CN114336532B - Sampling resistor short-circuit protection method - Google Patents

Sampling resistor short-circuit protection method Download PDF

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Publication number
CN114336532B
CN114336532B CN202110248483.7A CN202110248483A CN114336532B CN 114336532 B CN114336532 B CN 114336532B CN 202110248483 A CN202110248483 A CN 202110248483A CN 114336532 B CN114336532 B CN 114336532B
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circuit
sampling resistor
signal
sampling
switch
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CN114336532A (en
Inventor
陈伟
张洞田
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Shenzhen Injoinic Technology Co Ltd
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Shenzhen Injoinic Technology Co Ltd
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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02JCIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
    • H02J7/00Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
    • H02J7/0029Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries with safety or protection devices or circuits
    • H02J7/00304Overcurrent protection
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02HEMERGENCY PROTECTIVE CIRCUIT ARRANGEMENTS
    • H02H3/00Emergency protective circuit arrangements for automatic disconnection directly responsive to an undesired change from normal electric working condition with or without subsequent reconnection ; integrated protection
    • H02H3/08Emergency protective circuit arrangements for automatic disconnection directly responsive to an undesired change from normal electric working condition with or without subsequent reconnection ; integrated protection responsive to excess current
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M3/00Conversion of dc power input into dc power output
    • H02M3/22Conversion of dc power input into dc power output with intermediate conversion into ac
    • H02M3/24Conversion of dc power input into dc power output with intermediate conversion into ac by static converters
    • H02M3/28Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac
    • H02M3/325Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal
    • H02M3/335Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal using semiconductor devices only
    • H02M3/33569Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal using semiconductor devices only having several active switching elements
    • H02M3/33576Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal using semiconductor devices only having several active switching elements having at least one active switching element at the secondary side of an isolation transformer
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B70/00Technologies for an efficient end-user side electric power management and consumption
    • Y02B70/10Technologies improving the efficiency by using switched-mode power supplies [SMPS], i.e. efficient power electronics conversion e.g. power factor correction or reduction of losses in power supplies or efficient standby modes

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Dc-Dc Converters (AREA)

Abstract

The invention provides a sampling resistor short-circuit protection method, which comprises the steps that a switch control circuit is used for periodically sending out a first on signal and a first off signal; detecting a first sampling electric signal of a sampling circuit, collecting a first on signal and a first off signal of a switch control circuit, obtaining a switching cycle and a switching time of the switch control circuit according to the first on signal and the first off signal, judging whether the circuit enters a sampling resistor short-circuit protection state according to the switching cycle, the switching time and the first sampling electric signal, and outputting the first switch control signal for a transmission path switch according to a judging result. The invention can conveniently and effectively provide short-circuit protection control of the circuit.

Description

Sampling resistor short-circuit protection method
Technical Field
The invention relates to the technical field of charge protection, in particular to a sampling resistor short-circuit protection method.
Background
With the wide application of the fast-charging technology, the safety requirements of the market on electronic products with the fast-charging function are higher and higher, the protection functions of charging equipment such as mobile phones and the specification requirements of protocols are more and more strict, for example, the requirements of LPS (limited power supply) are regulated in the IEC60950-1 standard, the LPS requirements can be used for defining a power supply with relatively low highest voltage, current and capacitance, and the LPS power supply brings the advantages for customers that a system installer only needs to observe relatively loose requirements when wiring and installing loads powered by an LPS authentication power supply in the field.
For meeting the LPS requirement, the LPS power supply is required to have limitation when delivering output current and voltage to a load, the delivered output current and voltage are required to be stable, and the abnormality such as over high or over low cannot be generated. In the current control technology for output current, the voltage difference between two ends of a sampling resistor Rs is detected by an AC-DC control chip to directly detect the output current, and the output power is controlled by a primary PWM duty ratio; if the sampling resistor Rs is short-circuited, the AC-DC control chip enters a protection state when the primary PWM changes beyond a certain ratio, and the maximum output current is limited by controlling the working state of the main power switch circuit; if the sampling resistor Rs is operating normally, the maximum output current will be limited by controlling the current through the sampling resistor Rs. The method adopts difficult technical means, has complex control method, is not convenient to process and has high cost.
Disclosure of Invention
The invention aims to provide a sampling resistor short-circuit protection circuit and method and a fast charging charger, which can conveniently and effectively provide short-circuit protection control of the circuit.
In a first aspect, a sampling resistor short-circuit protection circuit is provided, for a fast charging charger, the sampling resistor short-circuit protection circuit includes a switch control circuit, a logic control circuit, a detection sampling circuit, and a transmission path switch, the logic control circuit is electrically connected with the switch control circuit, the detection sampling circuit, and the transmission path switch, respectively, wherein:
The switch control circuit comprises a switch module and a switch control module, the switch control module is used for controlling the on-off of the switch module, the logic control circuit is internally arranged in a quick-charge chip, the detection sampling circuit comprises a sampling resistor, the switch module is electrically connected with the switch control module, the switch module is electrically connected with the sampling resistor, the switch control module is electrically connected with the logic control circuit, and the logic control circuit is connected with two ends of the sampling resistor in parallel;
the switch control circuit: for periodically emitting a first on signal and a first off signal;
the logic control circuit: a first sampling electric signal for detecting the detection sampling circuit, and a first switching-on signal and a first switching-off signal for collecting the switch control circuit, and for detecting the first sampling electric signal and the first switching-on signal according to the first switching-on signal and the first switching-off signalA turn-off signal to obtain the switching period T and the turn-on time T of the switch control circuit on And for controlling the on-time T according to the switching period T on And the first sampling electric signal judging circuit is used for judging whether the first sampling electric signal enters a sampling resistor short-circuit protection state or not and outputting a first switch control signal for the transmission path switch corresponding to the sampling resistor according to the judging result.
In one implementation, the switch module is a synchronous rectification switch, the switch control module is a synchronous rectification controller, and the synchronous rectification controller is configured to periodically send a first on signal and a first off signal to the synchronous rectification switch, where a time difference between the first off signal and the first on signal in the same period is the on time t on The time difference between the first conduction signals of two adjacent periods is the switching period T.
In one implementation manner, the synchronous rectification switch is a first NMOS transistor, a gate of the first NMOS transistor is electrically connected to the synchronous rectification controller, the first on signal is a rising edge signal, and the first off signal is a falling edge signal.
In one implementation, the sampling resistor short-circuit protection circuit further comprises a secondary power module, a charging capacitor and an output load of a fast charging port, the secondary power module, the charging capacitor and the synchronous rectification switch form a first power transmission loop, and the transmission path switch, the output load, the sampling resistor and the charging capacitor form a second power transmission loop.
In one implementation manner, the first sampled electrical signal is an output sampled current Io, the transmission path switch is a second NMOS tube, the logic control circuit includes a sampling detection module, a time detection module and a judgment module, the sampling detection module includes an amplifier and an analog-digital converter, the amplifier is connected in parallel to two ends of the sampling resistor, the analog-digital converter is electrically connected with the amplifier, the judgment module is electrically connected with the analog-digital converter, the time detection module is respectively electrically connected with the switch control circuit and the judgment module, and the judgment module is electrically connected with a gate of the second NMOS tube, wherein:
the sampling detection module is used for detecting the output sampling current Io by detecting the voltage difference value between two ends of the sampling resistor and outputting the output sampling current Io to the judgment module;
the time detection module is used for collecting the first on signal and the first off signal of the switch control circuit and obtaining the switching period T and the switching time T of the switch control circuit according to the first on signal and the first off signal on And for sending the switching period T and the on-time T to the determination module on
The judging module is used for receiving the switching period T and the conduction time T on And the output sampling current Io according to the switching period T and the on time T on And the output sampling current Io judging circuit is in a sampling resistor short-circuit protection state or not, and a first switch control signal for the transmission path switch is output according to the judging result.
In one implementation, the on-time T is determined in accordance with the switching period T on And the output sampling current Io judging circuit is configured to determine whether the circuit enters a sampling resistor short-circuit protection state, and output a first switch control signal for the transmission path switch according to the judging result, where the judging module is specifically configured to: when it is judged thatWhen the counter is incremented by one; when the value of the counter is greater than or equal to a first preset number of times N1, the determining circuit enters a sampling resistor short-circuit protection state, and outputs a first switch control signal, wherein the first switch control signal is used for controlling the switch of the transmission path to be switched to an off state.
In one implementation, the The method is based on the following steps:
executing an energy conservation law and an inductive current segmentation equation on the first power transmission loop and the second power transmission loop to obtain a first equation set;
analyzing the first equation set to obtain a first discriminant, wherein the first discriminant is used for enabling the sampling resistor to be in a normal state when the first discriminant is established;
obtaining according to the first discriminantWherein the first system of equations is:
the first discriminant is:
wherein I is A Is the direct current component of the inductor current.
In one implementation, the on-time T is determined in accordance with the switching period T on And the output sampling current Io judging circuit is configured to determine whether the circuit enters a sampling resistor short-circuit protection state, and output a first switch control signal for the transmission path switch according to the judging result, where the judging module is specifically configured to: when it is judged thatWhen the counter is incremented by one; when the value of the counter is greater than or equal to a first preset number of times N1, the determining circuit enters a sampling resistor short-circuit protection state, and outputs a first switch control signal, wherein the first switch control signal is used for controlling the switch of the transmission path to be switched to an off state.
Wherein A isThe error coefficient has a value range of 5% -95%; v (V) 0 For the voltage across the output load, the L s And the inductance is corresponding to the secondary power supply module.
In one implementation, the sampling resistor short-circuit protection circuit further comprises a primary power supply module, a primary path switch and a flyback converter primary inductance, wherein the primary power supply module, the primary path switch and the flyback converter primary inductance form a third power transmission loop, the secondary power supply module is a flyback converter secondary inductance, and the flyback converter primary inductance is used for supplying power to the protection circuit through the flyback converter secondary inductance.
In a second aspect, a fast charging charger is provided, the fast charging charger includes a sampling resistor short-circuit protection circuit, the sampling resistor short-circuit protection circuit includes a switch control circuit, a logic control circuit, a detection sampling circuit, and a transmission path switch, the logic control circuit is electrically connected with the switch control circuit, the detection sampling circuit, and the transmission path switch, respectively, wherein: the switch control circuit comprises a switch module and a switch control module, the switch control module is used for controlling the on-off of the switch module, the logic control circuit is internally arranged in a quick-charge chip, the detection sampling circuit comprises a sampling resistor, the switch module is electrically connected with the switch control module, the switch module is electrically connected with the sampling resistor, the switch control module is electrically connected with the logic control circuit, and the logic control circuit is connected with two ends of the sampling resistor in parallel; the switch control circuit: for periodically emitting a first on signal and a first off signal; the logic control circuit: the first sampling electric signal used for detecting the detection sampling circuit, the first conduction signal and the first turn-off signal used for collecting the switch control circuit, and the first sampling electric signal used for obtaining the switch period T and the switch time T of the switch control circuit according to the first conduction signal and the first turn-off signal on And for controlling the on-time T according to the switching period T on And the first sampled electrical signal judgment circuit isAnd whether the sampling resistor is in a short-circuit protection state or not, and outputting a first switch control signal for the transmission path switch corresponding to the sampling resistor according to the judging result.
In one implementation manner, the fast charging charger includes a fast charging chip, a micro control unit MCU is built in the fast charging chip, the MCU includes the sampling resistor short-circuit protection circuit according to the first aspect, and the fast charging chip is a charging chip supporting fast charging.
In a third aspect, a sampling resistor short-circuit protection method is provided, which is applied to the sampling resistor short-circuit protection circuit described in the first aspect, and includes: collecting a first on signal and a first off signal of a switch control circuit through a logic control circuit; determining a switching period T and a switching time T of the switching control circuit according to the first switching-on signal and the first switching-off signal by the logic control circuit on The method comprises the steps of carrying out a first treatment on the surface of the Acquiring a first sampling electric signal of a sampling resistor through the logic control circuit; according to the switching period T and the on time T by the logic control circuit on Determining a first switch control signal of a transmission path switch corresponding to the sampling resistor by a micro control unit of the fast charging chip according to the first sampling electric signal; transmitting the first switch control signal to the transmission path switch through the micro control unit; and receiving the first switch control signal through the transmission path switch, and executing an operation corresponding to the first switch control signal.
In one implementation, the first sampled electrical signal is an output sampled current Io, and the logic control circuit is configured to control the logic circuit according to the switching period T and the on-time T on And determining, by the micro control unit of the fast charging chip, a first switch control signal of a transmission path switch corresponding to the sampling resistor according to the first sampled electrical signal, where the first switch control signal includes: the logic control circuit controls the switching period T and the on time T on Calculating the output sampling current Io to obtain a first numerical result; the logic control circuit outputs the voltage V at two ends of the load to the quick charge port 0 And sampling electricityInductance L corresponding to secondary power supply module of flyback converter of resistive short-circuit protection circuit s Calculating to obtain a second numerical result; judging the relation between the first numerical result and the second numerical result in the switching period of the same switching control circuit through the logic control circuit, if the first numerical result is smaller than the second numerical result, adding one count by a counter, wherein each count of the counter corresponds to one switching period of the switching control circuit; when the count number of the counter reaches a first preset number N1, determining the first switch control signal for the transmission path switch.
In one implementation, the first sampled electrical signal is an output sampled current Io, and the logic control circuit is configured to control the logic circuit according to the switching period T and the on-time T on And determining, by the micro control unit of the fast charging chip, a first switch control signal of a transmission path switch corresponding to the sampling resistor according to the first sampled electrical signal, where the first switch control signal includes: the logic control circuit controls the switching period T and the on time T on Calculating the output sampling current Io to obtain a first numerical result; the logic control circuit outputs the voltage V at two ends of the load to the quick charge port 0 Inductance L corresponding to flyback converter secondary power supply module of sampling resistor short-circuit protection circuit s Calculating to obtain a second numerical result; multiplying the second numerical result by an error coefficient through the logic control circuit to obtain a third numerical result, wherein the value range of the error coefficient is 5% -95%; judging the relation between the first numerical result and the third numerical result in the switching period of the same switching control circuit through the logic control circuit, and adding a count by a counter if the first numerical result is smaller than the third numerical result; when the count number of the counter reaches a first preset number N1, determining the first switch control signal for the transmission path switch.
In one implementation, the logic control circuit controls the switching period T and the on time T on And the describedThe output sampling current Io is calculated to obtain a first numerical result, which comprises the following steps: the logic control circuit controls the switching period T and the on time T on And executing a first operation formula on the output sampling current Io to obtain a first numerical result, wherein the first operation formula is that
In one implementation, the logic control circuit outputs the voltage V across the load to the fast charge port 0 Inductance L corresponding to flyback converter secondary power supply module of sampling resistor short-circuit protection circuit s Calculating to obtain a second numerical result, including: the logic control circuit outputs the voltage V at two ends of the load to the quick charge port 0 Inductance L corresponding to flyback converter secondary power supply module of sampling resistor short-circuit protection circuit s Executing a second operation formula to obtain a second numerical result, wherein the second operation formula
In one implementation, the first and second formulas are derived based on the following procedure: executing an energy conservation law and an inductive current segmentation equation on the first power transmission loop and the second power transmission loop to obtain a first equation set; analyzing the first equation set to obtain a first discriminant, wherein the first discriminant is used for enabling the sampling resistor to be in a normal state when the first discriminant is established; obtaining the first operation formula and the second operation formula according to the first discriminant; wherein the first system of equations is:
The first discriminant is:
wherein I is A Is the direct current component of the inductor current.
In one implementation, after outputting, by the logic control circuit, a first switch control signal for a transmission path switch corresponding to the sampling resistor, the method further includes: resetting the counter, and adding the counter once every clock period of the logic control circuit when the transmission path switch is in an off state; when the counting times of the counter reach a second preset times N2, outputting a second switch control signal of the transmission path switch through the logic control circuit, resetting a protection state of the sampling resistor, and controlling the transmission path switch to be switched to a channel state by the second switch control signal.
It can be seen that, in this embodiment of the present application, the logic control circuit in the sampling resistor short-circuit protection circuit may determine, according to the first sampling electrical signal and the first on signal and the first off signal periodically sent by the switch control circuit, whether the sampling resistor needs to enter the short-circuit protection state, and output, according to the determination result, the first switch control signal of the transmission path switch, so that short-circuit protection control of the circuit is implemented by the logic control circuit built in the fast charging chip, and convenience of circuit protection control is improved.
Drawings
FIG. 1 is a schematic diagram of a circuit schematic of a sampling resistor short-circuit protection circuit according to the present invention;
FIG. 2 is a schematic diagram of another schematic circuit diagram of a sampling resistor short-circuit protection circuit according to the present invention;
FIG. 3 is a signal waveform diagram of a rising edge signal and a falling edge signal sent by a synchronous rectification controller;
FIG. 4 is a secondary inductor currentSchematic change with rising and falling edge signals;
FIG. 5 is a schematic diagram of a schematic circuit diagram of another sampling resistor short-circuit protection circuit according to the present invention;
FIG. 6 is a schematic flow chart of a sampling resistor short-circuit protection method provided by the invention;
fig. 7 is a schematic flow chart of another sampling resistor short-circuit protection method provided by the invention.
Detailed Description
The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.
It is noted that the terminology used in the embodiments of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used in this application and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any or all possible combinations of one or more of the associated listed items.
Referring to fig. 1, fig. 1 is a schematic structural diagram of a sampling resistor short-circuit protection circuit provided in an embodiment of the present application, where the sampling resistor short-circuit protection circuit includes a switch control circuit 1, a logic control circuit 2, a detection sampling circuit 3, and a transmission path switch Q1, and the logic control circuit 2 is electrically connected to the switch control circuit 1, the detection sampling circuit 3, and the transmission path switch Q1, respectively, where:
the switch control circuit 1 comprises a switch module 11 and a switch control module 12, wherein the switch control module 12 is used for controlling the on-off of the switch module 11, the logic control circuit 2 is arranged in a quick-charge chip, the detection sampling circuit 3 comprises a sampling resistor Rs, the switch module 11 is electrically connected with the switch control module 12, the switch module 11 is electrically connected with the sampling resistor Rs, the switch control module 12 is electrically connected with the logic control circuit 2, and the logic control circuit 2 is connected with two ends of the sampling resistor Rs in parallel;
The switch control circuit 1: for periodically emitting a first on signal and a first off signal;
the logic control circuit 2: for detecting a first sampled electrical signal of the detection sampling circuit 3, for acquiring the first on signal and the first off signal of the switch control circuit 1, and for deriving a switching period T and a switching time T of the switch control circuit 1 from the first on signal and the first off signal on And for controlling the on-time T according to the switching period T on And the first sampling electric signal judging circuit is used for judging whether the first sampling electric signal enters a sampling resistor short-circuit protection state or not and outputting a first switch control signal for the transmission path switch Q1 corresponding to the sampling resistor according to the judging result.
As shown in fig. 1, the sampling resistor short-circuit protection circuit further includes a power module 31, where the power module 31 may be a flyback converter, a forward converter, a buck converter, a boost chopper, an LLC resonant converter, and other power topologies, which are not limited herein.
In one implementation manner of the present application, as shown in fig. 2, the switch module 11 is a synchronous rectification switch Q2, the switch control module 12 is a synchronous rectification controller 101, and the synchronous rectification controller 101 is configured to periodically send a first on signal and a first off signal to the synchronous rectification switch Q2, where a time difference between the first off signal and the first on signal in the same period is the on time t on The time difference between the first conduction signals of two adjacent periods is the switching period T.
Specifically, as shown in fig. 3, the switch control circuit 1 periodically sends out two signals, namely a first on signal and a first off signal, respectively, in the first on signal of the current periodThe time between the number and the first turn-off signal is the turn-on time t on The time between the first turn-off signal of the current period and the first turn-on signal of the next period is turn-off time, the time between the first turn-on signal of the current period and the first turn-on signal of the next period is switch period T, additionally the first sampling electric signal can be obtained by detecting the sampling circuit 3, when the logic control circuit 2 determines the switch period T and the turn-on time T on And after the first sampled electrical signal is collected, judging through operation, and outputting a first switch control signal according to the judging result, in the embodiment, the current in the circuit is detected through using the resistor Rs, so that the first sampled electrical signal is the output sampled current I o The circuit also comprises a transmission path switch Q1, the transmission path switch Q1 is electrically connected with the logic control circuit 2, and the transmission path switch Q1 switches the on-off state according to a first switch control signal output by the logic control circuit 2; when the sampling resistor Rs has a short-circuit fault, the logic control circuit 2 can only detect a very small output sampling current I from the sampling resistor Rs o But according to the switching period T and the on-time T on It is deduced that there is still a large load current, and therefore, it is determined that the sampling resistor is short-circuited to a protection state, and thus, when the sampling resistor Rs is short-circuited, the output sampling current I is caused o When the voltage is too low, after logic operation and judgment of the logic control circuit 2, a first switch control signal for turning off the transmission path switch Q1 is output, and after the transmission path switch Q1 is turned off, the circuit is opened, and no output current is generated at the moment, so that circuit protection is realized; and output a sampling current I o Too high, possibly the actual output sampling current I o Too high an output sampling current I o The charging electronic product may be damaged, so that the embodiment may protect the output abnormality in the normal circuit state or may protect the output abnormality in the abnormal circuit state.
It should be noted that, the synchronous rectification controller 101 may be an IC such as MP6908, which is common in the market, or may be a separate circuit, which is externally mounted, so as to achieve the control purpose; the logic control circuit is a fast charging protocol chip IC with higher integration degree, for example, a fast charging protocol chip IC with built-in MCU types such as the common market models IP2726 and IP2712, and other types of SOCs.
It can be seen that, in this embodiment of the present application, the logic control circuit in the sampling resistor short-circuit protection circuit may determine, according to the first sampling electrical signal and the first on signal and the first off signal periodically sent by the switch control circuit, whether the sampling resistor needs to enter the short-circuit protection state, and output, according to the determination result, the first switch control signal of the transmission path switch, so that short-circuit protection control of the circuit is implemented by the logic control circuit built in the fast charging chip, and convenience of circuit protection control is improved.
In one implementation manner of the present application, as shown in fig. 2, the synchronous rectification switch Q2 is a first NMOS transistor, a gate of the first NMOS transistor is electrically connected to the synchronous rectification controller 101, the first on signal is a rising edge signal, and the first off signal is a falling edge signal.
In one implementation of the present application, the sampling resistor short-circuit protection circuit further includes a secondary power module, a charging capacitor C 0 And an output load R of the quick charge port load The secondary power module and the charging capacitor C 0 Forming a first power transmission loop with the synchronous rectification switch Q2, wherein the transmission path switch Q1 and the output load R load The sampling resistor Rs and the charging capacitor C 0 And forming a second power transmission loop.
When the power module 31 is a flyback converter, as shown in fig. 2, the power module 31 includes a secondary power module, and the secondary power module is a secondary inductance Ls301 of the flyback converter, as shown in fig. 4, when the synchronous rectification controller 101 sends a first conduction signal to the synchronous rectification switch Q1, the synchronous rectification switch Q1 is turned on to enable the first power transmission loop to be in a connected state, and the flyback converter secondary inductance L s A current passes through and charges the capacitor C 0 Charging;
when the synchronous rectification controller 101 sends the second on-time signal to the synchronous rectification switch Q1, the synchronous rectification switch Q1 is turned off to enable the first power transmission loopIn an open circuit state, flyback converter secondary inductance L s No current passes through, at this time, charge capacitor C 0 Discharging until the first conducting signal of the next period;
at the on time t on Internal flyback converter secondary inductance L s Charge capacitor C 0 Discharging, charging capacitor C 0 Charging, flyback converter secondary inductance L s Is used for generating secondary inductance currentWhile during the off-time the secondary inductor current +. >Zero, when the first conduction signal of the next period appears again, the flyback converter secondary inductance L s Is to generate a secondary inductor current again>This cycle is repeated.
Wherein the utilization of flyback converter secondary inductance L is realized in the first power transmission loop s Charge capacitor C 0 A step of charging, wherein the switch control circuit 1 is positioned in the first power transmission loop and acts as a switch to control the on-off of the switch control circuit 1; implementing charging capacitor C in second power transmission loop 0 For output load R load And a discharging step is performed, and the transmission path switch Q1 is positioned in the second transmission loop and acts as a switch to control the on-off of the circuit.
In one implementation manner of the present application, as shown in fig. 5, the first sampled electrical signal is an output sampled current Io, the transmission path switch Q1 is a second NMOS tube, the logic control circuit 2 includes a sampling detection module 21, a time detection module 22 and a judgment module 23, the sampling detection module 21 includes an amplifier 201 and an analog-to-digital converter 202, the amplifier 201 is connected in parallel to two ends of the sampling resistor Rs, the analog-to-digital converter 202 is electrically connected with the amplifier 201, the judgment module 23 is electrically connected with the analog-to-digital converter 202, the time detection module 22 is respectively electrically connected with the switch control circuit 1 and the judgment module 23, and the judgment module 23 is electrically connected with a gate of the second NMOS tube, where:
The sampling detection module 21 is configured to detect the output sampling current Io by detecting a voltage difference between two ends of the sampling resistor Rs, and output the output sampling current Io to the determination module 23;
the time detection module 22 is configured to collect the first on signal and the first off signal of the switch control circuit 1, and obtain a switching period T and an on time T of the switch control circuit 1 according to the first on signal and the first off signal on And for transmitting the switching period T and the on-time T to the determination module 23 on
The judging module 23 is configured to receive the switching period T and the on time T on And the output sampling current Io according to the switching period T and the on time T on And the output sampling current Io judging circuit is in a sampling resistor short-circuit protection state or not, and a first switch control signal for the transmission path switch Q1 is output according to the judging result.
Wherein, while the synchronous rectification controller 101 sends a rising edge signal to the synchronous rectification switch Q2, the rising edge of the outside of the time detection module 22 is interrupted; while the synchronous rectification controller 101 sends the falling edge signal to the synchronous rectification switch Q2, the external falling edge of the time detection module 22 is interrupted, and the switching period T and the on time T are calculated by the state difference of the two interruption time points of the time detection module 22 on The method comprises the steps of carrying out a first treatment on the surface of the The judging module 23 receives the switching period T and the on time T on And output a sampling current I o And outputs a first switch control signal, and the judging module 23 is connected with the transmission path switch Q1 in the second transmission loop, so as to control the on-off of the transmission path switch Q1.
In one implementation of the present application, at the rootAccording to the switching period T and the on time T on And the output sampling current Io judging circuit is configured to determine whether the circuit enters a sampling resistor short-circuit protection state, and output a first switch control signal for the transmission path switch according to the judging result, where the judging module is specifically configured to: when it is judged thatWhen the counter is incremented by one; when the value of the counter is greater than or equal to a first preset number of times N1, the determining circuit enters a sampling resistor short-circuit protection state, and outputs a first switch control signal, wherein the first switch control signal is used for controlling the switch of the transmission path to be switched to an off state.
In one implementation of the present application, theThe method is based on the following steps:
executing an energy conservation law and an inductive current segmentation equation on the first power transmission loop and the second power transmission loop to obtain a first equation set;
Analyzing the first equation set to obtain a first discriminant, wherein the first discriminant is used for enabling the sampling resistor to be in a normal state when the first discriminant is established;
obtaining according to the first discriminantWherein the first system of equations is:
the first discriminant is:
wherein I is A Is the straight of inductance currentA stream component.
In particular, the method comprises the steps of,the logic control circuit 2 indicates that only a very small output sampling current I can be detected from the sampling resistor Rs o It is necessary to enter the sampling resistor short-circuit protection state.
Wherein the first sampled electrical signal is the output sampled current I o In the flyback converter secondary inductance L s Is used for generating secondary inductance currentAt the on time t on Internal flyback converter secondary inductance L s Charge capacitor C 0 Discharging, charging capacitor C 0 Charging, flyback converter secondary inductance L s Is generated with a secondary inductor current->While during the off time, the secondary inductor current L s Zero, when the first conduction signal of the next period appears again, the flyback converter secondary inductance L s Is to generate a secondary inductor current again>This cycle is repeated. Wherein, as shown in fig. 4, the secondary inductor current +.>There are two modes: a. current discontinuous mode (Discontinuous Conduction Mode, DCM); b. current continuous mode (Continuous Conduction Mode, CCM), wherein in DCM mode, flyback converter secondary inductance L as shown in fig. 4 s Is 0, and in CCM mode, flyback converter secondary inductance L s Is I A And I A >0。
The above equation can be used to obtain the basic theoretical basis for judging whether the sampling resistor Rs is shorted in the present embodiment:
in this judgment formula, when the synchronous rectification controller 101 is set, the on-time t is set after the period of the rising edge signal and the falling edge signal is determined on And the value of the switching period T is kept constant, and the on-time T on And the switching period T is not caused by short circuit of the sampling resistor Rs even if the switching period T is changed, and the condition of the sampling resistor Rs is not reflected. And V is 0 And L s For rated output voltage and current of the protection circuit or the protection system, after components of other parts in the circuit are well fixed, the value is also a fixed value, so that the only value capable of reflecting the condition of the sampling resistor Rs is the output sampling current I obtained by sampling and detecting the sampling resistor Rs o Thus, the output current I can be sampled o And whether it is short-circuited or not.
No matter what secondary inductance current is in actual operation of circuitIn the current interrupt mode or the current continuous mode, if the output sampling current Io is abnormally low: />That is, it is proved that the sampling resistor Rs has an abnormal condition such as a short circuit, and when the abnormal condition cannot be relieved within N1 periods lasting for the first preset times, the first switch control signal is output to control the transmission path switch Q1 to switch to the off state.
In the above equation, the output sampling current I o On time t on And the switching period T are all detection data, and the judgment type can be converted intoThe right side of the judgment formula is a fixed value, and the left side of the judgment formula is changed in real time, namely/>For the first operation formula, +.>Is the second operation formula, when +.>When the detection result is satisfied, the counter adds one count, each time the judging period is a switching period T, the counter is started to count 0, when the abnormality occurs in the continuous first preset times N1 periods, that is, the duration of N1 x T is passed, it is proved that the sampling resistor Rs has the abnormality such as short circuit, that is, the first switching control signal is output, and the transmission path switch Q1 is controlled to switch to the off state.
In one implementation of the present application, the switching period T and the on-time T are defined as on And the output sampling current Io judging circuit is configured to determine whether the circuit enters a sampling resistor short-circuit protection state, and output a first switch control signal for the transmission path switch according to the judging result, where the judging module is specifically configured to: when it is judged thatWhen the counter is incremented by one; when the value of the counter is greater than or equal to a first preset number of times N1, the determining circuit enters a sampling resistor short-circuit protection state, and outputs a first switch control signal, wherein the first switch control signal is used for controlling the switch of the transmission path to be switched to an off state.
Wherein A is an error coefficient, and the value range of the error coefficient is 5% -95%; v (V) 0 For the voltage across the output load, the L s And the inductance is corresponding to the secondary power supply module.
For example, when the error coefficient is 50%, the logic control circuit 2 takes into consideration the sampling error of the sampling resistor Rs, and adopts a method of reducing the judgment threshold value to avoid the sampling errorThe resultant misjudgment problem, i.eThe error coefficient can be properly adjusted according to the actual sampling precision, and the higher the sampling precision is, the more the error coefficient can be properly adjusted, for example, the error coefficient is taken as 95%, and the lower the sampling precision is, the more the error coefficient can be properly adjusted, for example, the error coefficient is taken as 5%, which is not limited herein.
In one implementation manner of the present application, as shown in fig. 5, the sampling resistor short-circuit protection circuit further includes a primary power module, a primary path switch, and a flyback converter primary inductor, where the primary power module, the primary path switch, and the flyback converter primary inductor form a third power transmission loop, and the secondary power module is a flyback converter secondary inductor, and the flyback converter primary inductor is configured to supply power to the protection circuit through the flyback converter secondary inductor.
Wherein, the primary power module Vg is responsible for providing a power source, and utilizes the flyback converter primary inductance Lp and the flyback converter secondary inductance L s The energy transmission is realized, the proportion of the voltage is adjusted by adjusting the number of turns of the coil, in addition, the primary path switch Q3 is responsible for controlling the on-off of the third power transmission loop, and when the primary path switch Q3 is in a communicating state, the primary coil of the flyback converter is directly connected to Vg. The current in the primary coil and the magnetic field in the flyback converter core increase, storing energy in the core. The voltage generated in the secondary winding is reversed, at which time the synchronous rectification switch Q1 is turned off and cannot be turned on. At this time, the capacitor C 0 To the load R load Providing a voltage and a current. During the switch off phase, the current in the primary coil is 0. At the same time the magnetic field in the core starts to drop, inducing a forward voltage on the secondary winding. At this time, the diode is in a forward bias state and turns on the synchronous rectification switch Q1, and the conducted current flows into the capacitor C 0 And a load R load . The energy stored in the core is transferred to the capacitor C 0 And a load R load Is a kind of medium. When the sampling resistor Rs has short circuit fault, the logic control circuit 2 can only detect the very micro from the sampling resistor RsSmall output sampling current I o Thus, when the sampling resistor Rs is short-circuited, the output sampling current I is caused o When the voltage is too low, under the operation control of the logic control circuit 2, the transmission path switch Q1 in the second power transmission loop switches off, so that the situation that detection is inaccurate when the sampling resistor Rs is short-circuited and output current in the second power transmission loop cannot be detected in real time, and therefore the output current and power are possibly abnormal, and damage to a charging product is caused is avoided.
Referring to fig. 6, fig. 6 is a flow chart of a sampling resistor short-circuit protection method according to an embodiment of the present application, where the method is applied to the sampling resistor short-circuit protection circuit, and includes the following steps:
step 601: collecting a first on signal and a first off signal of a switch control circuit through a logic control circuit;
step 602: determining a switching period T and a switching time T of the switching control circuit according to the first switching-on signal and the first switching-off signal by the logic control circuit on
Step 603: acquiring a first sampling electric signal of a sampling resistor through the logic control circuit;
step 604: according to the switching period T and the on time T by the logic control circuit on Determining a first switch control signal of a transmission path switch corresponding to the sampling resistor by a micro control unit of the fast charging chip according to the first sampling electric signal;
step 605: transmitting the first switch control signal to the transmission path switch through the micro control unit;
step 606: and receiving the first switch control signal through the transmission path switch, and executing an operation corresponding to the first switch control signal.
Before step 601, the sampling resistor short-circuit protection circuit needs to be powered up and a reset operation is performed, where the reset operation includes program initializing sampling data, initializing a register state, and controlling the transmission path switch Q1 to switch to a closed state.
It can be seen that, in this embodiment of the present application, the logic control circuit in the sampling resistor short-circuit protection circuit may determine, according to the first sampling electrical signal and the first on signal and the first off signal periodically sent by the switch control circuit, whether the sampling resistor needs to enter the short-circuit protection state, and output, according to the determination result, the first switch control signal of the transmission path switch, so that short-circuit protection control of the circuit is implemented by the logic control circuit built in the fast charging chip, and convenience of circuit protection control is improved.
In one implementation manner of the present application, after outputting, by the logic control circuit, a first switch control signal for a transmission path switch corresponding to the sampling resistor, the method further includes:
resetting the counter, and adding the counter once every clock period of the logic control circuit when the transmission path switch is in an off state;
when the counting times of the counter reach a second preset times N2, outputting a second switch control signal of the transmission path switch through the logic control circuit, resetting a protection state of the sampling resistor, and controlling the transmission path switch to be switched to a channel state by the second switch control signal.
Wherein, since the transmission path switch Q1 is already controlled to the off state, no current flows in the second power transmission loop, and is in the stop state, after the duration of N2 clock cycles of the logic control circuit is passed in this state, the transmission path switch is closed again, and then the execution process of the sampling resistor short-circuit protection method of the next round is entered.
In particular, the sampling resistor short-circuit protection method includes other steps, which can be described with reference to the foregoing sampling resistor short-circuit protection circuit.
Referring to fig. 7, fig. 7 is a flow chart of a sampling resistor short-circuit protection method according to an embodiment of the present application, where the method is applied to the sampling resistor short-circuit protection circuit, and includes the following steps:
step 701: and the sampling resistor short-circuit protection circuit is powered on, performs reset operation and initializes sampling data.
Step 702: the protection state for the sampling resistor is reset, and the transmission path switch Q1 is controlled to switch to the closed state.
Step 703: the first on signal and the first off signal of the switch control circuit are collected through the logic control circuit.
Step 704: determining a switching period T and a switching time T of the switching control circuit according to the first switching-on signal and the first switching-off signal by the logic control circuit on
Step 705: and acquiring a first sampling electric signal of the sampling resistor through the logic control circuit.
Step 706: the logic control circuit controls the switching period T and the on time T on And calculating the output sampling current Io to obtain a first numerical result.
Step 707: the logic control circuit outputs the voltage V at two ends of the load to the quick charge port 0 Inductance L corresponding to flyback converter secondary power supply module of sampling resistor short-circuit protection circuit s And calculating to obtain a second numerical result, and multiplying the second numerical result by an error coefficient to obtain a third numerical result.
Step 708: and judging the relation between the first numerical result and the third numerical result in the switching period of the same switching control circuit through the logic control circuit, and adding one count by a counter if the first numerical result is smaller than the third numerical result.
Step 709: when the counting times of the counter reach a first preset times N1, outputting a first switch control signal aiming at a transmission path switch corresponding to the sampling resistor through the logic control circuit, wherein the first switch control signal is used for controlling the transmission path switch to be switched to an off state.
Step 710: and (3) resetting the counter, adding one count to the counter every time a clock cycle of the logic control circuit is passed when the transmission path switch is in an off state, and executing step 702 again when the count number of the counter reaches the second preset number N2.
It can be seen that, in this embodiment of the present application, the logic control circuit in the sampling resistor short-circuit protection circuit may determine, according to the first sampling electrical signal and the first on signal and the first off signal periodically sent by the switch control circuit, whether the sampling resistor needs to enter the short-circuit protection state, and output, according to the determination result, the first switch control signal of the transmission path switch, so that short-circuit protection control of the circuit is implemented by the logic control circuit built in the fast charging chip, and convenience of circuit protection control is improved.
The above examples are preferred embodiments of the present invention, but the embodiments of the present invention are not limited to the above examples, and any other changes, modifications, substitutions, combinations, and simplifications that do not depart from the spirit and principle of the present invention should be made in the equivalent manner, and the embodiments are included in the protection scope of the present invention.

Claims (7)

1. A sampling resistor short-circuit protection method, wherein the method is applied to a sampling resistor short-circuit protection circuit for a fast charger, the method comprising: the sampling resistor short-circuit protection circuit collects a first on signal and a first off signal of the switch control circuit;
the sampling resistor short-circuit protection circuit determines the switching period T and the switching time T of the switch control circuit according to the first switching-on signal and the first switching-off signal on
The sampling resistor short-circuit protection circuit obtains a first sampling electric signal of a sampling resistor;
the sampling resistor short-circuit protection circuit is used for protecting the sampling resistor according to the switching period T and the conduction time T on Determining a first switch control signal of a transmission path switch corresponding to the sampling resistor by a micro control unit of the fast charging chip according to the first sampling electric signal;
The micro control unit sends the first switch control signal to the transmission path switch;
the transmission path switch receives the first switch control signal and executes an operation corresponding to the first switch control signal;
wherein the first sampled electrical signal is an output sampled current Io, and the sampling resistor short-circuit protection circuit is configured to perform the switching according to the switching period T and the on time T on And determining, by the micro control unit of the fast charging chip, a first switch control signal of a transmission path switch corresponding to the sampling resistor according to the first sampled electrical signal, where the first switch control signal includes:
the sampling resistor short-circuit protection circuit is used for controlling the switching period T and the conduction time T on Calculating the output sampling current Io to obtain a first numerical result;
sampling resistor short-circuit protection circuit outputs voltage V at two ends of load to fast charging port 0 Inductance L corresponding to flyback converter secondary power supply module of sampling resistor short-circuit protection circuit s Calculating to obtain a second numerical result;
the sampling resistor short-circuit protection circuit judges the relation between the first numerical value result and the second numerical value result in the switching period of the same switching control circuit, if the first numerical value result is smaller than the second numerical value result, a counter adds one count, and each count of the counter corresponds to one switching period of the switching control circuit;
When the count number of the counter reaches a first preset number N1, determining the first switch control signal for the transmission path switch.
2. The method of claim 1, wherein the step of determining the position of the substrate comprises,
the first sampled electrical signal is an output sampled current Io, and the sampling resistor short-circuit protection circuit is used for controlling the switching period T and the on time T on And determining, by the micro control unit of the fast charging chip, a first switch control signal of a transmission path switch corresponding to the sampling resistor according to the first sampled electrical signal, where the first switch control signal includes:
samplingThe resistance short-circuit protection circuit is used for controlling the switching period T and the conduction time T on Calculating the output sampling current Io to obtain a first numerical result;
sampling resistor short-circuit protection circuit outputs voltage V at two ends of load to fast charging port 0 Inductance L corresponding to flyback converter secondary power supply module of sampling resistor short-circuit protection circuit s Calculating to obtain a second numerical result;
the sampling resistor short-circuit protection circuit multiplies the second numerical result by an error coefficient to obtain a third numerical result, wherein the value range of the error coefficient is 5% -95%;
the sampling resistor short-circuit protection circuit judges the relation between the first numerical value result and the third numerical value result in the switching period of the same switching control circuit, and if the first numerical value result is smaller than the third numerical value result, the counter adds one count;
When the count number of the counter reaches a first preset number N1, determining the first switch control signal for the transmission path switch.
3. The method according to claim 1 or 2, wherein the sampling resistor short-circuit protection circuit is configured to provide the switching period T, the on-time T on And calculating the output sampling current Io to obtain a first numerical result, including:
the sampling resistor short-circuit protection circuit is used for controlling the switching period T and the conduction time T on And executing a first operation formula on the output sampling current Io to obtain a first numerical result, wherein the first operation formula is that
4. The method according to claim 1 or 2, wherein the sampling resistor short-circuit protection circuit outputs the voltage V across the load to the fast charge port 0 Flyback converter secondary with sampling resistor short-circuit protection circuitInductance L corresponding to stage power source module s Calculating to obtain a second numerical result, including:
the sampling resistor short-circuit protection circuit outputs the voltage V at two ends of the load to the fast charging port 0 Inductance L corresponding to flyback converter secondary power supply module of sampling resistor short-circuit protection circuit s Executing a second operation formula to obtain a second numerical result, wherein the second operation formula is that
5. A method according to claim 3, wherein the first operational formula is derived based on the following procedure:
executing an energy conservation law and an inductive current segmentation equation on the first power transmission loop and the second power transmission loop to obtain a first equation set;
analyzing the first equation set to obtain a first discriminant, wherein the first discriminant is used for enabling the sampling resistor to be in a normal state when the first discriminant is established;
obtaining the first operation formula according to the first discriminant;
wherein the first system of equations is:
the first discriminant is:
wherein I is A Is the direct current component of the inductor current.
6. The method of claim 4, wherein the second operational formula is derived based on the following procedure:
executing an energy conservation law and an inductive current segmentation equation on the first power transmission loop and the second power transmission loop to obtain a first equation set;
analyzing the first equation set to obtain a first discriminant, wherein the first discriminant is used for enabling the sampling resistor to be in a normal state when the first discriminant is established;
obtaining the second operation formula according to the first discriminant;
wherein the first system of equations is:
The first discriminant is:
wherein I is A Is the direct current component of the inductor current.
7. The method of claim 3, wherein after the sampling resistor short-circuit protection circuit outputs the first switch control signal for the transmission path switch corresponding to the sampling resistor, the method further comprises:
resetting the counter, and adding the counter once every clock period of one logic control circuit when the transmission path switch is in an off state; when the counting times of the counter reach a second preset times N2, outputting a second switch control signal of the transmission path switch through the logic control circuit, resetting a protection state of the sampling resistor, and controlling the transmission path switch to be switched to a channel state by the second switch control signal.
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