CN110417036B - Distribution system converges - Google Patents

Abstract

The invention discloses a confluence distribution system which comprises a waste battery pack, household electrical equipment and a mains supply alternating current power supply, wherein the waste battery pack is connected with a battery detection unit and used for detecting the voltage value of the waste battery pack and connecting a charging loop or a discharging loop; the battery detection unit is connected with the data processor and used for transmitting detection information to the data processor; the battery detection unit is connected with the low-voltage distribution driving unit and the boosting distribution driving unit, the low-voltage distribution driving unit and the boosting distribution driving unit are both connected with the data processor, and the low-voltage distribution driving unit or the boosting distribution driving unit is selectively switched on through the data processor to transmit electric energy to the battery detection unit. The invention can recover the residual electric energy in the waste battery pack to provide part of electric energy for the normal work of household electrical equipment, and simultaneously, the induced electricity harmful to human bodies, which is generated when the household electrical equipment works, is collected to charge the waste battery pack.

Description

Distribution system converges

Technical Field

The invention relates to the technical field of electric energy collection, in particular to a confluence distribution system.

Background

With the development of economy and technology, the demand of human beings on energy is increasing, and at present, various types of batteries have entered families, and a large number of electronic devices used in daily life of people can not be separated from the batteries during working, but people usually discard the batteries when the batteries do not have enough residual electric energy, and the batteries are regarded as having no utilization value. However, the waste batteries which are considered to be unusable by people actually store a certain amount of electric energy, which causes a certain energy waste, and under the large background that energy conservation and environmental protection are continuously advocated in China, the recycling of the residual electric energy in the waste batteries becomes a problem which needs to be solved urgently. On the other hand, household electrical appliance equipment can produce the response electricity harmful to the human body when working, and if this part response electricity can be concentrated and collected and utilized, not only can eliminate the injury of response electricity to the human body, will produce considerable economic benefits moreover.

Disclosure of Invention

The invention aims to provide a confluence distribution system which can recover residual electric energy in a waste battery pack to provide part of electric energy for normal work of household electrical equipment, and meanwhile, can collect induced electricity which is harmful to human bodies and is generated when the household electrical equipment works and is used for charging the waste battery pack.

In order to achieve the purpose, the invention provides the following technical scheme: a confluence distribution system comprises a waste battery pack, household electrical equipment and a mains supply alternating current power supply, wherein the waste battery pack is connected with a battery detection unit and used for detecting the voltage value of the waste battery pack and connecting a charging loop or a discharging loop; the battery detection unit is connected with the data processor and is used for transmitting detection information to the data processor;

the battery detection unit is connected with the low-voltage distribution driving unit and the boosting distribution driving unit, the low-voltage distribution driving unit and the boosting distribution driving unit are both connected with the data processor, and the low-voltage distribution driving unit or the boosting distribution driving unit is selectively switched on through the data processor to transmit electric energy to the battery detection unit;

the battery detection unit is connected with the low-voltage collection region and used for transmitting the electric energy of the waste battery pack to the low-voltage collection region for storage through the battery detection unit, and the low-voltage collection region is connected with the boosting storage region and used for boosting direct-current voltage;

the boosting storage area is connected with the area to be thrown in, and the area to be thrown in is connected with the auxiliary direct-current capacitor bank and used for charging the auxiliary direct-current capacitor bank through the area to be thrown in;

the auxiliary direct current capacitor bank is connected with the distribution controller, the distribution controller is also connected with the main direct current capacitor bank, the output ends of the auxiliary direct current capacitor bank and the main direct current capacitor bank are both connected with the alternating voltage unit, and the distribution controller is used for controlling the auxiliary direct current capacitor bank or the main direct current capacitor bank to be switched on to output electric energy to the alternating voltage unit;

the input end of the main direct current capacitor bank is connected with a commercial power alternating current power supply through a rectifying circuit;

the alternating voltage unit is connected with the household appliance through the induced electricity detection area, wherein the alternating voltage unit is used for converting direct current into alternating current to supply power to the household appliance.

Preferably, the induced electrical detection area is connected with a data processor and used for transmitting detection information to the data processor.

Preferably, the faradic electricity detection region is connected with a faradic electricity static collection region for collecting the detected faradic electricity.

Preferably, the induced electricity electrostatic collecting region is connected with the low-voltage energy collecting region and is used for collecting induced electricity in a centralized manner.

Preferably, the low-voltage energy collecting region is electrically connected with both the low-voltage distribution driving unit and the boosting distribution driving unit.

Preferably, the battery detection unit comprises a first input end BTIN1, a second input end BTIN2, a first output end BTOU1, a second output end BTOUT2 and a detection output end BTZ, wherein the first input end BTIN1 is connected with the low-voltage distribution driving unit and the boosting distribution driving unit, the second input end BTIN2 is connected with the discharge loop of the waste battery pack, the first output end BTOU1 is connected with the charge loop of the waste battery pack, the second output end BTOUT2 is connected with the low-voltage collection area, and the detection output end BTZ is connected with the data processor;

when the voltage value of the waste battery pack is smaller than 12V, the battery detection unit is connected with the charging loop, and when the voltage value of the waste battery pack is larger than or equal to 12V, the battery detection unit is connected with the discharging loop.

Preferably, the battery detection unit further comprises a triode Q1, a single chip microcomputer, a first rectification circuit VC1 and a second rectification circuit VC2, wherein an emitter of the triode Q1 is connected with a first input end BTIN1, a base of the triode Q1 is connected with an output end of the single chip microcomputer, a collector of the triode Q1 is connected with an input end of the first rectification circuit VC1, and an output end of the first rectification circuit VC1 is connected with the input end of the single chip microcomputer through a series loop of a resistor R1, a resistor R2 and a resistor R3;

the input end of the second rectifying circuit VC2 is connected with the positive output end of the detection output end BTZ, and the output end of the second rectifying circuit VC2 is connected with the first output end BTOU 1.

Preferably, the battery detection unit further comprises a triode Q2, a second rectification circuit VC3, and a fourth rectification circuit VC4, and a base of the triode Q2 is connected with an output end of the single chip microcomputer; the collector of the triode Q2 is connected with the second output end BTOUT2, the emitter of the triode Q2 is connected with the input end of the second rectifying circuit VC3, and the output end of the second rectifying circuit VC3 is connected with the negative output end of the detection output end BTZ through the resistor R300; and the second input end BTIN2 is connected with the negative output end of the detection output end BTZ through a fourth rectifying circuit VC 4.

Preferably, the induction detection area comprises first input ports IN11 and IN12, second input ports IN21 and IN22, and third input ports IN31 and IN32, and is used for connecting with household appliances;

the faradic detection region includes a first output port OU1 and OU2 for connection to a faradic collection region.

Preferably, the area to be launched includes second OUTPUT ports OUTPUT1 and OUTPUT2, which are used for connecting with the secondary dc capacitor bank; the to-be-dosed zone comprises a second INPUT port INPUT1 and INPUT2 for connection to the boost storage zone.

Compared with the prior art, the invention has the beneficial effects that:

1. the confluence distribution system comprises a waste battery pack, household electrical equipment and a mains supply alternating current power supply, wherein the waste battery pack is connected with a battery detection unit and used for detecting the voltage value of the waste battery pack and connecting a charging loop or a discharging loop; the battery detection unit is connected with the data processor and used for transmitting detection information to the data processor; when the voltage value of the waste battery pack is smaller than 12V, the battery detection unit is connected with the charging loop, and when the voltage value of the waste battery pack is larger than or equal to 12V, the battery detection unit is connected with the discharging loop; the battery detection unit is connected with the low-voltage collection region, the low-voltage collection region is connected with the boosting storage region, the boosting storage region is connected with the to-be-put-in region, the to-be-put-in region is connected with the auxiliary direct-current capacitor bank, output ends of the auxiliary direct-current capacitor bank and the main direct-current capacitor bank are connected with the alternating voltage unit, the alternating voltage unit is connected with the household appliance through the induced electricity detection region, and the alternating voltage unit is used for converting direct current into alternating current to supply power to the household appliance. Therefore, the function of recycling the residual electric energy in the waste battery pack to provide part of electric energy for the normal work of household electrical equipment is realized.

2. The confluence distribution system comprises an induced electricity detection area and an induced electricity static collection area, wherein the induced electricity detection area is connected with a data processor and is used for transmitting detection information to the data processor, and the induced electricity detection area is connected with the induced electricity static collection area and is used for collecting the detected induced electricity; the induced electricity static collecting region is connected with the low-voltage energy collecting region and used for collecting induced electricity in a centralized mode, the low-voltage energy collecting region is electrically connected with the low-voltage distribution driving unit and the boosting distribution driving unit, the low-voltage distribution driving unit and the boosting distribution driving unit are connected with the data processor, and the data processor selects to be connected with the low-voltage distribution driving unit or the boosting distribution driving unit to transmit electric energy to the battery detection unit. The induced electricity detection area is connected with the household appliance, induced electricity harmful to a human body generated when the household appliance works is induced through the induced electricity detection area, then the induced electricity is transmitted to the induced electricity static collection area to be collected, then the induced electricity is transmitted to the low-voltage energy collection area to be collected in a centralized manner, and finally the low-voltage distribution driving unit or the boosting distribution driving unit is selected to be switched on through the data processor to transmit electric energy to the battery detection unit. Therefore, the function of collecting the induced electricity harmful to human bodies generated when the household electrical appliance works and charging the waste battery pack is realized. Meanwhile, the damage of induction electricity to human bodies can be eliminated.

Drawings

FIG. 1 is a schematic diagram of a circuit connection of a bus distribution system according to the present invention;

FIG. 2 is a schematic circuit diagram of a battery detection unit in a bus distribution system according to the present invention;

FIG. 3 is a schematic circuit diagram of an inductive sensing area in a bus distribution system according to the present invention;

FIG. 4 is a schematic circuit diagram of a drop zone in a conflux distribution system according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-4, an embodiment of the present invention is shown: a confluence distribution system comprises a waste battery pack, household electrical equipment and a mains supply alternating current power supply, wherein the waste battery pack is connected with a battery detection unit and used for detecting the voltage value of the waste battery pack and connecting a charging loop or a discharging loop; the battery detection unit is connected with the data processor and is used for transmitting detection information to the data processor;

the battery detection unit is connected with the low-voltage distribution driving unit and the boosting distribution driving unit, the low-voltage distribution driving unit and the boosting distribution driving unit are both connected with the data processor, and the low-voltage distribution driving unit or the boosting distribution driving unit is selectively switched on through the data processor to transmit electric energy to the battery detection unit;

the battery detection unit is connected with the low-voltage collection region and used for transmitting the electric energy of the waste battery pack to the low-voltage collection region for storage through the battery detection unit, and the low-voltage collection region is connected with the boosting storage region and used for boosting direct-current voltage;

the boosting storage area is connected with the area to be thrown in, and the area to be thrown in is connected with the auxiliary direct-current capacitor bank and used for charging the auxiliary direct-current capacitor bank through the area to be thrown in;

the auxiliary direct current capacitor bank is connected with the distribution controller, the distribution controller is also connected with the main direct current capacitor bank, the output ends of the auxiliary direct current capacitor bank and the main direct current capacitor bank are both connected with the alternating voltage unit, and the distribution controller is used for controlling the auxiliary direct current capacitor bank or the main direct current capacitor bank to be switched on to output electric energy to the alternating voltage unit;

the input end of the main direct current capacitor bank is connected with a commercial power alternating current power supply through a rectifying circuit;

the alternating voltage unit is connected with the household appliance through the induced electricity detection area, wherein the alternating voltage unit is used for converting direct current into alternating current to supply power to the household appliance.

Preferably, the induced electrical detection area is connected with a data processor and used for transmitting detection information to the data processor.

Preferably, the faradic electricity detection region is connected with a faradic electricity static collection region for collecting the detected faradic electricity.

Preferably, the induced electricity electrostatic collecting region is connected with the low-voltage energy collecting region and is used for collecting induced electricity in a centralized manner.

Preferably, the low-voltage energy collecting region is electrically connected with both the low-voltage distribution driving unit and the boosting distribution driving unit.

As shown in fig. 2, a schematic circuit diagram of a battery detection unit in the confluence distribution system is shown, wherein the battery detection unit includes a first input terminal BTIN1, a second input terminal BTIN2, a first output terminal BTOU1, a second output terminal BTOUT2 and a detection output terminal BTZ, the first input terminal BTIN1 is connected with a low voltage distribution driving unit and a boost distribution driving unit, the second input terminal BTIN2 is connected with a discharge loop of a used battery pack, the first output terminal BTOU1 is connected with a charge loop of the used battery pack, the second output terminal BTOUT2 is connected with a low voltage collection region, and the detection output terminal BTZ is connected with a data processor;

when the voltage value of the waste battery pack is smaller than 12V, the battery detection unit is connected with the charging loop, and when the voltage value of the waste battery pack is larger than or equal to 12V, the battery detection unit is connected with the discharging loop.

Preferably, the battery detection unit further comprises a triode Q1, a single chip microcomputer, a first rectification circuit VC1 and a second rectification circuit VC2, wherein an emitter of the triode Q1 is connected with a first input end BTIN1, a base of the triode Q1 is connected with an output end of the single chip microcomputer, a collector of the triode Q1 is connected with an input end of the first rectification circuit VC1, and an output end of the first rectification circuit VC1 is connected with the input end of the single chip microcomputer through a series loop of a resistor R1, a resistor R2 and a resistor R3;

the input end of the second rectifying circuit VC2 is connected with the positive output end of the detection output end BTZ, and the output end of the second rectifying circuit VC2 is connected with the first output end BTOU 1.

Preferably, the battery detection unit further comprises a triode Q2, a second rectification circuit VC3, and a fourth rectification circuit VC4, and a base of the triode Q2 is connected with an output end of the single chip microcomputer; the collector of the triode Q2 is connected with the second output end BTOUT2, the emitter of the triode Q2 is connected with the input end of the second rectifying circuit VC3, and the output end of the second rectifying circuit VC3 is connected with the negative output end of the detection output end BTZ through the resistor R300; and the second input end BTIN2 is connected with the negative output end of the detection output end BTZ through a fourth rectifying circuit VC 4.

As shown IN fig. 3, a schematic circuit diagram of an induced electricity detection area IN the bus distribution system is shown, wherein the induced electricity detection area includes first input ports IN11 and IN12, second input ports IN21 and IN22, and third input ports IN31 and IN32, and three sets of input ports are used for connecting different household electrical appliances to obtain induced electricity harmful to human bodies generated during the operation of the household electrical appliances.

The induced electricity detection area comprises a first output port OU1 and an output port OU2, and is used for being connected with the induced electricity collection area and transmitting the obtained induced electricity generated by the household appliance to the induced electricity collection area for collection.

Fig. 4 is a schematic circuit diagram of a to-be-dropped region in the bus distribution system, wherein the to-be-dropped region includes second OUTPUT ports OUTPUT1 and OUTPUT2, which are used for connecting to the secondary dc capacitor bank; the to-be-dosed zone comprises a second INPUT port INPUT1 and INPUT2 for connection to the boost storage zone. The function of the region to be put in is to store the raised direct-current voltage, and then release the direct-current voltage at the later stage, so that the direct-current voltage is used for the process of storing and releasing electric energy.

The working principle is as follows: the confluence distribution system comprises a waste battery pack, household electrical equipment and a mains supply alternating current power supply, wherein the waste battery pack is connected with a battery detection unit and used for detecting the voltage value of the waste battery pack and connecting a charging loop or a discharging loop; the battery detection unit is connected with the data processor and used for transmitting detection information to the data processor; when the voltage value of the waste battery pack is smaller than 12V, the battery detection unit is connected with the charging loop, and when the voltage value of the waste battery pack is larger than or equal to 12V, the battery detection unit is connected with the discharging loop; the battery detection unit is connected with the low-voltage collection region, the low-voltage collection region is connected with the boosting storage region, the boosting storage region is connected with the to-be-put-in region, the to-be-put-in region is connected with the auxiliary direct-current capacitor bank, output ends of the auxiliary direct-current capacitor bank and the main direct-current capacitor bank are connected with the alternating voltage unit, the alternating voltage unit is connected with the household appliance through the induced electricity detection region, and the alternating voltage unit is used for converting direct current into alternating current to supply power to the household appliance. Therefore, the function of recycling the residual electric energy in the waste battery pack to provide part of electric energy for the normal work of household electrical equipment is realized.

The confluence distribution system comprises an induced electricity detection area and an induced electricity static collection area, wherein the induced electricity detection area is connected with a data processor and is used for transmitting detection information to the data processor, and the induced electricity detection area is connected with the induced electricity static collection area and is used for collecting the detected induced electricity; the induced electricity static collecting region is connected with the low-voltage energy collecting region and used for collecting induced electricity in a centralized mode, the low-voltage energy collecting region is electrically connected with the low-voltage distribution driving unit and the boosting distribution driving unit, the low-voltage distribution driving unit and the boosting distribution driving unit are connected with the data processor, and the data processor selects to be connected with the low-voltage distribution driving unit or the boosting distribution driving unit to transmit electric energy to the battery detection unit. The induced electricity detection area is connected with the household appliance, induced electricity harmful to a human body generated when the household appliance works is induced through the induced electricity detection area, then the induced electricity is transmitted to the induced electricity static collection area to be collected, then the induced electricity is transmitted to the low-voltage energy collection area to be collected in a centralized manner, and finally the low-voltage distribution driving unit or the boosting distribution driving unit is selected to be switched on through the data processor to transmit electric energy to the battery detection unit. Therefore, the function of collecting the induced electricity harmful to human bodies generated when the household electrical appliance works and charging the waste battery pack is realized. Meanwhile, the damage of induction electricity to human bodies can be eliminated.

The method comprises the following specific implementation steps: the working process of the confluence distribution system mainly comprises two processes, when the voltage value of the waste battery pack is smaller than 12V, the battery detection unit is connected with the charging loop, and when the voltage value of the waste battery pack is larger than or equal to 12V, the battery detection unit is connected with the discharging loop. When the battery pack is in a discharging process, residual electric energy in the waste battery pack is collected to a low-voltage collecting region, the low-voltage collecting region is connected with a boosting storage region, then the boosting storage region boosts the direct-current voltage and transmits the boosted direct-current voltage to a region to be put in for storage, and the region to be put in is connected with an auxiliary direct-current capacitor bank and used for charging the auxiliary direct-current capacitor bank through the region to be put in; the distribution controller controls the auxiliary direct current capacitor bank or the main direct current capacitor bank to be connected to output electric energy to the alternating voltage unit (the auxiliary direct current capacitor bank is preferentially connected, when the electric energy provided by the auxiliary direct current capacitor bank is insufficient, the main direct current capacitor bank is supplied with power by the commercial power alternating current power supply), and the direct current is converted into alternating current through the alternating voltage unit and then is used for supplying power to household electrical equipment. Therefore, the functions of recycling, repairing and using the energy of the waste battery are realized.

When the household appliance is in a charging process, induced electricity harmful to a human body, generated by the household appliance, is detected through the induced electricity detection area and is transmitted to the induced electricity static collection area for collection, the induced electricity static collection area is connected with the low-voltage energy collection area and is used for transmitting electric energy to the low-voltage distribution driving unit and the boosting distribution driving unit after the induced electricity is collected in a centralized manner, and the waste battery pack is charged through the battery detection unit under the control of data processing. The optimization processing of various induced electricity is realized, and the harm of the induced electricity to human bodies is eliminated.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (9)

1. The utility model provides a distribution system converges, includes old and useless group battery, domestic appliance equipment and commercial power alternating current power supply, its characterized in that: the waste battery pack is connected with the battery detection unit and used for detecting the voltage value of the waste battery pack and connecting the charging loop or the discharging loop; the battery detection unit is connected with the data processor and is used for transmitting detection information to the data processor;

the battery detection unit is connected with the low-voltage distribution driving unit and the boosting distribution driving unit, the low-voltage distribution driving unit and the boosting distribution driving unit are both connected with the data processor, and the low-voltage distribution driving unit or the boosting distribution driving unit is selectively switched on through the data processor to transmit electric energy to the battery detection unit;

the battery detection unit is connected with the low-voltage collection region and used for transmitting the electric energy of the waste battery pack to the low-voltage collection region for storage through the battery detection unit, and the low-voltage collection region is connected with the boosting storage region and used for boosting direct-current voltage;

the boosting storage area is connected with the area to be thrown in, and the area to be thrown in is connected with the auxiliary direct-current capacitor bank and used for charging the auxiliary direct-current capacitor bank through the area to be thrown in;

the auxiliary direct current capacitor bank is connected with the distribution controller, the distribution controller is also connected with the main direct current capacitor bank, the output ends of the auxiliary direct current capacitor bank and the main direct current capacitor bank are both connected with the alternating voltage unit, and the distribution controller is used for controlling the auxiliary direct current capacitor bank or the main direct current capacitor bank to be switched on to output electric energy to the alternating voltage unit;

the input end of the main direct current capacitor bank is connected with a commercial power alternating current power supply through a rectifying circuit;

the alternating voltage unit is connected with the household appliance equipment through an induced electricity detection area, wherein the alternating voltage unit is used for converting direct current into alternating current to supply power to the household appliance equipment;

the battery detection unit comprises a first input end BTIN1, a second input end BTIN2, a first output end BTOU1, a second output end BTOUT2 and a detection output end BTZ, the first input end BTIN1 is connected with the low-voltage distribution driving unit and the boosting distribution driving unit, the second input end BTIN2 is connected with a discharge loop of the waste battery pack, the first output end BTOU1 is connected with a charge loop of the waste battery pack, the second output end BTOUT2 is connected with a low-voltage collection area, and the detection output end BTZ is connected with the data processor;

when the voltage value of the waste battery pack is smaller than 12V, the battery detection unit is connected with the charging loop, and when the voltage value of the waste battery pack is larger than or equal to 12V, the battery detection unit is connected with the discharging loop.

2. The confluence dispensing system of claim 1, wherein: the induced electricity detection area is connected with the data processor and used for transmitting detection information to the data processor.

3. The confluence dispensing system of claim 1, wherein: the induced electricity detection area is connected with the induced electricity static collection area and used for collecting detected induced electricity.

4. The confluence dispensing system of claim 3, wherein: the induced electricity static collecting area is connected with the low-voltage energy collecting area and used for collecting induced electricity in a centralized mode.

5. The confluence dispensing system of claim 1, wherein: the low-voltage energy collection area is electrically connected with the low-voltage distribution driving unit and the boosting distribution driving unit.

6. The confluence dispensing system of claim 1, wherein: the battery detection unit further comprises a triode Q1, a single chip microcomputer, a first rectification circuit VC1 and a second rectification circuit VC2, wherein an emitter of the triode Q1 is connected with a first input end BTIN1, a base of a triode Q1 is connected with an output end of the single chip microcomputer, a collector of the triode Q1 is connected with an input end of the first rectification circuit VC1, and an output end of the first rectification circuit VC1 is connected with the input end of the single chip microcomputer through a series loop of a resistor R1, a resistor R2 and a resistor R3;

the input end of the second rectifying circuit VC2 is connected with the positive output end of the detection output end BTZ, and the output end of the second rectifying circuit VC2 is connected with the first output end BTOU 1.

7. The confluence dispensing system of claim 6, wherein: the battery detection unit further comprises a triode Q2, a second rectifying circuit VC3 and a fourth rectifying circuit VC4, and the base of the triode Q2 is connected with the output end of the single chip microcomputer; the collector of the triode Q2 is connected with the second output end BTOUT2, the emitter of the triode Q2 is connected with the input end of the second rectifying circuit VC3, and the output end of the second rectifying circuit VC3 is connected with the negative output end of the detection output end BTZ through the resistor R300; and the second input end BTIN2 is connected with the negative output end of the detection output end BTZ through a fourth rectifying circuit VC 4.

8. The confluence dispensing system of claim 1, wherein: the induction electricity detection area comprises first input ports IN11 and IN12, second input ports IN21 and IN22, and third input ports IN31 and IN32, and is used for being connected with household electric appliance equipment;

the faradic detection region includes a first output port OU1 and OU2 for connection to a faradic collection region.

9. The confluence dispensing system of claim 1, wherein: the region to be thrown comprises second OUTPUT ports OUTPUT1 and OUTPUT2, and is used for being connected with the auxiliary direct current capacitor bank; the to-be-dosed zone comprises a second INPUT port INPUT1 and INPUT2 for connection to the boost storage zone.

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