DE2852625C2 - - Google Patents

Description

The invention relates to a device for testing Ak accumulators with at least one on the poles of the accumulator connectable discharge resistor.

Capacity is an important parameter of accumulators. It indicates how much current the accumulator has within one certain period can be removed. However, that depends Capacity of the amount and duration of the discharge current and of white other variable sizes. Therefore one has for the so-called named nominal capacity, fixed reference values were introduced. In the Testing of accumulators must comply with these reference values be.

For testing accumulators and for determining the nominal ca capacity these are usually with a constant Ent charging current over a discharge resistor up to a predetermined Discharge voltage or during a predetermined time span unloaded. Because during unloading, the Voltage changes, it is necessary from time to time readjust the discharge resistance. The necessary for it Personnel expenses are not negligible, especially  then, if several accumulators are checked at the same time the. From the measured start and end values of current and voltage of the respective accumulator can then Determine nominal capacity. Do you want more information about the behavior of the battery during discharge hold, then in the meantime further measurements have to be carried out be performed. The effort required for this increases itself very significantly if the discharge behavior of a Accumulator not only with constant discharge current, but also according to other criteria, e.g. B. with constant discharge performance should be determined.

The preferred object of the invention is therefore the test of accumulators and batteries, especially under consideration consideration of different criteria without large personnel and to allow time and in a documentable form.

The inventive solution to the problem and advantageous The structure of these results from the content of Pa claims that precede this description.

The device connected to an accumulator measures the operational parameters, namely voltage, current and time during the discharge, and calculates the respective criteria according to which the discharge is to be controlled or regulated. Depending on the measured parameters or the selected criterion, the control unit switches the discharge resistors required for a desired discharge into the discharge circuit. The accuracy of the control or regulation depends on the number of dual staggered discharge resistors and can be set up with a relatively small number of discharge resistors so that it is sufficient for technical purposes. For example, with six discharge resistors, to which the dual values 1, 2, 4, 8, 16, 32 are assigned, a minimum step change of 1.6% of the maximum range is achieved ( 63 ). If, according to a preferred embodiment of the invention, a circuit for minimizing the control deviation is provided, which causes the fluctuation in the manipulated variable resulting from the binary structure of the actuator, the minimization taking place to a little more than half of this fluctuation, a control deviation is only slightly more achievable as 0.8%. The individual discharge resistors are connected to the discharge circuit using separate switches, which switches can be designed as electronic switches or as contactors, depending on the size of the resistance present.

But there is also the option of instead of several dual staggered discharge resistors a variable Ent charging resistor, for example in the form of a to a network lockable converter working in inverter operation to be used, which is controlled by the control unit so that the discharge current emitted by the accumulator directly back into the network is fed.

The measured operational parameters are appropriately too first digitized and then from the control unit's arithmetic unit processed. For this purpose, the arithmetic unit can be processed separately paths for the determination of the desired criterion exhibit. The desired criterion can e.g. B. with a Operating mode selector switch on the outside of the control unit can be set. But there is also the possibility that Control arithmetic unit with a program. A complete one Discharge measurement is usually carried out with an operating arm leads. A change of the operating mode during the measurement is possible still possible.

All start and end values of the characteristic data of the test Accumulator and all start and end sizes of the operation parameters are saved and protected against forgery  can use it to create a test report that is capable of being documented can be printed out. During the measurement, the ge measured operational parameters and other, from it he calculated sizes in cyclical alternation and can can be called up as intermediate values by pressing a button will. You can also use it to create a complete Measurement protocol can be printed out at certain intervals.

In particular, the following Be Realize modes of operation with the device according to the invention:

A capacity measurement with constant discharge current. That ent speaks of the usual determination of the capacity of a battery lators with constant discharge current. The control switches so the discharge resistors into the discharge circuit, that despite changing voltage, the current within the Limits of the control accuracy remains constant. The goal is Determine the capacity, ending the measurement either by a preselectable minimum discharge voltage or a preselectable time is determined.

A measurement with constant discharge resistance. This ent speaks of discharging the battery with a constant Load, e.g. B. when operating emergency lighting. Here a certain resistance remains on, the steering wheel device does not regulate, but measures or calculates the be drive parameters or other sizes. The end of Measurement is by a predetermined minimum voltage or determined by a predetermined time.

A measurement with constant power. This is the case if the accumulator z. B. feeds an inverter that supplies a constant load with constant voltage, e.g. B. an emergency power supply for electronic systems. Here the control unit regulates the activation of the unloader  would be such that the instantaneous value of the performance, that is Product of voltage and current, within the limits of Control accuracy is kept constant. The end of the Mes solution is determined by a predetermined minimum voltage or determined by a predetermined time.

The device according to the invention can also be used for measurement the charging operation of the battery can be used. Here at the battery is charged from a charging current source the. The control unit can use a digital-to-analog converter control the charging current source, but in any case measures and calculates the operational parameters or the parameters derived from them headed sizes. When properly charged, a can closing discharge process the efficiency of the accumulator tors are determined.

In addition, other applications are possible disregard the possibilities of the device according to the invention, e.g. B. for measurement and data acquisition battery-powered Systems in the broad sense, e.g. B. battery-powered driving witness, in the endurance test of solar cells and the like, for the determination and logging of system characteristics considering feedback (vehicles) or Long-term performance yield of solar cells, furthermore for the investigation of solar panels and the like, wherein also the detection of alternating variables by means of a suitable measured value converter, e.g. B. thermal crosses is not excluded. In In all cases, the test or data acquisition is carried out with With the help of the device according to the invention, automatically the device provides a printed measurement report.

The following is an embodiment shown in the drawing Example of the invention explained; it shows  

Fig. 1 shows a schematic representation of a block diagram of a load connected to an accumulator device

Figures 2a, 2b shows the object of Fig. 1 with further particulars.,

Fig. 3 shows the circuit of the discharge resistors with further details.

The device shown in the figures is used for testing accumulators 1 . It consists in its basic structure of a control unit 2 , which is supplied via a network connection 3 or, for example, also from the test object itself and from which control lines 4 lead to discharge resistors 5 , which can be switched into the discharge circuit 6 of the accumulator 1 . In addition, the control device 2 is connected via measuring lines 7 to the discharge circuit 6 .

It is understood that the control lines 4 and the measurement lines 7 and the lines of the discharge circuit 6 can be connected to the respective parts via plug connections 8 . Otherwise, the control unit 2 can also be connected to a remote control 9 and in turn controlled by this.

From Fig. 3, it extracts the structure of the discharge circuit 6 in detail. The discharge circuit 6 has two connection terminals 10, 11 which are placed on the poles of the accumulator 1 , not shown. In addition, the discharge circuit 6 has an auxiliary terminal 12 , which is connected to a charging current source (not shown) when charging the battery and ensures that the charging current flows through the measuring shunt, because only then is it ensured that the values of interest are maintained under constant conditions and with satisfactory accuracy, e.g. B. look at Dauerver to determine quasi-continuous changes with the same control unit 2 can be detected.

In the discharging circuit 6, several, in the illustrated embodiment 6 discharge resistors 13-18 are switchable. The discharge resistors 13-18 have dual staggered resistance coefficients in the order 1, 2, 4, 8, 16 and 32. Each discharge resistor 13-18 is assigned a switch 19-24 which can be actuated by the control unit 2 . In the scarf tern 19-21 of the discharge resistors 13-15 are electronic switches, namely transistors, the emitters 25 and collector 26 are connected to the discharge circuit 6 , while their respective base 27 is connected to an associated output of the control unit 2 . If thyristors are used as electronic switches, a further commutation connection 28 is provided between the control unit and the thyristor.

The switches 22-24 of the discharge resistors 16-18 are contactors, the control lines 29 of which are connected to an assigned output of the control device 2 . In addition, feedback lines 30, 31 leading to the control unit 2 can be provided, via which the control unit 2 receives information about the respective switching state of the switches 22-24 . The switches (contactors) 22, 23 are operated with an operating voltage of 24 V, while the switch (contactor) 24 is operated with an operating voltage of 220 V. So that the switch 24 is still operated with the same voltage who can as the other switches, an auxiliary contactor 32 is connected in the control circuit of this switch 24 . All connections to the switches 19-24 are combined in a control plug.

The control plug also receives the connections for a control loop 33 or 34 connected to the discharge circuit 6 . All connections or lines described so far are summarized to the control line 4 shown in Fig. 1 summarized.

Details of the measuring line 7 , which ends with a measuring plug, are shown in the left part of FIG. 3. Lines 35, 36 for voltage measurement and lines 36, 37 for current measurement can be seen. In addition, in the area of this measuring line 7, a large number of further connection points are indicated, which lead to coding loops of different voltage or different current in the control device.

FIG. 2a shows a simplified representation of the circuit of the discharge resistors in the upper part, while the lower part of FIG. 2a together with FIG. 2b show details of the control unit 2 . The control device 2 has a power supply unit 38 with the mains connection 3 , and also measuring paths 39, 40 for voltage and current, an arithmetic unit 41 with memory 42 and finally a central control unit 43 and a display 44 and a printer 45 . The power supply 38 is constructed in a conventional manner and supplies the voltages required to operate the other devices. All of these devices are connected to the central control unit 43 via connections Z and can thus be controlled centrally.

With a nominal voltage switch, the power supply 38 , a voltage range monitor 47 and the measuring path 39 are adapted to the nominal voltage of the battery 1 to be tested, so that the available devices can be used optimally and system-related errors remain minimal.

The measured values reaching the measuring paths 39 and 40 are first amplified and then digitalized in digital voltmeters 48, 49 . The digital measured values then arrive in the computer 41 which , in the exemplary embodiment shown, contains different processing paths. The incoming voltage measurement value is compared in a comparator 50 with a predetermined voltage end value 51 .

A conductance calculator 52 forms the actual resistance 53 from the respective measured values of voltage and current, which is compared in a comparator 54 with a predetermined target resistance 55 .

A power calculator 56 calculates the respective actual power 57 , which is compared in a comparator 58 with a predetermined target power. The actual power 57 is integrated in an integrator 60 , at the output of which the value of the electrical work is present at the end of the measurement.

The measured current is compared in a comparator 62 with a target current 63 . The measured current is also integrated in an integrator 64 , at the output 65 of which the netted ampere hours are present after the measurement has ended.

The comparators 54, 58 and 62 are connected via a line system 66 shown in broken lines in FIG. 2b to a control switch 67 ( FIG. 2a), which receives the switching signals for switching a specific combination of the discharge resistors 13-18 and this via a Isolation stage 68 and driver 69 passes on to switches 19-24 . The isolating stage 68 has the function of a signal shaper and level converter, it provides a galvanic isolation between the voltage levels of the electronics via optocouplers. Symbolic displays 70 on the front of the control unit indicate the respective switching state of the discharge resistors 13-18 .

The device shown works as follows: On a key and control field, not shown in detail, of the central control unit 43 with control keys 71 , mode switches 72 and keys 73 for data input, the device is switched on, the desired operating mode is selected and the data of the Checking accumulator and other operating data, such as B. setpoints, keyed and stored in memory 42 .

Furthermore, the switches 74, 75 are closed, so that the initial values of voltage and current and the further variables calculated from them can also be transferred to the memory 42 . In the following, the actual values of voltage and current are then measured and processed at certain time intervals in accordance with a timer 76 , the times of which are of course also transferred to the memory, the control switch 67 possibly being connected to the outputs of the comparators 54, 58 or contains 62 information such that the combination of the discharge resistors 6 to be switched in the discharge circuit 6 is to be changed.

All measured and calculated values are first collected in the memory 42 . During the measurement, these values can be displayed cyclically on the display 44 , which is connected to the central control unit 43 via a display controller 77 . If necessary, intermediate values can also be called up by pressing a button.

There is also the possibility of printing out the retrieved intermediate values via the printer 45 , which is connected to the central control unit 43 via a printer controller 78 , between temporally or continuously.

At the end of the measurement, which is determined either by the output of the comparator 50 or in some other way, the end values are printed out and the device is then switched off. In the event of a malfunction, the central control unit 43 provides an optical or acoustic display 79 .

The device according to the invention is provided with all the necessary safeguards and precautions which prevent damage or destruction from occurring due to incorrect polarity or selection of an incorrect operating mode. This includes the voltage range monitor 47 as well as an electronic changeover relay 80 in the area of the measuring path 40 for the current as well as further components and devices not shown in detail.

The in the description, the claims and the drawing disclosed features of the invention can be both individually as well as in any combination with each other for the Realization of the invention in its various forms leadership forms are essential.

Claims (14)

1. Apparatus for testing batteries with at least one discharge resistor that can be connected to the poles of the battery, characterized by an actuator designed as a discharge resistor or a plurality of dual staggered actuators ( 13-18 ) that can be switched in parallel and optionally in the discharge circuit ( 6 ) and by one Via measuring lines ( 7 ) to the discharge circuit ( 6 ) and via control lines ( 4 ) to the actuator (s) ( 13-18 ) connected control unit ( 2 ) for measuring and processing the operating parameters and for setting the required Resistance value depending on the measured parameters. 2. Device according to claim 1, characterized in that each actuator ( 13-18 ) is assigned a separate, to a control line ( 4; 27, 29 ) connected switch ( 19-24 ) which can be actuated by the control device ( 2 ) and with which the relevant actuator ( 13-18 ) in the Ent charging circuit ( 6 ) can be switched. 3. Apparatus according to claim 2, characterized in that the switch ( 19-21 ) is an electronic switch. 4. The device according to claim 2, characterized in that the switch ( 22-24 ) is a contactor. 5. The device according to claim 1, characterized in that the actuator is a connectable to a network, in Inverter operation is working converter. 6. The device according to one or more of claims 1-5, characterized in that the control unit ( 2 ) has an arithmetic unit ( 41 ), at the input of which, if necessary via digital voltmeter ( 48, 49 ) or analog-digital converter, the measuring lines ( 7; 35, 36, 37 ) and whose output ( 54, 58, 62 ) controls a control switch ( 67 ) which is connected to the control lines ( 4; 27, 29 ). 7. The device according to one or more of claims 1-6, characterized in that the arithmetic unit ( 41 ) and a central control unit ( 43 ) are coupled correlatively, the arithmetic unit ( 41 ) having outputs for a display ( 44 ) and / or one Has printer ( 45 ), which may be coupled to the control unit ( 43 ). 8. The device according to one or more of claims 1-7, characterized in that the arithmetic unit ( 41 ) is assigned a memory ( 42 ). 9. The device according to one or more of claims 1-8, characterized in that the arithmetic unit ( 41 ) is assigned a timer ( 76 ). 10. The device according to one or more of claims 5-9, characterized in that a digital-to-analog converter is connected to the control switch ( 67 ) for controlling the converter. 11. The device according to one or more of claims 1-10, characterized in that the arithmetic unit ( 41 ) separate processing paths for current and / or voltage and / or resistance and / or power and / or charge, each with an output to the control switch ( 67 ) forming comparator ( 54, 58, 62 ), and that the processing paths are selectively switchable from the central control unit ( 43 ) into the control circuit formed between the discharge circuit ( 6 ) and control unit ( 2 ). 12. The device according to one or more of claims 1-11, characterized in that the device as communicative System is formed by inevitable rows follow the operating parameters and their processing availability checked and rejected if necessary. 13. The device according to one or more of claims 1-11, characterized by a circuit to minimize the Deviation, which is due to the binary structure of the Actuator fluctuation of the manipulated variable ver causes a little more than half of these Fluctuation. 14. The device according to one or more of claims 1-11, characterized by a when changing the manipulated variable smaller current preferred comparator circuit.