DE4231970A1 - Storage battery charging circuit - has transformer and rectifier with protective switch as relay or power semiconductor between charging circuit output and at least one of the charging pole connections - Google Patents

Abstract

The charger is for car batteries, individual batteries, nickel-cadmium batteries, and the like, which are connectable to the same charger, if necessary via different adapter inserts. Between the output of the charging circuit (17) around at least one of the charging pole connections (AKKU 1) is connected a protection switch (16) in the form of a relay or a semiconductor. The charger is controlled by an electronic pole protection logic circuit i.e. microprocessor (12) which by circumventing the protective switch with at least one recognition connection (A,B) connects directly with the battery being charged, determining any false poling. With correct measurement data, the micro-processor then connects the battery to the charger circuit (17). USE/ADVANTAGE - To protect a battery charger or parts of it against a battery which is backwardly poled.

Description

State of the art

The invention relates to a battery charger the preamble of claim 1.

Battery chargers are in multiple forms and with under different functions known; are most common currently such devices in use, which under consideration adjustment of the respective battery condition, in particular also the temperature of the battery to be charged, determine the charging current, making significant improvements specifically with regard to the so-called quick charging properties can be achieved by battery chargers can.

It is also common for car battery chargers to  to work with special loading curves, depending on the Consideration of the battery's state of charge take, so that initially high current is used, which increases until the gassing limit is reached reduced and back to a maintenance current value goes.

The basic equipment of such battery chargers te, which is usually the available network span step down and rectifier circuits in for charging batteries or Batteries convert suitable direct current is so always designed so that depending on the requirements, So especially the amount of at least initially available provided charging current the capacity of the charging circuit is designed with appropriate performance of the upstream transformer and any smoothing members.

In this context, it is already known (DE-OS 40 36 374), a main charger a variety of Assign adapters, for example in the main charging slot of the charger can be used and are adapted to a wide variety of batteries, so that you can use a common charger a lot number of different batteries and battery types, too with different voltages.

However, there remains a problem with such chargers and is also particularly serious, if out Awkwardness or for any other reason charging battery wrong, so reverse polarity in the charging slot  is used or the charging connections for example for a car battery, maybe also because the corresponding signs on the polarity are hardly legible anymore, connected the wrong way round becomes.

Since most batteries do not reach full er state of creation can be discharged, which is itself because of the limited life of the Prohibiting batteries, there is often a risk that through a wrongly polarized or wrong in a drawer shaft inserted and therefore with the wrong poles battery in contact due to its reverse polarity the entire charging circuit, but at least the ver used rectifier systems ruined, whereupon the Then the device becomes unusable.

One way of such destruction is equal Preventing richter diodes is that in Series with the charging circuit switches fuses that when the currents are excessive, i.e. flowing backwards speak - a total security can be hereby however, do not reach because of the delicate semi-lead ter-rectifier diodes only by very fast fuse that may not be protected are always used.

Based on this problem, there is therefore the underlying invention the task for a Bat electronic charger to reverse polarity create who under all circumstances ensures that a reverse polarity battery the charger or  Cannot damage parts of it.

Advantages of the invention

The invention solves this problem with the features of Claim 1 and has the advantage that no matter how any accumulator or battery in the Charging slot is used or with the charging port Poland is connected, the electrical connection of the Charging circuit to the battery is only realized if from a monitoring circuit, the following is referred to as reverse polarity protection logic circuit, sure is that the accumulator or the battery properly connected.

In the other case, a polarity reversal message is issued acoustically or optically, in one embodiment of the inven If necessary, the reverse polarity protection logic circuit reversal of the pole connections made can be, depending on the design of the device and the closed battery or accumulators.

This means that after connecting the to be charged Battery and switching on the device electrical connection to device parts is established, however, the series connection between the actual Charging circuit with transformer and rectifier diodes is interrupted, namely at least one protection switch so that the battery does not even charge circuit can react.  

Checking for correct polarity of the used The battery then takes a very short time from the Ver polarity protection logic circuit, which in preferred Ausge design is a microprocessor and that when recognized the electrical charge connector ver ties realized.

Embodiments of the invention are the subject of the sub claims and laid down in these.

drawing

The invention is based on the schematic block circuit diagram of the drawing below in more detail explained.

Description of the embodiments

The basic idea of the present invention is the charging line between a charging circuit and one connected accumulator or a battery body open, even when the device is switched on and connected. Keep the battery open for so long until a check of the battery shows that this is connected with the correct polarity. Only then will the battery turned on for charging, the one here Micropro provided as reverse polarity protection logic circuit processor also performs other tasks at the same time takes, for example, temperature monitoring to load the battery, checking the battery used  for example, by finding the pre adapter and setting a suitable drawer programs for this, for example by capturing of a signal encoded, for example, by a resistor at another input of the microprocessor.

Through one of the measuring inputs of the reverse polarity protection Microprocessor associated with the detection circuit Protection circuit ensures that the microprocessor itself is not be can be damaged by the action of the micro processor itself a destruction of both the Ladege advice as well as mechanical damage to the attached closed batteries is excluded because high short final currents and therefore no longer a risk of explosion possible are.

In the drawing, which is only one possible embodiment of the invention, a charging slot of a charger with 10 and a lead battery or individual battery inserted therein or otherwise connected are designated by 11 . The charging slot can be exchangeable and vary depending on the type of battery to be charged, so that in the drawing connections 1 , 2 , 3 , 4 are shown as contacts in the charging slot area, with corresponding counter contacts 1 ', 2 ', 3 ', 4 'correspond in the charging device and durchkontaktie ren with this when a corresponding charging slot 10 is inserted into the respective charger to be able to load a certain battery.

The charging slot contact connection 1 corresponds to the charging input connection for the rechargeable battery (z. B. positive pole) and is therefore referred to as ACCU; Via a resistor R1 is connected to the charging input terminal 1, a further contact terminal 2 of the charging slot, which serves to monitor the temperature of the battery or the rechargeable battery during the charging process and is therefore referred to as NTC; Via the third charging input connection 3 , the microprocessor 12 recognizes, via a resistor R2 built into the charging shaft, the adapter provided for charging a very specific individual battery or lead-acid battery and sets the appropriate program, so that there is a basically coded recognition value which is shown in the drawing is referred to as KOD; the fourth charging input terminal 4 finally establishes the ground connection and corresponds to the negative pole connection (MASS).

The inputs A, B and C of the microprocessor, which are identification inputs for polarity reversal protection, are assigned a protective circuit 13 which, with respect to identification input A, consists of two diodes connected in the reverse direction in series between positive voltage + U and ground, the detection input A is connected to the center connection of the two diodes; a resistor R3 is also provided, via which the detection input A is connected to the charging input terminal 1 .

The two further detection inputs B and C are connected via resistors R4 and R5 at the connection point of two further diodes D3 and D4, which are also switched in the reverse direction and are connected equally between positive voltage + U and ground, the connecting point E of the two resistors R4 and R5 to the NTC input port 2 in the charging slot or 2 'at the device output.

The detection input D of the microprocessor 12 is at the loading slot code connection 3 ; Finally, the microprocessor in the schematically simplified block circuit shown still has two outputs, namely an output terminal F, which serves the reverse polarity message, and an alarm via an optical signal (lamp 14 ) and / or an acoustic signal, for example via a loudspeaker or driven piezo quartz 15 is used.

The second output X of the microprocessor 12 is the actual control output and works on a relay 16 , which is arranged in series with the charging circuit 17 indicated only in the form of a diode and the charging input port 1 . This relay 16 is designed, at least in the concept presented in the drawing and now discussed, that it is permanently off if it is not controlled by the microprocessor, which then connects the charging circuit 17 and the charging input port 1 on the charging shaft will be produced.

The basic function of the circuit is such that at the detection input D the microprocessor 12 first recognizes the adapter R2 intended for charging individual batteries or lead-acid batteries via the resistor R2 built into the charging slot 10 and sets the corresponding program.

Is then a battery in the adapter or in the charging slot is inserted or are charging leads 18 , 18 ', which are equipped, for example, with output terminals, connected to a larger lead-acid battery, then the microprocessor first tries to determine via its detection input A, at what voltage the assumed that the battery mulator is connected with the correct polarity. There is no sensible signal to be evaluated at input A, because if the battery is connected to the battery charging input connection 1 incorrectly polarized, the processor will not be able to recognize the negative voltage it is supplied with, because it cannot measure a negative voltage In ent speaking training or programming of the Mikropro processor 12 proceeded so that the microprocessor 12 produces a positive voltage at its terminal C and supplies it to the connection point E, which leads to a voltage division across the resistors R5 and R1. It goes without saying that the resistor R1 can of course also be arranged in the area of the protective circuit 13 or inside the microprocessor; in any case, under these circumstances (comparatively high positive voltage at the connection C of the microprocessor 12 ) at the circuit point E there is a positive voltage which the microprocessor can measure at its detection input B via the resistor R4 and interpret accordingly. If the voltage at the switching point E is too low compared to a threshold value - of course matched to the voltage point at the output connection c and the negative voltage values that result from incorrect battery polarity at the charging input connection 1 , a corresponding polarity reversal message is sent via the output connection S and the relay 16 is not activated, so that in this exemplary embodiment shown at first, no switch is made to charging.

A variant of the present invention can then consist in that, depending on which accumulators are to be charged, which can easily be detected by the microprocessor 12 via its code connections, the polarity of the charging lines can also be reversed by the microprocessor, if necessary. by in example the relay 16 , which can also be a suitably designed power semiconductor, is designed as a double switch. Such a double changeover relay then takes a defined zero position in the uncontrolled state, i.e. it switches the charging current neither to the charging input connection 1 or, which would then make sense in the case of incorrect polarity, to the ground connection 4 .

Depending on the result of the polarity reversal measurement, this can then Relays are controlled so that it is used Battery either properly with the charging port lines connecting or in crossover connection, so turned over so that if the battery is inserted with the wrong polarity the polarity is correct again. This possibility However, for various reasons, for example general ground connection also for other devices ten, less preferred.  

Finally, it is pointed out that the claims che and in particular the main claim wording try the invention without extensive knowledge of State of the art and therefore without restrictive pre are judiz. Therefore, it is reserved for everyone in the Description, the claims and the drawing Darge presented features both individually and individually in any combination with each other as a fiction essential to look at and down in the claims as well as the main claim in its feature set stop reducing.

Claims (6)

1. Battery charger, especially for any battery mulators, lead acid batteries for cars, individual batteries, nickel-cadmium batteries and. Like., Which can be connected to the same charger, if necessary via different adapter inserts, with a charging circuit comprising at least one transformer and rectifier arrangements, characterized by :

• a) a circuit breaker (relay 16 or power semiconductor) connected between the output of the charging circuit ( 17 ) by at least one of the charging pole connections (plus pole ACCU 1), which
• b) is controlled by an electronic reverse polarity protection logic circuit (microprocessor 12 ), which in turn
• c) bypassing the circuit breaker with at least one detection connection (A, B) is present directly on the battery ( 11 ) to be charged and detects its possible incorrect polarity and then connects the battery to the charging circuit ( 17 ) if the measurement result is correct.

2. Battery charger according to claim 1, characterized in that the polarity protection logic circuit forming microprocessor ( 12 ) is designed so that it is the permanent-OFF circuit breaker (relay 16 ) then for connecting the charging circuit ( 17 ) to the triggers the charging battery if there is a positive signal from one of its detection inputs (A) from the battery used for charging. 3. Battery charger according to claim 1 or 2, characterized in that a further detection connection (B) of the microprocessor ( 12 ) via a voltage divider circuit (R1, R4) is connected to the positive charging input connection (ACCU 1) and the Ver connection point of the series circuit positive measurement pulses can be fed from a further microprocessor output (C), which lead to a voltage signal at the detection input (B) which is below a predetermined threshold if the battery is incorrectly polarized. 4. Battery charger according to one of claims 1-3, characterized in that the detection inputs (A, B) and the pulse test output (C) of the microprocessor are protected by a protective circuit ( 13 ) consisting of in series to avoid over-currents Diodes (D1, D2; D3, D4) connected in reverse direction between positive voltage (+ U) and ground, the diode connection points being connected to the respective connections (A, B, C) of the microprocessor via resistors (R4, R5). 5. Battery charger according to one of claims 1-4, characterized in that an optical indicator (lamp 14 ) and / or an acoustical cal signal generator ( 15 ) is controlled for polarity reversal. 6. Battery charger according to one of claims 1-5, characterized in that the microprocessor ( 12 ) is designed such that it detects the polarity of an inserted battery or battery, the charging connections by controlling a double changeover relay cross to the charging circuit ( 17th ) turns on.