DE3411234C1 - Device for transmitting information via supply lines - Google Patents

Abstract

The invention relates to a device for transmitting information via supply lines in the case of battery-operated vehicles which are connected to a supply point (docked), in order to charge the batteries. The measurements for the terminal voltage of the batteries are coupled in on the vehicle side on the incoming and outgoing lead for the charging current, via coupling elements, are coupled out on the side of the stationary charging apparatus and are supplied to the charging apparatus as control signals for the battery charging current. The information can be converted into radio-frequency signals by means of a voltage/frequency converter and can be coupled in or out on the supply lead, via coupling capacitors. Decoupling elements can be provided between the battery and the coupling-in point on the vehicle side and between the charging apparatus and the stationary coupling-out point. The device according to the invention allows the charging current of the batteries to be regulated in an optimum manner. The sliding contacts on a supply point for the transmission of the terminal voltage can be dispensed with.

Description

The invention relates to a device for transmitting information via supply lines according to the preamble of claim 1. A similar device is already from the publication of the company micro-electric GmbH, Osterdeich 92, 2800 Bremen 1, known.

When charging accumulators, the prescribed charging currents or charging voltages must be of interest a long service life of the batteries are strictly adhered to. Are batteries in charging stations stationary charged, charging voltages and charging currents on the battery can be monitored without any problems. Should batteries, however, be connected to different Zapfoder in mobile vehicles (industrial trucks) Docking points are loaded or buffered, this prepares the precise recording of the terminal voltages the batteries trouble. However, it is particularly important that the terminal voltage is accurate when charging of the batteries and thus the charging current is controlled. Too low end-of-charge voltage does not lead to Correctly formed plates, excessively high end-of-charge voltage leads to increased gases and increased thermal Stress on the batteries.

The exact detection of the terminal voltage is difficult because of the relatively high charging currents the voltage drops on the charging cables, at the terminal points of the cables and at the transitions between busbars and sliding contacts in vehicles that only dock for charging on the Measurement received (AEG-Telefunken publication "Chargers for Electric Vehicle Batteries", July 1982). Aggravating is that the clamping and sliding contacts do not remain constant and that at different taps the voltage drops do not remain constant even due to different cable lengths and thus cannot be corrected by setting the charger. A remedy could be created if sensor lines are laid parallel to the charging flow path up to the battery terminals, which only the Feed the terminal voltage of the battery back to the high-resistance control input of the charger. This is also common for stationary power supplies and chargers for higher currents. However, this technique would also be one Separate cable routing up to the terminals of batteries and thus also for tapping points for vehicles require further sliding contacts with sliders. It was therefore looked for ways, which then in addition to bypass the necessary conductor lines or existing systems without sensor lines for the improved To make technology retrofittable.

Furthermore, the Hoppecke company has patented a process ("Hoppecke Batteries" publication, Shape. 5816 / 03.84 / 3.), According to which the temperature of the gases that are generated when charging batteries via the gassing voltage Form addition, measured in a catalytic converter and thereby the charging current is controlled. This method however, it requires sensor lines and is - because of the sliding contacts mentioned above - at multiple tapping points - more difficult to implement for industrial trucks.

The object of the invention is, in battery-operated vehicles that attach to a supply point (dock), the measured values without interference and with little effort between charging devices and batteries transfer.

According to the invention, this object is achieved by the measures specified in claim 1. Refinements of the invention are described in the subclaims.

The invention is illustrated by way of example with reference to the drawing F i g. 1 explained.

In the immediate vicinity of the battery 1, the terminal voltage of which is to be monitored, a voltage-frequency converter 3 (f / UW andler) is connected (in this case on the vehicle 2). Voltage-frequency converters are available as modules or as integrated circuits. This module delivers a signal whose frequency / the applied voltage U is proportional. This signal with the frequency f is coupled with the help of the capacitors 4 and 5 inside the vehicle 2 to the charging lines with the sliding contacts 6 and 7. It is transmitted from there to the charging station 10 via the permanently installed charging lines 8 and 9. This charging station 10 contains a frequency-voltage converter 11, which converts the frequency originally supplied by the voltage-frequency converter 3 back into a voltage proportional to it.

This is used for control via inputs 12 and 13 the actual battery charger 14 effective. The battery charging current is taken from terminals 15 and 16 and can also supply other conductor lines 24 and 17.

To improve the signal transmission, the outputs 15 and 16 of the charger 14 and the input körinen the battery 1 via chokes 18, 19, 20 and 21 against higher-frequency signals that the converter 3 is delivering, be blocked. These chokes 18,19,2Ö and 21 sol- ίο len have a small DC resistance. In the simplest case, they are implemented in that only ferrite toroidal cores be pushed over the line sections to be throttled. The line section that runs from the Ring core is surrounded, has a higher inductance.

Furthermore, at the input of the frequency-to-voltage converter 11 ensure that this does not short-circuit the outputs 15 and 16 of the charger 14. This happens here with Koppelkondertsätören 22 and 23.

It is still possible to use the components 18, 19, 20, 21,5,4,22 and 23 by other components, for example to replace suitable transformers and chokes. They only serve to follow the Gleichsiromweg des Charging circuit from the alternating current path of the signal circuit zjjjrejinen. Others can use this method as well Battery parameters such as electrolyte temperature, gas pressure and degree of gassing to the charger either be reported back in time division multiplex or frequency division multiplexing.

For recording the parameter terminal voltage, degree of gassing, electrolyte temperature, temperature of the Gases, suitable sensors can be used on the batteries to be charged. Are the sensor signals in to frequency-controlled AC voltages proportional to these parameters are implemented, so these can be applied to the Charging lines coupled and evaluated on the charger will. Since the information to be transmitted is in the frequency of the sensor signals and the If the frequency is not influenced by the transmission path, a very reliable feedback is obtained the charging parameters of batteries.

1 sheet of drawings

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Claims (5)

Patent claims: 1. Device for the transmission of information via supply lines, with at one point the supply lines receive the information to be transmitted as a high-frequency signal via a coupling element each can be coupled into the outgoing and return lines and at another point on the supply lines a coupling element can be decoupled via "r, characterized in that it is at Battery charging units of battery-operated vehicles that are moored (docked) at a supply point is used. 2. Device according to claim 1, characterized in that the terminal voltage of the on one Vehicle (2) mounted batteries (1) measured by means of a voltage-frequency converter (3) in High-frequency signals is converted so that capacitors (4, 5) are provided for coupling the high-frequency signals on the vehicle-side supply lines (6, 7) that capacitors (22, 23) are provided for coupling out the high-frequency signals on the stationary side of the supply lines (8, 9) that a frequency-voltage converter (ti) is provided for converting the high-frequency signals back into the terminal voltage the battery connected to the terminals (12, 13) of the charger (14) as a control signal for the battery charging current is fed. 3. Device according to claim 1 and 2, characterized in that in the supply lines (6, 7, 8, 9) between battery and vehicle coupling point and between charger and stationary Decoupling point decoupling elements (18, 19, 20, 21) are provided for the high-frequency signals. 4. Device according to claim 1 and 3, characterized in that the signals to be transmitted consist of a high-frequency carrier frequency to which the information to be transmitted is analog or are digitally modulated. 5. Device according to claim 1 to 4, characterized in that the information via a supply line (6, 8) and mass are transferred.