CN209387578U - A kind of electrolyte intermediate ion apparatus for measuring concentration - Google Patents

Abstract

The utility model relates to electrochemical fields, a kind of electrolyte intermediate ion apparatus for measuring concentration, including high-voltage DC power supply, charging resistor, charging cable, spark switch, lens, laser, laser power supply, impulse generator, power divider, attenuator, transmission line I, impedance matching circuit, oscillograph, transmission line II, sample cell and circuit for measuring potential, the ion concentration in electrolyte is measured using the circuit for measuring potential of special designing, stable and controllable high voltage square wave pulse is generated by the spark switch of laser triggering to be applied on electrolyte sample, measurement lower limit is low, the relatively low ion concns under high voltage in electrolyte can be measured；The method for using laser vertical incidence cathode surface carrys out Trigger Spark Switch to generate voltage pulse, can apply stable and controllable high voltage square wave pulse to electrolyte；Spark switch with special laser triggering can apply stable and controllable high voltage square wave pulse to generate voltage pulse to electrolyte.

Description

A kind of electrolyte intermediate ion apparatus for measuring concentration

Technical field

The utility model relates to electrochemical field, especially a kind of lower ion that can be measured under high voltage in electrolyte A kind of electrolyte intermediate ion apparatus for measuring concentration of concentration.

Background technique

Electrolyte is widely used in chemical field such as battery, capacitor, is also largely related in biological field, to electrolyte Research includes the research of the characteristic to ion concentration therein and electrolyte under high voltages, prior art defect one: existing Acidometer is generallyd use in technology to measure ion concentration, measurement lower limit can only be to 10^-4Mol/L magnitude；The prior art lacks Fall into two: when studying characteristic of the electrolyte under high voltage condition, needing to apply electrolyte has certain duration and width The voltage square wave pulse of degree, and the duration of the voltage square wave pulse and amplitude needs are adjustable, usually adopt in the prior art It is realized with spark switch, voltage pulse is adjusted by the distance between anode and cathode of adjusting spark switch and air pressure Amplitude, but this method generate voltage pulse rise time and amplitude can generate certain shake, influence voltage arteries and veins The stability of punching, a kind of electrolyte intermediate ion apparatus for measuring concentration are able to solve problem.

Utility model content

To solve the above-mentioned problems, the utility model is measured in electrolyte using the circuit for measuring potential of special designing Ion concentration, measurement lower limit is low, in addition, the method for using laser vertical incidence cathode surface carrys out Trigger Spark Switch to generate electricity Pulse is pressed, stable and controllable high voltage square wave pulse can be applied to electrolyte.

The technical scheme adopted by the utility model is

A kind of electrolyte intermediate ion apparatus for measuring concentration includes high-voltage DC power supply, charging resistor, charging cable, spark Switch, lens, laser, laser power supply, impulse generator, power divider, attenuator, transmission line I, impedance matching electricity Road, oscillograph, transmission line II, sample cell and circuit for measuring potential, high voltage range are 5kV to 15kV, the power divider With input, output end I and output end II；Spark switch includes shell, electrode I, blow vent, window I, electrode II, window II, insulative bottom cap and window III；The high-voltage DC power supply, charging resistor, the electrode II of charging cable and spark switch are successively electric Cable connection, the input terminal of the electrode I connection power divider of the spark switch, the output end I of power divider successively cable Connect transmission line II and sample cell, the core wire and sample cell casing insulation of transmission line II, the sample cell earthing of casing, power divider Output end II successively cable connection attenuator, transmission line I, impedance matching circuit and oscillograph, the laser, laser electricity Source and impulse generator successively cable connection, the lens are between spark switch and laser, the laser of laser transmitting Spark switch can be injected by lens；The shell of the spark switch is that cylinder is barrel-shaped and be connected with insulative bottom cap below, outside Shell inner upper is equipped with electrode I, and downward and be hemispherical, electrode II is installed on insulative bottom cap, electrode on the top of electrode I Upward and be hemispherical, the lower end electrode II is equipped with window III, and electrode II has the through-hole along axis, laser on the top of II The laser of transmitting can pass sequentially through window III and the through-hole, be mapped to the top of electrode I, the top of electrode I is with electrode II's The distance between top can be adjusted, and the side of shell has blow vent, window I and window II, by adjusting spark switch Position, the laser for enabling to laser to emit are mapped to the top of electrode I by the window II, can pass through the blow vent Spark switch is inflated and bleed air operation is to control the air pressure inside spark switch, window I is for observing laser transmitting Laser be mapped to electrode I top spot size；Circuit for measuring potential include membrane electrode, reference electrode, temperature sensor, in Heart conductor, shielded layer, ground plane, operational amplifier, buffer, filter I, filter II, digital quantizer I, number conversion Device II, microcontroller, DC power supply I, DC power supply II, USB converter and connector, the membrane electrode, reference electrode and temperature Degree sensor is respectively positioned in sample cell, and operational amplifier has noninverting input, reverse input end and output end, and buffer has Input terminal and output end, center conductor periphery successively have shielded layer and ground plane, and membrane electrode connects operation by center conductor The noninverting input of amplifier, reference electrode connect the reverse input end of operational amplifier by ground plane, operational amplifier Output end connects the input terminal of buffer, and the output end of buffer connects shielded layer, and the output end of operational amplifier is sequentially connected Filter I, digital quantizer I and microcontroller, temperature sensor are sequentially connected filter II, digital quantizer II and microcontroller Device, microcontroller are sequentially connected USB converter and connector, and DC power supply I and DC power supply II are connected to connector.Electricity Pole I and electrode II is made of ratio of 6: 4 tungsten-copper alloy, and the top hemispherical diameter of electrode I is 3 millimeters, electrode II's Top hemispherical diameter is 4 millimeters, and the adjustable range of distance is 1 millimeter to 15 between the top of electrode I and the top of electrode II Millimeter；The energy range of each laser pulse of laser transmitting is 200mJ to 900mJ, the duration of each laser pulse For 2 nanoseconds to 8 nanoseconds；Air pressure range inside spark switch is 50kPa to 700kPa.

The working method of circuit for measuring potential:

Membrane electrode, reference electrode and temperature sensor are respectively positioned in the electrolyte in sample cell, the membrane electrode have from Son selectivity is generated on the interface of its sensitive membrane and solution and is lived with to measured ion with containing when the solution of measured ion contacts Property directly related membrane potential, i.e., there is selective response to specific ion.

Center conductor, shielded layer and ground plane constitute coaxial signal transmission structure, are used for membrane electrode, reference electrode and fortune The connection between amplifier is calculated, wherein center conductor is transmitted for signal, and shielded layer is used to carry out the signal in center conductor Shielding, ground plane are grounded the electromagnetic interference to prevent external environment.Operational amplifier and buffer have cutoff frequency in 3dB 3kHz, for DC voltage to be amplified and exported to the analog signal that membrane electrode generates, in addition, operational amplifier and buffer It can prevent the parasite current between electromagnetic interference and circuit and environment.Filter I and filter II is second order Butterworth Low-pass filter, for mitigating 60Hz and frequency multiplication noise in circuit.Digital quantizer I and digital quantizer II respectively will filtering The analog signal of device I and filter II output is converted to digital signal, and microcontroller is for handling the digital signal And storage.

For the analog signal transmission generated by membrane electrode and reference electrode to operational amplifier, operational amplifier has high input Impedance, since the impedance of membrane electrode and reference electrode is several hundred megohms of magnitudes, the direct current pressure drop in circuit on transmission cable The analog signal of the output end of operational amplifier can be seriously affected, in order to enable the voltage drop minimizes, is connected using filter I It connects between shielded layer and ground plane, it is very sensitive to high-frequency electromagnetic interference since operational amplifier has high input impedance, Therefore, using the output end of filter I connection operational amplifier, above-mentioned design is so that voltage drop in circuit on transmission cable It is minimized to microvolt magnitude.

After the analog signal that membrane electrode generates is amplified and filters, it is digitally converted device I and is converted to digital signal, and transmit To microcontroller, the analog signal that temperature sensor generates is digitally converted device II and is converted to number after wave filter II filtering Word signal is transmitted to microcontroller, and microcontroller will be transmitted to USB converter after signal processing, and be transmitted to connector, finally, The signal that membrane electrode of the DC power supply I output after enhanced processing generates, DC power supply II are exported after enhanced processing The voltage signal of the signal that temperature sensor generates, analysis DC power supply I output can obtain in electrolyte to the dense of measured ion Information is spent, the voltage signal of analysis DC power supply II output can obtain the temperature value in electrolyte.

The generation of square voltage pulse:

Electrode I ground connection, high-voltage DC power supply is applied the voltage on electrode II by charging resistor and charging cable, so that electric Region between pole II and electrode I has high voltage differential, and the laser of laser transmitting passes through lens, window III and electrode II Through-hole is vertically mapped to the top electrode I, and due to photoelectric effect, electrode I generates seed electrons, the seed electrons make electrode II with The gas in region is by high electrical breakdown, spark switch conducting between electrode I.

The advantages of laser is vertically mapped to the electrode top I by the through-hole of lens, window III and electrode II is: compared to sharp Light oblique the case where being mapped to the electrode top I, the delay time of the voltage pulse of generation and shake are for other experiment conditions, such as gas Pressure, gaseous species, electrode material, the experiment condition dependence of electrode tip shape are much smaller, it is easier to control voltage pulse.

The step of ion concentration under high voltage in electrolyte is measured using a kind of electrolyte intermediate ion apparatus for measuring concentration Are as follows:

Step 1, sample cell is added in electrolyte sample to be measured, according to ionic species to be measured in electrolyte, selection is corresponding Membrane electrode, and membrane electrode, reference electrode and temperature sensor are placed in electrolyte sample；

Step 2, high-voltage DC power supply is opened, so that generating voltage difference between electrode I and electrode II；

Step 3, the air pressure inside spark switch is adjusted by blow vent, air pressure representative value is 300kPa；

Step 4, laser power supply and impulse generator are opened, and adjusts laser and lens position, so that laser is sent out The laser pulse penetrated vertically is mapped to the top electrode I by lens, the through-hole of window III and electrode II；

Step 5, the voltage waveform between the electrode I and electrode II of spark switch is monitored by oscillograph；

Step 6, the power of the laser pulse of laser transmitting is adjusted by laser power supply and impulse generator and is continued Time, pulse power representative value are 400mJ, and pulse duration representative value was 4 nanoseconds, so that between electrode I and electrode II Gas is breakdown, spark switch conducting；

Step 7, within the time of spark switch conducting, voltage is generated between the core wire and sample cell shell of transmission line II Difference, and be applied on electrolyte sample；

Step 8, the voltage signal of membrane electrode and reference electrode is exported after amplification and processing by DC power supply I；

Step 9, the voltage signal of analysis DC power supply I output, obtains the concentration value in electrolyte to measured ion.

The beneficial effects of the utility model are:

Utility model device generates stable and controllable high voltage square wave pulse by the spark switch of laser triggering To be applied on electrolyte sample, and the lower ion concentration in electrolyte can be measured.

Detailed description of the invention

It is further illustrated below with reference to the figure of the utility model:

Fig. 1 is utility model diagram；

Fig. 2 is spark switch enlarged diagram；

Fig. 3 is circuit for measuring potential schematic diagram.

In figure, 1. high-voltage DC power supplies, 2. charging resistors, 3. charging cables, 4. spark switch, 4-1. shell, 4-2. electrode I, 4-3. blow vent, 4-4. window I, 4-5. electrode II, 4-6. window II, 4-7. insulative bottom cap, 4-8. window III, 5. lens, 6. laser, 7. laser power supplies, 8. impulse generators, 9. power dividers, 10. attenuators, 11. transmission line I, 12. impedances Match circuit, 13. oscillographs, 14. transmission line II, 15. sample cells, 16. circuit for measuring potential, 16-1. membrane electrode, 16-2. ginseng Examine electrode, 16-3. temperature sensor, 16-4. center conductor, 16-5. shielded layer, 16-6. ground plane, 16-7. operational amplifier, 16-8. buffer, 16-9. filter I, 16-10. filter II, 16-11. digital quantizer I, 16-12. digital quantizer II, 16-13. microcontroller, 16-14. DC power supply I, 16-15. DC power supply II, 16-16.USB converter, 16-17. connector.

Specific embodiment

If Fig. 1 is utility model diagram, xyz is three-dimensional coordinate system, if Fig. 2 is spark switch amplification signal Figure, measuring device includes high-voltage DC power supply (1), charging resistor (2), charging cable (3), spark switch (4), lens (5), laser Device (6), laser power supply (7), impulse generator (8), power divider (9), attenuator (10), transmission line I (11), impedance It is with circuit (12), oscillograph (13), transmission line II (14), sample cell (15) and circuit for measuring potential (16), high voltage range 5kV to 15kV, the power divider (9) have input, output end I and output end II；Spark switch (4) includes shell (4-1), electrode I (4-2), blow vent (4-3), window I (4-4), electrode II (4-5), window II (4-6), insulative bottom cap (4- 7), window III (4-8)；The high-voltage DC power supply (1), charging resistor (2), charging cable (3) and spark switch (4) electrode II (4-5) successively cable connection, the input terminal of electrode I (4-2) the connection power divider (9) of the spark switch (4), power The output end I of distributor (9) successively cable connection transmission line II (14) and sample cell (15), the core wire and sample of transmission line II (14) Product slot (15) casing insulation, sample cell (15) earthing of casing, the output end II of power divider (9) successively cable connection attenuator (10), transmission line I (11), impedance matching circuit (12) and oscillograph (13), the laser (6), laser power supply (7) and arteries and veins Generator (8) successively cable connection is rushed, the lens (5) are located between spark switch (4) and laser (6), laser (6) hair The laser penetrated can inject spark switch (4) by lens (5)；The shell (4-1) of the spark switch (4) be cylinder it is barrel-shaped, And it is connected with insulative bottom cap (4-7) below, shell (4-1) inner upper is equipped with electrode I (4-2), the top of electrode I (4-2) It downward and is hemispherical, electrode II (4-5) is installed on insulative bottom cap (4-7), and the top of electrode II (4-5) is upward and for partly Spherical shape, the lower end electrode II (4-5) are equipped with window III (4-8), and electrode II (4-5) has the through-hole along axis, laser (6) The laser of transmitting can pass sequentially through window III (4-8) and the through-hole, be mapped to the top of electrode I (4-2), electrode I (4-2) The distance between top and the top of electrode II (4-5) can adjust, the side of shell (4-1) has blow vent (4-3), window Mouth I (4-4) and window II (4-6), by adjusting the position of spark switch (4), the laser for enabling to laser (6) to emit is logical Cross the top that the window II (4-6) is mapped to electrode I (4-2), can by the blow vent (4-3) to spark switch (4) into To control the internal air pressure of spark switch (4), air pressure range is 50kPa to 700kPa, window I (4- for row inflation and bleed air operation 4) spot size for being mapped to the top of electrode I (4-2) for observing the laser of laser (6) transmitting；Electrode I (4-2) and electrode II (4-5) is made of ratio of 6: 4 tungsten-copper alloy, and the top hemispherical diameter of electrode I (4-2) is 3 millimeters, electrode II The top hemispherical diameter of (4-5) is 4 millimeters, the tune of distance between the top of electrode I (4-2) and the top of electrode II (4-5) Adjusting range is 1 millimeter to 15 millimeters；The energy range of each laser pulse of laser (6) transmitting is 200mJ to 900mJ, often The duration of a laser pulse is 2 nanoseconds to 8 nanoseconds.

If Fig. 3 is circuit for measuring potential schematic diagram, circuit for measuring potential (16) includes membrane electrode (16-1), reference electrode (16-2), temperature sensor (16-3), center conductor (16-4), shielded layer (16-5), ground plane (16-6), operational amplifier (16-7), buffer (16-8), filter I (16-9), filter II (16-10), digital quantizer I (16-11), number conversion Device II (16-12), microcontroller (16-13), DC power supply I (16-14), DC power supply II (16-15), USB converter (16- 16) with connector (16-17), the membrane electrode (16-1), reference electrode (16-2) and temperature sensor (16-3) are respectively positioned on sample In product slot (15), operational amplifier (16-7) has noninverting input, reverse input end and output end, and buffer (16-8) has Input terminal and output end, center conductor (16-4) periphery successively have shielded layer (16-5) and ground plane (16-6), membrane electrode (16-1) by the noninverting input of center conductor (16-4) connection operational amplifier (16-7), reference electrode (16-2) is by connecing Stratum (16-6) connects the reverse input end of operational amplifier (16-7), and the output end of operational amplifier (16-7) connects buffer The output end of the input terminal of (16-8), buffer (16-8) connects shielded layer (16-5), the output end of operational amplifier (16-7) Be sequentially connected filter I (16-9), digital quantizer I (16-11) and microcontroller (16-13), temperature sensor (16-3) according to Secondary connection filter II (16-10), digital quantizer II (16-12) and microcontroller (16-13), microcontroller (16-13) according to Secondary connection USB converter (16-16) and connector (16-17), DC power supply I (16-14) and DC power supply II (16-15) are respectively It is connected to connector (16-17).

The working method of circuit for measuring potential (16):

Membrane electrode (16-1), reference electrode (16-2) and temperature sensor (16-3) are respectively positioned on the electrolysis in sample cell (15) In liquid, the membrane electrode (16-1) has ion selectivity, and containing when the solution of measured ion contacts, in its sensitive membrane and molten The membrane potential directly related with ion activity to be measured is generated on the interface of liquid, i.e., there is selective response to specific ion.

Center conductor (16-4), shielded layer (16-5) and ground plane (16-6) constitute coaxial signal transmission structure, are used for Connection between membrane electrode (16-1), reference electrode (16-2) and operational amplifier (16-7), wherein center conductor (16-4) is used It is transmitted in signal, shielded layer (16-5) is for shielding the signal in center conductor (16-4), ground plane (16-6) ground connection To prevent the electromagnetic interference of external environment.Operational amplifier (16-7) and buffer (16-8) have cutoff frequency 3kHz in 3dB, Analog signal for generating to membrane electrode (16-1) amplifies and exports DC voltage, in addition, operational amplifier (16-7) And buffer (16-8) can prevent the parasite current between electromagnetic interference and circuit and environment.Filter I (16-9) and filter Wave device II (16-10) is second order Butterworth LPF, for mitigating 60Hz and frequency multiplication noise in circuit.Number conversion The simulation that device I (16-11) and digital quantizer II (16-12) respectively exports filter I (16-9) and filter II (16-10) Signal is converted to digital signal, and microcontroller (16-13) is for being handled and being stored to the digital signal.

The analog signal transmission generated by membrane electrode (16-1) and reference electrode (16-2) is transported to operational amplifier (16-7) Calculating amplifier (16-7) has high input impedance, since the impedance of membrane electrode (16-1) and reference electrode (16-2) is several hundred megaohms Nurse magnitude, the direct current pressure drop in circuit on transmission cable can seriously affect the simulation letter of the output end of operational amplifier (16-7) Number, in order to enable the voltage drop minimizes, shielded layer (16-5) and ground plane (16-6) are connected to using filter I (16-9) Between, it is very sensitive to high-frequency electromagnetic interference since operational amplifier (16-7) has high input impedance, therefore, using filter The output end of wave device I (16-9) connection operational amplifier (16-7), above-mentioned design is so that voltage in circuit on transmission cable Drop is minimized to microvolt magnitude.

After the analog signal that membrane electrode (16-1) generates is amplified and filters, it is digitally converted device I (16-11) and is converted to number Word signal, and it is transmitted to microcontroller (16-13), the analog signal that temperature sensor (16-3) generates is through wave filter II (16- 10) it after filtering, is digitally converted device II (16-12) and is converted to digital data transmission to microcontroller (16-13), microcontroller (16-13) will be transmitted to USB converter (16-16) after signal processing, and be transmitted to connector (16-17), finally, DC power supply The signal that membrane electrode (16-1) of I (16-14) output after enhanced processing generates, DC power supply II (16-15) output are passed through The voltage signal of the signal that temperature sensor (16-3) after enhanced processing generates, analysis DC power supply I (16-14) output can The concentration information in electrolyte to measured ion is obtained, the voltage signal of analysis DC power supply II (16-15) output can obtain electricity Solve the temperature value in liquid.

The generation of square voltage pulse:

Electrode I (4-2) ground connection, high-voltage DC power supply (1) are applied the voltage to by charging resistor (2) and charging cable (3) On electrode II (4-5), so that the region between electrode II (4-5) and electrode I (4-2) has high voltage differential, laser (6) transmitting Laser the top electrode I (4-2) is vertically mapped to by the through-holes of lens (5), window III (4-8) and electrode II (4-5), due to Photoelectric effect, electrode I (4-2) generate seed electrons, and the seed electrons make area between electrode II (4-5) and electrode I (4-2) The gas in domain is by high electrical breakdown, spark switch (4) conducting.

Laser is vertically mapped to the top electrode I (4-2) by the through-hole of lens (5), window III (4-8) and electrode II (4-5) The advantages of be: the case where compared to laser oblique incidence to the top electrode I (4-2), the delay time of the voltage pulse of generation and tremble It moves for other experiment conditions, wants small such as the experiment condition dependence of air pressure, gaseous species, electrode material, electrode tip shape and obtain It is more, it is easier to control voltage pulse.

A kind of electrolyte intermediate ion apparatus for measuring concentration includes high-voltage DC power supply (1), charging resistor (2), charging Line (3), spark switch (4), lens (5), laser (6), laser power supply (7), impulse generator (8), power divider (9), attenuator (10), transmission line I (11), impedance matching circuit (12), oscillograph (13), transmission line II (14), sample cell (15) and circuit for measuring potential (16), high voltage range are 5kV to 15kV, and the power divider (9) has input terminal, output Hold I and output end II；Spark switch (4) includes shell (4-1), electrode I (4-2), blow vent (4-3), window I (4-4), electrode II (4-5), window II (4-6), insulative bottom cap (4-7) and window III (4-8)；The high-voltage DC power supply (1), charging resistor (2), the electrode II (4-5) of charging cable (3) and spark switch (4) successively cable connection, the electrode I (4- of the spark switch (4) 2) connect power divider (9) input terminal, the output end I of power divider (9) successively cable connection transmission line II (14) and Sample cell (15), the core wire and sample cell (15) casing insulation of transmission line II (14), sample cell (15) earthing of casing, power distribution The output end II of device (9) successively cable connection attenuator (10), transmission line I (11), impedance matching circuit (12) and oscillograph (13), successively cable connection, the lens (5) are located at fire for the laser (6), laser power supply (7) and impulse generator (8) The flowers are in blossom closes between (4) and laser (6), and the laser of laser (6) transmitting can inject spark switch (4) by lens (5)；Institute The shell (4-1) for stating spark switch (4) is that cylinder is barrel-shaped and be connected with below insulative bottom cap (4-7), on the inside shell (4-1) Side is equipped with electrode I (4-2), and downward and be hemispherical, electrode II (4-5) is installed on insulative bottom cap on the top of electrode I (4-2) On (4-7), upward and be hemispherical, the lower end electrode II (4-5) is equipped with window III (4-8) on the top of electrode II (4-5), Electrode II (4-5) has the through-hole along axis, and the laser of laser (6) transmitting can pass sequentially through window III (4-8) and described Through-hole, is mapped to the top of electrode I (4-2), and the distance between the top of electrode I (4-2) and the top of electrode II (4-5) can adjust The side of section, shell (4-1) has blow vent (4-3), window I (4-4) and window II (4-6), by adjusting spark switch (4) Position, the laser for enabling to laser (6) to emit is mapped to the top of electrode I (4-2), energy by the window II (4-6) Enough spark switch (4) is inflated by the blow vent (4-3) and bleed air operation is to control the internal gas of spark switch (4) Pressure, the laser that window I (4-4) is used to observe laser (6) transmitting are mapped to the spot size on the top of electrode I (4-2)；Potential is surveyed Amount circuit (16) includes membrane electrode (16-1), reference electrode (16-2), temperature sensor (16-3), center conductor (16-4), screen Cover layer (16-5), ground plane (16-6), operational amplifier (16-7), buffer (16-8), filter I (16-9), filter II (16-10), digital quantizer I (16-11), digital quantizer II (16-12), microcontroller (16-13), DC power supply I (16- 14), DC power supply II (16-15), USB converter (16-16) and connector (16-17), the membrane electrode (16-1), with reference to electricity Pole (16-2) and temperature sensor (16-3) are respectively positioned in sample cell (15), operational amplifier (16-7) have noninverting input, Reverse input end and output end, buffer (16-8) have input terminal and output end, and center conductor (16-4) periphery successively has Shielded layer (16-5) and ground plane (16-6), membrane electrode (16-1) pass through center conductor (16-4) connection operational amplifier (16-7) Noninverting input, reference electrode (16-2) by ground plane (16-6) connection operational amplifier (16-7) reverse input end, The output end of the input terminal of output end connection buffer (16-8) of operational amplifier (16-7), buffer (16-8) connects shielding Layer (16-5), the output end of operational amplifier (16-7) are sequentially connected filter I (16-9), digital quantizer I (16-11) and micro- Controller (16-13), temperature sensor (16-3) are sequentially connected filter II (16-10), digital quantizer II (16-12) and micro- Controller (16-13), microcontroller (16-13) are sequentially connected USB converter (16-16) and connector (16-17), DC power supply I (16-14) and DC power supply II (16-15) are connected to connector (16-17)；Electrode I (4-2) and electrode II (4-5) is equal It is made of ratio of 6: 4 tungsten-copper alloy, the top hemispherical diameter of electrode I (4-2) is 3 millimeters, the top of electrode II (4-5) Hemispherical diameter is 4 millimeters, and the adjustable range of distance is 1 milli between the top of electrode I (4-2) and the top of electrode II (4-5) Rice is to 15 millimeters；The energy range of each laser pulse of laser (6) transmitting is 200mJ to 900mJ, each laser pulse Duration is 2 nanoseconds to 8 nanoseconds；The internal air pressure range of spark switch (4) is 50kPa to 700kPa.

The utility model has the spark switch of special laser triggering to generate voltage pulse, can apply to electrolyte steady Fixed and controllable high voltage square wave pulse, and the ion measured in electrolyte using the circuit for measuring potential of special designing is dense Degree.

Claims (4)

1. a kind of electrolyte intermediate ion apparatus for measuring concentration, including high-voltage DC power supply (1), charging resistor (2), charging cable (3), Spark switch (4), lens (5), laser (6), laser power supply (7), impulse generator (8), power divider (9), decaying Device (10), transmission line I (11), impedance matching circuit (12), oscillograph (13), transmission line II (14), sample cell (15) and potential Measuring circuit (16), high voltage range are 5kV to 15kV, and the power divider (9) has input, output end I and output Hold II；Spark switch (4) include shell (4-1), electrode I (4-2), blow vent (4-3), window I (4-4), electrode II (4-5), Window II (4-6), insulative bottom cap (4-7) and window III (4-8)；The high-voltage DC power supply (1), charging resistor (2), charging The electrode II (4-5) of line (3) and spark switch (4) successively cable connection, electrode I (4-2) the connection function of the spark switch (4) The input terminal of rate distributor (9), the output end I of power divider (9) successively cable connection transmission line II (14) and sample cell (15), the core wire of transmission line II (14) and sample cell (15) casing insulation, sample cell (15) earthing of casing, power divider (9) Output end II successively cable connection attenuator (10), transmission line I (11), impedance matching circuit (12) and oscillograph (13), institute Laser (6), laser power supply (7) and impulse generator (8) successively cable connection are stated, the lens (5) are located at spark switch (4) between laser (6), the laser of laser (6) transmitting can inject spark switch (4) by lens (5),

It is characterized in that: the shell (4-1) of the spark switch (4) is that cylinder is barrel-shaped and be connected with below insulative bottom cap (4-7), Shell (4-1) inner upper is equipped with electrode I (4-2), the top of electrode I (4-2) downward and be hemispherical, electrode II (4-5) Be installed on insulative bottom cap (4-7), the top of electrode II (4-5) upward and be hemispherical, the lower end electrode II (4-5) is equipped with Window III (4-8), electrode II (4-5) have the through-hole along axis, and the laser of laser (6) transmitting can pass sequentially through window III (4-8) and the through-hole, are mapped to the top of electrode I (4-2), the top of the top of electrode I (4-2) and electrode II (4-5) it Between distance can adjust, the side of shell (4-1) has blow vent (4-3), window I (4-4) and window II (4-6), passes through The position for adjusting spark switch (4), the laser for enabling to laser (6) to emit are mapped to electrode I by the window II (4-6) The top of (4-2) can be inflated spark switch (4) by the blow vent (4-3) and bleed air operation is to control spark (4) internal air pressure is switched, the laser that window I (4-4) is used to observe laser (6) transmitting is mapped to the top of electrode I (4-2) Spot size；Circuit for measuring potential (16) include membrane electrode (16-1), reference electrode (16-2), temperature sensor (16-3), in Heart conductor (16-4), shielded layer (16-5), ground plane (16-6), operational amplifier (16-7), buffer (16-8), filter I (16-9), filter II (16-10), digital quantizer I (16-11), digital quantizer II (16-12), microcontroller (16- 13), DC power supply I (16-14), DC power supply II (16-15), USB converter (16-16) and connector (16-17), the film Electrode (16-1), reference electrode (16-2) and temperature sensor (16-3) are respectively positioned in sample cell (15), operational amplifier (16- 7) there is noninverting input, reverse input end and output end, buffer (16-8) has input terminal and output end, center conductor The periphery (16-4) successively has shielded layer (16-5) and ground plane (16-6), and membrane electrode (16-1) is connected by center conductor (16-4) The noninverting input of operational amplifier (16-7) is connect, reference electrode (16-2) connects operational amplifier by ground plane (16-6) The reverse input end of (16-7), the input terminal of output end connection buffer (16-8) of operational amplifier (16-7), buffer The output end of (16-8) connects shielded layer (16-5), the output end of operational amplifier (16-7) be sequentially connected filter I (16-9), Digital quantizer I (16-11) and microcontroller (16-13), temperature sensor (16-3) be sequentially connected filter II (16-10), Digital quantizer II (16-12) and microcontroller (16-13), microcontroller (16-13) are sequentially connected USB converter (16-16) With connector (16-17), DC power supply I (16-14) and DC power supply II (16-15) are connected to connector (16-17).

2. a kind of electrolyte intermediate ion apparatus for measuring concentration according to claim 1, it is characterized in that: electrode I (4-2) and electricity Pole II (4-5) is made of ratio of 6: 4 tungsten-copper alloy, and the top hemispherical diameter of electrode I (4-2) is 3 millimeters, electrode II The top hemispherical diameter of (4-5) is 4 millimeters, the tune of distance between the top of electrode I (4-2) and the top of electrode II (4-5) Adjusting range is 1 millimeter to 15 millimeters.

3. a kind of electrolyte intermediate ion apparatus for measuring concentration according to claim 1, it is characterized in that: laser (6) emits The energy range of each laser pulse be 200mJ to 900mJ, duration of each laser pulse is 2 nanoseconds to 8 nanoseconds.

4. a kind of electrolyte intermediate ion apparatus for measuring concentration according to claim 1, it is characterized in that: in spark switch (4) The air pressure range in portion is 50kPa to 700kPa.