DE3917795A1 - CHARGER FOR RECHARGING A SECONDARY CELL WITH A LI-CUCL (DOWN ARROW) 2 (DOWN ARROW) CONNECTION - Google Patents

Abstract

A recharger for a non-aqueous secondary cell having an Li-CuCl2 couple. A constant voltage limited-constant current power supply (12), a voltage sense circuit (17) and a microprocessor (16) are employed to control the recharging sequence. Noting that a cell based upon an Li-CuCl2 couple exhibits a substantially constant open circuit voltage, the cell is not charged if the open circuit voltage is less than the lower set point voltage set for a particular cell.

Description

The invention relates to a charger for recharging a non-aqueous secondary cell with a Li-CuCl ₂ linkage, which emits an essentially constant open circuit voltage.

These secondary cells contain an alkali metal, such as lithium, as an anode and a cathode collector, which by means of a Separation membrane is separated from the anode. Among all of them known combinations of lithium anodes with different The cells have certain cathodes and electrolytes inorganic liquids as an active cathode depolarizer the greatest energy density and the smallest Internal shine resistance. This type of cell chemistry is commonly known as a "liquid cathode". Because the here explained cells use this chemistry, it will be short explained.

Use liquid cathode cells according to US-PS 39 26 669 Oxide halides. As stated therein, there is the anode generally made of lithium metal or alloys with lithium and the electrolytic solution is an ion-conducting, substance dissolved in a solvent that simultaneously also forms the active cathode depolarizer. The fabric can be a single or double salt, the one ion-conductive solution forms when in the solvent is solved. Preferred solvents are complexes of  inorganic or organic Lewis acids and inorganic, ionizable salts. The requirements for usability are that the salt, simple or complex, compatible with the solvent in the way is that it forms an ion-conducting solution.

A typical Lewis acid suitable for use in cells of the type in question here is aluminum chloride, which forms with a suitable ionizable salt, such as lithium chloride, lithium aluminum chloride (LiAlCl ₄ ), in a suitable solution such as sulfur dioxide (SO ₂ ).

In addition to an anode, an active cathode depolarizer and an ion-conducting electrolyte require cells this type a current or cathode collector. As the GB-PS 14 09 307 shows any compatible solid can be used as a cathode collector when in essentially electrically conductive and inert in the cell is because the function of the collector is one external electrical contact with the active cathode material to manufacture. In GB-PS 14 09 307 it is taught that it is desirable to have the largest possible surface contact between the liquid cathode and the current collector to have. Many publications have focused on use of porous material, such as graphite, as a current collector concentrated.

It has been recognized that, for a non-aqueous secondary cell, the cathode collector should preferably be inert under certain severe environmental conditions. This includes a striking lack of response to the electrolytes in the solvent, such as lithium aluminum tetrachloride (LiAlCl ₄ ) in the sulfur dioxide (SO ₂ ) solvent.

This unresponsiveness should go over a range of tension from 2.5 V to 4 V, including one There may be no reaction to overload products should.

It is general knowledge of non-aqueous electrochemical Secondary cells that the electrolyte solution copper (II) chloride contains. This is the result of the following reaction:

CuCl ₂ + AlCl ₄ → CuCl ₂ + AlCl ₃ + e⁻.

Suitable cathode collectors must therefore also against Copper (II) chloride and its reduced substances are inert be and represent a low resistance.

In view of the fact that cells of the type discussed allow high current draw and high output, the cells can be said to be unsafe when exposed to abusive conditions. For example, it has been recognized that such non-aqueous cells with a Li-CuCl ₂ linkage have a shorter lifespan than comparable aqueous systems with cadmium or lead negative electrodes. A major cause of the death of such lithium cells is the formation of dendrites that grow on the lithium electrode and make electronic contact with the complementary positive electrodes. This can lead to catastrophic heating of the cell and the resulting gasification of cell components.

It is therefore an object of the invention to provide a charger for Recharge a non-aqueous electrochemical To create a cell based on lithium, the unsafe Determine cell conditions and recharge can interrupt if such contingencies occur.  

This object is achieved according to the invention in that it is a power source for controllably feeding one constant current limited to a constant voltage to the cell that a voltage measuring device connectable to the cell for measuring the open circuit voltage and that a microprocessor is the recharge sequence controls the cell, with the power source being controlled is that the cell is loaded alternately and from the Power source is disconnected to the open circuit voltage to measure the cell and the cell is not loaded, if this open circuit voltage is less than a lower one, voltage setpoint selected for a particular cell.

Advantageous developments of the invention can Subclaims and the description of a Embodiment are taken.

The invention is explained in more detail with reference to the drawings. It shows

Fig. 1 is a block diagram of the various components that make up the battery charger according to the invention,

Fig. 2 is a logic diagram of the charging process of the battery charger, as controlled by the microprocessor of Fig. 1,

Fig. 3 shows the EMF (electromotive force = primary voltage) of a typical cell during the charging process and

Fig. 4 shows the current flow when a typical electrochemical cell is connected to the charger according to the invention.

The present invention relates to a charger for recharging a non-aqueous secondary cell with a Li-CuCl ₂ linkage that has a substantially constant open circuit voltage. The charger has a power source with a constant current limited to a constant voltage, a voltage measuring device and a microprocessor which controls the recharging sequence. The microprocessor is programmed so that the cell will not be charged if the open circuit voltage is less than a lower, predetermined voltage setpoint selected for a particular cell.

The present invention is based on the finding that the overall reaction of the cell with a Li-CuCl ₂ linkage is independent of the state of charge of the cell. This is the result of the fact that the cell is operating with a fixed chemical activity and as a result any abnormal drop in open circuit voltage will indicate a malfunction of the cell. By monitoring the open circuit voltage during the charging process, the charging process can be stopped at the first sign of a malfunction of the cell.

The charger consists of a power source 12 with a constant current limited to a constant voltage, which is connected via the rectifier 17 to a low-voltage AC input and to the controller 13 .

The recharge sequence is controlled by the microprocessor 16 , which is connected to the positive cell connection 14 and the voltage measuring device 17 via the power source 12 .

The charger works by first checking the open circuit voltage and if this open circuit voltage is less than a lower voltage setpoint, then no charging process takes place. The state of the microprocessor 16 can be determined by the LED driver 19 , the output signal of which is made visible by the LED indicators 20 .

If the open circuit voltage is greater than the lower, predetermined Voltage setpoint, then the cell becomes a predetermined one Time period loaded. After loading, the cell becomes one subject to predetermined ventilation time during which the Open-circuit voltage is measured again. Is the Open circuit voltage less than the specified lower one Voltage setpoint, then the charging process is ended again, if not, then the charging process is again for one given period of time added to the compulsory a predetermined venting time and a measurement of the Follow the open circuit voltage. This sequence is repeated as long as until a predetermined total charging time is reached or until the open circuit voltage below the lower voltage setpoint has dropped.

The flowchart which indicates the logic for controlling the charger is shown in FIG. 2 and is self-explanatory. The microprocessor 16 can be programmed to perform the logic steps of FIG. 2. Programming is well known. The charger is usually set to maximum current and voltage ratings, typically 40 mA and 3.9 V. The charger tries to deliver the maximum current that matches the charger set point. If, for example, a discharged cell is connected to the charger, then it wants to deliver a current of 40 mA if the open circuit voltage is less than 3.9 V. This means that the charger is current-limited and delivers the maximum permissible current of 40 mA. This is the constant current part of the charge cycle and this operating state is maintained until the cell is almost recharged. Then the cell voltage rises quickly and the charger can no longer supply 40 mA, because this would require a higher voltage than the maximum permissible voltage of 3.9 V. The charger is now voltage-limited and only emits a voltage of 3.9 V. Since the charger cannot deliver 40 mA at 3.9 V, it delivers a smaller current. As the cell voltage increases, the current gradually decreases as long as the charger continues to deliver the maximum allowable voltage. The graded charging process is a consequence of the use of the voltage-limiting power source. No switch is required to switch the charger from constant current to constant voltage.

In a preferred embodiment, this works Charger according to the invention with a current limit of 40 mA, a voltage limitation of 3.9 V and a lower voltage set point of approximately 3.15 V. All of these Setpoints can be set on the charger and on the be adapted to a wide variety of conditions. The Venting time is also adjustable and is typically about 5 minutes, while charging time between the venting times are typically about 15 minutes and the total charging time can be set between 15 and 24 hours is.

The charging current, the lower and the upper voltage setpoint, the charging time, the venting time and the total charging time are parameters that are set manually. The Microprocessor "reads" this information as input signals  and causes the charger to go within this given Parameters to work.

FIGS. 3 and 4 show the EMK and the charge current flow for charging an AA cell with a lithium secondary CuCl ₂ link. It should be noted that when considering FIG. 3, the EMF is basically stable and drops to the open circuit voltage of the cell during the venting times. This is followed by a rapid rise in EMF on the voltage of the charger.

Fig. 4 is a graphical representation of the charge current curve of an AA type secondary cell. As was to be expected, the current is generally stable during the charging process and drops to zero in the ventilation lines. As a result, a rapid increase in current occurs when the charge is resumed. The sloping curve near the end of the charging process shows that the charger is transitioning to the graded charging process while still monitoring the open circuit voltage of the cell.

As is also to be mentioned, all components which are contained in the block diagram according to FIG. 1 are commercially available. The commercial designations are - if applicable - entered in each block of FIG. 1.

Claims (7)

1. Charger for recharging a non-aqueous secondary cell with a Li-CuCl ₂ linkage which emits an essentially constant open circuit voltage, characterized in that
that it has a power source for controllably supplying a constant current limited to a constant voltage to the cell,
that a voltage measuring device for measuring the open circuit voltage can be connected to the cell, and
that a microprocessor controls the recharge sequence of the cell, controlling the power source so that the cell is alternately charged and disconnected from the power source to measure the open circuit voltage of the cell and the cell is not charged if this open circuit voltage is less than one lower voltage setpoint selected for a particular cell. 2. Charger according to claim 1, characterized, that the power source predetermined maximum allowable Has current and voltage values.   3. Charger according to claim 2, characterized, that the specified, maximum permissible current is approximately Is 40 mA. 4. charger according to claim 2, characterized, that the predetermined maximum allowable voltage is approximately Is 3.9 V. 5. Charger according to claim 1, characterized in
that the cell is charged in the recharge sequence for a predetermined period of time if the open circuit voltage is equal to or greater than the predetermined lower voltage setpoint,
that the charge is then interrupted for a predetermined venting time and
that after the venting time the open circuit voltage of the cell is measured again. 6. Charger according to claim 5, characterized in
charging is interrupted when the open circuit voltage in the cell recharge sequence is less than the predetermined lower voltage set point, and
that the charging process is continued for a predetermined period of time if the open circuit voltage is greater than the predetermined, lower voltage setpoint. 7. Charger for recharging a non-aqueous secondary cell with a Li-CuCl ₂ linkage that delivers a substantially constant open circuit voltage, the

• a power source for delivering a constant current limited to a constant voltage for charging the cell,
• - A voltage measuring device connectable to the cell for measuring the open circuit voltage of the same and
• has a microprocessor which is connected to the power source and the voltage measuring device in order to control the recharge sequence of the cell, the recharge sequence comprising the following steps:
  • (a) Measuring the open circuit voltage of the cell by means of the voltage measuring device and if the open circuit voltage is less than the lower predetermined voltage setpoint, but prevents the cell from being charged
  • (b) if the open circuit voltage of the cell is equal to or greater than the lower, predetermined voltage setpoint, the cell is charged for a predetermined period of time, the charging process is interrupted for a predetermined venting time, and then the open circuit voltage of the cell is measured and
  • (i) if the measured open circuit voltage is less than the lower, predetermined voltage setpoint, the charging process is stopped, but (ii) if the measured open circuit voltage is greater than the lower, predetermined voltage setpoint, step ( b ) is repeated until a predetermined total charging time has expired is.