CN211183382U - Leakage protector circuit, chip and leakage protection system thereof - Google Patents

Leakage protector circuit, chip and leakage protection system thereof Download PDF

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Publication number
CN211183382U
CN211183382U CN201922165706.4U CN201922165706U CN211183382U CN 211183382 U CN211183382 U CN 211183382U CN 201922165706 U CN201922165706 U CN 201922165706U CN 211183382 U CN211183382 U CN 211183382U
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signal
leakage
amplifier
filter
protector circuit
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张启东
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Xi'an Guosi Micro Semiconductor Co ltd
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Xi'an Guosi Micro Semiconductor Co ltd
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Abstract

The utility model provides a leakage protector circuit, chip and leakage protection system thereof. The method comprises the following steps: the amplifier is used for amplifying the leakage signal input by sampling and generating an amplified leakage signal; the comparator compares the amplified leakage signal with a reference signal to generate a comparison signal; the high-frequency signal detection module is used for carrying out frequency detection on the leakage signal and generating an indication signal; the signal path selection module outputs a control signal according to the states of the indication signal and the comparison signal; and the multi-pulse output driving module is triggered by the control signal to generate a multi-pulse signal. The utility model has the advantages of it is following: the high-frequency leakage current signal is filtered by adopting a structure of combining a high-frequency signal detection module and an amplifier, the input common mode rejection is high, and the anti-interference capability is strong; the optimized amplifier and the high-frequency signal detection module have small high-frequency node change and strong product consistency.

Description

Leakage protector circuit, chip and leakage protection system thereof
Technical Field
The utility model relates to a power electronic technology field, concretely relates to earth leakage protector circuit, chip and earth leakage protection system thereof.
Background
The leakage protector, called leakage breaker for short, is mainly used for protecting the electric shock of human body with fatal danger when the equipment has leakage fault, has the functions of overload and short circuit protection, can be used for protecting the overload and short circuit of a circuit or a motor, and can also be used for the infrequent switching and starting of the circuit under normal conditions.
The earth leakage protector is mainly realized by a chip comprising a series of circuits with different functions. Earth leakage protectors and electrical switching apparatus including the same are widely used in power supply lines. When the power supply wire leaks electricity, the power supply wire is cut off in time to prevent electric shock accidents.
The leakage protector generally includes a magnetic core around which a winding is wound for sensing a magnetic flux therethrough and generating a sensing signal, and a control circuit for receiving the sensing signal and controlling a protection switch to open or close a power supply line. The control circuit receives and detects the induction signals through the circuit units with different functions and controls the on-off state of the power line through the protection switch according to the detection result.
Taking a common household lighting power supply as an example, under normal conditions, the current passing through a live wire and a zero wire is equal, the magnetic flux passing through a winding is zero, no induction signal is generated, and a control circuit does not work. When the electric leakage phenomenon occurs, the currents in the live wire and the zero line are unequal, so that the magnetic flux passing through the winding is not zero, an induction signal is generated, and after the induction signal is received by the control circuit, the protection switch is controlled to cut off the power supply, so that the electric shock accident is prevented.
The existing leakage protector circuit and the chip thereof have the following defects:
1. the current leakage protection chip circuit adopts a low-bandwidth amplifier to realize the suppression of high-frequency leakage current, but the realization causes the defects of low input common mode suppression and weak interference resistance;
2. the unit gain bandwidth of the low-bandwidth amplifier is greatly influenced by temperature and external voltage, so that the change of a filter node is large, and the consistency of a product is poor;
3. the existing high-frequency leakage current suppression protection chip adopts leakage fault latching, when the leakage occurs, a driving signal is output to be locked, and the mechanism is randomly adhered, so that a power switch or a release coil is burnt.
SUMMERY OF THE UTILITY MODEL
In order to solve the above-mentioned problems,
according to the first aspect of the utility model, the utility model provides a leakage protector circuit,
the concrete technical solution is as follows:
a leakage protector circuit comprising:
the amplifier is used for amplifying the leakage signal input by sampling and generating an amplified leakage signal;
the comparator compares the amplified leakage signal with a reference signal to generate a comparison signal;
the high-frequency signal detection module is used for carrying out frequency detection on the leakage signal and generating an indication signal;
the signal path selection module outputs a control signal according to the states of the indication signal and the comparison signal;
and the multi-pulse output driving module is triggered by the control signal to generate a multi-pulse signal.
Preferably, the leakage signal detected by the high-frequency signal detection module is a leakage signal amplified by the amplifier.
Preferably, the leakage signal detected by the high-frequency signal detection module is a leakage signal input by sampling.
Preferably, the earth leakage protector circuit further comprises a filter;
and the sampled and input leakage signal is filtered by a filter and then amplified by the amplifier.
Further preferably, the filter is a low-pass filter.
Preferably, the amplifier is a fully differential amplifier.
Preferably, the fully differential amplifier is a high bandwidth fully differential amplifier.
Further preferably, the filter is a low-pass filter.
Still further preferably, the low-pass filter is a pi-type structure low-pass filter.
Preferably, the amplifier is a fully differential amplifier.
Further preferably, the fully differential amplifier is a high bandwidth fully differential amplifier.
Further preferably, the fully differential amplifier is a high bandwidth fully differential amplifier with a common mode reference voltage.
Preferably, the comparator is a hysteresis comparator.
Preferably, the signal path selection module is a two-path selector;
two inputs of the two-way selector are respectively a comparison signal and a fixed value signal;
enabling ends of the two selectors are indication signals;
the output of the two-way selector is a control signal.
Further preferably, the fixed value signal is at a high level or a low level.
Further preferably, the high frequency signal detection module is implemented by a high pass filter and a second amplifier.
Still further preferably, the high-pass filter is an analog filter or a digital high-pass filter.
Still further preferably, the high-pass filter is a multi-order high-pass filter.
Still further preferably, the high frequency signal detection module includes an RC filter and a second amplifier;
the RC filter is a high pass filter.
Still further preferably, the RC filter is composed of a resistor R1611 and a capacitor C1611; the input is connected with the positive phase input end of the second amplifier after passing through the RC filter;
the input is connected with the positive phase input end of the second amplifier after passing through a capacitor C1611; one end of the resistor R1611 is connected with the non-inverting input end of the second amplifier, and the other end of the resistor R1611 is connected with the second common-mode voltage; the inverting input and the output of the second amplifier are connected as an indication signal.
Still further preferably, the high frequency signal detection module includes an RC filter and a third amplifier;
the RC filter is a high-pass filter;
the RC filter comprises two RC filters, and the two RC filters form a two-order filter.
According to the utility model discloses a second aspect, the utility model provides a leakage protection chip
The concrete technical solution is as follows:
the leakage protection chip composed of the leakage protector circuit samples the input leakage signal and inputs the leakage signal through the input pins IN1 and IN 2.
Preferably, the chip further comprises an overvoltage protection module and an over-temperature protection module.
Preferably, the capacitor and/or the resistor of the high-pass filter of the high-frequency signal detection module in the chip are/is realized in an external chip connection mode.
According to the utility model discloses a second aspect, the utility model provides an earth leakage protection system
The concrete technical solution is as follows:
IN the leakage protection system composed of the leakage protection chip, the winding coil samples leakage of a power line, and a sampled leakage signal is input into the chip through two pins IN1 and IN2 of the chip.
Preferably, the leakage protector chip controls the power supply state of the power line through the controllable unit control switch.
Further preferably, the controllable unit is a thyristor.
Still further preferably, the controllable unit is a high-voltage MOS transistor, silicon carbide SiC or IGBT.
The utility model has the advantages of it is following:
the high-frequency leakage current signal is filtered by adopting a structure of combining a high-frequency signal detection module and an amplifier, the input common mode rejection is high, and the anti-interference capability is strong;
the optimized amplifier and the high-frequency signal detection module have small high-frequency node change and strong product consistency.
Drawings
Fig. 1 the utility model relates to a leakage protector circuit schematic diagram mode one.
Fig. 2 the utility model relates to a leakage protector circuit schematic diagram mode two.
Fig. 3 is a schematic diagram of an amplifier in a leakage protector circuit.
Fig. 4 is a schematic diagram of a signal path selection module in a leakage protector circuit.
Fig. 5 shows one of the schematic diagrams of the high frequency signal detection module in the circuit of the leakage protector.
Fig. 6 is a schematic diagram of a high frequency signal detection module in a leakage protector circuit according to the present invention.
Fig. 7 shows one of the first embodiments of the leakage protector circuit of the present invention.
Fig. 8 is a second schematic diagram of a first embodiment of a leakage protector circuit according to the present invention.
Fig. 9 is a schematic diagram of a second embodiment of a leakage protector circuit according to the present invention.
Fig. 10 is a second schematic diagram of a second embodiment of a leakage protector circuit according to the present invention.
Detailed Description
The present invention will be described in more detail and fully with reference to the following examples and accompanying drawings.
The utility model discloses mainly adopt the structure that high frequency signal detection and amplifier combined together to realize the filtering to the high frequency leakage current signal.
The main principle of the utility model is that:
the signal after sampling the leakage current is amplified by the amplifier, judged by the comparator and then passes through the signal path selection module; meanwhile, the frequency of the sampling signal is monitored through a high-frequency signal detection module; the output of the high-frequency signal detection module is connected with the signal path selection module; and the signal path selection module controls the multi-pulse output driving module according to the states of the comparator and the high-frequency signal detection module.
The frequency of the high-frequency signal detection module for monitoring the sampling signal can be carried out in two modes, which are respectively:
and monitoring the frequency of the signal amplified by the amplifier or before amplification.
The above cases will be described separately below.
The first method is as follows: and (3) carrying out frequency monitoring on the signal before being amplified by the amplifier:
fig. 1 shows one schematic diagram of a leakage protector circuit according to the present invention, which includes a filter 11, an amplifier 12, a comparator 13, a signal path selection module 14, a multi-pulse output driving module 15, and a high-frequency signal detection module 16.
The filter 11, the amplifier 12, the comparator 13, the signal path selection module 14 and the multi-pulse output driving module 15 are connected in sequence; the output of the filter 11 is also connected to a high frequency signal detection module 16, and the output of the high frequency signal detection module 16 is connected to the signal path selection module 14.
It should be noted that the amplifier 12 is a fully differential amplifier, which can have better interference rejection capability. The further fully differential amplifier is a high bandwidth fully differential amplifier.
Amplifier 12 is implemented using a fully differential amplifier with a common mode reference voltage as shown. The amplifier has the characteristics of high common mode rejection, strong anti-interference capability and the like.
After the leakage current signal after sampling the leakage current is filtered by the filter 11: and simultaneously respectively output to the amplifier 12 or the high-frequency signal detection module 16; the amplifier 12 outputs the amplified leakage signal to the comparator 13, and the comparator 13 compares the amplified leakage signal with the reference signal to determine and outputs a comparison signal to the signal path selection module 14.
Here:
the comparator 13 determines the presence or absence of an input leakage current by comparison with a reference signal;
the high-frequency signal detection module 16 detects the frequency of the leakage signal sampled and input, and generates an indication signal to output to the path selection module 14;
when the comparator 13 detects the presence of a leakage current, a drive signal is generated. Meanwhile, if the leakage frequency is larger than the set value, the output drive is turned off, otherwise, the drive signal is generated.
The second method comprises the following steps: and monitoring the frequency of the signal amplified by the amplifier.
As shown in fig. 2, the schematic diagram of a leakage protector of the present invention includes a filter 11, an amplifier 12, a comparator 13, a signal path selection module 14, a multi-pulse output driving module 15, and a high-frequency signal detection module 16 similar to fig. 1. The filter 11, the amplifier 12, the comparator 13, the signal path selection module 14 and the multi-pulse output driving module 15 are connected in sequence.
The difference from fig. 1 is: the output of the amplifier 12 is also connected to a high frequency signal detection module 16, and the output of the high frequency signal detection module 16 is connected to the signal path selection module 14. Namely: here, the high frequency signal detection module 16 detects the leakage signal as a leakage signal amplified by the amplifier 12.
Also, the amplifier 12 is a fully differential amplifier, which can have better interference rejection. The further fully differential amplifier is a high bandwidth fully differential amplifier.
The signals sampled by the leakage current pass through an amplifier 12 and are simultaneously and respectively output to a comparator 13 or a high-frequency signal detection module 16; the comparator 13 outputs the result to the signal path selection module 14 after judgment.
Also, here:
the comparator 13 determines the presence or absence of an input leakage current by comparison with a reference signal;
the high-frequency signal detection module 16 detects the frequency of the leakage signal amplified by the amplifier 12, and generates an indication signal to output to the channel selection module 14;
when the existence of the leakage is detected, a driving signal is generated. Meanwhile, if the leakage frequency is larger than the set value, the output drive is turned off, otherwise, the drive signal is generated.
The difference between the two implementations of fig. 1 and 2 is: the input to the high frequency signal detection module 16 is the output from either the filter 11 or the amplifier 12. That is, the high-frequency signal detection module 16 directly detects the leakage signal input by sampling, or detects the leakage signal amplified by the amplifier.
In fig. 2, the input of the high frequency signal detection module 16 is the output from the amplifier 12, that is, the leakage signal amplified by the amplifier is detected. In this case, the requirement for the accuracy of the high-frequency signal detection module 16 is reduced, the circuit is simplified, and the cost is saved. Meanwhile, port multiplexing can be carried out, and the flexibility is improved.
Here too, particular emphasis is to be placed on: the filter 11 in the above two modes is not necessary, but the signal obtained by filtering the leakage signal sampled and input by the filter 11 is less noisy and is more beneficial to subsequent processing.
The above modules are described separately below.
The filter 11:
the filter 11 is a low-pass filter, mainly for filtering low-frequency noise and signals, and its structure will not be described in detail here.
The amplifier 12:
as mentioned above, the amplifier 12 is a fully differential amplifier for better noise immunity. The further fully differential amplifier is a high bandwidth fully differential amplifier. Amplifier 12 is implemented using a fully differential amplifier with a common mode reference voltage as shown. The amplifier has the characteristics of high common mode rejection, strong anti-interference capability and the like.
As shown in fig. 3, the amplifier 12 has a first common mode voltage of the common mode reference voltage; the amplifier comprises a dual-input dual-output amplifier 121, a dual-input single-output amplifier 122, resistors R1211, R1212 and R1213, and resistors R1221, R1222 and R1223; the input signal of the amplifier (i.e. the leakage signal of the sampling input or the leakage signal filtered by the filter 11).
The positive pole of the input signal is connected with the first common mode voltage and the input positive phase end of the amplifier 121 through resistors R1211 and R1212 respectively; two ends of the resistor R1213 are respectively connected with the input positive phase end and the output positive phase end VM + of the amplifier 121; the output positive phase end VM + of the amplifier 121 is connected with the input positive phase end of the amplifier 122;
symmetrical:
the negative pole of the input signal is connected with the first common mode voltage and the input negative phase end of the amplifier 121 through resistors R1221 and R1222 respectively; two ends of the resistor R1223 are respectively connected with the input negative phase end and the output negative phase end VM < - >, of the amplifier 121; the output negative terminal VM of the amplifier 121 is connected to the input negative terminal of the amplifier 122;
the output terminal of the amplifier 122 serves as the output terminal of the amplifier 12 to output the amplified leakage signal.
The comparator 13:
the comparator 13 may be a general-purpose conventional comparator, and will not be described in detail here. It should be noted that in order to detect the leakage, the reference signal of the comparator needs to be selected and determined properly.
Signal path selection module 14:
fig. 4 shows the schematic diagram of the signal path selection module in the circuit of the leakage protector of the present invention: here the signal path selection module 14 is a two-way selector: the two inputs are respectively a comparison signal (generated by the comparator 13), a fixed value signal; the enabling end of the two-way selector is an indication signal (generated by the high-frequency signal detection module 16); the output of the two-way selector is a control signal (output to the multi-pulse output driving module 15).
In normal operation, if the high-frequency signal detection module 16 does not detect a high-frequency signal, and the comparator 13 detects the existence of input leakage by comparing with the reference signal; the two-way selector selects the comparison signal as an output signal (control signal), the control signal is output to the multi-pulse output driving module 15, and the output signal of the multi-pulse output driving module 15 cuts off a power supply loop through a switch. Otherwise, the power supply is kept.
If the high-frequency signal detection module 16 detects a high-frequency signal, no matter whether the comparator 13 detects the existence of electric leakage, the control signals of the two selectors select a fixed value as an output signal (control signal), the control signal is output to the multi-pulse output driving module 15, and the output signal of the multi-pulse output driving module 15 cuts off a power supply loop through a switch. Otherwise, the power supply is kept.
The fixed value here is a preset value, and may be a high level or a low level, and is set according to actual needs as long as the aforementioned switching-off of the power supply loop through the multi-pulse output driving module 15 is satisfied.
The multi-pulse output driving module 15:
the multi-pulse output driving module 15 is a conventional general-purpose module, and will not be described in detail here.
The high-frequency signal detection module 16:
the high frequency signal detection module 16 is implemented by a high pass filter and an amplifier, and the high pass filter may be an analog filter or a digital high pass filter. The high-pass filter may be a multiple order high-pass filter.
As shown in fig. 5, which is one of the schematic diagrams of the high frequency signal detection module in the leakage protector circuit of the present invention, the high frequency signal detection module generally includes an RC filter 161 (shown by a dashed box in the figure) and an amplifier 162; the RC filter 161 is a high pass filter; the RC filter 161 is composed of a resistor R1611 and a capacitor C1611; the input is connected with the non-inverting input terminal of the amplifier 162 after passing through the RC filter 161; the specific input is connected to the non-inverting input terminal of the amplifier 162 through the capacitor C1611; one end of the resistor R1611 is connected to the non-inverting input terminal of the amplifier 162, and the other end of the resistor R1611 is connected to the second common mode voltage; the inverting input and output of amplifier 162 are connected as an indication signal.
It should be noted that the capacitor C1611 may also be considered as an input capacitor, and in an actual circuit or in a chip, the capacitance may be generally implemented by an external capacitor, so that the external capacitor may perform capacitance value adjustment, thereby increasing flexibility. The resistor R1611 may be implemented by an external resistor. This also increases flexibility.
The threshold of the frequency can be adjusted.
Fig. 6 is a schematic diagram of a high frequency signal detection module in a leakage protector circuit according to a second embodiment of the present invention, which includes two RC filters respectively composed of a resistor R1621 and a capacitor C1621; a resistor R1622 and a capacitor C1622; the RC filter is a high pass filter. The two RC filters constitute a two-order filter. The RC filter of fig. 6 is connected differently from that of fig. 5 and will not be described in detail here. It should be emphasized, however, that both the resistor and the capacitor may be connected externally. This allows the threshold of the frequency to be adjusted, which may increase flexibility.
The high pass filter in the high frequency signal detection module can be connected in various combinations, which will not be described in detail here.
The application of the present invention to a chip will be described below with reference to two specific embodiments, which correspond to the different circuit modes (mode one and mode two) described above. Each mode corresponds to the chip structure and the application of the chip.
The first embodiment is as follows:
the embodiment corresponds to the first method (frequency monitoring of the signal before amplification by the amplifier). Fig. 7 shows one of the schematic diagrams of a first embodiment of a leakage protector circuit of the present invention, where fig. 7 shows an implementation of a first leakage protector circuit mode in a chip of the present invention. Corresponding to the first mode, it can be seen from the figure that two input pins IN1 and IN2 of the chip are respectively connected to the filter, the amplifier, the comparator, the signal path selection module, and the multi-pulse output driving module IN sequence; meanwhile, the high-frequency signal detection module is connected behind the filter and used for detecting the filtered leakage signal. The two input pins IN1 and IN2 are used to input the leakage signal after sampling.
Here, it should be specifically noted that:
the filter (low pass filter) here adopts a pi-type structure, which can better filter out noise, but the filter may also have other implementation manners, which is only a preferred embodiment here.
The comparator is a hysteresis comparator, which has the advantage that the characteristics of the hysteresis comparator can be utilized to have good anti-interference capability while comparing and detecting.
In order to make the chip work well, other functional modules are also included in the chip: overvoltage protection, over-temperature protection, power-on reset, voltage reference, reference current, regulated power supply, oscillator and the like.
The overvoltage protection and over-temperature protection module aims to protect the chip safety after the voltage and the temperature exceed preset values; the voltage reference, the reference current and the stabilized voltage power supply module are used for providing current and voltage for normal operation and the like for the chip; the oscillator is used to provide a normal operating clock for the corresponding module. The power-on reset module is used for enabling the chip to carry out reset operation.
Fig. 8 is a second schematic diagram of a first embodiment of a leakage protector circuit according to the present invention, which is applied to the chip in fig. 7. As can be seen from fig. 8: the power supply line is sampled for leakage by the winding coil 17, and the leakage signal after sampling is input to the chip through two pins IN1 and IN 2. If the condition of detecting the electric leakage is met, the pin OS of the chip of the leakage protector controls the switch 19 through the controllable silicon 18 to finally cut off the power supply of the power line.
It should also be emphasized here that the thyristor 18 is only a preferred embodiment, and may also be a high-voltage MOS transistor, silicon carbide SiC, or IGBT, for example.
The second embodiment is as follows:
here, the embodiment corresponds to the second method (frequency monitoring of the signal amplified by the amplifier).
Fig. 9 is a schematic diagram of a second embodiment of the leakage protector circuit according to the present invention, which is different from the second embodiment in that the high-frequency signal detection module is not directly connected to the output of the filter, and here, the leakage signal amplified by the amplifier is output to the high-frequency signal detection module.
Here, it should be noted that: the amplifier is not directly connected with the high-frequency signal detection module in the figure; but is connected to pin OA, and the input of the high frequency signal detection module is accessed through pin NR; as mentioned above, in order to increase the flexibility of the high frequency signal detection module in detecting the frequency, the threshold of the frequency is adjusted. The input capacitor of the high-pass filter in the high-frequency signal detection module is externally connected, and the external connection capacitor is realized through a pin OA and a pin NR. Other modules and their connections similar to the embodiments described herein will not be described in detail. It is to be understood that in the embodiments, a high frequency signal detection module may also be implemented in a manner similar to an external capacitor resistor, which is not described in detail herein.
Fig. 10 is a second schematic diagram of a second embodiment of the leakage protector circuit according to the present invention, for the application of the chip in fig. 9. As shown. As can be seen from fig. 10: the external capacitor C16 is connected via pin OA and pin NR. Of course, in other specific applications, the resistor or the combination of the capacitor and the resistor can be externally connected according to the situation. The flexibility of the detection frequency of the high-frequency signal detection module can be improved, and the type and the size of the capacitor and/or the resistor can be flexibly selected in an external connection mode. Similarly, other modules and their connections similar to the embodiments described herein will not be described in detail.
Compared with the prior art:
the utility model adopts the structure of combining the high-frequency signal detection module and the amplifier to realize the filtering of high-frequency leakage current signals, and has high input common mode rejection and strong anti-interference capability; meanwhile, the optimized amplifier and the high-frequency signal detection module are small in high-frequency node change and strong in product consistency.

Claims (25)

1. An electrical leakage protector circuit, comprising:
the amplifier is used for amplifying the leakage signal input by sampling and generating an amplified leakage signal;
the comparator compares the amplified leakage signal with a reference signal to generate a comparison signal;
the high-frequency signal detection module is used for carrying out frequency detection on the leakage signal and generating an indication signal;
the signal path selection module outputs a control signal according to the states of the indication signal and the comparison signal;
and the multi-pulse output driving module is triggered by the control signal to generate a multi-pulse signal.
2. The earth leakage protector circuit of claim 1,
the leakage signal detected by the high-frequency signal detection module is the leakage signal amplified by the amplifier.
3. The earth leakage protector circuit of claim 1,
the leakage signal detected by the high-frequency signal detection module is a sampling input leakage signal.
4. The earth leakage protector circuit of claim 1,
the leakage protector circuit further comprises a filter;
and the sampled and input leakage signal is filtered by a filter and then amplified by the amplifier.
5. The earth leakage protector circuit of claim 4,
the filter is a low pass filter.
6. The earth leakage protector circuit of claim 5,
the low-pass filter is a low-pass filter with a pi-shaped structure.
7. The earth leakage protector circuit of claim 1,
the amplifier is a fully differential amplifier.
8. The earth leakage protector circuit of claim 7,
the fully differential amplifier is a high bandwidth fully differential amplifier.
9. The earth leakage protector circuit of claim 8,
the fully-differential amplifier is a high-bandwidth fully-differential amplifier with a common-mode reference voltage.
10. The earth leakage protector circuit of claim 1,
the comparator is a hysteresis comparator.
11. The earth leakage protector circuit of claim 1,
the signal path selection module is a two-path selector;
two inputs of the two-way selector are respectively a comparison signal and a fixed value signal;
enabling ends of the two selectors are indication signals;
the output of the two-way selector is a control signal.
12. The earth leakage protector circuit of claim 11,
the fixed value signal is high or low.
13. The earth leakage protector circuit of claim 11,
the high-frequency signal detection module is realized by a high-pass filter and a second amplifier.
14. The earth leakage protector circuit of claim 13,
the high-pass filter is an analog filter or a digital high-pass filter.
15. The earth leakage protector circuit of claim 13,
the high-pass filter is a multi-order high-pass filter.
16. The earth leakage protector circuit of claim 13,
the high-frequency signal detection module comprises an RC filter and a second amplifier;
the RC filter is a high pass filter.
17. The earth leakage protector circuit of claim 16,
the RC filter consists of a resistor R1611 and a capacitor C1611; the input is connected with the positive phase input end of the second amplifier after passing through the RC filter;
the input is connected with the positive phase input end of the second amplifier after passing through a capacitor C1611; one end of the resistor R1611 is connected with the non-inverting input end of the second amplifier, and the other end of the resistor R1611 is connected with the second common-mode voltage; the inverting input and the output of the second amplifier are connected as an indication signal.
18. The earth leakage protector circuit of claim 13,
the high-frequency signal detection module comprises an RC filter and a third amplifier;
the RC filter is a high-pass filter;
the RC filter comprises two RC filters, and the two RC filters form a two-order filter.
19. A leakage protection chip is characterized in that,
the earth leakage protection chip is composed of the earth leakage protector circuit of any one of claims 1-18;
the leakage signal of the sampling input is input through the input pins IN1 and IN 2.
20. A leakage protection chip as claimed in claim 19,
the chip also comprises an overvoltage protection module and an over-temperature protection module.
21. A leakage protection chip as claimed in claim 19,
and the capacitor and/or the resistor of the high-pass filter of the high-frequency signal detection module in the chip are/is realized in an external chip connection mode.
22. An earth leakage protection system is characterized in that,
the earth leakage protection system is composed of the earth leakage protection chip of any one of claims 19-21;
the power line is sampled for leakage through the winding coil, and the leakage signal after sampling is input into the chip through two pins IN1 and IN2 of the chip.
23. A residual current protection system as claimed in claim 22,
the leakage protector chip controls the power supply state of the power line through the controllable unit control switch.
24. A residual current protection system as claimed in claim 23,
the controllable unit is a silicon controlled rectifier.
25. A residual current protection system as claimed in claim 23,
the controllable unit is a high-voltage MOS tube, silicon carbide SiC or IGBT.
CN201922165706.4U 2019-12-05 2019-12-05 Leakage protector circuit, chip and leakage protection system thereof Active CN211183382U (en)

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Application Number Priority Date Filing Date Title
CN201922165706.4U CN211183382U (en) 2019-12-05 2019-12-05 Leakage protector circuit, chip and leakage protection system thereof

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201922165706.4U CN211183382U (en) 2019-12-05 2019-12-05 Leakage protector circuit, chip and leakage protection system thereof

Publications (1)

Publication Number Publication Date
CN211183382U true CN211183382U (en) 2020-08-04

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Application Number Title Priority Date Filing Date
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