CN205942329U - Arsenic ion concentration real -time processing's embedded device that exceeds standard in sewage - Google Patents

Abstract

The utility model relates to an arsenic ion concentration real -time processing's embedded device that exceeds standard in sewage belongs to electron technical field. The utility model discloses electricity generation circuit module links to each other with screw, battery respectively, single -chip computer control module respectively with battery, alarm circuit module, regularly circuit module, electrical control valve I, detect circuit module, the circuit module that bleeds, electrical control valve II, electrical control valve III and workbin control circuit module link to each other, single -chip computer control module 0 connects the detection case, detection case, spelter are connected respectively to the detection circuitry module, through positive pole voltammetry electrolysis spelter generate current signal, workbin control circuit module is connected with container case, level sensor respectively, the liquid level variation of the solution of level sensor test container incasement to workbin control circuit module department sends a signal. The utility model discloses a detection, alarm and integrated treatment when reasonable constitution and connecting makes it can realize effectively that the arsenic ion exceeds standard.

Description

The embedded equipment of arsenic ion concentration over-standard real-time processing in a kind of sewage

Technical field

The utility model is related to a kind of embedded equipment of arsenic ion concentration over-standard real-time processing in sewage, belongs to electronics skill Art field.

Background technology

Develop rapidly with industrial, factory's quantity is also increasing rapidly.The industry that factory produces during producing Waste water and industrial waste gas increase in a large number.Substantial amounts of arsenic is contained in the sewage producing in the smelting process of some heavy metals, these Sewage is directly discharged among river after simply being processed, and the vegetation for lower reaches of river and the domestic water of the people are made Become pollution.

Set up the embedded equipment of arsenic ion concentration over-standard real-time processing in sewage, need to consider arsenic ion concentration in sewage Connectivity problem between the composition of the embedded equipment of exceeded real-time processing and composition.

Content of the invention

The utility model provides a kind of embedded equipment of arsenic ion concentration over-standard real-time processing in sewage, for solution Certainly to the connectivity problem between setting up the composition of the embedded equipment of arsenic ion concentration over-standard real-time processing in sewage and constituting.

The technical solution of the utility model is：The embedded equipment of arsenic ion concentration over-standard real-time processing in a kind of sewage, Including screw 1, electricity-generating circuit module 2, battery 3, circuit for alarming module 4, single chip control module 5, timing circuit module 6th, detection case 7, electric control valve I 8, spelter 9, testing circuit module 10, pumping circuit module 11, sewage conduct 12, electric control valve II 13, container case 14, electric control valve III 15, liquid level sensor 16, hopper control circuit module 17；

Wherein electricity-generating circuit module 2 is connected with screw 1, battery 3 respectively, single chip control module 5 respectively with electric power storage Pond 3, circuit for alarming module 4, timing circuit module 6, electric control valve I 8, testing circuit module 10, pumping circuit module 11, automatically controlled Valve II 13, electric control valve III 15 are connected with hopper control circuit module 17, sewage conduct 12 connecting detection case 7；Testing circuit Module 10 connecting detection case 7, spelter 9 respectively, is electrolysed spelter 9 by anode voltammetry and produces current signal；Hopper control circuit Module 17 is connected with container case 14, liquid level sensor 16 respectively, the liquid level of the solution in liquid level sensor 16 detection container case 14 Change, and transmit a signal at hopper control circuit module 17.

Described circuit for alarming module 4 includes resistance R1, resistance R2, resistance R3, resistance R4, resistance R5, resistance R6, amplifier Fa1, electric capacity C1, electric capacity C2, loudspeaker V2, NE555 chip；Wherein one end of resistance R1, R2 and single chip control module 5 interface phase Even, the other end of resistance R1 is connected with the in-phase input end of amplifier Fa1, and the other end of resistance R2 is anti-phase with amplifier Fa1's Input is connected, and one end of resistance R3 is connected on resistance R2, and the other end of resistance R3 connects the output end of amplifier Fa1, electricity Resistance R4 one end, resistance R4 one end is also connected with NE555 chip, and the resistance R4 other end connects resistance R5 one end, NE555 chip, resistance The R5 other end connects NE555 chip, and electric capacity C2 one end is connected on loudspeaker V2, and the electric capacity C2 other end connects NE555 chip, electric capacity C1 one end connects resistance R5, and the electric capacity C1 other end connects electric capacity C2, and resistance R6 one end is connected to loudspeaker V2 one end, and resistance R6 is another End connects NE555 chip.

Described timing circuit module 6 includes electric capacity C13, electric capacity C14, crystal oscillator X, 80C51 single-chip microcomputer, amplifier V1, resistance R7；Wherein crystal oscillator X and 80C51 single-chip microcomputer carry out in parallel, then are connected with electric capacity C13, electric capacity C14, shape Become the circuit of a closure, one end of resistance R7 is connected with single chip control module 5 interface, the resistance R7 other end is mono- with 80C51 Piece machine interface is connected, and one end of amplifier V1 is connected with single chip control module 5 interface, and the amplifier V1 other end is mono- with 80C51 Piece machine interface is connected.

Described pumping circuit module 11 includes resistance R8, resistance R9, switch K5, relay coil P1, contactor coil P2； Wherein one end of resistance R8 is connected with single chip control module 5 interface, and the other end of resistance R8 is connected with one end of switch K5, opens The other end of K5 closing is connected with one end of relay coil P2, and relay coil P2 and contactor coil P1 is connected in parallel on circuit In, the other end of relay coil P1 is connected with resistance R9, and the other end of resistance R9 is connected with single chip control module 5 interface.

Described testing circuit module 10 includes resistance R10, resistance R11, resistance R12, resistance R13, resistance R14, resistance R15, amplifier L1, amplifier L2, AT89C51 chip；Wherein resistance R11 one end is connected with single chip control module 5 interface, electricity On another in-phase input end terminating at amplifier L1 of resistance R11, one end of resistance R12 is connected with resistance R11, and resistance R12 is another Terminate on the inverting input of amplifier L1, resistance R13 one end is connected with single chip control module 5 interface, and resistance R13 is another Terminate on resistance R12, the in-phase input end of amplifier L2 is connected to one end of resistance R11, the inverting input of amplifier L2 It is connected on resistance R13, the output end of amplifier L2 is connected to resistance R15 one end, and the output end of amplifier L1 connects resistance R14 One end, the resistance R15 other end connects AT89C51 chip, and the resistance R14 other end connects AT89C51 chip.

Described hopper control circuit module 17 includes amplifier OP1, resistance R16, electric capacity C3, electric capacity C4, electric capacity C5, electric capacity C6, electric capacity C7, electric capacity C8, electric capacity Cx, electric capacity C9, electric capacity C10, switch K1, switch K2, switch K3, switch K4；Wherein electric capacity C8, C9 one end is grounded, another termination capacitor Cx of electric capacity C8, C9 one end, switch K3 one end ground connection, and electric capacity C3 one end is grounded, electric capacity C3 another termination switch K3 other end, electric capacity Cx one end, switch K4 one end is connected with single chip control module 5 interface, switchs K4 Another terminate on electric capacity C4, one end of electric capacity C4 ground connection, the another of electric capacity C4 terminates at electric capacity Cx one end, and switch K1 mono- terminates Ground, switch K1 is another to be terminated on switch K2, and electric capacity C10 one end is grounded, and electric capacity C10 is another to be terminated on switch K2, electric capacity C5 One end is connected on switch K2, and electric capacity C5 is another to be terminated on the in-phase input end of amplifier OP1, and electric capacity C7 and resistance R16 is carried out One end in parallel is linked into the output of amplifier OP1, and the other end is connected with one end of electric capacity C6, switch K2, and electric capacity C6's is another One end is connected to the inverting input of amplifier OP1.

Described electric control valve I 8, electric control valve II 13, electric control valve III 15 structure are identical, and wherein electric control valve I 8 includes electricity Resistance R17, resistance R18, resistance R19, resistance R20, resistance R21, electric capacity C11, resistor Y1, electric capacity C12, TS555CN chip；Its Middle resistance R17 one end is connected with single chip control module 5 interface, and the resistance R17 other end is connected with resistor Y1, and resistor Y1 is also It is connected with resistance R18, TS555CN chip interface, one end of electric capacity C11 is connected on TS555CN chip interface, and electric capacity C11 is another One end is connected on electric capacity C12, and one end of electric capacity C12 connects resistance R20 one end, and the C12 other end connects electric capacity C11, resistance R20 mono- End is also connected with TS555CN chip interface, and the resistance R20 other end connects TS555CN chip interface, and one end of resistance R21 is connected to At resistance R20, the resistance R21 other end connects resistance R19 one end, and one end of resistance R18 connects TS555CN chip interface, R18's The other end is connected to TS555CN chip interface, and the resistance R19 other end is connect with single chip control module 5 interface, TS555CN chip Mouthful.

Described electricity-generating circuit module 2 includes resistance R22, resistance R23, resistance R24, resistance R25, electric capacity C15, diode D1, diode D2, diode D3, diode D4, diode D5, diode D6, diode D7, diode D8, diode D9, 89C51 single-chip microcomputer；Wherein one end of resistance R22, one end of resistance R24, the positive pole of diode D1, the negative pole of diode D5 all connect In resistance R23 end, the other end of resistance R22 is connected with diode D2 positive pole, diode D6 negative pole, the resistance R23 other end It is connected with diode D3 positive pole, diode D7 negative pole, the other end of resistance R24 and diode D4 positive pole, diode D8 negative pole phase Even, the positive pole of diode D1 is connected with the negative pole of diode D5, the negative pole of diode D1 respectively with diode D2, D3, D4 negative pole It is connected, the positive pole of diode D5 connects the positive pole of diode D6, D7, D8,5 points of 89C51 single-chip microcomputer, single chip control module respectively It is not connected with the negative pole of diode D3, resistance R25 one end is connected at electric capacity C15, the resistance R25 other end and diode D4 negative pole Connect, the negative pole of diode D9 is connected at electric capacity C15, and the positive pole of diode D9 is connected with 89C51 interface microcontroller, electric capacity C15 is also connected with the interface of 89C51 single-chip microcomputer, and 89C51 interface microcontroller is connected with the positive pole of diode D7, and diode D7 is just Pole is also connected with single chip control module 5 interface, and the negative pole of diode D8 connects the positive pole of D4, and diode D7 negative pole is just connecting D3 Pole, diode D6 negative pole connects D2 positive pole.

Described single chip control module 5 can adopt 80C51 single-chip microcomputer.

Operation principle of the present utility model is：

Anode voltammetry, the method reference are used for arsenic ion Concentration Testing in sewage《Ambroxol hydrochloride is in carbon The research of paste electrode Anodic voltammetry》In thought.The program is primarily with respect to the arsenic in waste water ion concentration of plant emissions Real-time detection, if occurring, arsenic in waste water ion concentration is exceeded to carry out integrated treatment to it.

Wherein single chip control module 5 issues a signal at timing circuit module 6, sets the time interval of response.When When reaching setting time, timing circuit module 6 issues a signal at single chip control module 5, and single chip control module 5 sends letter Number at pumping circuit module 11, pumping circuit module 11 receives the waste water suction discharged detection after signal by pipeline 12 In case 7.Detect whether the arsenic ion concentration in water is exceeded, and current signal is passed to testing circuit module 10 by anode voltammetry Place.If arsenic in waste water ion concentration is exceeded, testing circuit module 10 transmits a signal at single chip control module 5, single-chip microcomputer control Molding block 5 transmits a signal at circuit for alarming module 4, carries out alarm sounds；Single chip control module 5 transmits a signal to electrically-controlled valve At door III 15, open electric control valve III 15 input aqua calcis and synthesis is carried out for exceeded sewage；Single-chip Controlling mould Block 5 transmits a signal at electric control valve I 8, opens electric control valve I 8 and releases the waste water in detection case 7.Liquid level sensor 16 for Aqua calcis liquid level in container case 14 carries out real-time detection, when the liquid level in container case 14 is less than given threshold, material Think that control circuit module 17 transmits a signal at single chip control module 5, single chip control module 5 transmits a signal to electric control valve At II 13, open electric control valve II 13 and aqua calcis is injected in container case 14.

Wherein electricity-generating circuit module 2 is connected with screw 1, and current scour screw 1 goes to and generated electricity.Electricity-generating circuit mould Block 2 is connected with battery 3, and generating power by water current is carried out being stored at battery 3.Battery 3 and liquid level sensor 16, electrically operated valve II 13, electrically operated valve III 15, hopper control circuit module 17, timing circuit module 6, pumping circuit module 11, detection case 7, electricity Control valve I 8, testing circuit module 10, circuit for alarming module 4 are connected, and are powered for them.The arrangement achieves self-powered and The functions such as automation, energy-conserving and environment-protective, real-time control.

The beneficial effects of the utility model are：Make it can be effectively realized arsenic ion by rational composition and its connection When exceeded detection, alarm and integrated treatment；Save the trouble of manpower detection, ensure that in water quality, arsenic content is up to standard, safely, in fact When, environmental protection.

Brief description

Fig. 1 is overall construction drawing of the present utility model；

Fig. 2 is circuit for alarming module circuit diagram of the present utility model；

Fig. 3 is timing circuit module circuit diagram of the present utility model；

Fig. 4 is pumping circuit figure of the present utility model；

Fig. 5 is the testing circuit module circuit diagram of utility model；

Fig. 6 is hopper control circuit module circuit diagram of the present utility model；

Fig. 7 is the electric control valve circuit diagram of utility model；

Fig. 8 is electricity-generating circuit module circuit diagram of the present utility model；

In figure is respectively numbered：1- screw, 2- electricity-generating circuit module, 3- battery, 4- circuit for alarming module, 5- single-chip microcomputer Control module, 6- timing circuit module, 7- detection case, 8- electric control valve I, 9- spelter, 10- testing circuit module, 11- pumping electricity Road module, 12- sewage conduct, 13- electric control valve II, 14- container case, 15- electric control valve III, 16- liquid level sensor, 17- material Case control circuit module.

Specific embodiment

Embodiment 1：As shown in figures 1-8, in a kind of sewage arsenic ion concentration over-standard real-time processing embedded equipment, including Screw 1, electricity-generating circuit module 2, battery 3, circuit for alarming module 4, single chip control module 5, timing circuit module 6, inspection Measuring tank 7, electric control valve I 8, spelter 9, testing circuit module 10, pumping circuit module 11, sewage conduct 12, electric control valve II 13, Container case 14, electric control valve III 15, liquid level sensor 16, hopper control circuit module 17；

Wherein electricity-generating circuit module 2 is connected with screw 1, battery 3 respectively, single chip control module 5 respectively with electric power storage Pond 3, circuit for alarming module 4, timing circuit module 6, electric control valve I 8, testing circuit module 10, pumping circuit module 11, automatically controlled Valve II 13, electric control valve III 15 are connected with hopper control circuit module 17, sewage conduct 12 connecting detection case 7；Testing circuit Module 10 connecting detection case 7, spelter 9 respectively, is electrolysed spelter 9 by anode voltammetry and produces current signal；Hopper control circuit Module 17 is connected with container case 14, liquid level sensor 16 respectively, the liquid level of the solution in liquid level sensor 16 detection container case 14 Change, and transmit a signal at hopper control circuit module 17.

Described circuit for alarming module 4 includes resistance R1, resistance R2, resistance R3, resistance R4, resistance R5, resistance R6, amplifier Fa1, electric capacity C1, electric capacity C2, loudspeaker V2, NE555 chip；Wherein one end of resistance R1, R2 and single chip control module 5 interface phase Even, the other end of resistance R1 is connected with the in-phase input end of amplifier Fa1, and the other end of resistance R2 is anti-phase with amplifier Fa1's Input is connected, and one end of resistance R3 is connected on resistance R2, and the other end of resistance R3 connects the output end of amplifier Fa1, electricity Resistance R4 one end, resistance R4 one end is also connected with NE555 chip, and the resistance R4 other end connects resistance R5 one end, NE555 chip, resistance The R5 other end connects NE555 chip, and electric capacity C2 one end is connected on loudspeaker V2, and the electric capacity C2 other end connects NE555 chip, electric capacity C1 one end connects resistance R5, and the electric capacity C1 other end connects electric capacity C2, and resistance R6 one end is connected to loudspeaker V2 one end, and resistance R6 is another End connects NE555 chip.

Described timing circuit module 6 includes electric capacity C13, electric capacity C14, crystal oscillator X, 80C51 single-chip microcomputer, amplifier V1, resistance R7；Wherein crystal oscillator X and 80C51 single-chip microcomputer carry out in parallel, then are connected with electric capacity C13, electric capacity C14, shape Become the circuit of a closure, one end of resistance R7 is connected with single chip control module 5 interface, the resistance R7 other end is mono- with 80C51 Piece machine interface is connected, and one end of amplifier V1 is connected with single chip control module 5 interface, and the amplifier V1 other end is mono- with 80C51 Piece machine interface is connected.

Described pumping circuit module 11 includes resistance R8, resistance R9, switch K5, relay coil P1, contactor coil P2； Wherein one end of resistance R8 is connected with single chip control module 5 interface, and the other end of resistance R8 is connected with one end of switch K5, opens The other end of K5 closing is connected with one end of relay coil P2, and relay coil P2 and contactor coil P1 is connected in parallel on circuit In, the other end of relay coil P1 is connected with resistance R9, and the other end of resistance R9 is connected with single chip control module 5 interface.

Described testing circuit module 10 includes resistance R10, resistance R11, resistance R12, resistance R13, resistance R14, resistance R15, amplifier L1, amplifier L2, AT89C51 chip；Wherein resistance R11 one end is connected with single chip control module 5 interface, electricity On another in-phase input end terminating at amplifier L1 of resistance R11, one end of resistance R12 is connected with resistance R11, and resistance R12 is another Terminate on the inverting input of amplifier L1, resistance R13 one end is connected with single chip control module 5 interface, and resistance R13 is another Terminate on resistance R12, the in-phase input end of amplifier L2 is connected to one end of resistance R11, the inverting input of amplifier L2 It is connected on resistance R13, the output end of amplifier L2 is connected to resistance R15 one end, and the output end of amplifier L1 connects resistance R14 One end, the resistance R15 other end connects AT89C51 chip, and the resistance R14 other end connects AT89C51 chip.

Described hopper control circuit module 17 includes amplifier OP1, resistance R16, electric capacity C3, electric capacity C4, electric capacity C5, electric capacity C6, electric capacity C7, electric capacity C8, electric capacity Cx, electric capacity C9, electric capacity C10, switch K1, switch K2, switch K3, switch K4；Wherein electric capacity C8, C9 one end is grounded, another termination capacitor Cx of electric capacity C8, C9 one end, switch K3 one end ground connection, and electric capacity C3 one end is grounded, electric capacity C3 another termination switch K3 other end, electric capacity Cx one end, switch K4 one end is connected with single chip control module 5 interface, switchs K4 Another terminate on electric capacity C4, one end of electric capacity C4 ground connection, the another of electric capacity C4 terminates at electric capacity Cx one end, and switch K1 mono- terminates Ground, switch K1 is another to be terminated on switch K2, and electric capacity C10 one end is grounded, and electric capacity C10 is another to be terminated on switch K2, electric capacity C5 One end is connected on switch K2, and electric capacity C5 is another to be terminated on the in-phase input end of amplifier OP1, and electric capacity C7 and resistance R16 is carried out One end in parallel is linked into the output of amplifier OP1, and the other end is connected with one end of electric capacity C6, switch K2, and electric capacity C6's is another One end is connected to the inverting input of amplifier OP1.

Described electric control valve I 8, electric control valve II 13, electric control valve III 15 structure are identical, and wherein electric control valve I 8 includes electricity Resistance R17, resistance R18, resistance R19, resistance R20, resistance R21, electric capacity C11, resistor Y1, electric capacity C12, TS555CN chip；Its Middle resistance R17 one end is connected with single chip control module 5 interface, and the resistance R17 other end is connected with resistor Y1, and resistor Y1 is also It is connected with resistance R18, TS555CN chip interface, one end of electric capacity C11 is connected on TS555CN chip interface, and electric capacity C11 is another One end is connected on electric capacity C12, and one end of electric capacity C12 connects resistance R20 one end, and the C12 other end connects electric capacity C11, resistance R20 mono- End is also connected with TS555CN chip interface, and the resistance R20 other end connects TS555CN chip interface, and one end of resistance R21 is connected to At resistance R20, the resistance R21 other end connects resistance R19 one end, and one end of resistance R18 connects TS555CN chip interface, R18's The other end is connected to TS555CN chip interface, and the resistance R19 other end is connect with single chip control module 5 interface, TS555CN chip Mouthful.

Described electricity-generating circuit module 2 includes resistance R22, resistance R23, resistance R24, resistance R25, electric capacity C15, diode D1, diode D2, diode D3, diode D4, diode D5, diode D6, diode D7, diode D8, diode D9, 89C51 single-chip microcomputer；Wherein one end of resistance R22, one end of resistance R24, the positive pole of diode D1, the negative pole of diode D5 all connect In resistance R23 end, the other end of resistance R22 is connected with diode D2 positive pole, diode D6 negative pole, the resistance R23 other end It is connected with diode D3 positive pole, diode D7 negative pole, the other end of resistance R24 and diode D4 positive pole, diode D8 negative pole phase Even, the positive pole of diode D1 is connected with the negative pole of diode D5, the negative pole of diode D1 respectively with diode D2, D3, D4 negative pole It is connected, the positive pole of diode D5 connects the positive pole of diode D6, D7, D8,5 points of 89C51 single-chip microcomputer, single chip control module respectively It is not connected with the negative pole of diode D3, resistance R25 one end is connected at electric capacity C15, the resistance R25 other end and diode D4 negative pole Connect, the negative pole of diode D9 is connected at electric capacity C15, and the positive pole of diode D9 is connected with 89C51 interface microcontroller, electric capacity C15 is also connected with the interface of 89C51 single-chip microcomputer, and 89C51 interface microcontroller is connected with the positive pole of diode D7, and diode D7 is just Pole is also connected with single chip control module 5 interface, and the negative pole of diode D8 connects the positive pole of D4, and diode D7 negative pole is just connecting D3 Pole, diode D6 negative pole connects D2 positive pole.

Embodiment 2：As shown in figures 1-8, in a kind of sewage arsenic ion concentration over-standard real-time processing embedded equipment, including Screw 1, electricity-generating circuit module 2, battery 3, circuit for alarming module 4, single chip control module 5, timing circuit module 6, inspection Measuring tank 7, electric control valve I 8, spelter 9, testing circuit module 10, pumping circuit module 11, sewage conduct 12, electric control valve II 13, Container case 14, electric control valve III 15, liquid level sensor 16, hopper control circuit module 17；

Wherein electricity-generating circuit module 2 is connected with screw 1, battery 3 respectively, single chip control module 5 respectively with electric power storage Pond 3, circuit for alarming module 4, timing circuit module 6, electric control valve I 8, testing circuit module 10, pumping circuit module 11, automatically controlled Valve II 13, electric control valve III 15 are connected with hopper control circuit module 17, sewage conduct 12 connecting detection case 7；Testing circuit Module 10 connecting detection case 7, spelter 9 respectively, is electrolysed spelter 9 by anode voltammetry and produces current signal；Hopper control circuit Module 17 is connected with container case 14, liquid level sensor 16 respectively, the liquid level of the solution in liquid level sensor 16 detection container case 14 Change, and transmit a signal at hopper control circuit module 17.

Described circuit for alarming module 4 includes resistance R1, resistance R2, resistance R3, resistance R4, resistance R5, resistance R6, amplifier Fa1, electric capacity C1, electric capacity C2, loudspeaker V2, NE555 chip；Wherein one end of resistance R1, R2 and single chip control module 5 interface phase Even, the other end of resistance R1 is connected with the in-phase input end of amplifier Fa1, and the other end of resistance R2 is anti-phase with amplifier Fa1's Input is connected, and one end of resistance R3 is connected on resistance R2, and the other end of resistance R3 connects the output end of amplifier Fa1, electricity Resistance R4 one end, resistance R4 one end is also connected with NE555 chip, and the resistance R4 other end connects resistance R5 one end, NE555 chip, resistance The R5 other end connects NE555 chip, and electric capacity C2 one end is connected on loudspeaker V2, and the electric capacity C2 other end connects NE555 chip, electric capacity C1 one end connects resistance R5, and the electric capacity C1 other end connects electric capacity C2, and resistance R6 one end is connected to loudspeaker V2 one end, and resistance R6 is another End connects NE555 chip.

Embodiment 3：As shown in figures 1-8, in a kind of sewage arsenic ion concentration over-standard real-time processing embedded equipment, including Screw 1, electricity-generating circuit module 2, battery 3, circuit for alarming module 4, single chip control module 5, timing circuit module 6, inspection Measuring tank 7, electric control valve I 8, spelter 9, testing circuit module 10, pumping circuit module 11, sewage conduct 12, electric control valve II 13, Container case 14, electric control valve III 15, liquid level sensor 16, hopper control circuit module 17；

Wherein electricity-generating circuit module 2 is connected with screw 1, battery 3 respectively, single chip control module 5 respectively with electric power storage Pond 3, circuit for alarming module 4, timing circuit module 6, electric control valve I 8, testing circuit module 10, pumping circuit module 11, automatically controlled Valve II 13, electric control valve III 15 are connected with hopper control circuit module 17, sewage conduct 12 connecting detection case 7；Testing circuit Module 10 connecting detection case 7, spelter 9 respectively, is electrolysed spelter 9 by anode voltammetry and produces current signal；Hopper control circuit Module 17 is connected with container case 14, liquid level sensor 16 respectively, the liquid level of the solution in liquid level sensor 16 detection container case 14 Change, and transmit a signal at hopper control circuit module 17.

Described timing circuit module 6 includes electric capacity C13, electric capacity C14, crystal oscillator X, 80C51 single-chip microcomputer, amplifier V1, resistance R7；Wherein crystal oscillator X and 80C51 single-chip microcomputer carry out in parallel, then are connected with electric capacity C13, electric capacity C14, shape Become the circuit of a closure, one end of resistance R7 is connected with single chip control module 5 interface, the resistance R7 other end is mono- with 80C51 Piece machine interface is connected, and one end of amplifier V1 is connected with single chip control module 5 interface, and the amplifier V1 other end is mono- with 80C51 Piece machine interface is connected.

Embodiment 4：As shown in figures 1-8, in a kind of sewage arsenic ion concentration over-standard real-time processing embedded equipment, including Screw 1, electricity-generating circuit module 2, battery 3, circuit for alarming module 4, single chip control module 5, timing circuit module 6, inspection Measuring tank 7, electric control valve I 8, spelter 9, testing circuit module 10, pumping circuit module 11, sewage conduct 12, electric control valve II 13, Container case 14, electric control valve III 15, liquid level sensor 16, hopper control circuit module 17；

Wherein electricity-generating circuit module 2 is connected with screw 1, battery 3 respectively, single chip control module 5 respectively with electric power storage Pond 3, circuit for alarming module 4, timing circuit module 6, electric control valve I 8, testing circuit module 10, pumping circuit module 11, automatically controlled Valve II 13, electric control valve III 15 are connected with hopper control circuit module 17, sewage conduct 12 connecting detection case 7；Testing circuit Module 10 connecting detection case 7, spelter 9 respectively, is electrolysed spelter 9 by anode voltammetry and produces current signal；Hopper control circuit Module 17 is connected with container case 14, liquid level sensor 16 respectively, the liquid level of the solution in liquid level sensor 16 detection container case 14 Change, and transmit a signal at hopper control circuit module 17.

Described pumping circuit module 11 includes resistance R8, resistance R9, switch K5, relay coil P1, contactor coil P2； Wherein one end of resistance R8 is connected with single chip control module 5 interface, and the other end of resistance R8 is connected with one end of switch K5, opens The other end of K5 closing is connected with one end of relay coil P2, and relay coil P2 and contactor coil P1 is connected in parallel on circuit In, the other end of relay coil P1 is connected with resistance R9, and the other end of resistance R9 is connected with single chip control module 5 interface.

Embodiment 5：As shown in figures 1-8, in a kind of sewage arsenic ion concentration over-standard real-time processing embedded equipment, including Screw 1, electricity-generating circuit module 2, battery 3, circuit for alarming module 4, single chip control module 5, timing circuit module 6, inspection Measuring tank 7, electric control valve I 8, spelter 9, testing circuit module 10, pumping circuit module 11, sewage conduct 12, electric control valve II 13, Container case 14, electric control valve III 15, liquid level sensor 16, hopper control circuit module 17；

Wherein electricity-generating circuit module 2 is connected with screw 1, battery 3 respectively, single chip control module 5 respectively with electric power storage Pond 3, circuit for alarming module 4, timing circuit module 6, electric control valve I 8, testing circuit module 10, pumping circuit module 11, automatically controlled Valve II 13, electric control valve III 15 are connected with hopper control circuit module 17, sewage conduct 12 connecting detection case 7；Testing circuit Module 10 connecting detection case 7, spelter 9 respectively, is electrolysed spelter 9 by anode voltammetry and produces current signal；Hopper control circuit Module 17 is connected with container case 14, liquid level sensor 16 respectively, the liquid level of the solution in liquid level sensor 16 detection container case 14 Change, and transmit a signal at hopper control circuit module 17.

Described testing circuit module 10 includes resistance R10, resistance R11, resistance R12, resistance R13, resistance R14, resistance R15, amplifier L1, amplifier L2, AT89C51 chip；Wherein resistance R11 one end is connected with single chip control module 5 interface, electricity On another in-phase input end terminating at amplifier L1 of resistance R11, one end of resistance R12 is connected with resistance R11, and resistance R12 is another Terminate on the inverting input of amplifier L1, resistance R13 one end is connected with single chip control module 5 interface, and resistance R13 is another Terminate on resistance R12, the in-phase input end of amplifier L2 is connected to one end of resistance R11, the inverting input of amplifier L2 It is connected on resistance R13, the output end of amplifier L2 is connected to resistance R15 one end, and the output end of amplifier L1 connects resistance R14 One end, the resistance R15 other end connects AT89C51 chip, and the resistance R14 other end connects AT89C51 chip.

Embodiment 6：As shown in figures 1-8, in a kind of sewage arsenic ion concentration over-standard real-time processing embedded equipment, including Screw 1, electricity-generating circuit module 2, battery 3, circuit for alarming module 4, single chip control module 5, timing circuit module 6, inspection Measuring tank 7, electric control valve I 8, spelter 9, testing circuit module 10, pumping circuit module 11, sewage conduct 12, electric control valve II 13, Container case 14, electric control valve III 15, liquid level sensor 16, hopper control circuit module 17；

Wherein electricity-generating circuit module 2 is connected with screw 1, battery 3 respectively, single chip control module 5 respectively with electric power storage Pond 3, circuit for alarming module 4, timing circuit module 6, electric control valve I 8, testing circuit module 10, pumping circuit module 11, automatically controlled Valve II 13, electric control valve III 15 are connected with hopper control circuit module 17, sewage conduct 12 connecting detection case 7；Testing circuit Module 10 connecting detection case 7, spelter 9 respectively, is electrolysed spelter 9 by anode voltammetry and produces current signal；Hopper control circuit Module 17 is connected with container case 14, liquid level sensor 16 respectively, the liquid level of the solution in liquid level sensor 16 detection container case 14 Change, and transmit a signal at hopper control circuit module 17.

Described hopper control circuit module 17 includes amplifier OP1, resistance R16, electric capacity C3, electric capacity C4, electric capacity C5, electric capacity C6, electric capacity C7, electric capacity C8, electric capacity Cx, electric capacity C9, electric capacity C10, switch K1, switch K2, switch K3, switch K4；Wherein electric capacity C8, C9 one end is grounded, another termination capacitor Cx of electric capacity C8, C9 one end, switch K3 one end ground connection, and electric capacity C3 one end is grounded, electric capacity C3 another termination switch K3 other end, electric capacity Cx one end, switch K4 one end is connected with single chip control module 5 interface, switchs K4 Another terminate on electric capacity C4, one end of electric capacity C4 ground connection, the another of electric capacity C4 terminates at electric capacity Cx one end, and switch K1 mono- terminates Ground, switch K1 is another to be terminated on switch K2, and electric capacity C10 one end is grounded, and electric capacity C10 is another to be terminated on switch K2, electric capacity C5 One end is connected on switch K2, and electric capacity C5 is another to be terminated on the in-phase input end of amplifier OP1, and electric capacity C7 and resistance R16 is carried out One end in parallel is linked into the output of amplifier OP1, and the other end is connected with one end of electric capacity C6, switch K2, and electric capacity C6's is another One end is connected to the inverting input of amplifier OP1.

Embodiment 7：As shown in figures 1-8, in a kind of sewage arsenic ion concentration over-standard real-time processing embedded equipment, including Screw 1, electricity-generating circuit module 2, battery 3, circuit for alarming module 4, single chip control module 5, timing circuit module 6, inspection Measuring tank 7, electric control valve I 8, spelter 9, testing circuit module 10, pumping circuit module 11, sewage conduct 12, electric control valve II 13, Container case 14, electric control valve III 15, liquid level sensor 16, hopper control circuit module 17；

Wherein electricity-generating circuit module 2 is connected with screw 1, battery 3 respectively, single chip control module 5 respectively with electric power storage Pond 3, circuit for alarming module 4, timing circuit module 6, electric control valve I 8, testing circuit module 10, pumping circuit module 11, automatically controlled Valve II 13, electric control valve III 15 are connected with hopper control circuit module 17, sewage conduct 12 connecting detection case 7；Testing circuit Module 10 connecting detection case 7, spelter 9 respectively, is electrolysed spelter 9 by anode voltammetry and produces current signal；Hopper control circuit Module 17 is connected with container case 14, liquid level sensor 16 respectively, the liquid level of the solution in liquid level sensor 16 detection container case 14 Change, and transmit a signal at hopper control circuit module 17.

Described electric control valve I 8, electric control valve II 13, electric control valve III 15 structure are identical, and wherein electric control valve I 8 includes electricity Resistance R17, resistance R18, resistance R19, resistance R20, resistance R21, electric capacity C11, resistor Y1, electric capacity C12, TS555CN chip；Its Middle resistance R17 one end is connected with single chip control module 5 interface, and the resistance R17 other end is connected with resistor Y1, and resistor Y1 is also It is connected with resistance R18, TS555CN chip interface, one end of electric capacity C11 is connected on TS555CN chip interface, and electric capacity C11 is another One end is connected on electric capacity C12, and one end of electric capacity C12 connects resistance R20 one end, and the C12 other end connects electric capacity C11, resistance R20 mono- End is also connected with TS555CN chip interface, and the resistance R20 other end connects TS555CN chip interface, and one end of resistance R21 is connected to At resistance R20, the resistance R21 other end connects resistance R19 one end, and one end of resistance R18 connects TS555CN chip interface, R18's The other end is connected to TS555CN chip interface, and the resistance R19 other end is connect with single chip control module 5 interface, TS555CN chip Mouthful.

Embodiment 8：As shown in figures 1-8, in a kind of sewage arsenic ion concentration over-standard real-time processing embedded equipment, including Screw 1, electricity-generating circuit module 2, battery 3, circuit for alarming module 4, single chip control module 5, timing circuit module 6, inspection Measuring tank 7, electric control valve I 8, spelter 9, testing circuit module 10, pumping circuit module 11, sewage conduct 12, electric control valve II 13, Container case 14, electric control valve III 15, liquid level sensor 16, hopper control circuit module 17；

Wherein electricity-generating circuit module 2 is connected with screw 1, battery 3 respectively, single chip control module 5 respectively with electric power storage Pond 3, circuit for alarming module 4, timing circuit module 6, electric control valve I 8, testing circuit module 10, pumping circuit module 11, automatically controlled Valve II 13, electric control valve III 15 are connected with hopper control circuit module 17, sewage conduct 12 connecting detection case 7；Testing circuit Module 10 connecting detection case 7, spelter 9 respectively, is electrolysed spelter 9 by anode voltammetry and produces current signal；Hopper control circuit Module 17 is connected with container case 14, liquid level sensor 16 respectively, the liquid level of the solution in liquid level sensor 16 detection container case 14 Change, and transmit a signal at hopper control circuit module 17.

Described electricity-generating circuit module 2 includes resistance R22, resistance R23, resistance R24, resistance R25, electric capacity C15, diode D1, diode D2, diode D3, diode D4, diode D5, diode D6, diode D7, diode D8, diode D9, 89C51 single-chip microcomputer；Wherein one end of resistance R22, one end of resistance R24, the positive pole of diode D1, the negative pole of diode D5 all connect In resistance R23 end, the other end of resistance R22 is connected with diode D2 positive pole, diode D6 negative pole, the resistance R23 other end It is connected with diode D3 positive pole, diode D7 negative pole, the other end of resistance R24 and diode D4 positive pole, diode D8 negative pole phase Even, the positive pole of diode D1 is connected with the negative pole of diode D5, the negative pole of diode D1 respectively with diode D2, D3, D4 negative pole It is connected, the positive pole of diode D5 connects the positive pole of diode D6, D7, D8,5 points of 89C51 single-chip microcomputer, single chip control module respectively It is not connected with the negative pole of diode D3, resistance R25 one end is connected at electric capacity C15, the resistance R25 other end and diode D4 negative pole Connect, the negative pole of diode D9 is connected at electric capacity C15, and the positive pole of diode D9 is connected with 89C51 interface microcontroller, electric capacity C15 is also connected with the interface of 89C51 single-chip microcomputer, and 89C51 interface microcontroller is connected with the positive pole of diode D7, and diode D7 is just Pole is also connected with single chip control module 5 interface, and the negative pole of diode D8 connects the positive pole of D4, and diode D7 negative pole is just connecting D3 Pole, diode D6 negative pole connects D2 positive pole.

Embodiment 9：As shown in figures 1-8, in a kind of sewage arsenic ion concentration over-standard real-time processing embedded equipment, including Screw 1, electricity-generating circuit module 2, battery 3, circuit for alarming module 4, single chip control module 5, timing circuit module 6, inspection Measuring tank 7, electric control valve I 8, spelter 9, testing circuit module 10, pumping circuit module 11, sewage conduct 12, electric control valve II 13, Container case 14, electric control valve III 15, liquid level sensor 16, hopper control circuit module 17；

Wherein electricity-generating circuit module 2 is connected with screw 1, battery 3 respectively, single chip control module 5 respectively with electric power storage Pond 3, circuit for alarming module 4, timing circuit module 6, electric control valve I 8, testing circuit module 10, pumping circuit module 11, automatically controlled Valve II 13, electric control valve III 15 are connected with hopper control circuit module 17, sewage conduct 12 connecting detection case 7；Testing circuit Module 10 connecting detection case 7, spelter 9 respectively, is electrolysed spelter 9 by anode voltammetry and produces current signal；Hopper control circuit Module 17 is connected with container case 14, liquid level sensor 16 respectively, the liquid level of the solution in liquid level sensor 16 detection container case 14 Change, and transmit a signal at hopper control circuit module 17.

Above in conjunction with figure, specific embodiment of the present utility model is explained in detail, but the utility model does not limit In above-mentioned embodiment, in the ken that those of ordinary skill in the art possess, can also be new without departing from this practicality On the premise of type objective, various changes can be made.

Claims (8)

1. in a kind of sewage arsenic ion concentration over-standard real-time processing embedded equipment it is characterised in that：Including screw（1）、 Electricity-generating circuit module（2）, battery（3）, circuit for alarming module（4）, single chip control module（5）, timing circuit module（6）、 Detection case（7）, electric control valve I（8）, spelter（9）, testing circuit module（10）, pumping circuit module（11）, sewage conduct （12）, electric control valve II（13）, container case（14）, electric control valve III（15）, liquid level sensor（16）, hopper control circuit module （17）；

Wherein electricity-generating circuit module（2）Respectively with screw（1）, battery（3）It is connected, single chip control module（5）Respectively with Battery（3）, circuit for alarming module（4）, timing circuit module（6）, electric control valve I（8）, testing circuit module（10）, pumping Circuit module（11）, electric control valve II（13）, electric control valve III（15）With hopper control circuit module（17）It is connected, sewage conduct （12）Connecting detection case（7）；Testing circuit module（10）Connecting detection case respectively（7）, spelter（9）, by anode voltammetry electricity Solution spelter（9）Produce current signal；Hopper control circuit module（17）Respectively with container case（14）, liquid level sensor（16）Even Connect, liquid level sensor（16）Detection container case（14）The liquid level change of interior solution, and transmit a signal to hopper control circuit mould Block（17）Place.

2. in sewage according to claim 1 arsenic ion concentration over-standard real-time processing embedded equipment it is characterised in that： Described circuit for alarming module（4）Including resistance R1, resistance R2, resistance R3, resistance R4, resistance R5, resistance R6, amplifier Fa1, electricity Hold C1, electric capacity C2, loudspeaker V2, NE555 chip；Wherein one end of resistance R1, R2 and single chip control module（5）Interface is connected, The other end of resistance R1 is connected with the in-phase input end of amplifier Fa1, the anti-phase input of the other end of resistance R2 and amplifier Fa1 End is connected, and one end of resistance R3 is connected on resistance R2, and the other end of resistance R3 connects the output end of amplifier Fa1, resistance R4 One end, resistance R4 one end is also connected with NE555 chip, and the resistance R4 other end connects resistance R5 one end, NE555 chip, and resistance R5 is another One end connects NE555 chip, and electric capacity C2 one end is connected on loudspeaker V2, and the electric capacity C2 other end connects NE555 chip, electric capacity C1 mono- End connects resistance R5, and the electric capacity C1 other end connects electric capacity C2, and resistance R6 one end is connected to loudspeaker V2 one end, and the resistance R6 other end is even Connect NE555 chip.

3. in sewage according to claim 1 arsenic ion concentration over-standard real-time processing embedded equipment it is characterised in that： Described timing circuit module（6）Including electric capacity C13, electric capacity C14, crystal oscillator X, 80C51 single-chip microcomputer, amplifier V1, resistance R7；Wherein crystal oscillator X and 80C51 single-chip microcomputer carry out in parallel, then are connected with electric capacity C13, electric capacity C14, form one Circuit, one end of resistance R7 and the single chip control module of closure（5）Interface is connected, the resistance R7 other end and 80C51 single-chip microcomputer Interface is connected, one end of amplifier V1 and single chip control module（5）Interface is connected, the amplifier V1 other end and 80C51 monolithic Machine interface is connected.

4. in sewage according to claim 1 arsenic ion concentration over-standard real-time processing embedded equipment it is characterised in that： Described pumping circuit module（11）Including resistance R8, resistance R9, switch K5, relay coil P1, contactor coil P2；Wherein electricity One end of resistance R8 and single chip control module（5）Interface is connected, and the other end of resistance R8 is connected with one end of switch K5, switch The other end of K5 is connected with one end of relay coil P2, and relay coil P2 is in parallel with contactor coil P1 in circuit, continues The other end of electric apparatus coil P1 is connected with resistance R9, the other end of resistance R9 and single chip control module（5）Interface is connected.

5. in sewage according to claim 1 arsenic ion concentration over-standard real-time processing embedded equipment it is characterised in that： Described testing circuit module（10）Including resistance R10, resistance R11, resistance R12, resistance R13, resistance R14, resistance R15, amplification Device L1, amplifier L2, AT89C51 chip；Wherein resistance R11 one end and single chip control module（5）Interface is connected, resistance R11 On another in-phase input end terminating at amplifier L1, one end of resistance R12 is connected with resistance R11, and resistance R12 is another to be terminated at On the inverting input of amplifier L1, resistance R13 one end and single chip control module（5）Interface is connected, another termination of resistance R13 On resistance R12, the in-phase input end of amplifier L2 is connected to one end of resistance R11, and the inverting input of amplifier L2 connects On resistance R13, the output end of amplifier L2 is connected to resistance R15 one end, and the output end of amplifier L1 connects resistance R14 mono- End, the resistance R15 other end connects AT89C51 chip, and the resistance R14 other end connects AT89C51 chip.

6. in sewage according to claim 1 arsenic ion concentration over-standard real-time processing embedded equipment it is characterised in that： Described hopper control circuit module（17）Including amplifier OP1, resistance R16, electric capacity C3, electric capacity C4, electric capacity C5, electric capacity C6, electricity Hold C7, electric capacity C8, electric capacity Cx, electric capacity C9, electric capacity C10, switch K1, switch K2, switch K3, switch K4；Wherein electric capacity C8, C9 mono- End ground connection, another termination capacitor Cx of electric capacity C8, C9 one end, switch K3 one end ground connection, electric capacity C3 one end is grounded, the electric capacity C3 other end Connect the switch K3 other end, electric capacity Cx one end, switch K4 one end and single chip control module（5）Interface connects, and switchs the K4 other end It is connected on electric capacity C4, one end ground connection of electric capacity C4, the another of electric capacity C4 terminates at electric capacity Cx one end, switch K1 one end ground connection, opens Close another terminating at of K1 and switch on K2, electric capacity C10 one end is grounded, electric capacity C10 is another to be terminated on switch K2, and electric capacity C5 mono- terminates On switch K2, electric capacity C5 is another to be terminated on the in-phase input end of amplifier OP1, and electric capacity C7 and resistance R16 carries out in parallel one End is linked into the output of amplifier OP1, and the other end is connected with one end of electric capacity C6, switch K2, and the other end of electric capacity C6 is even It is connected on the inverting input of amplifier OP1.

7. in sewage according to claim 1 arsenic ion concentration over-standard real-time processing embedded equipment it is characterised in that： Described electric control valve I（8）, electric control valve II（13）, electric control valve III（15）Structure is identical, wherein electric control valve I（8）Including electricity Resistance R17, resistance R18, resistance R19, resistance R20, resistance R21, electric capacity C11, resistor Y1, electric capacity C12, TS555CN chip；Its Middle resistance R17 one end and single chip control module（5）Interface connects, and the resistance R17 other end is connected with resistor Y1, resistor Y1 Also it is connected with resistance R18, TS555CN chip interface, one end of electric capacity C11 is connected on TS555CN chip interface, electric capacity C11 The other end is connected on electric capacity C12, and one end of electric capacity C12 connects resistance R20 one end, and the C12 other end connects electric capacity C11, resistance R20 One end is also connected with TS555CN chip interface, and the resistance R20 other end connects TS555CN chip interface, and one end of resistance R21 connects At resistance R20, the resistance R21 other end connects resistance R19 one end, and one end of resistance R18 connects TS555CN chip interface, R18 The other end be connected to TS555CN chip interface, the resistance R19 other end and single chip control module（5）Interface, TS555CN core Piece interface.

8. in sewage according to claim 1 arsenic ion concentration over-standard real-time processing embedded equipment it is characterised in that： Described electricity-generating circuit module（2）Including resistance R22, resistance R23, resistance R24, resistance R25, electric capacity C15, diode D1, two poles Pipe D2, diode D3, diode D4, diode D5, diode D6, diode D7, diode D8, diode D9,89C51 monolithic Machine；Wherein one end of resistance R22, one end of resistance R24, the positive pole of diode D1, the negative pole of diode D5 are all connected on resistance R23 End, the other end of resistance R22 is connected with diode D2 positive pole, diode D6 negative pole, the resistance R23 other end and diode D3 Positive pole, diode D7 negative pole are connected, and the other end of resistance R24 is connected with diode D4 positive pole, diode D8 negative pole, diode D1 Positive pole be connected with the negative pole of diode D5, the negative pole of diode D1 is connected with diode D2, D3, D4 negative pole respectively, diode The positive pole of D5 connects the positive pole of diode D6, D7, D8,89C51 single-chip microcomputer, single chip control module respectively（5）Respectively with two poles The negative pole of pipe D3 connects, and resistance R25 one end is connected at electric capacity C15, and the resistance R25 other end is connected with diode D4 negative pole, and two The negative pole of pole pipe D9 is connected at electric capacity C15, and the positive pole of diode D9 is connected with 89C51 interface microcontroller, electric capacity C15 also with The interface of 89C51 single-chip microcomputer connects, and 89C51 interface microcontroller is connected with the positive pole of diode D7, the positive pole of diode D7 also with Single chip control module（5）Interface is connected, and the negative pole of diode D8 connects the positive pole of D4, and diode D7 negative pole connects D3 positive pole, Diode D6 negative pole connects D2 positive pole.