DE3319511A1 - Battery-aided power supply system I - Google Patents

Abstract

The invention relates to power supply systems having a plurality of subsystems which are battery-buffered, which batteries ensure the continuous supply of the loads connected even when the power of the energy sources supplying the subsystems fluctuates, as is the case, for example, with photovoltaic converters. In such systems, it is possible that, because of a different load, a lack of energy may arise in one subsystem and excess energy in the other. The invention describes a method and a device for transferring the energy excess to the subsystem having a lack of energy, both floating and potential-related exemplary embodiments being described. The energy flow takes place by transferring in each case from a subsystem having a higher rated voltage to a subsystem having a lower rated voltage.

Description

Title: Accumulator-based power supply system /

Field of application: The invention relates to an accumulator supported Power supply system, consisting of at least two sub-systems with different Nominal voltage, their batteries preferably from photovoltaic converters via blocking diodes Loading.

Purpose: Such arrangements serve the continuous supply of Consumers of different input voltages, on their permissible tolerances often adjust the output voltage tolerances of the battery-backed subsystems are. In some applications, for example with certain static inverters, combinations of the partial voltages must also be used for the loads connected to the system are supplied, the corresponding switching states being set with switching frequencies that extend far into the kHz range. If the system described gets its energy from photovoltaic converters, this normally applies to the design as a boundary condition that the energy fed in is optimal and as loss-free as possible is to be transferred to the consumer.

State of the art: It is known to have such a system with several Build up output voltages from individual subsystems, each from photovoltaic There are converters with charge regulator and output regulator, each of which has its own Have energy balance, and which can be interconnected as required. The charging voltage is limited by series transistors or by shunt transistors, which are from corresponding control elements are controlled (see Köthe, H. K .: "Praxis solar- and windelectric energy supply ", pp. 208 to 2112 VDI-Verlag, 1982).

Criticism of the state of the art: In any case, this charging voltage limitation electrical surplus energy that occurs in one of the subsystems, there in inferior, normally unused thermal energy is converted and given off to the environment.

Task: The invention is based on the task of limiting not to dissipate excess energy, but to another subsystem, the corresponding redarf has to supply.

Solution; The object is achieved according to the invention in that the subsystems are coupled with each other according to the rule that excess energy from subsystems with higher nominal voltages automatically the subsystems with lower nominal voltages is supplied, the circuit connection preferably taking place in this way should that a cascade-like overflow of the excess energy to the next lower Subsystem takes place.

In its simplest form, the overall system consists of only two Feeds into subsystems and only into the subsystem with the higher nominal voltage photovoltaic converter (solar generator). The accumulator reaches in this "higher" subsystem its limit charging voltage must be on the solar generator side Connection of the blocking diode, which is a power return from the battery to the solar generator is to prevent the excess through a shunt branch parallel to the solar generator Charge current offer can be deducted. This is done according to the invention in that the Shunt branch from a series connection of a coupling transistor, the blocking diode and of the accumulator of the subsystem with the lower nominal voltage and one Coupling diode between the reference conductor of the "lower" and the "upper" subsystem exists, and that the coupling transistor of a charge controller for the accumulator in the upper subsystem is controlled so that the excess current of this subsystem flows into the accumulator in the lower system. If this accumulator also reaches his Limit charging voltage, the limitation is carried out by deducting the charging current in the same Same as described for the upper subsystem, with the difference that here in the shunt branch the excess energy is fed to a dissipation resistor will. In special cases, the dissipation resistance can also be bridged.

lower To accelerate the charging process of the accumulator in the In a variant of the system described, this subsystem also becomes this subsystem assigned to a solar generator, whereby its design is expediently carried out in such a way that that the required charging energy is provided in the available charging time.

If the system consists of more than two sub-systems, in Another embodiment of the invention, the additional subsystems with the higher nominal voltages above the arrangement described in the same way arranged or increased like there the upper subsystem on the lower.

In a further embodiment of the invention, the outputs are the Provide subsystems with output regulators, preferably series regulators. Outgoing from this arrangement one obtains a circuit variant with which one can use any one Selection of the subsystems with a high switching sequence can be connected in series by 'man terminates the subsystem outputs behind the series regulators with terminating diodes whose Direction of passage in each case from the reference conductor to the main conductor outlet shows, and by each main conductor exit with the reference conductor of the next higher subsystem connects. Capacitors connected in parallel to the terminating diodes, support the outputs of the subsystems in the event of impulsive loading. If you ask in this variant the output voltages between two consecutive ones Subsystems in such a way that they are each in a ratio of 2: 1 to one another, see above a sequence of output voltages can be established for the entire system by means of a binary link represent the output voltage of the lowest subsystem as a stair step having. The above-mentioned binary link is made by appropriate control the series transistors.

Starting from the basic arrangement or from the arrangements with more than two subsystems, including the output controllers already described can be applied, it allows a variant of the invention, also a circuit to be shown in which all reference conductors are connected to one another by equipotential bonding lines connected, d. H. the above coupling diodes through a conductive connection are replaced.

Of course, these variants of the invention share a common reference potential a series connection of the subsystem outputs is excluded.

Description of execution examples: In the figures Fig.l to 3 embodiments of the invention are shown and explained in terms of function. Fig. 1 shows the basic design and Fig. 2 is a diagram showing how it works. while Fig. 3 shows an expansion of the basic design by an additional stage.

In Fig. 1, the main conductor 8 of the upper subsystem has a higher one Potential compared to its reference conductor 6 than the main conductor 7 of the lower one Subsystem with respect to its reference conductor 5 when the photovoltaic converter 4 feeds into the upper subsystem.

As a result, this also applies to the point 10 compared to the point 9 of the circuit arrangement.

Therefore, a current flows from point 10 to point 9, if the coupling transistor 16 is controlled, the circuit being closed by the coupling diode 14, The mentioned control of the coupling transistor is carried out by the control element 18, when the charging current IB2 flowing into the accumulator 2 via the blocking diode 12 the Charging voltage U52 above the limit value Ug, see FIG. 2, would let rise away.

This can namely be prevented by the fact that the excess 1o - 1B 'from the point in time tg on from the switching point 10 from another consumer is fed. In the circuit arrangement of FIG. 1, this is the accumulator 2, the at some point, however, it will even reach its charge limit voltage Ug. Then here too the excess current 10-1B 'supplied from node 9 from another use will. This causes the control element 17, which controls the dissipation transistor 15 and supplies the excess energy to the dissipation resistor 13. In special cases, i.e. when the solar generator 4 is connected via the series connection of the diode 14 and the transistors 15 and 16 can be operated short-circuited, it is also possible to adjust the dissipation resistance replace with a metallic conductor Lu.

In a further variant of the invention, the lower subsystem a photovoltaic converter 3 is connected, which accelerates the charging of the accumulator 1.

In the same way as the upper subsystem to the lower subsystem is coupled, a third subsystem with a higher rated voltage can also be connected to the called upper subsystem coupled or topped up on this, as it is is shown in a further embodiment of the invention in FIG. Here are denotes the components of the third subsystem with the index a.

When the subsystem output voltages are limited in height should, or if the sub-systems are switched through to consumers of your choice should, then in the further embodiment of the invention, output regulators, preferably series regulator 19, 20, 20a ... used as shown in the figures Fig. 1 and Fig. 3 is shown One leads in a further refinement the terminating diodes 25, 26, 26a ... and the conductor bridges 29, 29a ... a, so causes the activation of the series transistors 23, 24, 24a ... that the relevant subsystem output voltages connected in series and result in the system output voltage UA.

The capacitors 27, 28, 28a, ... support the output voltages Ul, U2, U2a, ... with pulsed loading.

If you remove the bridges 29, 29a, ... and the terminating diodes 25, 26, 26a, ..., and if the coupling diodes 14, 14a, ... are bridged, then one obtains as a further variant of the invention systems in which all main conductors have a common Have reference potential.

L e r s e i t e

Claims (10)

Battery-backed power supply system? Patent claims preamble Battery-supported power supply system consisting of at least two sub-systems with different nominal voltage, their batteries preferably from photovoltaic Converters are charged via blocking diodes, characterized in that characteristic Part of the subsystems are coupled with one another according to the rule that excess energy from sub-systems with higher nominal voltages automatically the sub-systems with lower ones Nominal voltages is supplied, the circuit connection preferably should be done so that a cascade-like overflow of the excess energy in each case takes place to the next lower subsystem. 2. Accumulator-supported power supply system according to claim 1, characterized in that at least one photovoltaic converter (4) with a upper reference conductor (6) and the anode-side connection (10) of an upper blocking diode (12) is connected that a coupling transistor (16) said terminal (10) with the anode-side terminal (9) of a lower blocking diode (11) connects that one Coupling diode (14) a connection between a lower reference conductor (5) and the mentioned reference conductor (6) that the mentioned coupling transistor (16) through a control element (18) is controlled according to the rule that the voltage Ug2 between the upper main conductor (8) and the reference conductor (6) a predetermined limit value must not exceed that said connection (9) through the series connection an oissipation resistor (13) connected to said reference conductor (5) is that said dissipation transistor (15) by a control element (17) after the regulation is controlled that the voltage UB1 between the lower main conductor (7) and the said reference conductor (5) a predetermined May not exceed the limit value. 3. Battery-supported power supply system according to claim 1 and 2, characterized in that a further photovoltaic converter (3) with the lower reference conductor (5) and the connection (9) of the blocking diode (11) is connected. 4. Accumulator-supported power supply system according to claim 2 or 3, characterized in that further subsystems (index a, b, ...) with higher Nominal voltages increased in the same way to the arrangements described are like there the second subsystem on the first. 5. AkkumiatorHgestützes power supply system according to one of the claims 1 to 4, characterized in that the output voltage (U1, U2, U2a, ...) is one each subsystem is limited by a series transistor (19, 20, 20a ...), which controls a control circuit (21, 22, 22a ...). 6. Accumulator-supported power supply system according to claim 5, characterized in that the outputs are terminated with terminating diodes (25, 26, 26a ...) and that each series regulator output is connected to the reference conductor of the next higher system is conductively connected by a bridge (29, 29a, ...). 7. Accumulator-supported power supply system according to claim 6, characterized in that backup capacitors are parallel to the terminating diodes (25, 26, 26a ...) (27, 28, 28a ...) are switched. 8. Accumulator-supported power supply system according to claim 6 or 7, characterized in that the series transistors (19, 20, 20a ...) through external signals formed via special inputs (23, 24, 24a ..) as required and can be switched off, the degree of control optionally according to the Specification of the controller (21, 22, 22a ..) or complete. 9. Accumulator-supported power supply system according to claim 6, 7 or 8, characterized in that the output voltages U1, U2 U2a ...) respectively are in a ratio of 1: 2 to each other. 10. Accumulator-supported power supply system according to claim 2, 3, 4 or 5, characterized in that instead of the coupling diodes (14, 14a ...) a conductive connection between the reference conductors (5, 6, 6a ...) for the purpose of equipotential bonding is made.