DE1158155B - Control device for two-stage charging of an accumulator battery - Google Patents

Description

Control device for two-stage charging of an accumulator battery The invention relates to a control device for the two-stage charging of a Accumulator battery using a transformer with separate primary and secondary winding between the feeding network and the accumulator battery, wherein a variable influenced by the charging current for the secondary winding of this transformer prevailing main flow influenced in the sense of a control of the battery charge.

It is known control devices for charging accumulator batteries using contact regulators or control transformers. The effort for such facilities is perceived as annoying when between dining Mains and the accumulator battery already have a transformer for the voltage translation is required and there is little space for the installation of a control device is. These conditions apply in particular to electric traction vehicles of the Local transport too. In such vehicles are now often fluorescent tubes for the indoor lighting used, the voltage being used to operate these fluorescent tubes Is taken from transistor converters. In the usual way, the transistor converter contains a transformer whose transformation ratio corresponds to the operating voltage of the fluorescent tubes is adapted.

There is also an arrangement for reducing the influence of mains voltage fluctuations on the voltage supplied by a rectifier has been specified necessary for charging a battery, especially a rarely used reserve battery, and the has a tilting characteristic. For this purpose, the rectifier is connected to the series-connected Secondary windings of two transformers connected, one of which is rectified Current is biased. Except for the winding fed by the rectified current a second winding is also provided, which is energized by an approximately constant current and counteracts the former winding.

In addition, a facility has already been published in which the voltage equalization takes place on the transformer itself. The transformer is with three legs executed; the primary and part of the secondary winding are located on one leg, the rest of the secondary winding on a second and the DC winding on a third leg. As the DC winding and the part of the secondary winding affected by it on different legs are located, the spread between the two is large, so that there is no proportionality between the direct current and the secondary voltage.

Another method uses a voltage equalizing transformer with three-legged iron core in connection with a rectifier, its internal voltage drop compensated for with an almost constant AC mains voltage with one primary and two counter-connected secondary windings, one of which is a secondary winding with the primary winding on the same transformer leg is wound, while the third leg is not wound. The primary winding is with the main secondary winding on a transformer leg, the auxiliary secondary winding together with a direct current winding through which the consumer current or part of it flows wound on the second transformer leg, and the third unwound Transformer leg without an air gap is connected to the other two legs.

Finally, a battery charger is known, which by two rectifier transformers connected secondary in parallel and primarily in series Makes use. Each of these transformers is designed with three legs, one of which carries the primary winding, a second with twice the cross-section the secondary winding and on a third an auxiliary winding through which direct current flows is housed. The saturation of this leg, which can be adjusted with a potentiometer determines the level of the secondary voltage.

The present invention is intended to provide a particularly simple device of small footprint are indicated on the use more mechanical Switching elements dispensed with. This is achieved by the fact that it is influenced by the charging current Size creates an additional flow that is perpendicular to the direction of the main flow stands and thereby displaces the latter.

A particularly advantageous development of this invention is therein to see that the additional flux increases the magnetic conductance, for example, the mean Legs of a three-legged core influenced, with primary and secondary winding are each attached to a special outer leg, or the additional flow influences the magnetic resistance of a single-window core, for example. In a likewise advantageous manner, the additional flow can be placed so that the axis of the winding generating the additional flux, the winding axis of the primary and secondary windings crosses.

A controller designed according to the invention does not have any movable ones Contacts, it is therefore maintenance-free and works continuously and without delay. One at the. Regulator connected battery is generally according to a two-point characteristic are charged, with a short-circuit current occurring in the battery circuit through the Effect of the non-linear elements in the excitation circuit of the additional flow on one for the power transistors of the converter is limited to the maximum permissible value.

Exemplary embodiments of the invention are described with reference to the drawing.

In Fig. 1, 1 designates a three-legged core on which Outer legs the primary winding 2 and the secondary winding 3 are applied. The middle leg is unwound. From the output winding 3 is a Rectifier arrangement 4, the accumulator battery 5 fed.

Between the output winding 3 and the rectifier arrangement 4 lies a bridge circuit 6 consisting of linear resistors 61 and 62 and non-linear ones Resistors 63 and 64, at the bridge diagonal a voltage to generate a Additional flow is tapped.

This additional flow excites a single-phase with the help of the winding 7 U-shaped core 8, the open legs of which through the middle leg of the core 1 getting closed. The pincer-shaped encircling the middle leg of the three-legged one Core 1 through the U-shaped core 8 requires a mutually right-angled arrangement of the two cores and a crossing arrangement of the winding 7 opposite the Windings 2 and 3.

If the winding 7 is excited from the bridge 6, 8 is created in the core a river which passes through the middle limb of the core 1 transversely to its extension, so that a main flux generated by the winding 2 when an additional flux occurs is displaced in the core 8 in the middle leg of the core 1. But this means an increase in the magnetic resistance for the central leg of the core 1 penetrating proportion of the main flow and thus an increase in the winding 2 penetrating portion of the main flow, so that the voltage for the charge of the Accumulator battery 5 is increased.

For a better understanding of the bridge circuit 6, it is shown again in FIG. 2 with its linear and non-linear resistance elements and the winding 7 connected to the bridge diagonal and its mode of operation is described below. The magnitude of the currents in the individual bridge branches can be seen in the diagram belonging to FIG. The course of the currents in the bridge branches with the linear or the non-linear elements are shown in this diagram by the straight lines a and b.

According to this representation, the non-linear branches (current branches b) have with small values of the charging current 1 a very high resistance value, so that only the current branches a with linear resistance elements 61 and 62 flowed through by this current will. However, if the current I rises above that marked by the point P on the abscissa Value, so do the bridge branches with the non-linear resistance elements 63 and 64 (current branches b) have a portion of the current I.

The winding 7 connected to the bridge diagonal receives after Fig. 2 shows the voltage e, which is the difference between the currents in the linear and the non-linear Bridge branches is proportionate. The voltage e is as shown in the diagram too see, in a range sufficient for the control Z the reciprocal of the Current I proportionally.

By the action of the bridge 6, as stated above, within the area Z of the middle limb of the core 1 is flooded by an additional flow, which is proportional to the reciprocal of the charging current I. This means that in the case of small values of the charging current 1 at the winding 7, a comparatively high one Voltage e is applied, which generates a strong additional flow. As a result of the suppressing Effect of this additional flow, practically no main flow can penetrate the middle limb, and the main flux must flow through the secondary winding 3 in its full strength. When the charging current increases, the voltage e drops, which also reduces the additional flow so that a part of the main flow flows over the middle leg of the core 1 closes. By this magnetic shunt, the winding 3 is only from part of the main river flooded. This means that the voltage on the Secondary winding 3 compared to the voltage on primary winding 2 is reduced.

If you now choose the resistances of the bridge 6 so that the area Z both contains the maximum value as well as the minimum value of the charging current, then by means of an arrangement According to FIG. 1, the charging current is constant with good accuracy over the entire charging range held.

Between the bridge 6 and the winding 7 there is generally still an impedance can be inserted, which is shown here as capacitor 9. By this impedance 9 is achieved that the flux in the leg 8 is in phase with the Flow in leg 1 pulsates.

In Fig. 3 is a further embodiment of the inventive concept shown, but according to Fig. 3, the conductance of the magnetic circuit is not but the resistance of this circle influences.

A single-phase core 11 here carries the primary winding 12 and one Secondary winding 19, from which via a rectifier arrangement 4 a storage battery 5 is fed.

The yoke of the single-phase core 11 is of an open U-shaped Core 8 enclosed. If this core 8 is excited, the core 11 is formed in the yoke an additional flow which displaces the main flow passing through the windings 12 and 13. To achieve the additional flow in the core 8, this core has a winding 18, depending on the battery Voltage is excited and with it the charging current is limited towards the end of charging. By inserting a non-linear resistor, for example a blocking cell in series with the winding 18, its effect can be can still be increased considerably.

To limit the charging current, there is a rectifier arrangement between 4 and the accumulator battery 5, a bridge 20 is used. The bridge 20 exists from branches 13 and 14, each with a linear characteristic, here as magnetic Windings are made and made up of branches with non-linear characteristics, which for example contain blocking cells 15 and 16, and supplies a voltage for the Excitation of a winding 17, which is tapped on the diagonal of this bridge.

In Fig. 4 is the bridge circuit consisting of the non-linear Branches 15 and 16, the linear branches 14 and 13 and the one in the bridge diagonal used winding 17 shown. By choosing the number of turns accordingly the exciting windings and the threshold voltage in the non-linear branches the charging characteristics of the connected battery adapt. For reinforcement the effect of this bridge circuit is the excitation of the windings 13 and 14 of the Excitation of the winding 17 in the opposite direction.

In the diagram attached to FIG. 4, the magnitude of the fluxes in the windings 13, 14 and 17 as a function of the charging current 1 is now shown using the designations from FIG. In the case of low currents, the voltage drop of which does not yet exceed the threshold voltage for the blocking cells 15 and 16, the current in branch a is equal to the current in branch e. After the threshold voltage for the blocking cells 15 and 16 is exceeded, ie with a current 1> h, the blocking cells become permeable. The consequence of this is that the voltage in branch e is first reduced to zero and then reversed as the current 1 rises further. Depending on the design of the blocking cells 15 and 16 and depending on the dimensioning of the ohmic resistance of the windings 13 and 14, the current in the branches a will also change as the charging current increases. In the present case, for the sake of simplicity, it is assumed that the bridge branches are balanced in such a way that with a current 1> II the current a remains constant in its level.

If a river becomes a further river in relation to branch a, which is proportional to e, added, a resultant flux 0 arises River 0 has a pronounced kink at point II. If you also lay the bridge so that point h corresponds to the largest permissible charging current, so is with this arrangement, taking into account the influence of the winding 11, the effect of an extremely simply constructed two-point controller.

Claims (10)

PATENT CLAIMS: 1. Control device for the two-stage charging of a Accumulator battery from an alternating current network using a transformer with separate primary and secondary winding between the feeding network and the Accumulator battery, a variable influenced by the charging current denoting the secondary winding this transformer penetrating the main flow in the sense of a control of the battery charge influenced, characterized in that the size influenced by the charging current a Generates additional flow that is perpendicular to the direction of the main flow and thereby the latter displaced. 2. Control device according to claim 1, characterized in that that the additional flux, for example, the magnetic conductance of the middle leg of a three-legged core, with primary and secondary winding respectively are applied to a special outer leg. 3. Control device according to claim 1, characterized in that the additional flux has the magnetic resistance of a influenced for example single-window core. 4. Control device according to claim 2 or 3, characterized in that the axis of the winding generating the additional flux the winding axis of the primary and secondary winding crosses. 5. Control device according to claim 4, characterized in that the additional flow through a single-window Core is guided, the yoke is formed by that leg. the to influencing main river leads. 6. Control device according to one of claims 1 to 5, characterized in that the additional flow by a direct voltage or generates an alternating voltage pulsating at the same frequency as the main flux will. 7. Control device according to claim 6, characterized in that the for the Excitation of the additional flow required voltage on the diagonal one in itself known bridge, consisting of linear and non-linear resistors, tapped that is fed by the charging current. B. Control device according to claim 6, characterized characterized in that complex in series with the additional flux exciting winding Resistances are placed. 9. Control device according to claim 7, characterized in that that the bridge between the battery to be charged and the one required for this Rectifier is looped in. 10. Control device according to claim 9, characterized in that the non-linear resistors are designed as blocking cells inserted in the forward direction and the linear resistors are designed as controlling magnetic windings, which are assigned a further magnetic winding which, fed by the diagonal voltage of the bridge, generates a flux that is opposite to the flow of the first windings. Considered publications: German Patent Specifications No. 715 406, 722 816; French patent specification No. 1 174 637.