compensation device 2 by the voltage of the battery 3 and in the case of the compensation device 4 by the voltage at the consumer 5. The compensation device 2 is influenced so that a The charge is maintained or the battery 3 is charged, while the compensation device is influenced in such a way that the voltage at the consumer 5 remains constant. A voltage is therefore added to the existing DC voltage or subtracted from it by the compensating device. The voltage at the output terminals 10 and 11 of the compensation device can therefore be higher or lower than at the input terminals 8 and 9.

This ensures an uninterruptible power supply during mains operation and in the event of a mains failure achieved with constant DC voltage from the AC or three-phase network and thereby the repercussions on the AC power supply kept to a minimum.

In addition 1 BJatt drawings

Claims (4)

Patent Claims: 1. Circuit arrangement for the uninterrupted supply of a load with constant DC voltage from the single or multi-phase AC network with an unregulated main rectifier, with a reserve battery and with additional rectifiers to keep the charging or power supply constant. Float voltage for the battery and the voltage for the consumer, characterized in that between the Hauptgleichricnter (1) and the battery (3) formed of an inverter with downstream rectifiers, influenced by the battery voltage and, if necessary, positive ode ^r negative Aiisgangsspa-iinung donating , first compensating device (2) is connected and that between the main rectifier (1) and the consumer (5) a similar, but influenced by the consumer voltage, second compensating device (4) is connected. 2. Circuit arrangement according to claim 1, characterized in that the two compensating devices (2, 4) with each other in series between the main rectifier (1) and the consumer (5) are connected. 3. Circuit arrangement according to claim 1, characterized in that the two compensating devices (2, 4) parallel to one another on the main rectifier (1), and that for the first compensation device (2) a bridging switch (7) is provided, which bridges this compensation device in the event of a power failure. 4. Circuit arrangement according to one of the preceding claims, characterized in that a bridging switch (C) is provided for the second compensation device (4), which this Compensating device bridged when it fails.