DE2051527B2 - Circuit arrangement for rapid charging of an electric battery - Google Patents

Description

The invention relates to a shuttering arrangement according to the preamble of claim 1.

Such a circuit arrangement is known from BE-PS 7 10 108, in which the duration of the charging intervals is used as a measured variable for the automatic termination of the charging process. ί ^γ > However, in order to reliably prevent the development of gas that occurs during overcharging, it is desirable to make the completion of the charging process dependent on a measured variable which is as precise a measure as possible for the state of charge. ^r <"

The object of the invention is therefore to provide a circuit arrangement of the type mentioned at the outset in which the charging process is terminated reliably and safely when the battery is charged before the battery is overcharged. '> ^r >

According to the invention, this object is achieved by the characterizing features of claim 1.

The advantages of the invention are in particular that as a measured variable for the completion of the charging process that value of the battery terminal voltage «> is used, which after a predetermined time interval Completion of the charging process is detected under load, since this value of the battery terminal voltage of the The state of charge of the battery closely depends.

Advantageous further developments of the invention are ·> ■> characterized by the features of the subclaims.

In the following, embodiments of

Invention explained in more detail with reference to the drawing

Fig. 1 is a schematic, partly in block form Drawn diagram of an arrangement for the automatic termination of the rapid charging process as a function of the terminal voltage of the battery during discharge;

F i g. 2 is a graph showing the terminal voltage shows a battery being discharged at different states of charge;

3 and 4 are schematic, partly in block form Drawn diagrams of modified circuit arrangements according to that of FIGS. 1;

F i g. Figure 5 is a schematic diagram of a particular application of the automatic termination circuit according to FIG. 4th

In Fig. 1 is a circuit arrangement for rapid charging an electric battery that automatically terminates the quick charge process when the Terminal voltage of the battery 1 during a certain period of time after the start of the discharge current flow of a discharge interval assumes a predetermined value

The curves in FIG. 2 represent the terminal voltage of the battery 1 as a function of time after the discharge current path has been applied and thus during the discharge of the battery in the course of the charging process. The discharge pulse begins at time Ti. The terminal voltage drops from its value at time Ti at a rate which depends on the state of charge of the battery 1 As the charge in the battery 1 increases, the rate of decrease decreases. Therefore, the terminal voltage of the battery 1 at the time point Ti after the discharge increases with the size of the charge.

Like F i g. 1 shows, the battery 1 is connected to a control circuit 3 via a contact 7, while a normally open contact A ₂ and a relay winding IVe are also connected to the control circuit 3 in series and via a contact 8. A charging current source 2 is connected to the battery 1 via the control circuit 3 and an interrupter 20. The charging current source 2 can supply direct current or alternating current, the latter being rectified by the control circuit 3. The contact A ₂ is controlled by a relay in the control circuit 3. A Zener diode 30 and a current limiting resistor 31 are connected in series parallel to the battery 1 via a normally open contact B. A winding 21, a controllable semiconductor switch 23 and a current limiting resistor 24 are also connected to the battery 1 through the contact 7.

The relay Wb is a delay relay. Therefore, the closing of the contact B after the closing of the contact A ₂ is delayed by the time period T ₂ - Ti. When the battery is being charged, the silicon rectifier 23 is non-conductive. Each time the contact A ₂ closes during a discharge interval, the contact closes a short period of time later, at time T ₂ in FIG. 2, in order to apply the terminal voltage of the battery 1 to the Zener diode 30 and the resistor 31 in series with it. When the battery 1 is fully charged or reaches the selected state of charge, its terminal voltage applied to the Zener diode 30 and the resistor 31 when the contact B is closed exceeds

voltage of the Zener voltage of the Zener diode 30, so that current flows through the resistor 31. When this happens, a positive voltage is applied to the control electrode of the controllable semiconductor switch 23 and ignites it. The current then flowing from the battery through the winding 21 is sufficient to open the contact of the interrupter 20 and to terminate the rapid charging process. Furthermore, the contact A ₂ opens with the interrupter 20 and prevents unnecessary discharge of the charged battery 1. ■■■■

F i g. 3 shows a modification of the circuit arrangement according to FIG. 1, in which the delay relay We is replaced by a monostable multivibrator 32. The resistors 33 and 34 and the contact A ₂ are above the battery 1. The trigger input ι. output of the multivibrator is coupled to the connection of the resistors 33 and 34, while the output of the multivibrator 32 is at the junction of the Zener diode 30 with the resistor 3t. The connection of the winding 21 and the Zener diode 30 is. · <. · with the Junction of the contact A ₂ and the resistor 33 connected. When the contact Ai closes at the beginning of each discharge interval, current flows from the battery 1 through the resistors 33 and 34, as a result of which the multivibrator 32 is triggered in its semi-stable state for the period T ₂ - 71.

If the multivibrator is in this semi-stable state, there is a negative potential at its output. For this reason, the controllable semiconductor switch 23 is not able to ignite regardless of the terminal voltage of the battery 1. After that period of time, the multivibrator 32 returns to its stable state, in which there is a positive potential at its output terminal. If at this point in time, ie at point in time T ₂ in FIG. 2, the r> terminal voltage of the battery 1 is sufficiently high, the controllable semiconductor switch 23 ignites and the contact of the interrupter 20 opens, so that the rapid charging process is ended.

FIG. 4 shows a further modification of the circuit arrangement according to FIG. 1, in which a delay circuit 39 has taken the place of the delay relay IVs. The delay circuit 39 lies across a load resistor 40, which is switched into the circuit across the battery 1 as a discharge current path, -r> when the relay contact A ₂ closes, which is connected to the load resistor 40 across the battery 1 in series. The delay circuit 39 also closes a resistor

41, which is in series with the parallel arrangement of a capacitor 42 and a resistor 43. Of the The voltage sensor circuit of the Zener diode 30 and the resistor 31 is connected to the capacitor 42.

If at the beginning of each discharge interval the contact A ₂ closes, current flows from the battery 1 through the resistor 41 and starts the capacitor

42 to load.

At the end of each discharge pulse and when contact A _{2 is opened,} the capacitor 42 discharges via the resistor 43 in parallel with the series connection of the resistors 41 and 40. If the charge of the battery t> o increases and the terminal voltage rises during the discharge processes, the capacitor 42 becomes charged to this higher voltage.

The voltage across capacitor 42 is across zener diode 30 and resistor 31. When the b5 Capacitor voltage exceeds the Zener voltage of the Zener diode 30, current flows through the resistor 31 and the control electrode of the controllable semiconductor switch 23, so that this ignites accordingly flows Current from the battery 1 through the winding 21 and opens the contact of the breaker 20, so that the Fast charging ends. The delay circuit can also be omitted if the Response time of the voltage sensor circuit or the associated elements, such as the Zener diode 30, is sufficiently long

In some cases it is desirable to apply an equalization charge at the end of the rapid charge process. In Fig. FIG. 5 shows a circuit for this which has a transformer 62 instead of the charging current source 2 with a primary winding 63 and a first secondary winding 64, a second secondary winding 66 and a third secondary winding 65 and its input terminals 60,61 via a switch 67 to the Usual alternating voltage (50 Hz) can be applied. The control circuit 3 is replaced by the circuit elements 70 to 80.

The series connection of the anode-cathode circuit of a second controllable semiconductor switch 70 and the battery 1 to be charged is connected to the secondary winding 64. The series connection of a resistor 72, a resistor 73 and a diode 74 is connected to the secondary winding 65. The diode 74 is polarized so that it conducts the same half-cycles of the alternating current as the semiconductor switch 70 (this is polarized so that it conducts current from the direction in which the battery 1 is charged). A diode 75 and a resistor 76 are connected in series between the anode and the control terminal of the semiconductor switch 70 The diode 75 is polarized so that it conducts during the same half cycles of the alternating current as the semiconductor switch 70. Between the control terminal and the cathode of the semiconductor switch 70 a resistor 77 is connected. A zener diode 78 connects the junction of the resistors 72 and 73 with the junction of the resistors 76 and 77. The zener diode 78 is polarized so that its breakdown voltage is exceeded as soon as the terminal voltage of the battery 1 rises above a certain value. The secondary winding 66, a second The current limiting resistor 50 and the anode-cathode circuit of a third controllable semiconductor switch 80 are connected in series across the terminals of the battery 1 and take the place of the relay contact A ₂ and the load resistor 40 of FIG. 4 a. The semiconductor switch 80 is polarized in such a way that it conducts the current supplied by the battery 1. The resistor 72 is located between the control terminal and the cathode of the semiconductor switch 80.

The circuit of delay circuit 39 and voltage sensor 30, 31, known from FIG. 4, is parallel to the second current limiting resistor 50 Series connection of the second secondary winding 66 and the second current limiting resistor 50, the control electrode of the semiconductor switch 23 receiving control voltage from the voltage sensor 30, 31.

When the switch 67 is closed, one ignites a short time after the start of the positive half-cycle, the second semiconductor switch 70 and sets the Charge current path to battery 1 as long as the secondary voltage is above the battery voltage. The one during the positive half-periods of the

The current i \ generated by the secondary winding 65 and flowing through the resistor 72 causes a voltage drop at the resistor 72 which, together with the terminal voltage of the battery 1, represents the bias voltage at the Zener diode 78.The breakdown voltage of the Zener diode 78 is only exceeded when the terminal voltage of the battery 1 reaches the selected value at which the discharge current path is to be applied for discharge. If the secondary voltage at the winding 65 then falls below the voltage generated by the battery 1 by means of the current component k at the resistor 72 during the positive half-cycles, the control terminal of the third semiconductor switch 80 is in because of the anode-cathode bias voltage supplied by the battery 1 The conductive state is triggered, and the battery 1 then begins to discharge through the secondary winding 66, the current limiting resistor 50 and the third semiconductor switch 80. The secondary winding 65 is used to generate a voltage across the resistor 72 that controls the point of breakdown of the Zener diode 78 after the terminal voltage of the battery 1 has reached the selected value; it also serves to control the application of the endi-charging current path after the breakdown Zener diode 78.

A normally open relay contact C ₂ lies between the control electrode and the cathode of the second controllable semiconductor switch 70. As soon as this contact closes, the controllable semiconductor switch 70 is prevented from igniting a low-resistance current path for passage

ι of charging current available. However, a small charging current flows through the current path of the diode 75 and the resistor 76 with a high resistance value, so that the battery 1 is supplied with an equalizing charge after the fast charging process has ended. The relay contact Ci is closed as follows: When the controllable semiconductor switch 80 is ignited, the terminal voltage of the battery 1 is applied to the voltage sensor in order to

! i mensvoltage, which corresponds to a selected state of charge of the battery 1, to actuate the controllable semiconductor switch 23. Its ignition allows sufficient current to flow through the relay winding Wc to energize it, so that the contact C ₂ closes. That opens

2D at the same time the contact G and switches the secondary winding 66 out of the circuit, so that the controllable semiconductor switches 23 and 80 remain positively biased by the battery 1. In this way, the winding Wc remains energized and holds the

? ". Relay contact Ci closed for supplying further equalizing charge.

For this purpose 3 sheets of drawings

Claims (4)

Patent claims: 1.Circuit arrangement for rapid charging of an electric battery by means of a charging current supplied in charging intervals with a control circuit that switches a load to the battery during the charging breaks (discharge intervals) and with a charging switch arranged between the battery and a charging voltage source, which is controlled by a voltage sensor Achieving a predetermined battery terminal voltage detected under load is opened to terminate the charging process, according to patent 1638085, characterized by a delay circuit (W _B ; 32; 39), which the application of the voltage ^{sensor (30) to:} the terminal voltage the battery (1) delayed compared to the beginning of a discharge interval. 2. A circuit arrangement according to claim 1, characterized in that part of the delay circuit, a delay relay (Ws), whose excitation is connected in development at the onset of discharging interval by the control circuit (3) to the battery (1). 3. Circuit arrangement according to claim 1, characterized in that the delay circuit ü a monostable multivibrator (32) belongs to the control circuit at the beginning of a discharge interval (3) is controlled and emits an output signal after a predetermined period of time has elapsed M) 4. Circuit arrangement according to claim 1, characterized in that the delay circuit of the control circuit (3) at the beginning of a discharge interval contains switched /? C-elements (39) with a predetermined time constant. * '>