DE19530849A1 - Battery charger e.g. for electrically powered tool - Google Patents

Abstract

A battery charger has a transformer 4 with a sensor 6 for its temperature. There is a memory 26 for a standard temperature and a control unit 8 for the current fed to the battery depending on the comparison between the measured and the standard temperatures. The temperature sensor is on the side of the core of the transformer. The sensor has a thermistor and/or a thermostat.

Description

The invention relates to the construction of a charger and a method for charging, in particular a charger and a method of charging a battery that is reliable are able to both worsen the Isolation properties of a transformer as well the destruction of the outer housing by a high tem to prevent temperature.

The Japanese patent application Hei 2-36 735 open has a charger that is used for electrically operated tools or the like. Fig. 1 shows a block diagram of the charger according to the prior art technology. A voltage from an AC power supply 71 passes through a noise filter circuit 72 , a rectifier circuit 73, and a switching device 74 . The voltage is then transformed by a transformer 75 . The current transformed by the transformer 75 is rectified by the rectifier circuit 76 , and the current is then applied to the battery 77 to charge the battery.

A control circuit 84 which carries out pulse width modulation (hereinafter referred to as PWM) controls the duty cycle of the switching circuit 74 through a feedback control to keep an output current and an output voltage from the rectifier voltage 76 below a certain amount in accordance with a signal from a constant current circuit 82 and a constant voltage circuit 73 . A temperature sensor 79 is connected to the battery 77 to measure the temperature of the battery. The temperature measured by the temperature sensor 79 is recorded by a temperature measuring circuit 80 .

When the battery charge rate exceeds 77 100%, the temperature of the battery increases by a certain amount. When the full charge is detected, an output signal is generated in order to set the input of a flip-flop circuit 81 from the temperature measuring circuit 80 . When the flip-flop circuit receives the output signal from the temperature measuring circuit, it outputs a signal to the constant current circuit 82 . When the signal from the flip-flop circuit 81 is received, a signal is output to the PWM control circuit 84 from the constant current circuit 82 . The duty cycle of the switch circuit 74 is controlled by the PWM circuit 84 to make the last stage current the output current. In the prior art, a control circuit for a constant temperature is provided. A sensor in the constant temperature control circuit is mounted on the heat-carrying parts of the rectifier circuit 78 or the like arranged on the load side of the transformer 75 to measure a temperature of the heat-carrying parts. If the measured temperature exceeds a certain value, the operating time of the switching circuit 74 is reduced by the PWM control circuit 84 . In this way, the output current to transformer 75 is reduced. The temperature increase of the heat-conducting parts can be prevented in this way. In this way it is possible to avoid problems and a breakdown of the electrically operated tool due to a high temperature.

However, the known charger has the following problems. In the example shown in Fig. 1 charger, the sensor of the control circuit 86 is mounted for the constant tempera ture of the heat-carrying parts disposed at the load side of the transformer 75, the output current from the rectifier circuit 76 in conformity to the detected temperature Taxes.

In this case, since the transformer 75 transforms the voltage down from the AC power source 71 , the temperature rise of the heat-carrying parts located on the voltage supply side of the transformer 75 is much larger than that of the heat-carrying parts located on the load side of the transformer 75 are arranged. However, it is not possible to measure a temperature of the heat-conducting parts which are either arranged on the voltage supply side of the transformer 75 or that of the transformer itself. This leads to a decrease in the insulation properties of the transformer 75 and destruction of the outer housing of the charger, which are caused by a high temperature.

It is the object of the present invention to have a drawer device to create that reliably both a ver deterioration of the insulation properties of the Transfor mators as well as destruction of the outer casing of the Charger caused by high temperature be preventing.

In accordance with the characteristics of the present invention, a battery charger is provided with:
an energy supply channel for generating electricity from the energy supply,
a transformer for transforming down a voltage of the current obtained through the power supply path to a desired voltage,
a load path for charging a rechargeable battery by applying a current of the step-down voltage generated by the transformer,
Transformer temperature measuring means for measuring the temperature of the transformer,
Standard temperature storage means for storing a predetermined standard temperature,
Control means for controlling the current applied to the battery via the load path in accordance with a comparison between the temperature measured by the transformer temperature measuring means and the standard temperature stored in the standard temperature storage means.

In accordance with the characteristics of the present invention, there is further provided a battery charger comprising:
an energy supply channel for generating electricity from the energy supply,
a transformer for transforming down a voltage of the current obtained through the power supply path to a desired voltage,
a load path for charging a rechargeable battery by applying a current of the step-down voltage generated by the transformer,
Temperature measuring means on the energy supply side for measuring a temperature of the path of the power supply,
Standard temperature storage means for storing a predetermined standard temperature, and
Control means for controlling the current applied to the battery via the load path in accordance with a comparison between the temperature measured by the temperature detection means on the power supply side and the standard temperature stored in the standard temperature storage means.

Furthermore, the invention provides a method for charging a battery, which has the following steps:
a step towards generating electricity from the power supply,
a step of transforming a voltage of the current down to a desired voltage by a transformer,
a step of charging the current of the down-transformed voltage to a rechargeable battery,
further performing the following steps:
the step of measuring the temperature of the transformer,
the step of controlling the current to the battery in accordance with a comparison between a temperature and the transformer and the predetermined standard temperature.

Furthermore, in accordance with the present invention, there is provided a method for charging a battery comprising the following steps, comprising:
the step of obtaining electricity from the power supply through an energy supply path,
a step of transforming the current down to a desired voltage,
the step of charging a current of the down-transformed voltage to a rechargeable battery,
the method comprising the following further steps:
a step to recognize a temperature of the energy supply path,
a step of controlling the current to the battery in accordance with a comparison between a temperature of the power supply path and a predetermined standard temperature.

Further features and advantages of the invention result from the following description in which an execution example of the invention explained with reference to a drawing becomes. It shows:

Fig. 1 is a block diagram showing the structure of previously known egg nes charger,

Fig. 2 is a block diagram showing an example of a charger present after the invention,

Fig. 3 is an illustration of GE in Fig. 2 showed charge control circuit,

FIG. 4A is a diagram of a circuit for measuring the temperature of the transformers tors, as shown in Fig. 2,

FIG. 4B is a circuit for detecting the temperature Tem of the battery shown in Fig. 2,

Fig. 5A is a diagram of a measuring circuit for the battery circuit, as shown in Fig. 2,

FIG. 5B is an illustration of a measuring circuit for the charging current,

Fig. 6 is a diagram of a circuit for detecting the zero crossing, as shown in Fig. 2,

Fig. 7 is a flow chart of a program Rechnerpro, which is executed by the gezeig th in Fig. 2 CPU,

Fig. 8A the course of a full-wave rectification,

FIG. 8B, a zero-cross detection signal,

Fig. 8C a switching element operating signal,

Fig. 9 is a diagram showing a relationship between the temperature of the transfor mators and indicating the value of the charging current,

Fig. 10 is a waveform of the charging voltage,

Fig. 11 is a diagram which shows the appearance of the charger according to the present invention,

Fig. 12 is a block diagram that represents the battery pack shown in Fig. 11,

Fig. 13 is a perspective view of the. 11 transformer shown displaying the appearance in Fig.

Fig. 14 represents a perspective view ei ne circuit board for the electronic components rule.

An embodiment of a charger according to the prior invention is described with reference to the figures. Fig. 11 is an illustration showing the appearance of the charger. The transformer 4 and a circuit board for the electronic construction parts 40 are mounted on a base plate 42 , they are surrounded by an outer housing 44 . A plus terminal 51 , a minus terminal, a thermostat terminal 53 and a thermistor terminal 54 rise from the outer housing 44 . The detachable battery pack 10 P is attached to the terminals to charge the battery pack 10 P.

Fig. 12 shows a block diagram showing the battery pack 10 P. In order to carry out the charging of the battery 10 P, the connections D1, D2 are connected to the positive connection 51 and the negative connection 52 , respectively. The thermostat 31 , which has a connection D3 and the thermistor 32 , which has a connection D4, are installed in the battery pack 10 P in. The terminal D3 and the terminal D4 are connected to the thermostat terminal 53 and the thermistor terminal 54 , respectively, as shown in FIG .

The temperature of the battery pack 10 P is received in the charging device via the thermistor connection 54 , when the temperature of the battery pack 10 P is below a predetermined temperature (for example 60 ° C.), the charger starts charging the battery the 10 P battery pack. It is also possible to keep charging the battery when the thermostat 31 is locked because the temperature of the battery 10 in the battery pack 10 P is lowered.

Fig. 12 shows a block diagram of the battery charger, as an embodiment of the present invention. A voltage from the power supply flows through a circuit on the power supply 2 . If the voltage is transformed down to a predetermined voltage by the transformer 4 , the voltage is added to the charging control circuit 8 . Then, the charge control circuit 8 carries out the charging by applying the step-down voltage, which has been step-down transformed by the transformer 4 , to the battery 10 . The charge control circuit 8 controls the battery charge to the battery 10 in accordance with a command from the CPU 20 .

To recognize the full charge, the CPU 20 receives a voltage from the battery 10 through the battery voltage measurement circuit 10 . In order to create a feedback control that keeps the charging current in a certain range, the CPU receives the charging current via the charging current measuring circuit 10 . The value of the battery voltage and the charging current are stored in the RAM 26 as independent data via the analog / digital converter 22 which is provided in the CPU 20 . He also knows a battery temperature measurement circuit 14, the temperature of the battery 10th The temperature of the battery 10 is recorded in the battery temperature measuring circuit 14 via the thermistor connection 54 .

The down-transformed voltage from the transformer 4 is brought to the zero crossing detection circuit 18 . The zero crossing of the full-wave rectification device is recognized by the zero crossing measuring circuit 18 and the detected zero crossing is output to the flip-flop circuit 22 b in the CPU 20 . The CPU 20 he knows the zero crossing point for detecting a state of the flip-flop 22 b. The CPU 20 also has a timer 24 .

In this embodiment, the sensor head 6 a of the temperature detection circuit for the transformer 6 is attached to the transformer 4 as a means for detecting the temperature of the transformer and a temperature of the transformer 4 is known from the sensor head 6 a. The temperature of the transformer 4 , which has been detected by the sensor head 6 a, leads to the CPU 20 ge. The sensor head 6 a is attached to the side of the transformer core 4 M, as shown in Fig. 13. The sensor head 6 a can be attached to the upper surface of the transformer core 4 M or to other surfaces. A thermistor, a thermostat or a thermo element or the like are suitable elements for the sensor head of the temperature detection circuit for the transformer.

Fig. 3 shows a circuit diagram of a charge control circuit 8 in practical embodiments. Next 4A, Fig. A diagram of the temperature measuring circuit for the transformer 6 and Fig. 4B is a lung depicting the temperature measuring circuit for the battery 14. Next 5A, FIG. A representation of the battery voltage measuring circuit 12, Fig. 5B is an illustration of the charging current measurement circuit 16, and Fig. 6 is a Dar position of the zero-crossing detecting circuit 18th

A voltage supply via the circuitry on the Energiever 2 shown in Fig. 2 is stepped down by the transformer 4. In order to transform the supplied voltage down, an induced voltage is developed by the transformer 4 on its load side. The induced voltage is determined by the number of windings on the transformer 4 .

The step down voltage is supplied to the charge control circuit 8, and the step down voltage is rectified by the charge control circuit 8 in a full wave rectified form as shown in Fig. 8A. The rectification is carried out as follows. An alternating voltage from the transformer 4 is applied to the zero crossing measuring circuit 18 . The AC voltage is, as shown in Fig. 8, brought into a rectified form in full waves by the zero crossing measuring circuit 18 which uses the diodes 106 and 107 . The rectified waveform is then fed to the transistor 100 of the charge control circuit 8 .

The CPU 20 operates the transistors 100 and 101 to turn on the two thyristors 102 and 103 . When the two thyristors 102 and 103 are turned on, a charging current is supplied to the battery pack 10 P, as will be described below.

If the secondary terminal of the transformer 4 a [+], a charging current flows from the transformer 4 se sequentially along the path such as the secondary terminal 4 a, the thyristor 102 , the plus terminal 51 , the plus terminal D1 of the battery pack 10 P, the minus terminal D2 of the battery pack 10 P, the minus terminal 52 , the diode 105 and the secondary terminal 4 b.

If, on the other hand, the secondary connection of the transformer 4 b becomes [+], the charging current flows from the transformer 4 the other way, namely through the secondary connection 4 b, the thyristor 103 , the positive connection 51 , the positive connection D1 of the battery pack 10 P, the minus connection D2 of the battery pack 10 P, the minus connection 52 , the diode 104 and the secondary connection 4 a.

The charging of the battery 10 is carried out as described above with full-wave rectification of the AC voltage from the transformer 4 by controlling the switching operation of the thyristors 102 and 103 by the CPU 20 . In this embodiment, other switching elements can be used instead of thyristors 102 and 103 .

The circuit structure for controlling the charging current is described below. The zero-crossing measuring circuit 18 shown in Fig. 6 performs a full-wave rectification of the direct current by using the diodes 106 , 107 as mentioned above. The voltage rectified to full waves is divided by a Zener diode 108 and resistors 109 and 110 , and the divided voltage is applied to transistor 111 . Also, the zero crossing measuring circuit 18 outputs a zero crossing measuring signal (see FIG. 8B), which corresponds to the divided voltage, to the CPU 20 .

The CPU 20 outputs a switching element operation signal (see Fig. 8C) to the charge control circuit t seconds after the zero-crossing measurement signal is received. The switching element control signal controls the two transistors 100 and 101 to switch on the thyristors 102 and 103 . The battery 10 is charged for the duration of t seconds as shown in Fig. 8C. That is, the CPU 20 controls the duration of T seconds (see FIG. 8B) to set the duration of t seconds during which the battery charging is carried out. This process is carried out to control the value of the charging current.

In particular, a count-up value corresponding to the duration of T seconds is stored in the RAM 26 under the control of the CPU 20 . The CPU 20 starts the timer 24 upon receipt of the zero-crossing measurement signal (see Fig. 8B). When the count value in the RAM 26 and a value counted by the timer 24 become equal, the CPU 20 outputs the switching element operation signal (see Fig. 8C).

In order to keep the value of the charging current at a certain level, feedback control is carried out by measuring a current value by means of the charging current measuring circuit 16 . The charge current measurement circuit 16 receives a voltage drop caused by the resistor 112 in the charge control circuit 8 (see FIG. 3) and removes noise by using the resistor 113 and the capacitor 114 as shown in FIG. 5B shows. The voltage is averaged by means of an integration circuit consisting of resistors 115 , 116 and a capacitor 117 , and the averaged voltage is applied to the CPU 20 .

The CPU 20 thus recognizes a current value and compares it with a target current value. If the measured current value is less than the target value, the CPU 20 controls the enumeration value stored in the RAM 26 to make the duration of T seconds shorter than it is (in other words, the CPU 20 makes the duration t Se customers longer than it is). This makes the current value higher than the usual current value. On the other hand, if the measured current value is larger than the target value, the CPU 20 influences the value stored in the RAM 26 to make the duration T seconds longer than it is (in other words, the CPU 20 makes the duration t seconds) shorter than it is). This makes the current value less than the usual current value. This feedback control helps to keep the charging current at a constant value.

A computer program executed by the CPU 20 will be described below in accordance with the flow shown in FIG. 7. The battery charge begins after the battery pack 10 P has been inserted into the charger. Assuming that the temperature of the transformer remains below the temperature limit in step S2, charging with constant current is carried out with a current value of 2A. That is, at this time, the enumeration value (duration of T seconds) stored in the RAM 26 is a value corresponding to carrying out the charge with a charging current 2A.

After completion of step S6 and step S8, the CPU 20 again measures whether or not the temperature of the transformer 4 reaches the temperature limit (the standard temperature). Here, the temperature limit is a value that is set and stored in the RAM 26 before the battery is charged. The tempera ture of the transformer 4 is measured by the temperature measuring circuit for the transformer (the transformer temperature measuring means) 6 . The temperature measurement circuit for the transformer 6 divides a voltage from the sensor head 6 A using the resistors 118 and 119 , as shown in Fig. 4, further the noise of the voltage is removed from the capacitor 120 . Then the voltage is supplied to the CPU 20 .

When the temperature of the transformer 4 reaches the temperature limit, the CPU 20 proceeds from step S2 to step S10. This means that the charging current is reduced from 2A to 1.5A. The CPU 20 rewrites the count value stored in the RAM 26 to a value corresponding to the charging current value of 1.5A.

That is, the charging current value decreases to 1.5A by making the duration of T seconds longer, in other words, shortening the duration of t seconds corresponding to the charging time. A relationship between the temperature of the transformer 4 and the charging current value is shown in FIG. 9.

By setting the temperature limit (the highest possible value) at which there is no problem in the charger in the RAM 26 , it is possible to destroy the outer case 44 (see Fig. 11) and deteriorate the insulation properties of the Transfor mators 4 , which is caused by the increase in temperature of the transformer 4 , prevent.

Since the transformer 4 transforms the voltage down from the voltage supply, the temperature increase of the heat-carrying parts of the transformer 4 itself is very much larger than that of the heat-carrying parts, which are arranged on the load side of the transformer. It is therefore reliably possible to prevent the deterioration of the insulating properties of the transformer 4 and the destruction of the outer casing 44 or other problems caused by a high temperature than in the event that the charging current is in accordance with the Temperature measurement on the load side of the transformer 4 is checked.

The charging current is reduced to 1.5A as described above. Then, as shown in Fig. 10, -ΔV is measured by sampling the charging current for a certain period (step S6, S8). The waveform of the charging current, as shown in Fig. 10, has an inclination which is reduced from the full charge so that the CPU 20 recognizes the full charge by measuring -ΔV.

The detection of the battery voltage is carried out by the battery voltage measuring circuit 12 . The battery voltage measuring circuit 12 divides a voltage using a Zener diode 121 , resistors 122 and 123, and noise of the voltage is generated by the capacitor 124 , the resistor 125 and the capacitor 126 as shown in FIG. 5A. away. The voltage is then supplied to the CPU 20 . The CPU 20 stops loading when it measures -ΔV.

In the example above, the charging current is controlled by detecting the temperature increase of the transformer 4 . In another embodiment, it is possible to measure a temperature of a voltage supply path of the transformer 4 , for example the circuits 2 , which are arranged on the voltage supply side. FIG. 14 is a perspective view showing a circuit board for the electronic components 40 shown in FIG. 11. The circuit of the voltage supply side 40 a and the circuits of the load side 40 b are formed on the circuit card for the electronic components, as shown in Fig. 14.

In the circuits on the voltage supply side 40 a thyristors 61 , 62 , diodes 63 , 64 , resistors 65 and 66 are arranged as components of the circuit. In Fig. 14 some of the circuit elements and the Lei terbahnen the circuits on the voltage supply side 40 a are shown, but not all Schaltele elements and conductor tracks are shown.

In an exemplary embodiment shown in FIG. 14, a sensor head 67 is fastened to the resistor 66 of the circuits on the voltage supply side 40 a. The temperature increase of the circuits of the voltage supply side 40 a is much larger than that of the circuits of the load side 40 b. It is thus reliably possible to avoid deterioration in the insulation properties of the transformer 4 and the destruction of the outer casing (see FIG. 11) or other problems caused by a high temperature.

Although the sensor head 67 in FIG. 14 is attached to the resistor 66 on the power supply side 40 a, the sensor head 67 can also be attached to another of the components, such as one of the thyristors 61 , 62 , the diodes 63 , 64 or another resistor , et wa the resistor 65 . Furthermore, the sensor head 67 can be attached to the printed circuit board (not shown) which carries the circuits on the voltage supply side 40 a.

The temperature increase of the above components, such as the thyristors 61 , 62 , the diodes 63 , 64 , the resistor 65 and the printed circuit board is very much greater than that of the circuits on the load side 40 b. It is thus reliably possible to prevent deterioration in the insulation properties of the transformer 4 and the destruction of the outer housing 44 (see FIG. 11) or other problems caused by a high temperature.

Also in the above embodiment, the drawer current controlled to decrease from 2A to 1.5A, where another value of the charging current can be taken can. It is also possible to charge the current in more than to control three levels.  

In the charger according to the present invention trans the transformer forms a voltage of a current, which were obtained via the voltage supply path, down. Then the control means saves the electricity that is on the battery is abandoned in accordance with ei a comparison between a temperature on the chip voltage supply channel or that of the transformer and the standard temperature in the standard temperature storage means is stored.

That is, it is possible to either increase the temperature the one on the power supply path or at the Transformer in which to increase the current flowing to the Battery is abandoned, is decreased when the tem temperature of the voltage supply path or the Transfor mators reached the standard temperature.

As the transformer steps down the voltage, the increase in temperature is much larger than that that of the power supply path or the Transfor mators compared to the load path. Under the assumption, that the charging current in accordance with a tempera load channel is controlled, it is not possible the temperature increase of the voltage supply channel or to recognize that of the transformer like this the present invention does. The high temperature that forming in one of them causes an Ab Isolation properties of the transformer and destruction of the outer casing or other problems me.

The charger adjusts to solve these problems of the present invention, the charging current in accordance with the temperature of the voltage supply path or the transformer. This prevents a tempera  decrease in the voltage supply channel or Transformer so that it is possible to decrease the Isolation properties of the transformer and a Zer external housing malfunction or other problems to be caused by the temperature.

Although the invention in its preferred embodiment examples has been described, it is understood that the terms used do not limit the invention should and that changes are within the from limits resulting from the enclosed claims are possible, without breaking away from the basic idea of the invention.

Which emerge from the claims and the description benden features and advantages of the invention can both individually as well as in any combination for the ver realization of the invention in its individual form important.

Claims (17)

1. A battery charger, characterized by

• an energy supply channel for generating electricity from an energy supply ( 2 ),
• a transformer for transforming down a voltage of a current obtained from the energy supply channel to a desired voltage,
• a load channel for charging a rechargeable battery ( 10 ) by applying a current that is transformed down by the transformer ( 4 ),
• - A transformer temperature measuring means ( 6 ) for measuring the temperature of the transformer ( 4 ),
• - a standard temperature storage means ( 26 ) for storing a predetermined standard temperature, and
• - Control means ( 8 ) for controlling the current to the battery ( 10 ) through the load channel in accordance with a comparison between the temperature by the transformer temperature measuring means ( 6 ) and the standard temperature in the standard temperature measuring means ( 26 ) is saved, is abandoned.

2. The battery charger according to claim 1, characterized in that the transformer temperature measuring means ( 8 ) on the core of the transformer ( 4 ) is introduced. 3. The battery charger according to claim 2, characterized in that the transformer temperature measuring means ( 8 ) on one side of the core of the transformer ( 4 ) is brought to. 4. The battery charger according to one of the preceding claims, characterized in that the transformer gate temperature measuring means ( 8 ) has a thermistor ( 6 a) which is used to measure the temperature of the transformer gate ( 4 ). 5. The battery charger according to one of claims 1 to 3, characterized in that the transformer temperature measuring means has a thermostat ( 6 a) which is used to measure the temperature of the transformer ( 4 ). 6. The battery charger according to one of claims 1 to 3, characterized in that the transformer gate temperature measuring means ( 8 ) has a thermocouple ( 6 a) which is used to measure the temperature of the transformer gate ( 4 ). 7. A battery charger characterized by

• an energy supply channel for generating electricity from an energy supply ( 2 ),
• a transformer for transforming down a voltage of a current obtained from the energy supply path to a desired voltage,
• a load channel for charging a rechargeable battery ( 10 ) by applying a current that is transformed down by the transformer ( 4 ),
• - A temperature measuring means ( 67 ) arranged on the energy supply side for measuring a temperature of the energy supply path,
• - a standard temperature storage means ( 26 ) for storing a predetermined standard temperature, and
• - Control means ( 8 ) for controlling the current that is applied to the battery ( 10 ) via the load path in accordance with a comparison between the temperature, which is measured by the energy supply-side temperature measuring means ( 67 ) and the standard temperature is stored in the standard temperature measuring means ( 26 ) is given up.

8. The battery charger according to claim 7, characterized in that the energy supply-side temperature measuring means ( 67 ) is arranged on a component ( 66 ) of the energy supply channel. 9. The battery charger according to claim 7, characterized in that the energy supply-side temperature measuring means ( 67 ) on the printed circuit board ( 40 ) of the energy supply path is arranged. 10. A method for charging a battery with the following steps:

• - the step of generating electricity from an energy supply,
• the step of transforming the voltage of the current down to a desired voltage by means of the transformer,
• the step of charging a current of the down-transformed voltage into a rechargeable battery,

characterized by the following steps:

• - The step of detecting the temperature of the transformer, and
• - the step of controlling the current of the battery in accordance with a comparison between the temperature of the transformer and a predetermined standard temperature.

11. The procedure for charging a battery according to An saying 10,  characterized in that in the step of tax erns the current to the battery the temperature of the Transformer and the specified standard temperature be compared and the one applied to the battery Electricity is reduced when the temperature of the Transfor mators is higher than the specified standard tempera door. 12. A method for charging a battery with the following steps:

• - the step of generating electricity from an energy supply,
• the step of transforming the voltage of the current down to a desired voltage by means of the transformer,
• the step of charging a current of the down-transformed voltage into a rechargeable battery,

characterized by the following steps:

• - The step of detecting the temperature of the voltage supply path, and
• - The step of controlling the current of the battery in accordance with a comparison between the temperature of the voltage supply path and a given standard temperature.

13. The procedure for charging a battery according to An saying 12, characterized in that in the step of tax erns the current to the battery the temperature of the Power supply path and the specified Stan dard temperature can be compared and that on the Bat terie applied current is reduced when the tem temperature of the transformer is higher than the specified one ne standard temperature. 14. A method for charging a battery with the following steps:

• - the step of generating electricity from an energy supply,
• the step of transforming the voltage of the current down to a desired voltage by means of the transformer,
• the step of charging a current of the down-transformed voltage into a rechargeable battery,

characterized by the following steps:

• - The step of detecting the temperature of the voltage supply path, and
• - The step of controlling the current of the battery in accordance with a comparison between the temperature of the voltage supply path and a given standard temperature.