DE10103431A1 - Power supply device - Google Patents

Abstract

The invention relates to a power supply device that comprises a photovoltaic generator (1) and secondary accumulators (5, 7) which are supplied by the generator and to which a consumer (16) is connected. The secondary accumulators (5, 7) have different accumulator technologies. These different accumulator technologies are especially characterized by their different voltages, different internal resistances, different self-discharges and different requirements to charging strategies and the like. One or more secondary accumulators (5, 7) of the same technology are connected by means of a system control (17) optionally via a switch (4, 6) to a direct current supply train (18) linked with the generator (1) and the consumer (16). The inventive concept using a plurality of different accumulator technologies in a no-break power supply mode is highly reliable and efficient as the different accumulators can be optionally and alternately used depending on the various requirements.

Description

The invention relates to a power supply device with a photovoltaic generator and with the generator fed accumulators to which a consumer is connected is.

To supply z. B. from sensors and telematics systems autonomous power supplies that require a maintenance-free and enable reliable operation over long periods of time ("mount and forget "principle). The measurement results can be made via radio networks forwarded to the central control center in various ways become.

With very low power requirements, primary batteries can also be used for several years of operation. But as soon as the consumption is higher and should be possible to operate without mains this is no longer possible.

Because of the availability of solar radiation and Energy requirements for such an autonomous power supply will be therefore photovoltaic generators used to be an accumulator to be able to charge the system.

The problem here, however, is that a considerable seasonal The difference in solar radiation occurs. Therefore  Energy from summer to winter is stored and available can be put.

The object of the present invention is to provide a power supply Establishment of the type mentioned to create a high Reliability, high efficiency and long Has lifespan. In addition, a flexible use should different consumers and different interconnections Photovoltaic generators may be possible.

To solve this problem, it is proposed that several secondary Accumulators of different technology are provided and that one or more secondary batteries of the same kind Technology by means of a system control, optionally via switches to one connected to the generator and the consumer DC power supply are switchable.

The present concept with several different accumulators technologies in an uninterruptible power supply highest reliability and efficiency because of the different batteries alternatively and in the context of the different requirements can be used.

The different accumulator technologies stand out especially due to different voltage levels, different Internal resistances, different self-discharge and under different requirements for the charging strategies.

If several accumulators are used, types can also be based the same electrochemical system with different ones Properties regarding cycle stability, service life, self discharge, power and energy densities and efficiency according to the different requirements as short-term or long-term storage can be used.

The use of multiple batteries also offers an increased Operational reliability. Identified by the system control as defective adorned accumulators can directly affect the  Supply task can be switched off.

Such a power supply device thus allows one flexible use with different consumers and differently connected photovoltaic generators.

With the help of the system control is the effort for the data acquisition in particular to determine the current state of charge all storage in the system, the loading and unloading management and the selection of the secondary battery or batteries to be activated comparatively low.

In addition to the secondary accumulators is advantageous a primary battery to the DC power supply connected, in particular decoupled via a diode.

This primary battery only supplies energy when the voltage on the DC power supply line under the voltage of the primary Batteries has dropped. The prerequisite is that the end of unloading voltages of the secondary accumulators above the voltage of the Primary accumulator. The primary battery is designed that their life expectancy is at least the time between two Maintenance intervals of the power supply device corresponds and that it has minimal self-discharge. It takes over the task of emergency care and allows in extreme cases bridging until maintenance personnel can be on site.

Advantageously, in the supply line from the photovoltaic Generator to the DC power supply and in the supply line an ammeter to the consumer, especially an ammeter Measurement shunts are provided, which are connected to the system control. Since only one accumulator on the DC power supply is activated, the state of charge can be determined with only two Current measurements regardless of the number of accumulators be performed. The electricity is measured by the producer (Photovoltaic generator) and the consumer electricity. The difference of these currents gives the respective accumulator current, which the each switched-on accumulator is assigned.  

A DC / DC voltage converter is preferably provided in the supply line between the DC supply line and the consumer. The consumer 16 can thus be supplied with a constant voltage regardless of the load and independent of the secondary battery that is just activated.

If necessary, this is in the supply line between direct current supply line and loads provided DC / DC voltage converter a bypass branch with one of the supply voltage at the consumer controlled electronic switch provided.

If the DC / DC voltage converter fails, the Power supply to the consumer must be maintained. The prerequisite is that the consumer voltage is lower than that Final discharge voltage of the primary accumulator is.

To a voltage drop at the consumer during switching operations To avoid accumulators, a capacitor is used Voltage stabilization. Depending on the needs of the consumer and the resulting size of the capacitor can be found here different technologies (capacitor, electrolytic capacitor, double layer capacitor) are used.

It is advantageous if in the supply line between photovoltaic Generator and the DC power supply one with the System control in control-related DC / DC voltage converter is provided.

The DC / DC voltage converter can be used in relation to the photovoltaic Generator simultaneously function as a maximum power point Fulfill trackers with optimal performance. The DC / DC Voltage converter brings up all available energy DC power supply line up to a maximum end of charge tension. This can be varied by the central system control specified according to the secondary battery that has just been activated become.

Additional embodiments of the invention are in the others Subclaims listed. The following is the invention with its  essential details with reference to the drawing explained.

The only figure shows:

a schematic circuit of a power supply Facility.

A power supply device 100 shown in the figure has a DC power supply line 18 to which at least one photovoltaic generator 1 as a power source, a plurality of secondary batteries 5 , 7 and a consumer 16 are connected. The figure shows an example of two secondary accumulators. Depending on the task, considerably more can be used.

In the exemplary embodiment, the photovoltaic generator 1 is connected to the direct current supply line 18 via a DC / DC voltage converter 2 . The DC / DC voltage converter 2 simultaneously fulfills the function of a MaxiumPowerPoint tracker with respect to the photovoltaic generator 1 , so that the maximum power is emitted even with different levels of radiation. The DC / DC voltage converter 2 thus brings all available energy to the DC power supply line 18 up to a maximum end-of-charge voltage. This can be variably specified by a central system controller 17 using a microcontroller. Provides the photovoltaic generator 1 decreases more power than the load 16, the voltage U _DC rises to the DC power supply strand 18 and is more energy than is supplied, the _DC voltage U is lowered to the DC supply line eighteenth

By way of example, two secondary batteries 5 , 7 of different technology are coupled to the DC power supply line 18 , although almost any number of batteries could be connected.

In the exemplary embodiment, the secondary accumulator 7 serves as a "daily storage", while the other secondary accumulator 5 serves as a "seasonal storage".

In addition, a primary battery 9 is connected via a diode 8 to the DC power supply line 18 and only supplies energy when the voltage U _DC on the DC power supply line 18 has dropped below the voltage U _{B3 of} the primary battery 9 . However, this only takes place when all rechargeable secondary batteries 5 , 7 are discharged. The primary battery 9 therefore has the lowest voltage level of all memories. The voltage of the primary battery must be higher than or equal to the minimum voltage for supplying the consumer 16 until discharge. This only applies if a bypass around the DC / DC converter is required. If the DC / DC converter can convert up and down, there is no restriction with regard to the voltage level of the consumer and the primary accumulator. The primary accumulator 9 must have a life expectancy that corresponds at least to the time between two maintenance intervals. It should also have minimal self-discharge.

When the power supply is transferred to the primary battery 9 , that is to say where the energy in the accumulators is exhausted, a warning signal can be sent to a monitoring center at an early stage and then reliable operation with an emergency reserve is still possible.

The day storage battery 7 has a voltage level U _B2 , which in the discharged state is as close as possible to the voltage U _{B3 of} the primary battery 9 .

The two batteries 5 and 7 are each connected via a self-locking MOSFET 4 , 6 as electronic switches, which work as an adjustable resistor or switch, to the direct current supply line 18 . The control inputs (gates) of the MOSFETs 4 , 6 are, as indicated by dashed lines, connected to the system controller 17 , so that the batteries 5 , 7 can optionally be connected to the DC power supply line 18 .

The battery 7 (daily storage) is connected to the DC power supply line 18 via the MOSFET 6 as long as this battery 7 has an operating state in which it is neither full nor empty. If the battery 7 is fully loaded, which can only occur if more energy is currently being supplied than is being consumed, the MOSFET switch 6 is opened. The voltage UDC on the DC supply line 18 rises until the current voltage U _{B1 of} the seasonal memory (battery 5 ) is reached. The seasonal memory (battery 5 ) is then connected to the direct current supply line 18 and absorbs the excess energy for charging. If the seasonal memory (battery 5 ) is fully charged, the energy supply from the photovoltaic generator 1 to the direct current supply line 18 is reduced to the current energy consumption by the DC / DC voltage converter 2 being controlled accordingly by the system controller 17 .

If the generation power of the photovoltaic generator 1 falls below the power requirement of the consumer and the daily storage with the secondary battery 7 is not empty, the consumer 16 is supplied from this battery 7 . Only when this is empty is energy from the seasonal storage made available with the secondary accumulator 5 . If this is also empty, the voltage U _DC on the DC power supply line 18 drops further. If it falls below the voltage U _{B3 of} the primary battery 9 , it supplies the consumer 16 .

The MOSFET 4 for the seasonal memory 4 works as an adjustable resistor, so that an adjustment of the voltage U _DC between the DC supply line 18 and the voltage U _{B1 of} the seasonal memory with the battery 5 is possible without a high current peak.

The MOSFET switch 6 of the day storage battery 7 is closed after opening in each case when the voltage U _{DC of} the direct current supply line 18 matches the current voltage level U _{B2 of} the day storage 7 . This prevents current peaks caused by compensating currents when switching.

The central system controller 17 opens the MOSFET switch 6 when the fully charged state is reached or when the daily memory 7 is empty.

The voltage of the DC power supply line 18 is stabilized by a capacitor 11 , so that the continuous power supply to the consumer 16 is ensured even during switching operations.

The voltage level of the DC power supply line 18 can fluctuate over a wide range. The consumer 16 is therefore preferably supplied with a constant voltage via a DC / DC voltage converter 15 .

In order to maintain the voltage supply in the event of a failure of the DC / DC voltage converter 15 to supply the load 16 , a bypass branch 19 bypassing the DC / DC voltage converter 15 is provided.

In the bypass branch 19 , an electronic switch 12 is provided, which is formed by a self-conducting MOSFET, the control input (gate) can be controlled in dependence on the consumer voltage, as is symbolically indicated by the dashed line connection.

Due to the self-conducting MOSFET 12 , the bypass branch 19 only becomes active when the voltage falls below a threshold value at the consumer 16 .

In the bypass branch 19 , a zener diode and a series resistor are connected in series with the self-conducting MOSFET, the consumer voltage between the zener diode 14 and series resistor 13 being tapped off. This voltage divider provides a stable voltage supply as long as the voltage on the DC supply line 18 is above the minimum consumer voltage.

The charge status of all memories 5 , 7 , 9 can always be monitored by means of the system control 17 . On the one hand, this enables a load management to be carried out in which the consumption can be reduced to the minimum functions as much as possible, and on the other hand a warning signal can be sent to a maintenance center at an early stage, which can, for example, carry out an external charging of the system.

In addition, the state of aging of the memories 5 , 7 , 9 can be monitored by the central system controller 17 . Can one of the memories no longer take over its function or will z. For example, if a significant reduction in storage efficiency is found, the other storage systems still available may have to take over the tasks. Here too, the central system controller 17 can decide how urgently an unscheduled maintenance is necessary or whether the system remains operational until the next scheduled maintenance.

Since, in addition to the capacitor 11 , only one battery is connected to the direct current supply line 18 , the state of charge can be determined with only two current measurements regardless of the number of batteries. With the aid of two ammeters 3 or 10, in particular designed as measuring shunts, the current I _PV from the generator 1 or the current I _{V in} front of the consumer 16 is measured. The difference between these currents gives the respective accumulator current.

Since the respective accumulator is also activated via the central system control 17 , a charge status can be carried out for each accumulator.

During the times when the batteries are unlocked the state of charge continues by extrapolating the self-discharge written and is available for system analysis at any time Available. By using multiple memories at times with high energy supply also targeted tests on the storage tanks regarding their still available capacity.

Different battery technologies can be used as secondary batteries 5 , 7 according to their respective special properties. For example, the use of lithium ion batteries, lithium polymer batteries, nickel metal hydride batteries, nickel cadmium batteries, lead batteries, lead gel batteries, RAM batteries, gold cap batteries and the like is possible. Lithium batteries are preferably used for the primary battery 9 because of their long standby life.

The central system controller 17 monitors all switch positions of the electronic switches 4 , 6 and also controls them.

In addition, the state of charge and the state of aging of the memories 5 , 7 , 9 are determined and the energy management for the consumer 16 is carried out. Current, voltage and temperature measurements are also carried out by the central system controller 17 . Adapted charging and operational management strategies can be implemented for the individual storage technologies.

With the present concept, reliable power supplies can using different storage technologies. This results in a high level of operational reliability and appropriate selection of the accumulators and the respective operation management strategy can have a long, maintenance-free system life can be achieved.

Claims (13)

1. Power supply device with a photovoltaic generator and with batteries fed by the generator, to which a consumer is connected, characterized in that a plurality of secondary batteries ( 5 , 7 ) of different technology are provided, and that in each case one or more secondary Accumulators ( 5 , 7 ) of the same technology can be switched by means of a system control ( 17 ) optionally via switches ( 4 , 6 ) to a direct current supply line ( 18 ) connected to the generator ( 1 ) and the consumer ( 16 ). 2. Power supply device according to claim 1, characterized in that in addition to the secondary batteries ( 5 , 7 ) a primary battery ( 9 ) to the DC power supply ( 18 ) is connected, in particular decoupled via a diode ( 8 ). 3. Power supply device according to claim 1 or 2, characterized in that in the supply line from the photovoltaic generator ( 1 ) to the direct current supply line ( 18 ) and in the supply line to the consumer ( 16 ) each have an ammeter ( 3 , 10 ), in particular current measuring shunts are provided which are connected to the system control ( 17 ). 4. Power supply device according to one of claims 1 to 3, characterized in that the switches ( 4 , 6 ) between the DC power supply line ( 18 ) and the respective secondary batteries ( 5 , 7 ) electronic switches ( 4 , 6 ), in particular are self-locking MOSFETS that are in control connection with the system controller ( 17 ). 5. Power supply device according to one of claims 1 to 4, characterized in that a DC / DC voltage converter ( 15 ) is provided in the supply line between the DC supply line ( 18 ) and the consumer. 6. Power supply device according to claim 5, characterized in that to the in the supply line between the DC supply line ( 18 ) and consumer ( 16 ) provided DC / DC voltage converter ( 15 ) has a bypass branch ( 19 ) with one of the supply voltage at the consumer ( 16 ) controlled electronic switch ( 12 ) is provided. 7. Power supply device according to claim 5 or 6, characterized in that the electronic switch ( 12 ) in the bypass branch ( 19 ) is a self-conducting MOSFET, whose control input (gate) can be controlled as a function of the consumer voltage. 8. Power supply device according to one of claims 5 to 7, characterized in that in the bypass branch ( 19 ) a Zener diode ( 14 ) and a series resistor ( 13 ) are connected in series to the self-conducting MOSFET ( 12 ) and that the consumer voltage between Zener diode and series resistor is tapped. 9. Power supply device according to one of claims 1 to 8, characterized in that in the feed line between the photovoltaic generator ( 1 ) and the direct current supply strand ( 18 ) with the system controller ( 17 ) in control connection DC / DC voltage converter ( 2 ) is provided. 10. Power supply device according to one of claims 1 to 9, characterized in that a buffer capacitor ( 11 ) is connected to the DC power supply strand ( 18 ). 11. Power supply device according to one of claims 1 to 10, characterized in that at least one secondary accumulators ( 7 ) are designed as daily storage and at least one further secondary accumulators ( 5 ) are designed as seasonal storage. 12. Power supply device according to one of claims 1 to 11, characterized in that the system controller ( 17 ) for determining the state of charge of the individual secondary batteries ( 5 , 7 ), for controlling the DC / DC connected to the photovoltaic generator ( 1 ) -Voltage converter ( 2 ), for the charge-dependent switching on and off of the secondary batteries ( 5 , 7 ), for load management, for performing battery tests, for checking the aging status of the secondary batteries ( 5 , 7 ) and the like. 13. Power supply device according to one of claims 1 to 12, characterized in that as secondary batteries ( 5 , 7 ) lithium-ion batteries, and / or lithium-polymer batteries, and / or nickel-metal hydride Batteries, and / or nickel-cadmium batteries, and / or lead batteries, and / or RAM batteries, and / or gold-cap batteries are provided.