FR2779881A1 - Battery charger for radio telephone - Google Patents

Abstract

The charger has a circuit that feeds current pulses to the inductance coil, of the charger, which acts as a transformer primary winding when the radio telephone is connected to it. The battery charger (1) has an inductance (10) which receives a set current from a primary voltage source (30) when the radio telephone (21) is connected to the battery charger. Its coil (20) is magnetically coupled with the charger's inductance (10) so that a transfer of electrical energy takes place which is used to charge the battery (25) of the radio telephone (21). The charger (1) includes a transistor (13) and resistors (R14,R15,R16) for control of the electrical supply to the coil (10), which stabilizes the power supplied to the coil (10) as a function of the source voltage (30). The components form an adder circuit which adds the inductance (10) current to a current which represents the source voltage (30), which is then used to control a charge pulse switch (13) which feeds the inductance (10).

Description

The present invention relates to recharging.

  of the battery of a portable communication or data processing terminal when its carrier is moving. If we consider for example a radiotelephony handset, its carrier has a charger to recharge it periodically, but the nominal mains voltage varies from country to country, so that it is sometimes

  0 unable to charge the handset.

  There may be an adjustment switch at the charger input but

  this complicates it and an adjustment error is not excluded.

  The present invention aims to provide a universal battery charger, that is to say operating, without manual adjustment, over a wide range of

input voltages.

  To this end, the invention relates to a battery charger comprising buffer means for storing electrical energy arranged to receive, from a primary source of determined voltage, a supply current of determined electrical power and then to restore to a battery a current corresponding to the stored energy, characterized in that it comprises means for controlling the storage means, arranged to stabilize, as a function of the voltage of the primary source, the

  power supply applied to the storage means.

  Thus, the power supply of the storage means being stabilized,

  they therefore restore a stabilized current to the battery. In the example above

  above, the buffer energy storage means thus constitute a stable secondary source replacing, vis-à-vis the battery, the variable sector. It will be noted that the invention applies to any fixed battery

or mobile.

  In a preferred embodiment, the storage means comprise a primary inductance of a charging transformer

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  battery and the control means comprise a circuit for adding the current of the inductance and a current representing the voltage of the source, and for controlling, according to the result, a

  inductance impulse load switch.

  Thus, the current representing the input voltage is combined with the current of the inductor to control the switch, in order to limit the inductance current to a value depending on the voltage of the source, the latter thus effecting a kind of feedback tending to cancel

  io the influence of variations in its value on the battery current delivered.

  The invention will be better understood using the following description of a

  preferred embodiment of the charger of the invention and of a portable radiotelephony handset, with reference to the appended drawing, in which FIG. 1 schematically represents the charger and the handset and - FIGS. 2A, 2B, 2C and 2D represent, as a function of time t,

  charger signal waveforms.

  The charger 1 shown comprises, at the head, a full-wave rectifier bridge 2 with low-pass filter (not shown), which can be supplied either with 110 or 220 volts AC from the sector 30. At the output of the rectifier 2, the voltage is substantially continuous V2, substantially proportional to the mains input voltage Ve, supplies a current I7 for basic control of a regulating transistor 16, of NPN type, the emitter of which is grounded. In this example, the low-pass filter (series inductance) is of limited volume and the low regulation current I7, which is derived therefrom, is filtered by an active low-power filter. The active filter comprises a divider bridge comprising two resistors R4 and R5, the latter going to ground, with a

  capacitor 3 across the resistor R4 at the output of rectifier 2.

  The voltage across the latter is thus free of residual ripple and represents a fraction of the output voltage V2 of the rectifier-filter 2, that is to say also of the mains voltage Ve. The emitter of a filtering transistor 7, of PNP type, is connected to the output of rectifier 2 through a

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  resistance R6, while its base is connected to the midpoint of the bridge

divider R4, R5.

  We thus have: I7. R6 + Vbe7 = A. V2, with A = R4 / (R4 + R5), division ratio

  Throughout this description, the voltages or currents relating to an element

  determined carry the reference thereof.

  The division ratio "A" is chosen large enough so that Vbe7 = emitter-base voltage of transistor 7, fixed and around 0.6 volts, is negligible compared to I7. R6, hence:

I7 = A. V2

R6

  The output of rectifier 2 also feeds a transformer primary 10 having a capacitor 11 in parallel, to form a circuit.

  oscillating L C, operating at supraphonic frequency.

  The radiotelephone handset, referenced 21, includes the secondary 20 of the above transformer, associated with a capacitor 22 in parallel to form an oscillating circuit. A 23 series diode detects

  peak and charge a filter capacitor 24 supplying a battery 25.

  A low-pass filter for regulating the battery current can be provided.

  Returning to the charger 1, it comprises in this example an annex primary winding 12 for supplying the regulating transistor 16. More precisely, the winding 12 connects the midpoint of a divider bridge R17, R18 supplied with the voltage V2, stabilized with respect to ground by a capacitor 19, to the collector of the transistor 16 and to the gate of a MOS transistor switch 13. The transistor 13 connects to the ground, through a resistor R14 connected to the ground, the free end of the primary, opposite to that supplied by the rectifier 2. A resistor R15 connects the base of the transistor 16 (and the collector from transistor 7) to point

  common between MOS 13 and resistance R14.

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  The operation of the above diagram will now be explained.

  The charger 1 comprises a receptacle for the handset 21, arranged so that the secondary 20 is magnetically coupled to the primary 10. The charger 1 operates in an oscillating mode under the control of the MOS transistor 13, which cyclically blocks the current I10 of the primary 10 during a fixed duration then lets it pass for a variable duration,

  varying in opposite direction to the input voltage Ve, or V2.

  The voltage V10 of the primary 10 can be written V10 = L dI10O dt with L: inductance of the primary 10, and d 10: time slope of the current dt

  Now dI10O varies like the mains voltage Ve, or V2.

  dt The energy stored in the primary 10 at each cycle is worth L.IM2 and the power thus passing to the battery 25 is worth

L.IM2. F

  F being the repetition frequency of the oscillation cycles, with recharging,

  of primary 10, and IM being the maximum current of primary 10.

  In order to keep this power substantially constant, and therefore to recharge the battery 25 at almost constant current, it is necessary to control the maximum current IM and / or the frequency F. Here, it is the maximum current IM which is adjusted by controlling the conduction time of the MOS transistor 13. At the level of the regulation transistor 16, one can write Vbel6 = R15. I7 + R14. (I10 + I7)

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  I10 being a power circuit current, much higher than I7, the latter being only used to produce a control voltage and a basic current, we can therefore simplify the formula in Vbel6 = R15 I7 + R14. I10

= R15. A. V2 + R14. I10

  O R6: I10 = Vbel6 = K. V2 (or K1. Ve)

R14

with K = A. R15

R6. R14

  The above equations are valid as long as the variable voltage Vbe16

  did not exceed the switching threshold of the transistor, ie approximately 0.6V.

  When the increasing instantaneous current I10 translates the base voltage to reach 0.6V, it then has its maximum value IM. Part of the current i7 is then derived in the base of the transistor 16, which becomes conducting and causes the ground of the gate of the MOS transistor 13 to be returned to the ground which is thus blocked. We then go into LC 10,11 oscillatory mode. The current IM which can no longer flow to ground produces an overvoltage and

flows into the capacitor 11.

  The voltage Vbel6, conduction of the transistor 16, thus forms a triggering threshold which is compared to the sum of the voltages V14 and V15 produced respectively by the main current I10 and by the regulating current 17 in the resistors R14 and R15. Thus, if the input voltage Ve increases, the continuous polarization V15 increases in the same way and goes up as much the instantaneous voltage Vbel6. The current IM producing the voltage V14 of

  triggering then has only a reduced value.

  Thus, the input voltage Ve or V2 more or less boosts (V15) the feedback command, delayed by the threshold Vbel6, due to the current

  I10 and thus controls IM as a function of the input voltage Ve, or V2.

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  FIG. 2C shows that the charging phase of the inductor 10, by drawing the source current by grounding the free end of the inductor, is followed by an oscillation phase which produces a discharge of energy in the secondary 20, FIG. 2A representing the waveform of the current in the secondary 20. The assembly is equivalent to a buffer capacitor connected to an oscillating relay blade putting it alternately in

  connection with the primary source 30 and with the downstream load (20).

  After a period of free oscillation, relaxation, the auxiliary winding 12 again supplies a sufficiently positive voltage (fig. 2D) for unblocking the gate of the MOS transistor 13, which, by setting

  conduction of it, blocks the oscillation (fig. 2C).

  The primary 10 begins to charge again (rising ramp of the current of FIG. 2B), until a new blocking, as explained above,

  when the current threshold IM is reached.

  Thus, if the input voltage Ve increases, the conduction time decreases and the frequency of the above cycles therefore increases, but more slightly

  since the duration of the oscillation remains constant.

  In this example, in order to facilitate the explanation, we have considered linear resistive elements. If, however, it is desired to be even more free from variations in the input voltage Ve, provision may be made for non-linear elements of current / voltage transduction, as for example

example of diodes.

  Thus, by choosing a relatively low division A ratio, the diode voltage Vbe7 will no longer be negligible and then I7 = A.V2 - Vbe7 R6

  will have a negative constant and will therefore vary proportional-

  slower than V2, or Ve. One or more diodes, possibly

  zener, in series with resistance R6, or R5, would have the same result.

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  Conversely, one or more diodes in series with the resistor R4 would tend to stabilize the base voltage of the transistor 7 with respect to V2,

  therefore to reduce the sensitivity of the current I7 compared to V2.

  Similarly, at the level of the addition of the voltages across the resistors R14 and R15, a diode in series or in parallel on one of these resistors would make it possible to modify the current / voltage response to adjust even better, depending on the voltage V2, l relative influence between the two currents I7 and I10. It is thus possible to adjust the maximum current IM so that it varies so that the electrical power passing through, with storage, in the primary 10 is substantially independent of the input voltage Ve, or V2. It is also possible, in this way, to compensate for the effects of possible thermal drifts (for example the diode voltage threshold Vbe16), since the thermal drift of the current / voltage characteristic of a

diode is known.

  It is understood that the composition or comparison of the three quantities I7, I10 and Vbel6, representing respectively the input voltage Ve, or V2, the current supplied by the source 30 and a triggering threshold limiting this current in an adjusted manner, can be carried out by circuits other than those of the example above. In particular, an operational amplifier can perform the addition of the two control quantities (I7, I10) to apply the result to a threshold comparator, equivalent to a subtractor whose change of sign at output would cause the

  desired trigger. It is therefore generally an adder-

three input subtractor.

  It will be noted that, since the power supply of the primary 10 varies with the maximum current IM and the repetition frequency F, it could, as a variant, regulate this power by modifying the frequency F, by varying it in the opposite direction of the variation of the mains voltage Ve. Such a control could consist in modifying the natural frequency of oscillation LC, for example by a dynamic adjustment of the capacitor 11, by adjusting it or by putting the capacitors into service in a set of various values, this under the control

of a microprocessor.

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Claims (9)

  1.- Battery charger comprising buffer means (10) for storing electrical energy arranged to receive, from a primary source (30) of determined voltage, a supply current of determined electrical power and then to restore to a battery (25) a current corresponding to the stored energy, characterized in that it comprises means (13, R14, R15, R16) for controlling the storage means (10), arranged to stabilize, according to the voltage of the primary source (30), the power supply applied to the means of storage (10).   2. Charger according to claim 1, in which the storage means comprise an inductance (10) of the primary of a battery recharging transformer and the control means comprise an adder circuit (R14, R15, R16) for adding the inductance current (10) and a current representing the source voltage (30) and for controlling, based on the result, a load switch (13)   impulse of the inductance (10).   3. Charger according to claim 2, in which the adder circuit comprises a dipole (R14, R15) for controlling an amplifier (16) for controlling the charge switch (13), a dipole connected at one end, to a current supply circuit (7) representing the input voltage and   connected to the inductor (10) by a midpoint of the dipole (R14, R15).   4. Charger according to claim 3, in which the amplifier (16) for controlling the charge switch (13) is supplied from a   auxiliary winding (12) of the transformer.   5. Charger according to claim 4, in which the auxiliary winding (12) is connected to a divider bridge (R17, R18), for supplying a voltage.   reference, arranged to be supplied by the source (30). 9 2779881   6. Charger according to one of claims 3 to 5, in which the circuit   for supplying the current representing the source voltage comprises a active filter (3, R4, R5, R6, 7).   7. Charger according to claim 6, in which the active filter (3, R4, R5, R6, 7) is an adjustable current generator controlled by the voltage. from the source (30).   8.- Charger according to one of claims 3 to 7, wherein the dipole of   control (R14, R15) includes a non-linear current / voltage transducer.   9. Charger according to one of claims 2 to 8, in which it is provided   means for receiving a portable terminal (21), arranged to magnetically couple the primary inductor (10) to an inductor   secondary (20) battery recharge (25) of the terminal.