DE1590863B2 - INDEPENDENT POWER SUPPLY SYSTEM FOR DC CONSUMERS - Google Patents

Description

The invention relates to an automatic power supply system for direct current consumers with a DC voltage source, which supplies the consumer with nominal voltage during normal operation and simultaneously charges a battery that is used for buffering and emergency supply and is divided into two groups, wherein the battery groups are each parallel to the DC voltage source and each battery group each a variable series resistor is assigned, and with a switching device, which in the event of failure of the DC voltage source or larger voltage drops the two battery groups in series switches, whereby the series voltage of both battery groups also corresponds approximately to the nominal voltage.

Reliable energy sources are used for switching and monitoring devices in power supply systems necessary. These systems are therefore often fed with direct current in conjunction with a battery. This mode of operation is generally referred to as buffer mode. In such systems are a mains powered charger, e.g. B. a rectifier, and the battery in parallel connected to the consumer. The battery smooths the ripple direct current supplied by the rectifier, absorbs peak loads and takes over the power supply in the event of a power failure.

The problem with these known systems is in particular the difficulty of the prescribed Adhere to the voltage limits at the consumer. These voltage limits are due to the fact that the charging voltage of the battery is always higher than the nominal voltage, this nominal voltage but should also be adhered to in the event of a prolonged disturbance in the network.

One is therefore forced to set the supply rectifier to the maximum permissible from the outset To regulate the voltage value of the system and the consumers always at the top if the network is available Operate voltage limit. In the event of a power failure and the associated discharging of the battery the terminal voltage drops until it has reached a lowest 'permissible value. This lies in many ' Cases still above the permissible end-of-discharge voltage of the battery.

The mean voltage level of the battery is in the flat part of the battery discharge curve, which is approximately between 20 and 80% of the capacity drain occurs. As the battery is continuously charged in the event of a power failure is operated out, - the flat part of the discharge is usually already considerably below the nominal voltage. If the consumer is not to be operated with undervoltage in the course of ■ further discharging, so the unloading - in many cases already before When the battery final discharge voltage is reached. -The full battery capacity can thus not being exploited.

Voltage tolerances can only be reduced within certain limits by the fact that a The battery is oversized, which means that the lower limit voltage value is higher.

Another option is to divide the battery into a main group and an additional group of cells, the so-called switching cells. The stem cells are constantly parallel to the consumer who Switching cells are only switched on automatically at a certain lower voltage limit of the power source. When charging begins and the voltage rises, the switching cells are switched off again. A load resistor ensures that the switching cells discharge evenly will; However, this alone does not guarantee that they will always be in the same state how the stem cells are located.

In the German Auslegeschrift 1 137 499 an automatic power supply system is the one mentioned at the beginning Type described that contains two groups of batteries. These are available for charging with the same Pole (+ -Pol) via series resistors on the grounded generator and both are also grounded. at If the generator is overloaded, the battery groups are connected in series via a contactor, whereby at the same time the earthing of a battery group is canceled. The pre-resistances are about a Relay switched off and the battery groups connected in series in parallel via another contactor switched to the generator. To connect the batteries in series when the generator is overloaded, a disproportionately high cost of switches is required. The contactors used must therefore have a large number of contacts, i. that is, the system becomes expensive and prone to failure. Through the A brief voltage drop cannot be avoided using mechanical switching elements.

From the German Auslegeschrift 1136 764 there is also a circuit arrangement for the uninterruptible Switching from mains operation to battery operation known, which contains an additional rectifier. A Such an additional rectifier could only replace a second battery group if the battery is in Trickle charge, i.e. charged with very little current. As soon as other charging methods are used must be, for example, if the battery is exposed to heavy loads, the must Rectifiers are dimensioned much larger, d. that is, it becomes much more expensive. In addition, the Half or a large part of the capacity of the battery is lost, so that either the remaining part of the battery must be chosen larger again, or peak loads can no longer be reliably absorbed will. _.

The known systems have an unfavorable battery utilization, unnecessary energy consumption, higher costs. Oversizing or due to additional cells as well as an unfavorable Tension. For this purpose, quite complex switching devices and control devices, eg. B. to determine when the switch cells are switched on. The use of mechanical Switching causes a brief voltage drop when switching over.

The object of the present invention is to improve or improve the known power supply systems. the cost of switching means of the known automatic power supply systems with regard to to reduce a higher level of operational reliability.

This object is achieved in that the negative pole of the first battery group has a diode with the negative pole of the DC voltage source and the positive pole via an adjustable resistor with the positive pole of the DC voltage source, the positive pole of the second battery group Via a second diode with the positive pole of the DC voltage source and the negative pole of the second battery group via a second adjustable resistor to the negative pole of the voltage source is connected and that the positive pole

3 4

the first battery group with the negative pole which theoretically discharges up to a voltage

second battery group via an electronic switching of 19.8 volts, d. H. up to the final discharge voltage

device that could be continued in the event of a power failure or overload of 1.1 volts per cell. the

Battery groups connects, is interconnected. So the capacity of the battery will not be perfect

An embodiment of the 5 according to the invention is used.

automatic power supply system is shown below. Curve 2 shows the voltage curve in the

on the basis of FIG. 1 explained in more detail. automatic power supply according to the invention

The F i g. 2 represents the voltage characteristic of this system. The nominal voltage should again be 24 volts

Arrangement in contrast to the characteristic curve of a be. The values are the same as deviations

known arrangement. OK as permitted above. Rectifier and consumer

The entire battery is then divided into two groups 1 and 2 to the nominal voltage of 24 volts, whereby the groups can be the same or differently set, ie the nominal number of cells can always be different in mains operation. Each group will be stressful for the consumer. For the battery, 20 cells are selected from the same charger or from the mains rectifier 3 in the example, which are charged in two groups independently of one another, the charging 15 to ten cells with 1.4 volts per cell = 14 volts method as desired, e.g. B. normal, maintenance or charging voltage can be charged. Can be continuous charging in switch-on eyes. The charging currents at a glance (t - 0), ie when the battery groups 1 and 2 are connected in series, the load voltage Un -f "10 ° / ₀ > resistors 4 and 5 are set by the diodes 6 this corresponds to a threshold voltage of 1.32 volts and a discharge of the groups in idle mode per cell is prevented at the consumer when the middle position is reached The entire operating voltage can be used in the charging circuits of the battery groups cell at about 24.2 volts, ie at Un + 1 ° / ₀ .

Group 1 is charged, for example, via deviation from the nominal voltage, so here is a substantial resistance 4 and diode 6, group 2 via resistor 25 borrowed less than most known current levels 5 and diode 7. Both battery groups are in supply systems, and the battery is dementich but always in the same state of charge. The contrary is better exploited.

Stands 4 and 5 can be replaced by other components, in the example given of the known circuit which allow current regulation, must be replaced due to the specified voltage mode through magnetically controlled components, 30 border 18 cells can be selected. In the case of the invention Kink chokes and the like according to the automatic power supply system

In the event of a power failure, however, the two groups in series are able to switch the number of cells purely from the face and feed the consumer 8. To choose the row point of the optimal battery utilization, circuit is effected by the d. i.e., instead of the 20 cells mentioned in the example Component. 35 can also depending on the requirements

Since the 19 to 21 cells are not used when charging the battery groups

Total voltage of the groups at the consumer. The higher the number of cells in a given one

the battery groups are dimensioned so that the specified nominal voltage can be selected,

The charging voltage of a battery group is less than the same - the lower the costs, capacity and volume.

rated voltage or consumer voltage is present. 4 ° men of the battery.

Due to the independent charging of the two batteries so the total voltage at rest element 9 can, for example, between the position equal to or greater than the nominal voltage, connection points 10 and 11 attached contactd. That is, the flat part of the voltage characteristic of the sets of a line relay or a contactor tripped Battery will be in the range of the chosen nominal 45 or to cover mechanical components entirely voltage shifted and thus allows better to do without, thanks to an electronic switch. Utilization of their capacity. Because of the high switching speed of such

These relationships are shown in FIG. 2 shown. electronic components can be an almost

The curve 1 represents the course of the voltage to achieve uninterrupted switchover. Example

in a previously common system. 50, a pnp transistor can be used,

In the example, the nominal voltage at the consumer should be its emitter at point 10 and its collector at

Un = 24 volts. As permissible upper voltage point 11 lies, the base is via a resistor

limit are selected the deviations + 10 ° / ₀ and a blocking diode is applied to the input voltage,

or -15% (according to VDE 0108). This corresponds to the fact that if the input voltage fails, the emitter becomes conductive to an upper voltage value of U ₁ = 26.4 volts 55 collector path of the transistor

and a lower voltage value of U ₂ - 20.4VoIt. connects the battery groups in series. As a tax

The continuous charge voltage of the battery to be used voltage of the transistor can be the mains voltage

so must not exceed 26.4 volts, i. H. at one or the output voltage of the rectifier

Continuous charging voltage of the single cell of 1.4 to 1.5VoIt can be used.

18 cells are required. These 18 cells are at 60 when the battery is under peak loads

Load case with nominal current a medium span should, the component 9, z. B. a transistor, over

voltage position of 1.2 volts per cell. Between 20 and one more connected in the consumer circuit

80 ° / ₀ capacity drain, the 18 cells are controlled with transistor stages, so that, for example, in the event of sudden

a total voltage of 22.4 to 21.2 volts already lent increases in current through. In this case well below the nominal voltage of 24 volts. In the 65, the mains rectifier can be used for low power

In the course of the discharge, the battery voltage falls until it is placed, because of short-term high loads from the

to the lower voltage limit of 20.4 volts. Be caught by the battery,

this point is to end the discharge, although the advantages of the inventive automatic

Power supply systems are the favorable voltage level at the consumer over the entire discharge range and the favorable capacity utilization of the battery due to the one described above free choice of number of cells. The mean deviation between nominal voltage and battery voltage is much less than with known buffer circuits. Furthermore, there is no oversizing of the Battery necessary and complex additional charging devices are not required. Because of the even charge and discharge of the battery groups, the same service life of all cells is achieved.

Claims (3)

Patent claims: 1. Automatic power supply system for direct current consumers with a direct voltage source, which supplies the consumer with nominal voltage during normal operation and at the same time a battery that is used for buffering and emergency supply and is divided into two groups charges, whereby the battery groups are each parallel to the DC voltage source and each battery group a variable series resistor is assigned to each, and with a switching device that the two battery groups in the event of failure of the DC voltage source or major voltage drops connected in series, with the series voltage of both battery groups also about corresponds to the nominal voltage, characterized in that the negative pole of the Battery group (1) via a diode (6) to the negative pole of the DC voltage source (3) and the positive pole via an adjustable resistor (4) with the positive pole of the DC voltage source (3), the positive pole of the battery group (2) via a diode (7) with the positive pole of the DC voltage source (3) and the negative pole of the battery group (2) via an adjustable Resistor (5) is connected to the negative pole of the voltage source (3) and that the positive Pole of the battery group (1) with the negative pole of the battery group (2) via an electronic Switching device (9) that connects the battery groups in the event of a power failure or overload is. 2. Automatic power supply system according to claim 1, characterized in that the electronic switching device (9) is controlled by the input voltage. 3. Automatic power supply system according to claim 1, characterized in that the electronic switching device (9) via one in the consumer circuit caused by the load controlled further switching device is controlled. 1 sheet of drawings