RU2340060C2 - Protective method and device for ground fault prevention - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device (1) contains normally open differential interrupter (20) and differential current transformer (39) generating signal proportional to leakage. Data processing unit (50) connected with transformer (39) registers specified signal and keeps interrupter (20) closed until unsafe condition arises implying that registered signal exceeds certain limit value.

EFFECT: higher reliability and sensitivity of protection with self-diagnostics and complete automation provided.

26 cl, 4 dwg

Description

The invention relates to a method of protection against leakage currents and a device for implementing this method.

It is known that when using devices powered by the mains and in direct contact with humans, there is always a high risk of electric shock; for this reason, security measures require the use of various protective devices that disconnect devices from the network.

Typically, in single-phase systems, an electrical appliance (i.e., generally speaking, a load) is powered by a consumer electrical network (also called a mains) via two wires. One of them is called “hot” or “phase”, the other - “zero”. Usually in distribution cells, a neutral wire is grounded.

The most common injuries occur when people use appliances that are connected to the electrical outlet while taking a bath or in the pool. Water becomes a conductor of current, called a leakage current, or short circuit to ground, which flows from the "hot" wire to the ground. If this current flows through the human body, an electric shock may occur. This happens when a person comes into contact with a "hot" wire during contact with a conductive surface when grounding.

Industrial protection circuits for this kind of hazard, called GFCI (earth current circuit breakers), contain a differential current transformer in which the primary winding consists of hot and neutral wires, and the secondary winding is connected to an amplification stage. If the current flowing through the hot wire reaches the load and returns through the neutral wire without leakage to the ground, then there will be no magnetomotive force in the core of the transformer to induce secondary current.

On the contrary, if a leakage current is present, then a current proportional to the difference between the currents in the hot and neutral wires is generated in the secondary winding; this signal is amplified, then compared with the maximum permissible and, if exceeded, the circuit breaker disconnects the load from the hot and neutral wires.

Since these devices protect household appliances as a whole, their sensitivity is limited to 30 mA, and small spurious leakage currents naturally present in electrical appliances are not taken into account.

When using electrical appliances or hand-held power tools in certain conditions, that is, in high humidity, as well as in case of contact with water in pipelines or sanitary devices, in order to ensure safety, protection circuits with a higher sensitivity should be used, which can fit in the plug power networks. In this case, devices sensitive to currents of 3 mA and below should be used.

The level of hazardous current depends on the type of dry cells and the standards set for medical devices, where the electrodes are in contact with the patient and a threshold current value of maximum 3 mA is required for the protection circuit, however, even currents less than 1 mA can be dangerous if switching on the protective circuit does not guarantee interruption of current until danger occurs.

A protective circuit with such high sensitivity can guarantee the safety of the operator, but only if it works reliably. To check the reliable operation of the protective circuit, modern electrical appliances are equipped with a control button, pressing which allows you to simulate leakage currents slightly exceeding the sensitivity of the circuit, which is why the protective circuit is switched on. However, the burden of such a test rests with the user, who each time must connect the device to the network, press the control button, and then switch the circuit again.

The protection system should be independent of user actions and provide a high degree of reliability.

The state of the art can be characterized by revealing the essence of some decisions.

US Pat. No. 5,982,593 proposes a circuit breaker including protection against short circuit to ground; such protection is provided with a test circuit to verify the safe operation of the protective circuit itself; however, such a test circuit is triggered by a control button.

US Pat. No. 6,426,632 proposes a sinusoidal current signal generation system for monitoring arc short circuit protection and briefly describes the use of a microprocessor to determine the secondary current of a differential transformer and compare it with a threshold value generated in the microprocessor. If this current exceeds the threshold value, the microprocessor sends a signal at which the relay is activated and disconnects from the mains.

However, it is not described in detail how the microprocessor and its related circuits perform this function, nor are any links given to what other functions are performed by the microprocessor.

US Pat. No. 5,857,087 discloses a chopper for controlling the current flowing from the mains to the load. The microprocessor is used to compare this current with the parameters generated in the microprocessor and generate a control signal to interrupt the circuit. In this case, the microprocessor provides control of the reliable operation of only neighboring circuits, and not the protection system as a whole, and the system is not calibrated.

US patent 6262871 suggests the use of an electronic circuit for automatic control of GFCI; An important property of this invention is that it must be connected to an already implemented GFCI or must contain its main components.

The artificial leakage currents generated by the microprocessor and the signal generated by the GFCI are examined cyclically: if these signals are normal, the control is terminated, otherwise the load is disconnected from the mains using the GFCI by opening the second breaker, which must be additionally included in the system.

The disadvantages of this solution are excessive redundancy of circuits, because GFCI is complicated by functions that are already available, i.e. the automation does not work efficiently; moreover, it is not always easy to determine the critical values of the selected voltage, and the consumption of wires and the cost of the system also increase. The GFCI construct on which the invention is based is considered a priori known. When changing the design of the system in accordance with this invention should be completely redone.

Thus, at the present stage of technological development, there are no GFCIs that simultaneously:

- do not need human participation, being fully automatic;

- have a high sensitivity to leakage currents;

- have a small size and are so compact that they can fit in any plug, socket or shunt element;

- include self-monitoring functions during their safe operation or during the initialization phase when the GFCI is turned on, or periodically after connecting the load to the power supply;

- show the user the type of failure;

- allow connection to the power grid only after checking the correct and effective operation of the protection;

- due to the calibration of the signal in the circuit detecting leakage currents work regardless of its design and are able to compensate for its errors;

- disconnect the load from the network when dangerous leakage currents occur.

The main objective of the present invention is to provide GFCI having the above properties.

This goal is achieved when GFCI is carried out in accordance with the claims.

All the advantages of GFCI in accordance with the present invention will become apparent from the description of the preferred, but not the only implementation option, an example of which is given below with reference to the accompanying drawings, where:

figure 1 shows a block diagram of a GFCI in accordance with the present invention;

figure 2 is a detailed electrical diagram of the GFCI shown in figure 1;

figure 3 is a diagram of a variant of the circuit shown in figure 2;

figure 4 is a diagram of another embodiment of the circuit shown in figure 2.

The invention is described for a household appliance, namely for a hairdryer, although its use is not limited to this, it can also be used for industrial purposes.

In the particular case of the invention, which does not limit the scope of the invention, the GFCI is placed in a plug at the end of the hair dryer wire; it is possible to place it in a wall outlet where the hair dryer plug is inserted.

Turning to FIG. 1, which shows a block diagram of a GFCI 1, a single-phase power network 10; a hot conductor 12 and a neutral conductor 14 with ground connect the network 10 to the contacts 22a, 22b of the relay 20. As a circuit breaker, other types of controlled switches, for example semiconductor devices, can be used. When the relay 20 is activated, the contacts 22a, 22b are connected to the terminals 24a, 24b, which are connected through the conductors 12a, 12b to the terminals of the hair dryer 16.

Conductors 12, 14 are part of the leakage current detection circuit in the conductors 12, 14 themselves, the differential current transformer 30 is made on a toroidal core with known characteristics. The primary winding of the transformer consists of conductors 12, 14, the secondary winding is schematically shown under the number 32. For detection of direct leakage currents, for example, a probe (probe) or a LEM product can be used.

The test generator 40 shunts the conductors 12, 14 through the conductors 42, 44. The purpose of the generator 40, as will be explained in more detail in the following description, is to artificially induce a precisely known value of the current flowing in the conductors 42, 44, and therefore, in conductors 12, 14. Since this current is a differential component for transformer 30, it will detect the current, generating a secondary signal proportional to the current.

This signal is processed using the logic unit 50, to which the secondary winding 32 is connected, after amplification, as will be understood hereinafter; the logic unit 50 is also connected to a test generator 40 and a relay 20 to which it supplies control and / or switching signals via conductors 36 and 38, respectively. Unit 50 also contains at least an arithmetic module for performing binary operations, RAM, ROM, and an analog-to-digital converter (all not shown).

Figure 2 presents a detailed electrical diagram of the GFCI 1 according to the invention, while retaining the corresponding links of figure 1.

Single-phase power supply network 10 is connected through two fuses 11 by conductors 12 and 14 with contacts 22a and 22b of relay 20; when the inductor 21 of the relay 20 is activated, the contacts 22a and 22b close the terminals 24a and 24b, from which two wires 12a and 12b are connected to the terminals of the hair dryer 16.

The components of this embodiment of the present invention are located inside the power plug 55 of the hairdryer 16 and are schematically shown in dashed lines in FIG.

As can be seen from this figure, the conductors 41, 42 connected to the test generator 40 (shown inside the dashed lines), and the conductor 45 bypass the conductors 12, 14 of the power grid 10.

The resistive-capacitive circuit 46, shown inside the dashed lines, is connected by a conductor 45 to a rectifier bridge 47, which is directly connected to the network 10 by a conductor 44. The output of the bridge 47 is filtered by an electrolytic capacitor 48 and smoothed by a zener diode 49, in this case the voltage is 30 V. This voltage is the first power source for GFCI 1. The positive terminal of the capacitor 48 is connected by a wire 200 to the emitters of two PNP transistors 60, 70, the negative terminal is connected to the wire 100, which is the ground for GFCI 1. This name is emlya 100 - used in the future. A resistor 61 is connected between the emitter and the base of the transistor 60, its base is connected via a limiting resistor 62 to the npn collector of the transistor 80, the emitter of which is connected to the ground 100, and the base through a bias resistor 63 by a wire 38 to the output terminal of the logic block 50. As such a block can be used, for example, the Motorola MC 908Q2 microcontroller. The collector of the transistor 60 is connected to the cathode of the inverse diode 64, the anode of which is connected to the ground 100, with the bias resistor 65 of the base of the transistor 70 and the output of the coil 21 of the relay 20. Another output of the coil 21 is connected in parallel with the regulating zener diode 92 and the filter capacitor 91, which are connected by their negative terminals with earth 100, and positive to the conductor 110, forming a positive output of the second voltage source (in this case, 5.1 V) to power the logic unit 50 and the operational amplifier 90 (for example, LPV3212). The conductor 110 is closed through the limiting resistor 71 by the collector current of the transistor 70 to which the Miller capacitor is connected.

The output 90u of the amplifier 90 is connected to the input of the block 50 and to the star-connected feedback resistances 74, 75, 76; the first two resistors are connected in series with the inverted input of the amplifier 90, the third resistor connects the common point of the resistors 74, 75 to a resistive divider shunting the second voltage source of 5.1 V.

The divider consists of two series-connected equal resistors 77a, 77b, the common point of which is connected to the resistor 76. Two shunt capacitors 78, 79 are connected in parallel to the resistors 77a, 77b, respectively.

The inverted and non-inverted inputs of the amplifier 90 are connected respectively to the resistor 82 and the isolation capacitor 83, connected in series, and the resistor 84. Using these components, the voltage is removed from the load resistor 85, connected in series with the terminals 32a, 32b of the secondary winding 32 of the transformer 30. The output of the load resistor 85 is also connected to the output of a divider consisting of resistors 77a, 77b.

The components of the test generator circuit 40 are shown inside the dashed line. A high-precision control resistor 86 connects the conductor 12 through the conductor 42 to the anode of the triac 88, the cathode of which is connected to the wire 14 through the wire 44. The resistor 86 shunts the conductor 12 at the branch point of the transformer 30 so that the current flowing through the resistor 86 returns to the network 10 along the conductors 44 and 14, without flowing through the toroidal core of the transformer 30. The conductor 44 actually connects the conductor 12 to the input of the transformer 30. Other locations of the conductors are also possible, since the current through the resistor 86 is only necessary for its detection by transformer 30. In parallel with resistor 86, another correction resistor 87 is connected, which shunts conductor 12 through conductor 41 to the input of transformer 30. Resistor 89 is connected between the grid and the cathode of triac 88. Resistor 101 and diode 104 are connected to the grid in series a resistor 103 and a diode 102 connected in series, the grid being connected to the anode of the diode 102. The diodes 104 and 103 are turned on in parallel. The resistor 103 is connected to the NPN collector of the transistor 105, and the emitter of the transistor 105 is connected to the ground 100, and the basic offset through the resistor 106 is supplied from the output terminal of the block 50. An anode of the diode 104 is also connected to this terminal, which is connected in series with the resistor 101.

Both outputs of the logic block 50 are powered by two series-connected resistors 111, 113 and, respectively, the LEDs 112, 114. Thanks to the LEDs, the logic block 50 is able to provide a visual alarm for the GFCI 1 user. To display the alarm, the LED 112 gives a green color, and the LED 114 gives a red . It is possible to use an acoustic alarm, such as a buzzer.

Two series-connected resistors 28, 29 form a divider, one end connected to the ground 100, and the other to a step-down resistor 46, which supplies rectangular voltage pulses with a power frequency of 10 to the output of block 50, which block 50 uses for internal synchronization by counting cycles ( 20 ms at a network frequency of 50 Hz and 16.6 ms at a frequency of 60 Hz). Another source of internal synchronization may be a square-wave signal obtained from the clock pulses of block 50 and properly reduced by the dividers.

The stages of operation of the GFCI 1 are described from the moment of switching on, when the user inserts the plug 55 into the outlet, to the stable mode, when he can use the hairdryer 16 safely. These stages are as follows.

1. The user inserts the plug 55 into an appropriate outlet. The relay 20, normally open, does not work until the hair dryer 16 is connected to the power supply 10, and therefore does not work. Through the diode bridge 47, the capacitor 48 is charged and the voltage at its terminals is stabilized until the breakdown voltage of the zener diode 49 is reached. The transistor 60 is locked, since the bias is not applied by the transistor 80, also locked, since the block 50 does not feed the bias to the base through the resistor 63. The transistor 70, on the contrary, is saturated due to the passage of the base current through the resistor 65, through the coil 21 of the relay 20 and the zener diode 92. This base current is insufficient for the relay 20 to operate. Through the resistor 71, the zener diode 92, the transistor 70 is saturated, the voltage otorrhea tank 91 is filtered and applied to an amplifier 90 and logic unit 50.

2. Since no current flows through the dryer 16, and accordingly no current flows through the primary and secondary windings of the transformer 30, therefore, there is no voltage across the resistor 85. Therefore, the output 90u maintains the steady-state value set by the divider formed from resistors 77a, 77b equal to half applied voltage. Unit 50 performs sequential sampling through its internal analog-to-digital A / D converter (8 bits in this embodiment) of the output voltage 90u of amplifier 90, averaging the discrete values using its internal digital module over 65536 (216) samples; this operation takes less than a second. The average value should be 127, namely half the full scale with deviations of 3 bits within the tolerance. This value is obtained if the rated voltage equal to half the applied voltage is removed from the divider, consisting of resistors 77a, 77b. If the desired value is outside this range, stage 2 is repeated first, otherwise stage 3 follows. At this stage, both LEDs 122 and 114 are on.

3. Block 50 stores the average value obtained in stage 2 and samples the output voltage 90u of the amplifier 90 for the next 65536 clock cycles; the average value is calculated in the same way as in stage 2. The obtained average value must be equal to the previous one with a maximum difference of 1 bit, otherwise the system returns to stage 2. This ensures that the second supply voltage is stable and the analog-to-digital converter is working properly. The average value calculated at this stage is stored in block 50 and takes a reference value for the analog-to-digital converter. LEDs 112 and 114 are kept on.

4. Unit 50 implements a sampling mode of the output voltage 90u of the amplifier 90: the absolute value of the difference between the sampled output voltage 90u of the amplifier 90 and the reference value stored in stage 3 is calculated. Of all these processed values, the maximum value is maintained, and after a delay of several network cycles 10, the block 50 verifies that said maximum value is below 2, that is, only the least significant bit is changed in the A / D converter. This ensures that the noise of the system is sufficiently low and does not interfere with the operation of the GFCI 1; if this condition is not met, unit 50 returns to stage 1. During this stage, both LEDs light up.

5. Unit 50 supplies a positive bias voltage across conductor 36 to transistor 105 through resistance 106 and saturates it. The base of the triac 88 through the diode 104 and the resistor 101 connected in series is saturated during the passage of the positive half-wave of the voltage of the mains 10 through the conductor 12. During the passage of the negative half-wave, the bias circuit of the triac 88 includes a diode 102, a resistor 103, and a transistor 105; in both cases, current flows through resistor 89 and triac 88 is turned on.

6. The open state of the triac is maintained for two cycles of the voltage of the network 10: when the triac is open, the control resistor 86, the value of which must be very accurate, creates a differential current for the transformer 30, which detects it and induces a current in the secondary winding 32, thereby forming a voltage on the resistor 85. This alternating voltage is amplified by the operational amplifier 90 and removed from its output 90u. Block 50 samples the voltage signal, as in the previous stages, and converts it to a digital value using an internal analog-to-digital converter, remembering the maximum value. Then, the block 50 checks that the maximum value is between the upper and lower limits, both are previously stored in the ROM of the block 50. This is necessary in order to ensure that the circuit for determining the differential currents as a whole is in working condition and has acceptable sensitivity. If the maximum discrete value is too low, the green LED 112 flashes for a short time and the system starts working again from stage 2. If the maximum discrete value is too high, the red diode 114 flashes and the system starts working again from stage 2. If the maximum discrete value is acceptable , then it is remembered as a test set by GFCI 1, and the transition to the next 7th stage is carried out.

7. Unit 50 supplies a positive bias voltage across conductor 38 using bias resistor 63 to transistor 80, which is saturated. Current is able to flow from the first 30 V power source to ground 100 through resistors 61, 62, saturating transistor 60 and energizing inductor 21 of relay 20 from the first power source. Now, a current of sufficient magnitude can flow through the coil 21 to trigger the relay 20, which allows the hair dryer 16 to be connected to the network, which allows it to be used. At the same time, block 50 constantly turns on the green diode 112 and turns off the red diode 114.

8. After the relay 20 has been activated and the hair dryer 16 has been powered from the network 10, the unit 50 continues to control the output voltage 90u of the operational amplifier 90 in the same way as in the previous stages. In particular, after converting the output voltage 90u to a digital series using an analog-to-digital converter, unit 50 subtracts its maximum value for the reference value, then calculating the module (or absolute value), obtains the maximum value of the actual leakage current. If this maximum is for more than 10 consecutive measures, i.e. for 10 registrations (performed in about 0.1 ms), more than the limit value, in this case it is the value stored at the end of stage 6, i.e. check value, block 50 removes voltage from resistor 38, thereby opening relay 20 and disconnecting hair dryer 16 from power supply 10. Logic block 50 signals danger with a flash of red LED 114. In hazardous conditions, GFCI 1 remains blocked, thereby preventing relay 20 from tripping , and can only be activated by turning it off and on again. This means that the user must unplug the plug 55 from the wall outlet, repair the problems causing the GFCI 1 to turn off, and reconnect the plug 55. From this moment, the GFCI 1 will start from stage 1.

In step 8, that is, when the hairdryer 16 is turned on, it is possible to perform periodic monitoring measurements, as in steps 5 and 6, to ensure that the GFCI 1 works well. In this case, during verification, that is, when the operations described in steps 5 and 6 are performed , to guarantee the safety of the user, the permissible (for not opening the relay 20) maximum value at the output 90u of the operational amplifier 90, that is, the limit value, is doubled.

According to the above, it follows that the advantage of the present invention is the ease of setting the threshold of the GFCI 1, that is, by changing the value of the test resistor 86. Since the threshold value is not a fixed value, which is a priori stored in block 50, but represents the actual set current, which should be determined by GFCI 1 at the initialization stage, GFCI 1 provides control even at a very low threshold for GFCI 1. In this case, the connected load will remain disconnected.

Another advantage of the present invention is the simplicity with which it is possible to add other types of operational protection, such as short circuit protection or discharge arc.

A short circuit occurs when the conductors 12a and 12b in FIG. 2 are in contact even temporarily or when the load impedance is very low, for example, when the user touches the conductors 12a and 12b. At this point, a high current, which is lethal, flows through the conductors 12a and 12b. Fuses 11 (see figure 2) do not guarantee a quick open circuit.

This inconvenience can be eliminated by implementing the variant of the present invention depicted in figure 3, which shows the numbered added components, while the rest of the chain is similar to that described above.

In this embodiment, protection against short-circuit currents is achieved by introducing a current transformer 300 onto conductor 14.

The introduction of the transformer 300 can also be carried out on the conductor 12 or at the output of the relay 20; the primary winding of the transformer 300 is conductor 14, and the secondary with a central tap is the second winding 330. The central tap is connected to a resistor 111a with a very low resistance value (several ohms), the second terminal of which is connected to the anodes of two diodes 310, 311, while the cathodes of these diodes are connected to the outputs of the secondary winding of the transformer 300.

The resistor 111, which in FIG. 2 is connected directly to the LED 112, in this case is connected to the combining point of the cathodes of the diodes 310, 311; a conductor 320 connects the center tap of the secondary winding 330 of the transformer 300 to an LED 112 to which a resistor 111b having a relatively high resistance (about 10 kΩ) is connected in parallel.

The voltage at the secondary winding 330 of the current transformer 300 is rectified by the diodes 310 and 311, so that a pulse signal proportional to the current flowing through the conductor 14 flows through the resistor 111a.

The operation of the circuit is as follows.

The output of block 50, to which resistor 111, in this case designated AO, is connected, is used as an output in the initialization process and triggers a red LED 112 through resistor 111 (as already described) and resistor 111a, while resistor 111b does not affect operation red LED 112. At the end of the initialization phase, the red LED 112 turns off, and the AO output becomes an analog input due to the proper program commands of block 50.

Then, the applied voltage is sampled using an analog-to-digital converter, and the current that feeds the load with the help of the current transformer 300 is indirectly measured: unit 50 provides the opening of relay 20, as already described, when the current through conductor 14 exceeds the set threshold value, thereby guaranteeing short circuit protection.

The second embodiment of the device in accordance with the present invention is shown in FIG. 4, much like the 1st embodiment, for simplicity, only new positions are indicated, and the rest are the same as in the previous description.

A current transformer 3001 is introduced to the conductor 12b connected to the load, which can also be introduced to the conductor 12a or to the output (relay) of the chopper 20; the primary winding of the transformer 3001 is made using the conductor 12b, the secondary - using the secondary winding 3301.

A resistor 1111a with a very low resistance (several ohms) is connected to the terminals of the secondary winding 3301. The resistor 111, which is connected to the LED 112 in FIG. 2, is connected to the resistor 1111a in this circuit, which energizes the anode of the LED 112. Its cathode is connected to the collector of the transistor 370, the emitter of which is connected to ground 100, and the base is offset by a divider formed from two resistors 346, 344, and is fed from the collector of transistor 70. A capacitance 340 is connected in parallel to transistor 370, and the collector of transistor 370 is connected with the output 90u of the operational amplifier 90 through a resistor 342.

The assembly, consisting of a resistor 342 and a capacitance 340, forms a low-pass filter for the voltage at the output 90u of the amplifier 90, thereby maintaining a constant voltage equal to half the voltage of the second power source on the collector of the transistor 370.

The operation of the circuit is as follows.

During initialization, the output of AO block 50 is used as an output and triggers a red LED 112, as already described, through resistor 111 and resistor 1111a, while transistor 370 is saturated, since transistor 70 is also saturated and relay 20 is not turned on and allows the LED to turn on 112. At the end of the initialization stage, the red LED 112 turns off and the output of the AO block 50 becomes an analog input due to its program.

At this time, the transistor 370 is locked, and the relay 20 is turned on due to the locked state of the transistor 70; then, a constant component of the output voltage 90u of the amplifier 90 will be present on the collector of the transistor 370; this constant voltage, which is added to the signal generated by transformer 3001 through resistor 1111a, is sampled by an analog-to-digital converter, and therefore, block 50 can indirectly measure the current consumed by the load.

The readout of the voltage at the AO pin is performed in the same way as the readout of the output voltage 90u of the amplifier 90: the absolute value of the difference between the voltage at the AO pin and the reference voltage (stored as the reference value during Step 4 above) is compared with the limit value stored in the ROM block 50, and when the relay 20 is exceeded, it opens, thereby disconnecting the load 16.

Minor deviations from the above protection method and the related electronic circuit are included in the scope of the claims.

Claims (26)

1. A method of protection against leakage currents generated by supplying a load (16) connected to an electrical network (10), which includes the following stages: a) obtaining a reference value before connecting the load to the network by receiving one or more times a signal from the amplifier output (90u) proportional to the leakage current, without generating a leakage test current; b) generating a test leakage current to check the efficiency and / or calibration, receiving the corresponding proportional signal from the output (90u) of the amplifier as a test value and checking the condition that this test value is in a predetermined range; c) connecting the load to the network, identifying the true leakage currents and generating a signal proportional to them. d) receiving a signal at the output (90u) of the amplifier proportional to the true leakage currents and disconnecting the load (16) from the network (10) when a dangerous condition occurs in which the value of the received signal exceeds the limit value, while the limit value is determined as the absolute value of the difference between the reference value and the verification value 2. The method according to claim 1, characterized in that stage (a) and / or (b) is performed before connecting the load (16) to the network (10). 3. The method according to claim 1 or 2, characterized in that at the stage (a) and / or (b) the condition is checked that the signal value (90u) falls within a predetermined range. 4. The method according to claim 1 or 2, characterized in that the limit value is determined by obtaining the absolute value of the difference between the reference value and the verification value. 5. The method according to claim 3, characterized in that the limit value is determined by obtaining the absolute value of the difference between the reference value and the verification value. 6. The method according to any one of claims 1, 2, 5, characterized in that it further includes a step of a cyclic check, which consists in the fact that after connecting the load (16) to the network (10), leakage currents are detected by generating at least test current. 7. The method according to claim 3, characterized in that it further includes a step of cyclic verification, which consists in the fact that after connecting the load (16) to the network (10), leakage currents are detected by generating at least a test current. 8. The method according to claim 4, characterized in that it further includes a step of cyclic verification, which consists in the fact that after connecting the load (16) to the network (10), leakage currents are detected by generating at least a test current. 9. The method according to claim 6, characterized in that it further includes the step of disconnecting the load (16) from the network (10), when during the stage of cyclic verification of the detection of leakage currents, the maximum value modulo the received proportional signal from the output (90u) of the amplifier is greater than the sum limit and reference values. 10. The method according to claim 7 or 8, characterized in that it further includes the step of disconnecting the load (16) from the network (10), when during the stage of cyclic verification of the detection of leakage currents, the maximum value modulo the received proportional signal from the output (90u) of the amplifier more than the sum of the limiting and reference values. 11. The method according to claim 1, characterized in that it further includes the step of detecting the current, at least in the conductor connected to the load (16), and disconnecting the load (16) when this current exceeds a predetermined threshold value. 12. The method according to claim 11, characterized in that the step of detecting the current, at least in the conductor connected to the load (16), is performed before and / or after connecting the load (16) to the network (10). 13. The device (1) for implementing the method according to claims 1-12, comprising an electrically controlled chopper (20) installed between the network (10) and the load (16), which disconnects the load (16) from the network (10) in the open state and connects in a closed state; means (30) for detecting leakage currents, which generates a signal proportional to these leakage currents; a generator (40) for generating a test leakage current; data processing unit (50) connected to means (30) for detecting leakage currents to obtain a proportional signal, with a generator (40) for controlling it and with a chopper (20) for controlling its opening with a control signal (38) in case of a dangerous condition characterized in that the unit (50) is configured to, when starting up the device, before connecting the load to the network, form a reference value by reading information from the means (30) for detecting the leakage current without generating leakage test currents, and generating test the leakage current by driving the generator (40), and receiving the corresponding proportional signal as a test quantity, and then after connecting the load to the network, receiving a signal proportional to the true leakage currents and disconnecting the load (16) from the mains (10) ) in the event of a dangerous condition in which the given signal exceeds the limit value. 14. The device according to item 13, characterized in that it contains a circuit for generating a stabilized power supply of the data processing unit (50), and this circuit is powered from the mains (10). 15. The device according to item 13, characterized in that the means (30) for detecting leakage currents contains a differential transformer with a core on which a primary winding of conductors (12, 14) that feed the load (16), and a secondary winding (32) are wound , which generates a signal proportional to the current flowing in the primary winding. 16. The device according to item 13, characterized in that the generator (40) contains a resistor (86) connected in series with the triac (88), the connection with which is controlled by a signal (36) supplied from the data processing unit (50), such a serial connection shunts the conductors (12, 14) supplying power to the load (16), with connection points at the output and at the input of the means (30) for detecting leakage currents. 17. The device according to item 13, characterized in that the data processing unit (50) controls visual (112, 114) and / or audible alarms. 18. The device of claim 13, characterized in that the data processing unit (50) is equipped with synchronization means (28, 29) configured to cyclically control the amount of leakage current before and / or after closing the breaker (20). 19. The device according to item 13, characterized in that the data processing unit (50) is equipped with an arithmetic module for comparing the value of the signal obtained by means of detecting leakage currents (30) with previously set or received values in real time. 20. The device according to claim 19, characterized in that the predetermined values are stored in the ROM of the data processing unit (50). 21. The device according to item 13, characterized in that it further comprises means (300, 3001) for detecting currents in at least a conductor connected to the load (16), and this means (300, 3001) generates a signal proportional to this currents, and is connected to the data processing unit (50) to control the operation of the chopper (20) in the event of a dangerous condition. 22. The device according to item 21, characterized in that the data processing unit (50) is connected to a means (300, 3001) for detecting currents in at least a conductor connected with a load (16), or with a chopper (20) to control the operation of the chopper (20) by means of a control signal (38) in case of a dangerous condition. 23. The device according to item 13, characterized in that when starting the unit (50) provides disconnection of the load (16) from the network (10). 24. An electric device equipped with a plug (55) for connecting to an electrical outlet (10), characterized in that it comprises a protection device (1) according to any one of claims 13-23. 25. The electrical appliance according to paragraph 24, characterized in that it is a hairdryer or any other household electrical appliance. 26. A plug for supplying power to electrical devices, characterized in that it comprises a protection device (1) according to any one of claims 13-23.

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