TW202006192A - Power supply method and apparatus for ramp down and/or ramp up of electrolytic ozone generator including an AC/DC power converter, a micro-control chip MCU, a constant-current generating circuit, an ozone generator and an electrolytic bucket - Google Patents

Abstract

This invention relates to a power supply method and an apparatus for ramp down and/or ramp up of an electrolytic ozone generator. Power supply and removal of the electrolytic ozone generator are performed in a step-up/down or a ramp-up/down manner. The power supply apparatus includes an AC/DC power converter, a micro-control chip MCU, a constant-current generating circuit, an ozone generator and an electrolytic bucket. This invention prolongs the service life of the generator, and is simple and practical in structure and convenient for a user to install and replace.

Description

Power supply method and power supply device for electrolytic ozone generator to rise and fall slowly

The invention relates to a power supply method and power supply device for an electrolytic ozone generator that uses water as a raw material to slowly rise and fall, and belongs to the technical field of electrolytic ozone generators.

At present, the power supply method of the electrolytic ozone generator that uses water as a raw material is temporary power-on when it is in use and immediate power-off method when it is stopped or continuous power supply of the generator. It has the following disadvantages: In many application fields, the generator cannot be continuously powered. If the instantaneous power-off method is adopted, the hydrogen and oxygen ions accumulated on both sides of the membrane at the instant of power-off will diffuse in the opposite direction to form a reverse current, and the reverse direction. The hydrogen and oxygen ions will damage the catalyst layer of the anode and cathode, thus causing the service life of the generator to be greatly reduced. Moreover, the electrolytic ozone generator using water as the raw material adopts an external structure, which has the following disadvantages: in some application areas, the installation and replacement of the external structure generator is cumbersome, and a small amount of water is discharged from the cathode to the user. cause inconvenience.

In view of this, the inventor has specially researched and created the cost case, and hopes to use the proposal in this case to improve the existing shortcomings, so as to make the function of the product more perfect and ideal, and meet the actual needs.

The purpose of the present invention is to overcome the shortcomings of the above-mentioned prior art and provide a power supply method and power supply device for an electrolytic ozone generator that increases the service life of the generator, has a simple and practical structure, and is easy for users to install and replace.

The present invention can be achieved by the following measures: a power supply method for the electrolytic ozone generator to slowly rise and fall, characterized in that it includes the following steps: during the initial power supply to the electrolytic ozone generator, firstly provide an initial voltage of 1.5V to 2.3V, Then gradually increase the voltage to the generator constant current power supply area, after which the generator will be powered with a constant current; at the end of the power supply to the electrolytic ozone generator, first gradually reduce the voltage to leave the generator constant current power supply area until the initial voltage value, then Stop the power supply of the electrolytic ozone generator or maintain the initial voltage value of 1.5V to 2.3V for a long time.

In order to further achieve the object of the present invention, the initial voltage is 1.5V to 2.3V, the process of gradually increasing the voltage to the generator constant current power supply area is 5 seconds, and the gradually decreasing voltage is out of the generator constant current power supply area The process until the initial voltage value is 10 seconds, and then maintained for at least 3 minutes, and then stop the power supply of the electrolytic ozone generator or maintain the initial voltage value of 1.5V to 2.3V for a long time.

An electrolytic ozone generator power supply device with slow rise and slow down, characterized in that it includes an AC/DC power converter, a miniature control chip MCU, a constant current generating circuit, an ozone generator and an electrolytic water bucket; The control chip MCU and the constant current generating circuit, the micro control chip MCU is connected to the constant current generating circuit, the constant current generating circuit is connected to the ozone generator, and the ozone generator is connected to the electrolytic water bucket.

In order to further achieve the object of the present invention, the constant current generating circuit includes a resistor R1 and a resistor R9 connected to the micro control chip MCU, the resistor R1 is respectively connected to one end of the capacitor C2, the base of the transistor N2, and the other of the capacitor C2 One end is connected to the emitter of the transistor N2, the collector of the transistor N2 is connected to one end of the resistor R4, the other end of the resistor R4 is respectively connected to one end of the capacitor C3 and one end of the resistor R5, and the two pins of the step-down DC power conversion chip U2 (XL4016) , The other end of the capacitor C3 and the other end of the resistor R5 are connected to the emitter of the transistor N2, one end of the capacitor C1, pin 2 of the integrated operational amplifier U1 (LM321), and pin 2 of the step-down DC power converter chip U2 (XL4016) Connect the negative electrode of diode D7 and one end of resistor R6 respectively. Pin 5 of the step-down DC power converter U2 (XL4016) is connected to one end of capacitor C5, one end of capacitor C4, one end of electrolytic capacitor E1, and one end of inductor ID2. The 4 pins of the step-down DC power converter chip U2 (XL4016) are connected to the other end of the capacitor C5, and the 3 pins of the step-down DC power converter chip U2 (XL4016) are respectively connected to one end of the resistor R7 and the voltage stabilizing diode D6 Negative electrode, one end of inductor ID4, the other end of resistor R7 is connected to one end of capacitor C6, the other end of inductor ID4 is connected to one end of capacitor C7, one end of electrolytic capacitor E2, the other end of resistor R6, one end of capacitor C8, electrolytic capacitor E3 One end of the capacitor, the other end of the electrolytic capacitor E1, the other end of the capacitor C4, pin 1 of the step-down DC power converter chip U2 (XL4016), the other end of the capacitor C6, the positive electrode of the voltage stabilizing diode D6, and the other end of the capacitor C7 One end, the other end of the electrolytic capacitor E2, and one end of the resistor R8 are connected, the other end of the resistor R8, pin 1 of the integrated operational amplifier U1 (LM321), the other end of the capacitor C8, the other end of the electrolytic capacitor E3, and the moving contact of the relay JD1 The point is connected; pin 5 of the integrated operational amplifier U1 (LM321) is connected to the other end of the inductor ID2 and the other end of the capacitor C1, pin 4 of the integrated operational amplifier U1 (LM321) is connected to the anode of the diode D7 and one end of the potentiometer RV1, Pin 3 of the integrated operational amplifier U1 (LM321) is connected to one end of the resistor R3 and one end of the resistor R2, the other end of the potentiometer RV1 is connected to the other end of the resistor R2; the other end of the resistor R9 is connected to one end of the capacitor C19 and the base of the transistor N1 The other end of the capacitor C19 is connected to the emitter of the transistor N1, the collector of the transistor N1 is connected to one end of the coil of the relay JD1, the normally open point of the relay JD1 is connected to the cathode of the ozone generator OG, and the anode of the ozone generator OG is connected to electrolysis One end of capacitor E3.

In order to further achieve the object of the present invention, the ozone generator includes a cathode structure and an anode structure. The cathode structure includes a lower reinforced titanium plate, an anode conductive stud is connected to the lower reinforced titanium plate, and a cathode frame is provided on the lower reinforced titanium plate The cathode frame is provided with a cathode water guide and air hole, the cathode frame is provided with a cathode conductive plate, the cathode conductive plate is processed with a water guide air hole, the cathode conductive plate is connected with a cathode conductive stud, and the cathode conductive plate is provided with a cathode A microporous titanium plate with a cathode catalyst layer on the cathode microporous titanium plate, a proton exchange membrane on the cathode catalyst layer, and an O-ring seal between the proton exchange membrane and the cathode frame; the anode structure includes an upper reinforced titanium plate The anode on the upper reinforced titanium plate has water and air holes, the anode frame is provided below the titanium plate, the anode frame is provided with an anode microporous titanium plate, and the anode microporous titanium plate is provided with an anode catalyst layer; the lower reinforcement titanium Plate, cathode frame, cathode conductive plate, O-ring, cathode microporous titanium plate, cathode catalyst layer, proton exchange membrane and anode catalyst layer, anode microporous titanium plate, anode frame, upper reinforced titanium plate are tightened by screws Solid together.

In order to further achieve the object of the present invention, the cathode structure passes through the bottom of the electrolytic bucket through the cathode conductive stud and passes through the bottom of the electrolytic bucket; the anode structure passes through the bottom of the electrolytic bucket through the bottom of the electrolytic bucket and is fastened by the nut; the cathode The conductive column is connected to the electrolytic capacitor E of the constant current generating circuit, and the anode conductive column is connected to the normally open point of the relay JD1 of the constant current generating circuit.

Compared with the prior art, the present invention has the following positive effects: Since the power supply device of the present invention realizes a slow rise and a slow fall of the power supply, during the initial power supply when the generator is turned on, the power supply voltage of the generator is slowly increased. Gradual distribution of hydrogen and oxygen ions is gradually established on the side. At the end of the power supply when the generator is turned off, the power supply voltage of the generator is slowly reduced. The gradient distribution of hydrogen and oxygen ions is gradually reduced on both sides of the generator membrane to avoid hydrogen and oxygen ions The diffusion in the opposite direction prevents the hydrogen and oxygen ions from damaging the catalyst, so in the application field of intermittent use, the generator life can be greatly improved. In addition, the electrolytic ozone generator of the present invention has a submerged structure, which has a simple and practical structure, and is easy for users to install and replace.

1‧‧‧AC/DC power converter

2‧‧‧Micro control chip MCU

3‧‧‧Constant current generating circuit

4‧‧‧Ozone generator

4-10‧‧‧Lower reinforced titanium plate

4-10-1‧‧‧Anode conductive stud

4-1‧‧‧Cathode frame

4-1-1‧‧‧ Cathode water and air holes

4-11‧‧‧O-ring

4-12‧‧‧ Cathode conductive plate

4-12-1‧‧‧ Cathode conductive stud

4-12-2‧‧‧Water and air holes

4-2‧‧‧Anode frame

4-3‧‧‧screw

4-4‧‧‧Anode microporous titanium plate

4-5‧‧‧Anode catalyst layer

4-6‧‧‧Proton exchange membrane

4-7‧‧‧ Cathode microporous titanium plate

4-8‧‧‧ Cathode catalyst layer

4-9‧‧‧Up reinforced titanium plate

4-9-1‧‧‧Water guide air hole

5‧‧‧Electrolysis bucket

6‧‧‧ Nut

The first figure is a schematic diagram of the structure of the power supply device of the present invention; the second figure is the circuit schematic diagram of the micro control chip MCU and the constant current generating circuit part of the power supply device of the present invention; the third figure is the voltage of the stepped lifting method of the present invention Waveform curve; the fourth figure is the voltage waveform curve of the power supply of the slow lifting mode of the present invention; the fifth figure is the voltage waveform curve of the power supply of the stepping lifting mode of the present invention that maintains the initial voltage value for a long time; The voltage waveform curve of the power supply in the mode of slow rise and fall which maintains the initial voltage value for a time; the seventh figure is a schematic diagram of the structure of the ozone generator of the present invention; the eighth figure is a schematic diagram of the installation structure of the ozone generator and the electrolytic water bucket of the present invention.

The following is a detailed description of a preferred embodiment of the present invention with respect to the structure and composition of the power supply method and power supply device for the electrolytic ozone generator of the present invention, which slowly rises and falls, and the resulting effects.

As in the embodiment, this kind of electrolytic ozone generator's power supply method of slowly rising and falling includes the following steps: at the initial power supply to the electrolytic ozone generator, firstly provide a lower initial voltage (a voltage of 1.5V to 2.3V, preferably 1.9V), and then gradually increase the voltage to the generator constant current power supply area (the rising process is preferably 5 seconds), after which, the electrolytic ozone generator will be powered with a constant current. At the end of the power supply for the electrolytic ozone generator, first gradually reduce the voltage to leave the generator constant current power supply area until the initial voltage value (declining process is preferably 10 seconds), and then maintain for a period of time (preferably 3 minutes), then stop the electrolytic ozone generator powered by.

An electrolytic ozone generator power supply device for slow rise and fall (see the first and second figures), which includes an AC/DC power converter 1, a micro control chip MCU 2, a constant current generating circuit 3, an ozone generator 4, and an electrolytic water bucket 5. The AC/DC power converter 1 is connected to the micro control chip MCU2 and the constant current generating circuit 3 respectively, the micro control chip MCU 2 is connected to the constant current generating circuit 3, the constant current generating circuit 3 is connected to the ozone generator 4, and the ozone generator 4 passes through the nut 6 Connected to the electrolytic water bucket 5.

The constant current generating circuit 3 includes a resistor R1 and a resistor R9 connected to the micro control chip MCU2. The resistor R1 is respectively connected to one end of the capacitor C2 and the base of the transistor N2, and the other end of the capacitor C2 is connected to the emitter of the transistor N2 and the transistor N2 The collector is connected to one end of the resistor R4, the other end of the resistor R4 is connected to one end of the capacitor C3, one end of the resistor R5, two pins of the step-down DC power conversion chip U2 (XL4016), the other end of the capacitor C3, the resistor R5 The other end is respectively connected to the emitter of the transistor N2, one end of the capacitor C1, the 2 pins of the integrated operational amplifier U1 (LM321), and the 2 pins of the step-down DC power converter chip U2 (XL4016) are respectively connected to the negative electrode and the resistor of the diode D7 At one end of R6, pin 5 of the step-down DC power conversion chip U2 (XL4016) is respectively connected to one end of the capacitor C5, one end of the capacitor C4, one end of the electrolytic capacitor E1, and one end of the inductor ID2. The step-down DC power conversion chip U2 ( 4 pins of XL4016) are connected to the other end of the capacitor C5, and the 3 pins of the step-down DC power conversion chip U2 (XL4016) are respectively connected to one end of the resistor R7, the negative electrode of the voltage stabilizing diode D6, one end of the inductor ID4, and the end of the resistor R7 The other end is connected to one end of the capacitor C6, the other end of the inductor ID4 is connected to one end of the capacitor C7, one end of the electrolytic capacitor E2, the other end of the resistor R6, one end of the capacitor C8, one end of the electrolytic capacitor E3, the other end of the electrolytic capacitor E1, The other end of the capacitor C4, one pin of the step-down DC power conversion chip U2 (XL4016), the other end of the capacitor C6, the positive electrode of the voltage stabilizing diode D6, the other end of the capacitor C7, the other end of the electrolytic capacitor E2, the resistor One end of R8 is connected, the other end of resistor R8, pin 1 of integrated operational amplifier U1 (LM321), the other end of capacitor C8, the other end of electrolytic capacitor E3, and the moving contact of relay JD1 are connected; integrated operational amplifier U1 (LM321) The 5 pin is connected to the other end of the inductor ID2 and the other end of the capacitor C1. The 4 pin of the integrated operational amplifier U1 (LM321) is connected to the anode of the diode D7 and one end of the potentiometer RV1, and the 3 pin of the integrated operational amplifier U1 (LM321) Connect one end of resistor R3, one end of resistor R2, the other end of potentiometer RV1 is connected to the other end of resistor R2; the other end of resistor R9 is connected to one end of capacitor C19, the base of transistor N1, the other end of capacitor C19 and transistor N1 The emitter of transistor N1 is connected, the collector of transistor N1 is connected to one end of the coil of relay JD1, the normally open point of relay JD1 is connected to the cathode of ozone generator OG, and the anode of ozone generator OG is connected to one end of electrolytic capacitor E3.

According to the present invention, when in use, the micro control chip MCU controls the transistor N2 to be completely cut off first, and the transistor N1 is turned on to close the relay JD1 to power the generator OG. The voltage of the second pin of the step-down DC power conversion chip U2 (XL4016) is constant at 1.25V, and the power supply voltage at this time is determined by the values of resistors R5 and R6 (adjust the values of R5 and R6 to control the voltage from 1.5V to 2.3V Range, preferably R5=20KΩ, R6=10KΩ, the initial power supply voltage is about 1.9V,) At this time, only a weak current flows through the generator OG. Then the micro control chip MCU outputs a PWM waveform to control the duty cycle of the transistor N2 on and off. The power supply voltage at this time is determined by the values of the resistors R5 and R6 and the equivalent resistance values of N2 and R4 (preferred: R5=20KΩ, R6= 10KΩ, R4=3KΩ), as the duty cycle of the transistor N2 is turned on and off, the voltage supplying the generator OG gradually increases. When the rated operating current of the generator OG is reached, the power supply circuit enters the constant current power supply mode. The constant current supply current is controlled by the integrated operational amplifier U1 (LM321), and the value is determined by the sampling resistor R8 and resistor R2, resistor R3 and potentiometer RV1. When discontinued, the micro-controller MCU outputs a PWM waveform to control the duty cycle of the transistor N2 to turn on and off gradually, and the voltage supplying the generator OG gradually decreases until the transistor N2 enters a completely cut-off state. Only a weak current flows. Continue to wait for a period of time (preferably 3 minutes), and then the MCU controls the transistor N1 to cut off so that the relay is turned off and the power supply to the generator OG is completely stopped. The stepped power supply waveforms are shown in the third and fifth figures, and the slowly rising and falling power supply waveforms are shown in the fourth and sixth figures.

Preferably, the power supply climbing time is 5-30 seconds, and the power supply falling time is 10-300 seconds.

Ozone generator (4) (see the seventh and eighth figures), the ozone generator 4 includes a cathode structure and an anode structure, the cathode structure includes a lower reinforcing titanium plate 4-10, the lower reinforcing titanium plate 4-10 An anode conductive stud 4-0-10-1 is connected, a cathode frame body 4-1 is provided on the lower reinforced titanium plate 4-10, and a cathode water and gas guide hole 4-1-1 is processed on the cathode frame body 4-1, and a cathode frame The body 4-1 is provided with a cathode conductive plate 4-12, a water conductive air hole 4-12-2 is processed on the cathode conductive plate 4-12, and a cathode conductive stud 4-12-1 is connected to the cathode conductive plate 4-12. A cathode microporous titanium plate 4-7 is provided on the cathode conductive plate 4-12, a cathode catalyst layer 4-8 is provided on the cathode microporous titanium plate 4-7, and a proton exchange membrane 4- is provided on the cathode catalyst layer 4-8 6. An O-ring 4-11 is provided between the proton exchange membrane 4-6 and the cathode frame 4-1; the anode structure includes an upper reinforced titanium plate 4-9, and the processed anode on the upper reinforced titanium plate 4-9 has a water guide Air guide hole 4-9-1, upper reinforced titanium plate 4-9 is provided with anode frame 4-2, anode frame 4-2 is provided with anode microporous titanium plate 4-4, anode microporous titanium plate 4- 4 There is an anode catalyst layer 4-5; a lower reinforced titanium plate 4-10, a cathode frame 4-1, a cathode conductive plate 4-12, an O-ring 4-11, a cathode microporous titanium plate 4-7, Cathode catalyst layer 4-8, proton exchange membrane 4-6 and anode catalyst layer 4-5, anode microporous titanium plate 4-4, anode frame 4-2, upper reinforcing titanium plate 4-9 are tightened by screws 4-3 Solid together. The cathode structure passes through the cathode conductive stud 4-12-1 through the bottom of the electrolyzed water bucket 5 to the outside; the anode structure passes through the anode conductive stud 4-10-1 through the bottom of the electrolyzed water bucket 5 to the outside and is fastened by the nut 6 The cathode conductive column 4-12-1 is connected to the electrolytic capacitor E of the constant current generating circuit 3, and the anode conductive column 4-10-1 is connected to the normally open point of the relay JD1 of the constant current generating circuit 3. Before use, add pure water to the electrolyzed water bucket to make the generator completely submerged in water, and then connect the generator power supply device. During use, the cathode drain remains in the bucket. Due to the complete isolation of the anode and cathode in the structure, the gas in the cathode water-conducting and air-conducting hole 4-1-1 cuts off the water and avoids the formation of a conductive path. Therefore, after use, disconnect the generator power supply and the generator is completely submerged in the water The anode and cathode are also electrically insulated to ensure the life of the generator. When the generator is abnormal and needs to be replaced, just remove the fixing nut. Save time and effort, fast and convenient.

The above examples are merely descriptions of preferred embodiments of the present invention, and do not limit the scope of the present invention. Without departing from the spirit of the design of the present invention, various modifications and changes made to the technical solutions of the present invention by those skilled in the art Improvements shall fall within the scope of protection determined by the claims of the present invention.

1‧‧‧AC/DC power converter

2‧‧‧Micro control chip MCU

3‧‧‧Constant current generating circuit

4‧‧‧Ozone generator

5‧‧‧Electrolysis bucket

Claims (6)

A power supply method for the electrolytic ozone generator to slowly rise and fall, characterized in that it includes the following steps: during the initial power supply to the electrolytic ozone generator, firstly provide an initial voltage of 1.5V to 2.3V, and then gradually increase the voltage to a constant current of the generator Power supply area, after which the generator will be powered with a constant current; at the end of the power supply for the electrolytic ozone generator, first gradually reduce the voltage to leave the generator constant current power supply area until the initial voltage value, and then stop the electrolytic ozone generator power supply or for a long time Maintain the initial voltage value of 1.5V to 2.3V. The power supply method of the electrolytic ozone generator according to claim 1, wherein the initial voltage is 1.5V to 2.3V, and the process of gradually increasing the voltage to the generator constant current power supply area is 5 seconds, the gradual decrease of the voltage leaves the generator constant current power supply area until the initial voltage value is 10 seconds, and then maintain for at least 3 minutes, and then stop the electrolytic ozone generator power supply or maintain an initial 1.5V to 2.3V for a long time Voltage supply. An electrolytic ozone generator power supply device with slow rise and slow down, characterized in that it includes an AC/DC power converter (1), a micro control chip MCU (2), a constant current generating circuit (3), an ozone generator (4) and Electrolytic water bucket (5); AC/DC power converter (1) is connected to the micro control chip MCU (2) and the constant current generation circuit (3), and the micro control chip MCU (2) is connected to the constant current generation circuit (3), constant The flow generating circuit (3) is connected to the ozone generator (4), and the ozone generator (4) is connected to the electrolytic water bucket (5). An electrolysis ozone generator ascending and descending power supply device according to claim 3, characterized in that the constant current generating circuit (3) includes a resistor R1 and a resistor R9 connected to a micro control chip MCU (2) The resistor R1 is connected to one end of the capacitor C2 and the base of the transistor N2, the other end of the capacitor C2 is connected to the emitter of the transistor N2, the collector of the transistor N2 is connected to one end of the resistor R4, and the other end of the resistor R4 is connected to one end of the capacitor C3 respectively 1. One end of resistor R5, two pins of step-down DC power conversion chip U2 (XL4016), the other end of capacitor C3, the other end of resistor R5 are connected to the emitter of transistor N2, one end of capacitor C1, integrated operational amplifier U1 ( 2 pins of LM321), the 2 pins of the step-down DC power converter chip U2 (XL4016) are respectively connected to the negative electrode of the diode D7 and one end of the resistor R6, and the 5 pins of the step-down DC power converter chip U2 (XL4016) are respectively connected One end of the capacitor C5, one end of the capacitor C4, one end of the electrolytic capacitor E1, one end of the inductance ID2, the 4-pin of the step-down DC power conversion chip U2 (XL4016) is connected to the other end of the capacitor C5, and the step-down DC power conversion chip U2 The three pins of (XL4016) are respectively connected to one end of the resistor R7, the negative electrode of the voltage stabilizing diode D6, and one end of the inductor ID4, the other end of the resistor R7 is connected to one end of the capacitor C6, and the other end of the inductor ID4 is respectively connected to one end of the capacitor C7, One end of the electrolytic capacitor E2, the other end of the resistor R6, one end of the capacitor C8, one end of the electrolytic capacitor E3, the other end of the electrolytic capacitor E1, the other end of the capacitor C4, one pin of the step-down DC power conversion chip U2 (XL4016) , The other end of the capacitor C6, the positive electrode of the voltage stabilizing diode D6, the other end of the capacitor C7, the other end of the electrolytic capacitor E2, one end of the resistor R8, the other end of the resistor R8, the integrated operational amplifier U1 (LM321) 1 The other end of the foot, the capacitor C8, the other end of the electrolytic capacitor E3, and the moving contact of the relay JD1 are connected; pin 5 of the integrated operational amplifier U1 (LM321) is connected to the other end of the inductor ID2, the other end of the capacitor C1, and the integrated operational amplifier U1 Pin 4 of (LM321) is connected to the anode of diode D7 and one end of potentiometer RV1. Pin 3 of the integrated operational amplifier U1 (LM321) is connected to one end of resistor R3 and one end of resistor R2. The other end of potentiometer RV1 is connected to resistor R2 The other end of the resistor is connected; the other end of the resistor R9 is connected to one end of the capacitor C19, the base of the transistor N1, the other end of the capacitor C19 is connected to the emitter of the transistor N1, the collector of the transistor N1 is connected to one end of the coil of the relay JD1, and the relay JD1 The normally open point is connected to the cathode of the ozone generator OG, and the anode of the ozone generator OG is connected to one end of the electrolytic capacitor E3. An electrolytic ozone generator ascending and descending power supply device according to claim 3, characterized in that the ozone generator (4) includes a cathode structure and an anode structure, and the cathode structure includes a lower reinforced titanium plate (4-10) , The lower reinforcing titanium plate (4-10) is connected with an anode conductive stud (4-10-1), the lower reinforcing titanium plate (4-10) is provided with a cathode frame (4-1), and a cathode frame ( 4-1) The cathode water conducting air holes (4-1-1) are processed on the cathode frame (4-1) are provided with a cathode conductive plate (4-12), and the cathode conductive plate (4-12) is processed with The water conducting air hole (4-12-2), the cathode conducting plate (4-12) is connected with the cathode conducting stud (4-12-1), and the cathode conducting plate (4-12) is provided with a cathode microporous titanium plate ( 4-7), cathode microporous titanium plate (4-7) is provided with cathode catalyst layer (4-8), cathode catalyst layer (4-8) is provided with proton exchange membrane (4-6), proton exchange membrane (4-6) There is an O-ring (4-11) between the cathode frame (4-1); the anode structure includes upper reinforced titanium plate (4-9) and upper reinforced titanium plate (4-9) The upper processed anode has water and air holes (4-9-1), the upper reinforced titanium plate (4-9) is provided with an anode frame (4-2), and the anode frame (4-2) is provided with anode micro holes Titanium plate (4-4), anode microporous titanium plate (4-4) is provided with anode catalyst layer (4-5); lower reinforced titanium plate (4-10), cathode frame (4-1), cathode Conductive plate (4-12), O-ring (4-11), cathode microporous titanium plate (4-7), cathode catalyst layer (4-8), proton exchange membrane (4-6) and anode catalyst layer (4-5), anode microporous titanium plate (4-4), anode frame (4-2), upper reinforced titanium plate (4-9) are fastened together by screws (4-3). An electrolytic ozone generator ascending and descending power supply device according to claim 5, characterized in that the cathode structure passes through the bottom of the electrolytic water bucket (5) through the cathode conductive stud (4-12-1) to the outside of the bucket ; The anode structure passes through the anode conductive stud (4-10-1) through the bottom of the electrolytic water bucket (5) and enters the outside of the bucket and is fastened by the nut (6); the cathode conductive column (4-12-1) and the constant current are generated The electrolytic capacitor E of the circuit (3) is connected, and the anode conductive column (4-10-1) is connected to the normally open point of the relay JD1 of the constant current generating circuit (3).

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