DE3016551A1 - DC power supply with two rectifiers and two thyristor switches - permitting no-break switching between battery and AC mains supply - Google Patents

Abstract

The dc power supply has two rectifiers (1,2) connected to an ac supply network (8). One output (A) of each rectifier is connected to a first load line (7). The second outputs (B) of the two rectifiers are connected to two electronic switches (4,5) (e.g. thyristors) that switch either one or the other second output through to a second load line (6). A battery (3) is connected between the first output of one rectifier and the second output of the other rectifier. When the ac supply is present, both rectifiers are operating, the second switch (5) is closed, the first (4) open and the battery is charged. When the ac supply fails, the dc load is supplied without a break from the battery via the second switch (5). When the ac supply returns only the first rectifier (1) supplies the load (the second switch (5) opens) and the second rectifier (2) charges the battery.

Description

Circuit arrangement for direct current supply orgun'gssysteme

The invention relates to a circuit arrangement for DC power supply systems, which has at least two rectifiers and an accumulator battery.

Using the simplest uninterruptible DC power system, the one or more, directly parallel to an accumulator battery switched rectifiers is formed, only the need of a narrower circle can be satisfied by consumers. This results from the fact that the output voltage of the system is the consumer voltage, which is within relatively wide limits between the final discharge voltage of the battery and the voltage required to charge it soon necessary fast charging voltage - fluctuates.

To reduce the voltage fluctuation, various Methods developed; see e.g. the Hungarian patent specification 167 883, which however has the common Have the disadvantage that they have many elements in a relatively complicated circuit arrangement contain. The relatively complex, multi-element circuitry is the reason that the resulting reliability or

the availability is not satisfactory.

The invention is based on the object of a DC power supply system from a small number of elements and with a relatively simple circuit arrangement to create in which the consumer voltage fluctuations are less than the when charging and discharging the accumulator battery voltages, its But reliability is good.

This task is achieved with a circuit arrangement of the type mentioned at the beginning Art solved according to the invention in that the one output terminals of each rectifier and the one terminal of the accumulator battery of the same polarity directly on a first load rail, the other output terminal of opposite polarity of the first rectifier output directly, and the other output terminal opposite Polarity of the second rectifier via a first thyristor switch to one second consumer rail are connected that between the other output terminals the rectifier is connected to a second thyristor switch, and that the other Terminal of the accumulator battery to the other output terminal of the second rectifier is switched.

Appropriate further developments of the invention are based on the claims 2 and 3.

The invention is described in more detail below with reference to FIG drawings explained, which represent exemplary embodiments of the circuit arrangement according to the invention. 1 shows an exemplary embodiment of the circuit arrangement according to the invention, 2 shows an embodiment variant for the circuit arrangement according to the invention, and 3 shows a further embodiment variant.

In FIG. 1, two rectifiers are connected to an AC power supply network 8 1, 2 connected. One output terminal A of each rectifier 1, 2 and one terminal the same polarity of the accumulator battery 3 are directly connected to a first consumer rail 7 connected. The other output terminal B of opposite polarity of the first Rectifier 1 is connected directly to a second load rail 6. The other output terminal B of opposite polarity of the second rectifier 2 is also connected to the second consumer rail via a first thyristor switch 5 6 connected. The rectifier 1, 2 is between the other output terminals B. a second thyristor switch 4 switched. The other terminal of the accumulator battery 3 is connected to the output terminal B of the second rectifier 2.

During operation on mains operation - when the AC power supply network is operational - both rectifiers 1, 2 work, with the first thyristor switch 5 is closed. That is, this is the other output terminal B of the second Rectifier 2 connects to the second consumer rail 6. The second thyristor switch 4 is in the open state. The two rectifiers 1, 2 jointly supply the to the consumer channels 6, 7 connected consumers. About that In addition, the second rectifier 2 also charges the accumulator battery 3.

If the supply network fails, the accumulator battery takes over 3 the supply of the consumer via the first thyristor switch 5 without a timeout. When the supply network returns, the first rectifier 1 supplies the consumer only because the first thyristor switch 5 is opened. This loads the second Rectifier 2, separated from the consumer rails 6, 7, only the accumulator battery 3 on. In this case, it is permissible that the second rectifier 2 is the accumulator battery with the so-called quick charge voltage, which is higher than the rated consumer voltage, loads. It follows that not only the charging time of the accumulator battery 3 is significantly shortened, but also the periodic charging with an increased Voltage has a beneficial effect on the life of the lead-acid battery.

After the accumulator battery 3 has been fully charged, the Output voltage of the second rectifier 2 back to one of the rated consumer voltage corresponding value. When the first thyristor switch closes, 5 returns the network operation back again.

Damage to one of the rectifiers 1, 2 results in the operation of the System the slight disturbance that the accumulator battery 3 according to the above-described Way - without disturbing the consumer - can not be charged quickly In the event No special measure is required to damage the first rectifier 1, because the entire consumer load is taken over by the second rectifier 2 will. In the event of damage to the second rectifier 2, the second thyristor switch should 4 are closed so that the first rectifier 1, in addition to taking over the consumer load, also the Accumulator battery 3 can charge.

With the use of a third rectifier 9 and a third thyristor switch 10 the reliability and operational safety can be increased significantly. Fig. 2 shows an embodiment variant for this, one output terminal A of the third Rectifier 9 also directly to one consumer rail 7, his other Output terminal B via the third thyristor switch 10 to the other consumer rail 6 is connected. In this embodiment of the invention, the second Thyristor switch 4 - unlike the circuit of FIG. 1 - between the others Output terminals B of rectifiers 2 and 9 switched.

The function of the first and second rectifiers 1, 2 is identical with the function described in connection with FIG. The third rectifier 9 has a reserve function, and if any other rectifier is damaged it can be switched on in its place.

In the event of damage to the first rectifier 1, the third will Thyristor switch 10, by the way. is always open during operation, closed, and herewith the third rectifier 9 takes over the function of the consumer supply from the first rectifier 1. In case of damage to the second rectifier 2, the second thyristor switch 4 is to be closed, and the third Rectifier 9 completely replace the second rectifier 2.

It is understood that this embodiment of the invention Circuit arrangement even then ensure the supply of the consumer completely if one of the rectifiers is damaged A further education Aspect of the invention is that of the circuit arrangement according to the invention Thyristor switches used are not based on the forced commutation principle Quenching circuit, which incidentally, the operation of the DC thyristor switch and is therefore always used. In the variant according to Fig. 3, in which the first and second rectifier 1, 2 control inputs 16, 16 ', this is achieved by using a sequence switch circuit 11 whose first outputs 14, 14 'to the inputs of the thyristor switch 4, 5 controlling ignition circuits and its second outputs 15, 15 'to the control inputs 16, 16 'of the rectifier 1, 2 are connected.

During operation, e.g. when the first thyristor switch 5 is open is to be issued, the sequence switch circuit 11 first gives a via its output 14 Delete command to input 13 of an ignition circuit controlling the first thyristor switch 5 12. The first thyristor switch 5 remains unchanged in the conductive state, i.e. in the switched-on state, which is caused by the direct current flowing through this consumer is made possible. In the next phase, the sequence switch circuit 11 influences over its second output 15 'the control input 16' of the second rectifier 2, so that its output voltage drops below the value of the consumer voltage. Because now the entire power supply of the consumer is taken over by the first rectifier 1 is, the current flowing through the first thyristor switch 5 is interrupted. This ends its conductive state and it blocks. Affected accordingly the sequence switch circuit 11 via the second output 15 'the control input 16' of the second rectifier 2, so that its output voltage is below the value of the consumer voltage sinks. Since the full consumer supply is taken over by the first rectifier 1 will, will the current flowing through the first thyristor switch 5 interrupted and so interrupting the line, the thyristor switch 5 is locked State. Then - the prohibition of the ignition circuit is ended unchanged the follow-up circuit 11 influences the output voltage of the second rectifier 2, which must also be increased up to the breakover voltage of the first thyristor switch 5, without this switching on. The first thyristor switch 5 can be terminated of the prohibition of the ignition circuit 12 are switched on.

The operating process is essentially identical to that described above, when the second thyristor switch 4 is to be switched.

The operating process is also in the embodiment of Fig. 2 when the sequential circuit 11 is used in the above manner.

The advantages achieved by the invention are how from the The above description shows that - the load voltage is only slightly Measures between the nominal and the discharge end voltage fluctuates; - the treatment of the battery (charging, reforming, etc.) is ensured without disturbing the consumer is. Charging with increased voltage is, apart from the shortening of the charging time, beneficial for the life of the battery; - the thyristor switches used can have a simpler construction and are reliable precisely because no quenching circuits based on the forced commutation principle required - the variant embodiment of the solution according to the invention in addition to the preservation the simple construction even if one of the rectifiers is damaged ensures full operation.

In brief, the invention comprises simple circuitry for DC power supply systems, the at least two rectifiers and a storage battery has that to each other and to a consumer in a corresponding manner Thyristor switches are connected. The circuit arrangement has several advantages, namely: - the consumer voltage fluctuates only slightly, - the battery can be handled without disturbing the consumer, - the thyristor switches can have a simpler construction - also in case of damage to the rectifier full operation can be ensured.

Claims (3)

Circuit arrangement for DC power supply systems Patent claims: Circuit arrangement for direct current supply systems, the at least two rectifiers and has an accumulator battery, thereby g e k e n n n z e i c h -n e t, that one output terminal (A) of each rectifier (1, 2) and one terminal the accumulator battery (3) of the same polarity directly to a first consumer rail (7) /, the other output terminal (B)) of opposite polarity of the first rectifier (1) immediately, and the other output cycle (B) opposite polarity of the second rectifier (2) via a first thyristor switch (5) to a second Load rail (6) are connected that between the other output terminals (B) the rectifier (1, 2) a second thyristor switch (4) is connected, and that the other terminal of the accumulator battery (3) on the other output terminal ßj of the second rectifier (2j is switched. 2. Circuit arrangement according to claim 1, which has three rectifiers, in that one output terminal (A) of the third Rectifier (9) directly to the first consumer rail (7) and its other output terminal (B) via a third thyristor switch (10) to the second consumer rail (6) is connected, with the second thyristor switch (4) between the others Output terminals (B) of the second and third rectifiers (2, 9) is connected. 3. Circuit arrangement according to claim 1 or 2, wherein the rectifier Have control inputs, thereby g e -k e n n n z e i c h n e t that first outputs (14, 14 ') of a sequence switch (11) to the inputs (13, 13') of the thyristor switch (4, 5) controlling ignition circuits (12, 12 ') and its other outputs (15, 15' ') are connected to the control inputs (16, 16 ') of the rectifiers (1, 2).