DE19613831C1 - System for interruption-free current supply to at least one load - Google Patents

Abstract

The system has a rechargeable battery, a charger, an emergency supply device and an electronic controller. The load is normally supplied from the mains and is only supplied from the battery if the mains fails. The load is connected to a d.c. bus rail (1) representing the mains. Switching network parts (7,8) are connected in antiparallel between the battery (9) and d.c. rail. The switching network changeover part (7) forming the emergency supply contains, in the direction of energy flow, a current converter (17) controlled by the electronic circuit (2123), a transformer (19) and a rectifier (20).

Description

The invention relates to a system for uninterruptible power supply after Preamble of claim 1.

A system of the type described in the preamble of claim 1 is from DE 34 35 432 C2 known. In the known system is an AC load with the output of the Switching power supply connected. The switching power supply has an additional winding to which a charge rectifier for the battery is connected. The frequency of the switching power supply is at known arrangement determined by the nominal frequency of the AC consumer. At The effort for the transformers is therefore high for consumers with low frequencies.

An uninterruptible AC power supply is known from DE 34 09 358 C2 contains a transformer with three windings, the first of which has a switch is connected to the AC network, the second via a voltage stabilization circuit is connected to the load and the third via a rectifier / inverter circuit is connected to a battery. In normal operation, the battery is powered from the mains. In the event of a mains voltage drop d. H. in emergency mode, the battery supplies the inverters circuit and the transformer the load.

From the essay by Clewing, Michael and Engel, Siegurt: Static UPS system: Wech free-pulsing rectifier in "electrical energy technology", 31st year 1986, No. 2 is a system is known in which the consumers described there are AC consumers who over an inverter can be supplied. A battery is connected upstream of the inverter is in turn connected to a rectifier powered by the mains. In the known Case is provided that both with an existing power supply and with one Power failure the consumers via the same converter, namely the change mentioned judge to be fed. The converter is controlled by the UPS control unit.

Finally, from DE 39 42 427 A1 is a circuit arrangement for uninterrupted Power supply from DC voltage consumers known, the consumer at one  Switching power supply are connected. In emergency operation, a DC voltage source feeds over one periodically switched switch current into a secondary winding of the switching device. From this secondary winding is in normal operation via a rectifier circuit with smoothing tion capacitor supplies a load.

The invention has for its object a system for uninterrupted Stromver Provide at least one load by means of DC voltage, whereby for the supply the load and the charge of the battery in normal operation as well as the discharge of the battery in Emergency operation no transformer with three windings is needed and the frequency for the arrangement for charging the battery and discharging no longer depends on the frequency of the Load depends.

This object is achieved according to the invention by a system for uninterruptible Power supply according to claim 1.

A pair of two anti-parallel switched mode power supplies can be used as one bidirectional Switching power supply can be understood, d. H. it allows an energy flow in two opposite Directions, namely on the one hand - for loading and charge maintenance - from the DC busbar to the battery and on the other hand - in the event of a power failure supply - from the battery to the DC busbar.

The system according to the invention has the advantage that the frequencies for charging the Battery and the feedback of the energy provided by the battery to the load switching power supplies can be set to high values, which increases the design effort, especially for the transmitters.

In normal operation, the load is no longer removed from the network with the interposition of the switch power supply. This avoids transformer losses. If an AC chip load can be connected to the conditions of the load such as span voltage, current and frequency adapted inverters with the DC voltage the.  

When operating in the charging direction, the battery can - when using an electronic rain lung - optimally loaded according to the manufacturer's instructions. This must be in the rules the battery characteristic curve specified by the manufacturer must be saved.

When connecting several pairs of anti-parallel switching power supplies in parallel the entire system can be designed for greater performance because the performance is based on the can split parallel switching power supplies. Due to the parallel connection, a red undant plant can be built.

If there is a capacitor on the connections on both sides of each pair of antiparal Switched power supplies are present, there is one for each direction of energy flow Smoothing of the voltage at the output of the respective switching power supply possible. It is of course it doesn't matter whether there are two separate capacitors for each pair or whether all pairs are connected together between just two individual capacitors.

Due to the design of the system, the same components can be used both for the charging mode as well as for the regenerative mode can be used. So the condens sensors that serve as smoothing capacitors in the charging direction, as regenerative operation Input capacitor used. The components used for interference suppression are used - with reverse energy flow - for radio interference suppression in the exit direction.

A soft start device according to claim 4 prevents a when switching on Power surge towards the battery.

A configuration of master and slave units according to claim 6 has the advantage that an even distribution of current to the parallel switching power supplies can be achieved, without the need for constant data exchange with a higher-level unit would. As a result, this superordinate unit and that originating from this unit central bus system relieved.  

Further preferred embodiments of the invention are in the rest Subclaims marked.

In the following an embodiment of the invention based on a Drawing from which further details and advantages result described.

1 it shows the Fig. Is a block diagram for a plant for uninterrupted power supply. Various direct current consumers are connected to a direct voltage busbar 1 , for example an inverter 2 with an alternating current motor 3 connected to it , a lamp 4 or another consumer 5 . When the DC voltage bus 1 , it can be a train bus on which a DC voltage U _ZS of z. B. 650 V is present.

In addition, a rechargeable battery 9 is connected to the DC busbar 1 - via two antiparallel switched-mode power supplies 7 and 8 . The battery 9 can - in a manner known per se - be a series connection of several electrochemical cells or a series connection of several smaller batteries.

In the case of an undisturbed network, this DC voltage busbar 1 is supplied by a rectifier 6 connected to the AC network, in the event of a power failure by the battery 9 .

A soft start device 10 and a capacitor 11 are connected between the switching power supplies 7 and 8 connected in anti-parallel and the DC bus bar 1 . The capacitor 11 is connected between the two connections at the input of the two antiparallel connected converters 7 and 8 , it serves as a smoothing capacitor when the DC busbar 1 is supplied from the battery 9 .

When a current flow from the DC bus bar 1 begins in the direction of the battery 9 , the soft start device 10 initially limits the current flowing into the capacitor 11 in order to avoid a current surge.

During this time, the soft start device 10 acts as an ohmic resistor. When the voltage on the capacitor 11 has reached the value of the voltage on the DC bus 1 , the current limitation is ended; the soft start device 10 then acts like a conductive connection.

With a current flow for charging or maintaining the charge of the battery 9 , only the switched-mode power supply 8 operates.

This switched-mode power supply 8 has a fast-switching high-power transistor 12 in the energy flow direction, a transformer 13 arranged behind it, and a rectifier 14 on the secondary side of the transformer 13 .

The high-performance transistor 12 is switched by an electronic control and monitoring unit 15 at a frequency of approximately 75 kHz. The voltage pulses thus obtained are fed to the transmitter 13 . The winding ratio in the transformer 13 ensures that the voltage at the output of the transformer 13 is lower than at the input. This voltage is applied to the rectifier 14 .

A smoothing capacitor 16 is connected to the two outputs of the anti-parallel connection of the two switching power supplies 7 and 8 facing the battery 9 . This smoothes the rectified voltage that is supplied to the battery 9 . The charging voltage of the battery 9 can have a value of 120 V, for example.

If the AC network fails, current flows from the battery 9 via the switching power supply 7 to the DC busbar 1 .

The switched-mode power supply 7 has a fast-switching high-power transistor 17 in the energy flow direction, a transformer 19 arranged behind it and a rectifier 20 . The high-power transistor 17 is controlled by a regulating and monitoring device 21 . It works at a switching frequency of approx. 75 kHz.

In this direction of energy flow, capacitor 11 acts as a smoothing capacitor for the voltage at the output of rectifier 20 .

The voltage at the input, the level of which is determined by the battery voltage, is increased by means of the transformer 19 .

The control and monitoring units 15 and 21 are connected to one another for data exchange and both detect the voltage U _ZS on the DC bus bar and the voltage U _Batt on the battery 9 . They generate pulses for driving the respective connected high-power transistor 12 or 17 , which in this way causes the DC voltage pulses mentioned.

The control and monitoring units 15 and 21 are supplied via a bus system 22 with auxiliary energy and commands for switching the switching power supplies 7 and 8 on and off and for specifying the respective operating mode. The bus system is routed to a unit 23 to which the two control and monitoring units 15 and 21 are connected for data transmission.

If several pairs of anti-parallel switched-mode power supplies 7 and 8 are connected in parallel, the control and monitoring units of these parallel switched-mode power supplies are connected to one another in such a way that data can be exchanged between them. For this purpose, they can also be connected to the unit 23 . In this case, the two control and monitoring units 15 and 21 of a pair of anti-parallel switching power supplies can be configured as master units. The corresponding control and monitoring units of the parallel pairs of switching power supplies are each connected to the associated master unit and configured as slave units. This makes it possible to achieve an even distribution of power between the parallel switched-mode power supplies without the need for data exchange via the bus system 22 to the higher-level unit connected to it.

The parallel connection of the switching power supplies serves on the one hand to distribute the power evenly (to relieve the switching power supplies) and on the other to create a redundant system which can continue to ensure an uninterruptible power supply even if a single switching power supply 7 or 8 fails.

Claims (12)

1. System for uninterruptible power supply, containing

• - a rechargeable battery ( 9 ),
• - A charging device ( 8 ) for charging or maintaining the charge of the battery ( 9 ) from a power network ( 1 ),
• - an emergency supply device ( 7 ) for feeding a load ( 2-5 ) connected to the system from the battery ( 9 ),
• - an electronic control ( 15 , 21 , 23 ) for the system,

in which

• - the load ( 2-5 ) is supplied from the power supply ( 1 ) during trouble-free operation and
• - only in the event of a power failure from the battery ( 9 ),

in which

• - The charging device ( 8 ) and the emergency supply device ( 7 ) are switching power supplies, and

the switching power supply forming the charging device ( 8 ) in the direction of the energy flow

• - a converter valve ( 12 ) controlled by the electronic control ( 15 , 23 ),
• - A transformer connected behind it ( 13 ) and
• - contains a rectifier ( 14 ) arranged behind it,

characterized by the following features:

• - the load is connected to an AC power (1) representing DC voltage bus (1),
• - The switching power supplies ( 7 , 8 ) are connected anti-parallel between the battery ( 9 ) and the DC busbar ( 1 ),

the switching power supply forming the emergency supply device ( 7 ) also in the direction of the energy flow

• - a converter valve ( 17 ) controlled by the electronic control ( 21 , 23 ),
• - A transformer connected behind ( 19 ) and
• - Contains a rectifier ( 20 ) arranged behind it.

2. Plant according to claim 1, characterized in that at least one further pair of antiparallel connected switching power supplies between DC busbar ( 1 ) and battery ( 9 ) is connected. 3. Installation according to claim 1 or 2, characterized in that a capacitor ( 11 , 16 ) is connected between the connections at the input and between the connections at the output of the or each pair of antiparallel connected switching power supplies. 4. Plant according to one of the preceding claims, characterized by the following features:

• - A soft start device ( 10 ) is connected between the DC busbar ( 1 ) and the capacitor ( 11 ) connected to it,
• - At the beginning of the current flow for charging or charge maintenance, this soft start device ( 10 ) limits the current as long as
• - Until the voltage on the capacitor ( 10 ) has reached the value of the voltage on the DC busbar (I).

5. Plant according to one of the preceding claims, characterized by the following features:

• - Both controllable converter valves of each pair of anti-parallel switched-mode power supplies ( 7 , 8 ) are each connected to a device ( 15 , 21 ) forming the electronic control for controlling or regulating,
• - Each of these devices ( 15 , 21 ) detects the battery voltage (U _batt ) and the voltage (U _ZS ) on the DC _busbar ( 1 ),
• - Each of these devices ( 15 , 21 ) controls the associated converter valve.

6. Plant according to claim 5, characterized by the following features:

• the device ( 15 , 21 ) of the or each pair of anti-parallel switched-mode power supplies ( 7 , 8 ) receives information from a common bus system ( 22 ) for switching on or off and / or controlling the connected converter valves,
• in the case of several pairs of switching power supplies ( 7 , 8 ), the devices ( 15 , 21 ) belonging to a predeterminable pair for controlling or regulating are configured as master units and the devices of the other pairs as slave units,
• - The master units and the slave units are interconnected for data exchange.

7. Installation according to one of the preceding claims, characterized, that the converter valves work with a switching frequency of approx. 75 kHz.