DE19508345A1 - Circuit for checking re-chargeable electro-chemical cells - Google Patents

Abstract

The circuit converts the total voltage of cells (2) connected in series or a proportion thereof into an electrically isolated high frequency current using a voltage-frequency converter (4). The series circuit consists of a block (1) with one or more cells (2) each with its own block checking circuit (22) comprising a temperature dependent resistance (14) located close to and connected to the block, a comparator (18) supplied with a voltage proportional to the voltage across the resistance and a voltage-frequency converter (4) supplied with a current proportional to the high frequency current, the output voltage of which is fed to the comparator. The comparator generates a signal if the voltage output of the amplifier (15) is greater or smaller by a specific value than the output voltage of the converter.

Description

The invention relates to a circuit arrangement for checking rechargeable electrochemical cells according to the preamble of the claim 1.

Such electrochemical cells are, for example, in Accumulator batteries (with a voltage of 12 V) are used. In plants for uninterruptible power supply (UPS) can be thirty-four such accumulator batteries can be connected in series. To this Way (for an emergency power supply in the event of a failure of the Mains voltage) a DC voltage of approx. 408 V is provided. This one Accumulator batteries may last several years for one Emergency power supply are not used, they must be precautionary be checked (regularly). You can do this at the terminals of each discharging battery element, the voltage and the current be measured. Such measurements, usually of two People must be carried out at regular intervals be repeated. The high cost of these operations is disadvantageous and the dangers faced by operators in such Environment exposed to high voltages. In case of problems in the Inside the accumulator batteries can also acid vapors emerge.

On the other hand, inadequate controls of the accumulator batteries reduce or even a waiver of such controls the reliability of the entire security system.

The electrochemical cells of lead accumulators have depending on their State of charge a different voltage. When recharging they are normally connected to a voltage of 2.4 V / cell. For Charge maintenance is usually a trickle charge voltage of 2.23 V / cell selected. The end discharge voltage recommended by the manufacturer can be, for example, 1.7 V / cell. Using the the aforementioned values result in a maximum voltage difference of 0.7 V per cell.  

Sometimes the manufacturers give advice on how to care for and check theirs rechargeable batteries. It is possible that the manufacturer has a Customer service request recommends when the cell voltage of the mean trickle charge voltage deviates by +0.2 V or -0.1 V or when the surface temperatures of different battery elements around deviate from each other by more than 5 K.

It should therefore be noted that the aforementioned permissible deviations of the mean value of the trickle charge voltage are lower than the one mentioned (permissible) maximum voltage difference between charging voltage and Final discharge voltage.

A measurement of the voltage values on the individual accumulator batteries without taking into account the current voltage values at the others Accumulator batteries consequently do not allow any conclusions to be drawn about the proper condition of the electrochemical cells.

The invention has for its object a simple and Inexpensive circuit arrangement for checking electrochemical To create cells with the help of which a reliable automatic Voltage and temperature monitoring is possible.

According to the invention, this object is achieved by a circuit arrangement for checking rechargeable electrochemical cells according to claim 1.

The circuit arrangement according to the invention is used for monitoring of the respective blocks using the (opposite to the series connection of the Cells with galvanically isolated flowing) high-frequency current Total voltage of the series connection taken into account. The Circuit arrangement is characterized by its particularly simple structure with standard components. The one for each block monitoring required circuit modules are very inexpensive to buy available. In addition, the circuit components can be minimized Accommodate rooms.

The blocks with the electrochemical cells need for checking neither to be moved nor is it necessary (high) Lead out battery voltages to the test facility via long cables. This reduces the risk of short circuits and fire.  

With the comparison device - in the event of a fault Blockes - Generate interference signals automatically. The workload for one Verification is therefore particularly low.

The total voltage is expediently determined using a Voltage divider reduced by a proportionality factor. This is particularly advantageous if the series connection consists of a certain Number of identical blocks (each with the same number of electrochemical cells). In this case the Proportionality factor corresponds to the reciprocal of the number of blocks. The voltage divider then gives the current average of the Tension of a single block. For this purpose, claims 12 and 13 referenced.

According to claim 6, at least one block is an accumulator battery. In an uninterruptible power supply system would usually each block is an accumulator battery.

The switch according to claim 11 prevents deep discharge of the electrochemical cells of the respective block.

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

The following is an embodiment of the invention based on two Drawings showing further details and advantages described in more detail.

Show it:

Fig. 1 is a circuit diagram of a circuit arrangement for checking a block with electrochemical cells and

Fig. 2 is a diagram showing the dependence of the voltage (at the output) on the frequency (at the input) on the converter that converts the frequency into a voltage.

Referring to FIG. 1, a circuit arrangement for checking the electrochemical cells in a series circuit with a number N of thirty-four lead-storage batteries.

Each lead-acid battery forms a block 1 with six electrochemical cells 2 and provides a DC voltage of 12 V. This results in a total voltage of approx. 408 V (34 _* 12 V = 408 V). If these lead-acid batteries are part of an uninterruptible power supply (UPS) system, the total voltage ensures that the power supplies connected to the system continue to operate in the event of a power failure.

A voltage divider 3 is connected to the series circuit and outputs a DC voltage on the output side, which corresponds to a thirty-fourth (1 / N = 1/34) of the total voltage at the series circuit of all lead accumulators. A voltage-frequency converter 4 is connected behind the voltage divider 3 and converts the direct voltage applied to it into a (high-frequency) current. This current is conducted into the primary winding 5 of a transformer 6 . The primary winding 5 is attached to a toroidal core 7 of the transformer 6 . The frequency of the current depends on the size of the DC voltage at the voltage-frequency converter, and the following applies: the higher the DC voltage, the higher the frequency. A current loop 8 , which is laid through the ring core 7 of the transformer 6 , serves as the secondary winding of the transformer 6 .

This current loop 8 is passed through a further toroidal core 9 and forms the primary winding of a further transformer 10 , the secondary winding 11 of which is attached to the toroidal core 9 and is connected to a frequency-voltage converter 12 . On the output side, this frequency-voltage converter 12 produces a DC voltage, the level of which depends on the frequency of the current fed in.

A series circuit comprising an ohmic resistor 13 and a temperature-dependent resistor 14 is connected to each block 1 consisting of a lead accumulator battery. The temperature-dependent resistor 14 is an NTC resistor and is directly attached to the housing of the associated lead-acid battery (of the respective block 1 ). In this way, an increase in temperature is recorded electronically.

The voltage across the temperature-dependent resistor 14 is amplified by an amplifier 15 connected to it; consequently, a voltage divider is formed by the resistors 13 and 14 , which simultaneously detects voltage and temperature at block 1 .

On the output side, the amplifier 15 is connected to an input of a window comparator 16 . The window comparator 16 forms, together with two light-emitting diodes 17 , which are connected antiparallel to the output of the window comparator 16 , a comparison unit 18 .

The output of the frequency-voltage converter 12 mentioned above is connected to the other input of the window comparator 15 .

Depending on the sign of the voltage between the inputs of the window comparator 15 , either one or the other light emitting diode 17 is now excited to light up. Instead of or in addition, a circuit can be provided which causes a fault message.

In particular, the amplifier 15 and the frequency-voltage converter 12 must be designed so that the voltage difference at the inputs of the comparison amplifier 16 is approximately zero when the electrochemical cells 2 in the monitored block 1 are in the correct state, so that neither of the two light-emitting diodes 17 emits light .

If the condition of a block 1 is correct in this sense, the cell voltages are in a range specified by the manufacturer (for example: deviation +0.2 V to -0.1 V) in comparison with the mean trickle charge voltage of all cells 2 . In addition, the temperature only deviates from a predetermined reference value up to a certain maximum value. This reference value is usually specified by the manufacturer of the lead accumulator batteries.

A branch is provided in parallel with the series connection of the resistor 13 with the temperature-dependent resistor 14 for the voltage supply of the electronic modules assigned to each block 1 . A resistor 19 limits the current flowing out.

To prevent deep discharges of the cells 2 in the respectively monitored block 1 with small currents ("battery death") there is a switch 20 between the block 1 and the series connection of the resistors 13 and 14 and parallel to the series connection of the two aforementioned resistors 13 and 14 an undervoltage coil 21 inserted. The switch 20 opens when the voltage at the block 1 has fallen below a predetermined limit.

When commissioning, the switch 20 is to be unlocked automatically or manually.

The transmitter 10 , the frequency-voltage converter 12 , the comparator 18 , the amplifier 15 , the ohmic resistor 13 , the temperature-dependent resistor 14 , the switch 20 and the undervoltage coil are components of a block check circuit 22 . The block check circuit 22 is delimited by a broken line in the figure; for each block 1 to be checked, such a block check circuit 22 must be provided. For the sake of clarity, only one is shown in FIG. 1.

Fig. 2 shows the dependence of the voltage at the output of the frequency-voltage converter 12 is a function of the frequency of the current at its input. The high-frequency current in the current loop 8 has a frequency within a range from 4 to 9 kHz.

Claims (14)

1. Circuit arrangement for checking rechargeable electrochemical cells, characterized in that
that the total voltage of a series connection of several electrochemical cells ( 2 ), reduced in full or by a proportionality factor, is converted into a high-frequency current by means of a voltage-frequency converter ( 4 ) with a device for electrical isolation,
that the series circuit contains at least one block ( 1 ) with a single cell ( 2 ) or with several cells ( 2 ) connected in series, and each block ( 1 ) has its own block check circuit ( 22 ) with a plurality of electronic components, namely with

• a temperature-dependent resistor ( 14 ) which is attached as close as possible to the block ( 1 ) and connected to it,
• a comparison device ( 18 ), one input of which is fed with a voltage proportional to the voltage across the temperature-dependent resistor ( 14 ),
• a frequency-voltage converter ( 12 ) which is fed with a current proportional to the high-frequency current and whose output-side voltage is led to a second input of the comparison device ( 18 ),

and that the comparison device ( 18 ) generates a signal when the voltage at the output of the amplifier ( 15 ) is at least a certain value smaller or greater than the voltage at the output of the frequency-voltage converter ( 12 ). 2. Circuit arrangement according to claim 1, characterized in that the voltage-frequency converter ( 4 ) is connected upstream of a voltage divider ( 3 ) to which the total voltage is present on the input side. 3. Circuit arrangement according to claim 1 or 2, characterized in that the device for galvanic isolation a toroidal core ( 7 ) with a winding ( 5 ) fed by the voltage-frequency converter ( 4 ) and a through the toroidal core ( 7 ), of the high-frequency current through current loop ( 8 ) as a secondary winding is that this current loop ( 8 ) is guided as a primary winding through a further ring core ( 9 ), such a further ring core ( 9 ) being provided for each block checking circuit ( 22 ), and that around each toroidal core ( 9 ) a winding ( 11 ) is placed as a secondary winding and this winding ( 11 ) is guided to the input of the frequency-voltage converter ( 12 ). 4. Circuit arrangement according to claim 1 or 2, characterized in that the device for electrical isolation is an optocoupler, that this optocoupler emits the high-frequency current and that this current is fed to a further optocoupler, the output side with the frequency-voltage converter ( 12 ) is connected, such a further optocoupler being present for each block checking circuit ( 22 ). 5. A circuit arrangement as claimed in any one of the preceding claims, that an amplifier (15) is connected to the temperature-dependent resistor (14) which amplifies the voltage across the temperature-dependent resistor (14). 6. Circuit arrangement according to one of the preceding claims, characterized in that at least one block ( 1 ) is an accumulator battery. 7. Circuit arrangement according to one of the preceding claims, characterized in that the comparison device ( 18 ) comprises a window comparator ( 16 ) with a positive and an inverting input and that on the window comparator ( 16 ) on the output side antiparallel two LEDs ( 17 ) are connected. 8. Circuit arrangement according to one of the preceding claims, characterized in that a branch for supplying the circuit arrangement is provided on the block check circuit ( 22 ) in series with the temperature-dependent resistor ( 14 ). 9. Circuit arrangement according to one of the preceding claims, characterized in that the block checking circuit ( 22 ) connected to the block ( 1 ) has, in addition to the temperature-dependent resistor ( 14 ), a further resistor ( 13 ) connected in series with this and that the amplifier ( 15 ) is connected in parallel to the temperature-dependent resistor ( 13 ). 10. Circuit arrangement according to one of the preceding claims, characterized in that the circuit arrangement is designed such that the voltage generated by the frequency-voltage converter ( 12 ) in relation to the instantaneous total voltage of the series circuit is as large as the ratio of the voltage across the Associated block ( 1 ) for the total voltage of the series circuit in the case of the same voltages in all electrochemical cells ( 11 ) of the series circuit. 11. Circuit arrangement according to one of the preceding claims, characterized in that a switch ( 20 ) is arranged in the supply line between the block ( 1 ) and the components of the block check circuit ( 22 ) that an undervoltage coil ( 21 ) when the switch ( 20 ) is closed. is electrically connected to the block ( 1 ) and that when the voltage falls below a predetermined limit for the block ( 1 ), the switch ( 20 ) is opened by means of the undervoltage coil ( 21 ). 12. Circuit arrangement according to one of the preceding claims, characterized in that the series circuit consists of a predetermined number N of blocks ( 1 ) each having an equal number of series-connected, structurally identical electrochemical cells ( 2 ). 13. Circuit arrangement according to claim 12, characterized, that the proportionality factor is 1 / N.