DE2247158A1 - METHOD AND DEVICE FOR DETERMINING THE CHARGE OF ACCUMULATORS - Google Patents

Description

Method and device for determining the charge of accumulators Accumulators The invention relates to, and particularly relates to, wet accumulators a method and a device for determining the charge of such accumulators; it also relates to accumulators with auxiliary electrodes for use therewith Procedure.

To use the full potential electrical capacity To convey an accumulator, it is necessary that the accumulator is present is fully loaded during the respective usage cycle. The accumulator receives when charging more charge than required, its service life is reduced.

Therefore, in order to achieve maximum capacity and maximum service life, Means are required to determine the exact point at which the battery is fully charged is loaded. Automatic interest devices that determine this point and the charge quit, - give the normal end product of end-of-charge systems.

Theoretically, the two plate groups are an accumulator cell always in the same state of charge; in practice, however, it is often found that they are not always on the same charge #egel are located. Local Effects cause the negative lead acid or sisenalkali plates to charge lose. Similarly, high temperatures can result in positive effects Nickel-alkali plates lose charge.

The two plate groups may also take during the Iacle process Do not charge with the same effectiveness. To ensure that there is an accumulator is fully charged, it would therefore be two-way to charge both the positive as well as the negative plate group.

The most common form of cargo control - and with it, is a facility meant for the automatic termination of the charging of an accumulator - works with the voltage of the accumulator when charging. The charging voltage increases with the charge of the accumulator and reaches its maximum value when fully charged. Unfortunately, the charging voltage of a cell does not only depend on the state of charge of the Cell but also on the charging speed, the temperature and the age of the From the accumulator. Because of these variables, this is working with the charging voltage Procedure not strictly accurate. To ensure that the accumulator is complete is charged, a little more charge is usually added than the voltage rise indicates. However, as mentioned above, this can reduce the total service life of the accumulator shorten.

Other methods of load control have also been used. Occasionally, ampere-hour meters have been used to measure the Measure the charge removed from the accumulator and the charge returned. Measurements of the degree of acidity in lead acid cells are also occasionally used to indicate the full charge state used. In addition, there are other means of control in accumulator technology known.

Auxiliary electrodes are in cells, especially in closed ones Cells, have been used to determine complete salvage status. Included it is common to have a single electrode as a gas recombination electrode to use and switch off the charge when the partial pressure of the gas has a certain limit reached.

The charging control devices mentioned above fail because they either do not measure a function that is directly related to the state of charge of both electrode groups related, or because the measured variable in addition to the state of charge of other Factors depends.

According to the present invention, the rate of gas evolution from the positive as well as from the negative plate group of a hiS; umulator cell Equated with the charging current during charging # Is the gas evolution of each Plate group stoichiometrically equal to the charging current, so the cell is complete loaded. According to the invention, it is also a matter of an accumulator cell that is equipped with a device is equipped to perform the above steps.

According to the invention, the on the positive plate of an accumulator exiting oxygen and the exiting hydrogen at the negative plate at Charge the accumulator measured and compared with each other. Are the two Gases in the stoichiometric ratio and the current equivalent to the gases is the same the charging current of the battery, the charging is ended.

The invention is described below with the aid of a preferred exemplary embodiment explained in detail in conjunction with the drawing; show in the drawing 1 shows a cross section through a typical line made with electrodes according to the invention is equipped, as well as Fig. 2 a typical charge control circuit for use in the cell do Fig. 1.

In Fig. 1 with io is a typical vessel of a nickel-iron accumulator cell designated. Located inside the vessel io yourself a positive Rod 14 and a negative rod 16. On the positive rod 14 are means of a positive Connecting rod 20 and spacers 22 are typical tubular positive plates 18 attached. Those from the rod, the plates, etc.

existing arrangement is called a positive group. In a similar way Way are negative plates SX by means of a negative connecting rod 26 and Spacer washers 22 attached to the negative rod 16. This arrangement is called called negative group. Pin insulators 28 prevent mutual contact between the positive and negative plates. A section 30 one of the positives Plate 18 is provided with an electrolyte-permeable, gas-impermeable gas deflector 32 wrapped. This device can be made from the available porous sheet materials be produced, such as those used for battery separators. The device directs the emerging from the section 39 of the positive plate 18 Oxygen to an oxygen electrode. 34.

There are many known oxygen electrodes. An electrode is preferred those made of a pressed porous plate made of carbon powder and polytetrafluoroethylene consists. A number of such platelets can be arranged in a graphite disc which forms the electrode shown at 34. As a lead for the electrode 34 is a carbon rod 36.

A portion 4o of one of the negative plates 24 is with one of the positive gas deflector 32 similar electrolyte-permeable, gas-impermeable Gas deflector 42 enveloped. It is important that the area ratio of the plate sections 30 and 4o, which are enclosed by the respective "gas deflector" devices 32 and 42, respectively are approximately equal to the ratio of the total active areas to the positive and negative plates is. On the exit side of the negative gas deflector 42, a hydrogen electrode 44 is arranged. This electrode can be one of the many well-known; #hydrogen electrodes. One is preferred Electrode that with the addition of a small amount of active platinum is constructed in the same way as the above-mentioned oxygen electrode the electrode 44 serves a sole rod 46.

In Fig. 2, an electrical circuit is shown that with the two Auxiliary electrodes works. According to FIG. 2, the accumulator cell 50 has a positive one Terminal 52, a negative terminal 54, a connection 56 for the positive gas electrode and a connection 58 for the negative gas electrode to 0 # A battery charger is shown at 60. Also provided is a two-winding relay 62, the one Charging current winding 64 and an electrode winding 66 comprises. The turns ratio of the two # windings 64 and 66 is equal to the ratio of that of the gas deflector enclosed plate area to total; area of the plate. For the sake of simplicity the ratio of the part surrounded by the gas deflector 32 becomes the positive Group to the entire positive group is denoted by n O In the same way, the Ratio of the part surrounded by the negative gas deflector 42 to the negative Group to the entire negative group with n is also selected. Furthermore, the turns ratio is also selected the current winding 64 to the electrode winding 66 is equal to n. The windings 64 and 66 are connected to each other in opposite directions. The relay 62 has three contacts provided, of which the contacts 68 and 7o close the charging leads and the Contact 72 closes the electrode circuit.

To initiate a charging cycle, the relay 62 is for example energized by depressing a button 74. This closes the charging circuit, and the relay is kept energized by the charging current winding 64.

When the accumulator reaches its full state of charge, it begins Oxygen to develop on the positive plate.

The oxygen touches the oxygen electrode and absorbs electrons, so that hydroxyl ions are formed in the electrolyte according to the well-known chemical equation: Meanwhile, hydrogen begins to be released on the negative plate. The hydrogen reacts at the hydrogen electrode and releases electrons according to the chemical equation: If the volume of the hydrogen produced is exactly twice as large as the volume of oxygen and if no further electrical energy is absorbed by the section of the plates enclosed by the gas deflector, then the magnetization of the winding 66 is just as great as that of the winding 64; relay 62 then drops out and ends the charge cycle. When the relay drops out, the ratio of the current in the electrode winding to the current in the charging current winding is equal to the vert of n.

The relay 62 no longer picks up because the supply lines to both windings 64 and 66 are interrupted, so that it is de-energized until key 74 is pressed again remain.

In the above description is a relatively simple one Two winding relays have been described as a comparison device; instead of this can also make more sophisticated circuits with modern electronic circuit elements can be used with advantage for the current comparison and charge control devices.

Other embodiments of the invention in which the charge of a Accumulator is terminated when stoichiometric amounts of oxygen and hydrogen are also included in the present invention.

Claims (7)

P a t e n t a n s p r ü c h e 1. Procedure for determining the point of complete charge an accumulator cell comprising a positive group and a negative group with the help of two arranged in the cell and electrically connected to one another Gas electrodes when charging, by not showing that a the positive group evolving first gas is supplied to a first gas electrode that converts the first gas into an electric current that one is at the negative group developing second gas fed to a second gas electrode that converts the second gas into an electric current that between the two Gas electrodes a current path is established that the one between the two gas electrodes flowing current is compared with the charging current and that the point of full Charge of the cell is determined according to that between the two gas electrodes flowing current is equal to the charging current. 2. The method according to claim 1, characterized in that g e k e n n z e i c hn e t, that the first gas evolving on the positive group is oxygen and that is itself the second gas evolving at the negative group is hydrogen. 3. The method according to claim 1 or 2, characterized g e k e n nz e i c h n e t that the first gas is from an n-th part the positive group and the second gas is derived from an n-th part of the second group and that the point of # full state of charge is determined after that the between the current flowing through the two gas electrodes is equal to the nth part of the charging current. 4, accumulator cell with positive plates, negative plates, in between arranged separating elements and a wash around the positive and negative plates and electrolytes passing through the separating elements, g e k e n n nz e i c h; n e t through a positive gas deflection device (32) which is attached to at least one part (5o) at least one positive plate C18) deflects first Gd's, a negative one Gas deflection device (42), which is at least one part (4o) at least a negative plate (24) evolving second gas deflects, one into the electrolyte immersed first gas electrode (34) which only with the electrolyte and the first gas comes into contact and on contact with the first gas one of the contacting gas quantities generates proportional positive current, a second immersed in the electrolyte Gas electrode (44) which only comes into contact with the electrolyte and the second gas and on contact with the second gas, an amount proportional to the contacting gas quantity negative electric current is generated, as well as one between the two gas electrodes electrically switched on current measuring device (66). 5. Accumulator cell according to claim 4, characterized g e k e n nz e i c h n e t that the first gas is oxygen and the second gas is hydrogen. 6. Accumulator cell according to claim 4 or 5, characterized in that g e k e n n z E i c h n e t that the current measuring device (66) performs a control function when the current flowing through it exceeds a selected value. 7. Accumulator cell according to one of claims 4 to 6, characterized g e k e n n z e i c h n e t9 that the current measuring device (66) with a device (62, 64) to compare the current between the two gas electrodes (34o 44) with cooperates with the accumulator charging current 0 L e r s e i t e