CN116840310A - Detection equipment - Google Patents

Abstract

The application discloses a detection device, comprising: the body is provided with a first accommodating cavity and a second accommodating cavity; the electrolysis device is arranged in the first accommodating cavity; the first liquid storage chamber is arranged in the body and is used for storing a first electrolyte and is provided with a first liquid inlet and a first liquid outlet; the second liquid storage chamber is arranged in the body and is used for storing a second electrolyte and is provided with a second liquid inlet and a second liquid outlet; the first circulating device is arranged in the second accommodating cavity, one end of the first circulating device is connected with the first liquid storage chamber through the first liquid inlet, and the other end of the first circulating device is connected with the electrolysis device through the first liquid outlet; the second circulating device is arranged in the second accommodating cavity, one end of the second circulating device is connected with the second liquid storage chamber through a second liquid inlet, and the other end of the second circulating device is connected with the electrolysis device through a second liquid outlet; the detection device is respectively connected with the electrolysis device, the anode chamber and the second cathode chamber; the processor is connected with the detection device and is used for obtaining detection data of the first electrolyte and the second electrolyte.

Description

Detection equipment

Technical Field

The present application relates to a detection apparatus.

Background

With the stricter requirements of the country on the environment, the byproduct salt cannot be directly discharged into rivers and landfills, the cost for treating the byproduct salt is high, and the utilization of the byproduct salt to change waste into valuable is the most economical and reasonable method, so that the byproduct salt is used in the chlor-alkali industry, but the byproduct salt has complex components and can possibly influence industrial chlor-alkali equipment by directly utilizing the byproduct salt, so that the evaluation of the byproduct salt before entering the chlor-alkali equipment is an essential link. Therefore, how to detect the byproduct salt and recycle the byproduct salt is an urgent problem to be solved at present.

Disclosure of Invention

In view of the above, it is desirable to provide a detection apparatus for solving at least the above-mentioned problems.

In order to achieve the above purpose, the technical scheme of the application is realized as follows:

an embodiment of the present application provides a detection apparatus, which is characterized in that the apparatus includes:

the body is provided with a first accommodating cavity and a second accommodating cavity;

the electrolysis device comprises an electrode film, a first storage cavity and a second storage cavity, wherein the electrode film is arranged in the first storage cavity and is used for dividing the first storage cavity into an anode cavity and a cathode cavity;

the first liquid storage chamber is arranged in the body and is used for storing a first electrolyte and is provided with a first liquid inlet and a first liquid outlet;

the second liquid storage chamber is arranged in the body and is used for storing a second electrolyte and is provided with a second liquid inlet and a second liquid outlet; the second electrolyte is different from the first electrolyte in composition;

the first circulating device is arranged in the second accommodating cavity, one end of the first circulating device is connected with the first liquid storage chamber through the first liquid inlet, and the other end of the first circulating device is connected with the electrolysis device through the first liquid outlet and the anode chamber and is used for realizing loop circulation of the first electrolyte;

the second circulating device is arranged in the second accommodating cavity, one end of the second circulating device is connected with the second liquid storage chamber through the second liquid inlet, and the other end of the second circulating device is connected with the electrolysis device through the second liquid outlet and the cathode chamber and is used for realizing loop circulation of the second electrolyte;

the detection device is arranged in the body and is respectively connected with the electrolysis device, the anode chamber and the second cathode chamber and is used for detecting the electric parameters of the electrolysis device, the anode chamber and the cathode chamber in the running state of the detection equipment;

and the processor is arranged in the body and connected with the detection device, and is used for analyzing the first electrolyte and the second electrolyte according to the electric parameters to obtain detection data of the first electrolyte and the second electrolyte.

In the above scheme, still be provided with in the body:

the first metering pump is connected with the first liquid storage chamber, and is used for supplementing the first liquid storage chamber with the first electrolyte with preset concentration under the condition that the concentration of the first electrolyte is reduced in the electrolysis process of the electrolysis device;

the second metering pump is connected with the second liquid storage chamber, and the second metering pump is used for supplementing the second liquid storage chamber with the second electrolyte with preset concentration under the condition that the concentration of the second electrolyte is reduced in the electrolysis process of the electrolysis device.

In the above scheme, still be provided with in the body:

the first overflow device is connected with the first liquid storage chamber, is arranged at a preset position of the first liquid storage chamber and is used for limiting the first electrolyte in the first liquid storage chamber;

the second overflow device is connected with the second liquid storage chamber, is arranged at a preset position of the second liquid storage chamber and is used for limiting the second electrolyte in the second liquid storage chamber.

In the above scheme, still be provided with on the body:

the first gas discharge port is connected with the first liquid storage chamber and is used for discharging the first electrolyte out of the body through waste gas generated in the electrolysis process of the electrolysis device;

and the second gas discharge port is connected with the second liquid storage chamber and is used for discharging the second electrolyte out of the body through waste gas generated in the electrolysis process of the electrolysis device.

In the above scheme, the detection device is further used for detecting the gas concentration generated by the first electrolyte and the second electrolyte in the electrolysis process;

and the body is internally provided with an alarm device which is connected with the detection device and used for outputting an alarm signal under the condition that the gas concentration and the electric parameter meet alarm conditions.

In the above scheme, the detection device is further used for detecting the temperatures in the first accommodating cavity and the second accommodating cavity;

and the heating device is also arranged in the body and is used for heating the first accommodating cavity and the second accommodating cavity under the condition that the temperature is smaller than a preset value.

In the above scheme, the detection device is further configured to detect a concentration of the first electrolyte in the first liquid storage chamber and a liquid concentration of the second electrolyte in the second liquid storage chamber;

the device further comprises an adjusting device which is respectively connected with the first metering pump and the second metering pump and is used for adjusting the concentration of the liquid supplied by the first metering pump and the second metering pump according to the concentration of the liquid.

In the above scheme, still be provided with on the body:

the first liquid outlet is connected with the first liquid storage chamber and/or the first metering pump and is used for discharging the first electrolyte in the first liquid storage chamber and/or the first metering pump out of the body;

and the second liquid outlet is connected with the second liquid storage chamber and/or the second metering pump and is used for discharging the second electrolyte in the second liquid storage chamber and/or the second metering pump out of the body.

In the above aspect, the first circulation device includes: the first circulating pump is used for supplying power to the loop circulation of the first electrolyte;

the second circulation device includes: the second circulating pump, second liquid supply pipeline and second return line, the second return line with the second liquid supply pipeline respectively with the second inlet with the second liquid outlet is connected, through the second circulating pump with electrolytic device connects, the second circulating pump is used for the return circuit circulation power of second electrolyte.

In the above scheme, the device further comprises:

and the waste liquid collecting groove is respectively connected with the first liquid storage chamber and the second liquid storage chamber and is used for collecting waste liquid from the first liquid storage chamber and the second liquid storage chamber.

In the above scheme, the device further comprises:

the display is connected with the processor and used for displaying detection data for the first electrolyte and the second electrolyte;

and the memory is connected with the processor and used for storing detection data for the first electrolyte and the second electrolyte.

The detection equipment provided by the application can detect whether byproduct salt can be used as recycled raw material or not by using a small amount of byproduct brine, so that irreversible damage caused by impurities such as organic matters in the brine polluting industrial equipment is avoided, the detection time is shortened, the use amount of brine detection is greatly reduced compared with that of the brine directly entering large-scale industrial equipment, and the detection efficiency of the byproduct salt is improved.

Drawings

FIG. 1 is a schematic diagram showing the structural components of a detecting device according to the present application;

FIG. 2 is a schematic diagram showing the structural components of the detecting device according to the present application;

FIG. 3 is a schematic diagram showing the structural components of the detecting device according to the present application.

Detailed Description

The technical scheme of the application is further elaborated below by referring to the drawings in the specification and the specific embodiments.

Various combinations of the features described in the embodiments may be performed without contradiction, for example, different embodiments may be formed by combining different features, and various possible combinations of the features in the present application are not described further to avoid unnecessary repetition.

In describing embodiments of the present application, unless otherwise indicated and limited thereto, the term "connected" should be construed broadly, for example, it may be an electrical connection, or may be a communication between two elements, or may be a direct connection, or may be an indirect connection via an intermediate medium, and it will be understood by those skilled in the art that the specific meaning of the term may be interpreted according to circumstances.

It should be noted that, the term "first\second\third" related to the embodiment of the present application is merely to distinguish similar objects, and does not represent a specific order for the objects, it is to be understood that "first\second\third" may interchange a specific order or sequence where allowed. It is to be understood that the "first\second\third" distinguishing objects may be interchanged where appropriate such that embodiments of the application described herein may be practiced in sequences other than those illustrated or described herein.

The detection apparatus according to the embodiment of the present application will be described in detail with reference to fig. 1 to 3.

As shown in fig. 1, the detection apparatus provided by the present application includes: a body 10, the body 10 having a first accommodation chamber 101 and a second accommodation chamber 102; as shown in fig. 2, the apparatus further includes: the electrolysis device 20, the first reservoir 30, the second reservoir 40, the first circulation device 50, the second circulation device 60, the detection device 70 and the processor 80. Wherein, the electrolytic device 20 is disposed in the first accommodating cavity 101, the electrolytic device 20 comprises an electrode film 201 for dividing the first accommodating cavity 101 into an anode chamber 1001 and a cathode chamber 1002; the first liquid storage chamber 30 is disposed in the body 10 and located at one side of the body, and is used for storing a first electrolyte, and has a first liquid inlet 301 and a first liquid outlet 302; for example, the first electrolyte is by-product brine.

Here, the anode chamber 1001 and the cathode chamber 1002 have electrode coatings on the inner walls.

The second liquid storage chamber 40 is disposed in the body 10 and located on the same side of the first liquid storage chamber 30, and is used for storing a second electrolyte, and has a second liquid inlet 401 and a second liquid outlet 402; wherein the second electrolyte is different from the first electrolyte in composition; for example, the second electrolyte is sodium hydroxide.

The first circulation device 50 is disposed in the second accommodating cavity 102, one end of the first circulation device is connected to the first liquid storage chamber 30 through the first liquid inlet 301, and the other end of the first circulation device is connected to the electrolysis device 20 through the first liquid outlet 302 and the anode chamber 1001, so as to implement a loop circulation of the first electrolyte;

the second circulation device 60 is disposed in the second accommodating cavity 102, one end of the second circulation device is connected to the second liquid storage chamber 40 through the second liquid inlet 401, and the other end of the second circulation device is connected to the electrolysis device 20 through the second liquid outlet 402 and the cathode chamber 1002, so as to implement loop circulation of the second electrolyte;

the detection device 70 is disposed in the body 10 and is respectively connected to the electrolysis device 20, the anode chamber 1001 and the second cathode chamber 1002, and is used for detecting electrical parameters of the electrolysis device 20, the anode chamber 1001 and the cathode chamber 1002 in the operation state of the detection device; here, the electrical parameter includes, but is not limited to, a voltage parameter, a current parameter, a potential parameter, an overpotential parameter.

And a processor 80, disposed in the body 10, connected to the detection device 70, and configured to analyze the first electrolyte and the second electrolyte according to the electrical parameter, so as to obtain detection data of the first electrolyte and the second electrolyte.

The detection equipment provided by the application can obtain the detection data of the electrolyte in a short time, and the detection data is used for a worker to analyze the influence of the electrolyte on the electrode film. For example, the electrolyte is byproduct brine, and the detection data can intuitively reflect the voltage and the overpotential of the anode chamber in the electrolysis process of the byproduct brine, so that whether the byproduct brine can be used as a raw material of industrial chlor-alkali can be judged based on the voltage and the overpotential.

Here, the electrolytic device 20 may be provided with a pressing device 202, and the electrolytic device may be press-fastened by the pressing device 202.

Here, the first circulation device 50 may include: the first circulation pump 501, the first liquid supply pipeline 502 and the first return pipeline 503, wherein the first return pipeline 502 and the first liquid supply pipeline 503 are respectively connected with the first liquid inlet 301 and the first liquid outlet 302, and are connected with the electrolysis device 20 through the first circulation pump 501, and the first circulation pump 501 is used for providing power for the loop circulation of the first electrolyte; the second circulation device 60 includes: the second circulation pump 601, the second liquid supply pipeline 602 and the second return pipeline 603, the second return pipeline 602 and the second liquid supply pipeline 603 are respectively connected with the second liquid inlet 401 and the second liquid outlet 402, and are connected with the electrolysis device 20 through the second circulation pump 601, and the second circulation pump 601 is used for providing power for loop circulation of the second electrolyte.

For example, the first circulation pump 501 and the second circulation pump 601 are magnetic pumps, wherein the first electrolyte can be pumped into the anode chamber by a high temperature alkali resistant magnetic pump; the second electrolyte may be pumped into the cathode chamber by an acid-resistant magnetic pump.

In the present application, the apparatus further includes a first metering pump 90 and a second metering pump 100, where the first metering pump 90 and the second metering pump 100 are both disposed in the body 10, and the first metering pump 90 is connected to a first fluid-filling port 303 on the first fluid-storage chamber 30, and when the concentration of the first electrolyte decreases during the electrolysis process of the electrolysis device 20, the first metering pump 90 is used to supplement the first electrolyte with a preset concentration to the first fluid-storage chamber 30 through the first fluid-filling port 303; the second metering pump 100 is connected to a second fluid-filling port 403 on the second fluid-storage chamber 40, where the second metering pump 100 is configured to supplement the second fluid-storage chamber 40 with the second electrolyte of the preset concentration through the second fluid-filling port 403 when the concentration of the second electrolyte decreases during the electrolysis process of the electrolysis device 20.

Here, since the concentrations of the first electrolyte and the second electrolyte are always decreasing during electrolysis, the first metering pump 90 and the second metering pump 100 are also always in the liquid replenishment state.

In the present application, the detecting device 70 is further configured to detect a concentration of the first electrolyte in the first liquid storage chamber 30 and a liquid concentration of the second electrolyte in the second liquid storage chamber 40; and an adjusting device (not shown) in the device, wherein one end of the adjusting device is connected with the detecting device 70, and the other end of the adjusting device is respectively connected with the first metering pump 90 and the second metering pump 100, so as to adjust the concentration of the liquid fed by the first metering pump 90 and the second metering pump 100 according to the concentration value of the liquid detected by the detecting device 70.

Here, the detecting device 70 may detect the concentration of the first electrolyte in the first liquid storage chamber 30 and the concentration of the second electrolyte in the second liquid storage chamber 40 according to a preset time interval, and when the detection result indicates that the current time period is different from the previous time period or the liquid concentrations in the last several continuous time periods, and the liquid concentration meets the adjustment condition, the adjusting device is triggered to adjust the liquid concentration of the supplement of the corresponding first metering pump 90 and/or the second metering pump 100.

For example, the liquid concentration of the first liquid storage chamber needs to be always kept at 30%, the liquid concentration of the first metering pump 90 and/or the second metering pump 100 is/are default to be 20%, the detection device detects the liquid concentration of the first liquid storage chamber and the second liquid storage chamber once every 1 hour, and when the detected liquid concentration of the first liquid storage chamber in the current time period is 27%, the triggering and adjusting device is used for adjusting the liquid concentration of the first metering pump 90 to be 25% so as to ensure that the liquid concentration of the first liquid storage chamber needs to be always kept at 30%. The adjustment of the liquid concentration in the second liquid storage chamber is similar to the adjustment of the liquid concentration in the first liquid storage chamber, and will not be described herein.

In the present application, the apparatus further comprises a first overflow device 110 and a second overflow device 120, wherein the first overflow device 110 is connected with a first overflow port 304 on the first liquid storage chamber 30, and is disposed at a preset position of the first liquid storage chamber 30, for limiting the first electrolyte in the first liquid storage chamber 30; the second overflow device 120 is connected to a second overflow port 404 on the second liquid storage chamber 40, and is disposed at a preset position of the second liquid storage chamber 40, and is configured to limit the second electrolyte in the second liquid storage chamber 40.

Here, both the first overflow means 110 and the second overflow means 120 may be overflow pipes. Avoiding spillage of the liquid in the first 30 and second 40 reservoirs.

In the present application, the apparatus further comprises a first gas discharge port 130 and a second gas discharge port 140, wherein the first gas discharge port 130 is connected to the first liquid storage chamber 30, and is used for discharging the first electrolyte out of the body through the exhaust gas generated during the electrolysis process of the electrolysis device 20; a second gas discharge port 140 is connected to the second liquid storage chamber 40 for discharging the second electrolyte through the exhaust gas generated during the electrolysis of the electrolysis apparatus 20.

Here, when the first electrolyte is by-product brine, the exhaust gas generated after the first electrolyte is electrolyzed may be chlorine gas, and the chlorine gas may specifically enter the sodium hydroxide absorption port through the first gas discharge port 130 to be absorbed by sodium hydroxide. When the second electrolyte is sodium hydroxide, the exhaust gas generated by the electrolysis of the second electrolyte may be hydrogen, and the hydrogen is discharged from the body through the second gas discharge port 140.

In the present application, the apparatus further comprises an alarm device (not shown), and the detecting device 70 is further configured to detect the gas concentrations generated by the first electrolyte and the second electrolyte during the electrolysis process; when the gas concentration in the body 10 is detected to meet the alarm condition, the alarm device is triggered to output an alarm signal. Here, the alarm condition of the gas concentration can be set by the user according to the requirement.

In the application, the equipment can trigger the alarm device to output an alarm signal when the detection device detects that the electrical parameters of the electrolysis device, the electrode film, the anode chamber and the cathode chamber are abnormal or meet the alarm condition. For example, when the voltage value of the electrolysis device is outside the 2.5 to 4 volt interval, an alarm signal is output. For another example, when the detection device detects the current value of the electrolysis device and the current value is larger than the preset threshold value, the current electrolysis device is larger in energy consumption, and an alarm signal is output.

Here, the alarm condition of the electrical parameter can also be set according to the user's requirement.

Here, the alarm signal of the electrical parameter and the alarm signal of the gas concentration may be different so that the user can know the current abnormal point position from the alarm signal.

In the present application, the detecting device 70 is further configured to detect temperatures in the first accommodating cavity 101 and the second accommodating cavity 102; heating means (not shown) are further disposed in the body 10, and the heating means are connected to the detecting means 70, so as to heat the first accommodating cavity 101 and the second accommodating cavity 102 when the detecting means detects that the temperature is less than the temperature preset value.

Here, the temperature preset value may be set according to the user's demand. The heating device may be, for example, a heating rod, a heating plate, or the like.

Here, the alarm device is further configured to output an alarm signal when the temperature of the chamber detected by the detection device is abnormal, and the alarm signal of the abnormal temperature may be different from the alarm signal of the electrical parameter and the alarm signal of the gas concentration, so that the user quickly knows the abnormal point location from the alarm signal.

In the application, the heating device can be connected with the first liquid storage chamber and the second liquid storage chamber through the heating interface and is used for heating the temperatures in the first liquid storage chamber and the second liquid storage chamber so that the electrolyte in the first liquid storage chamber and the second liquid storage chamber is always at a specific temperature. The use requirements of the equipment under different environmental conditions can be met.

In the present application, the body 10 is further provided with a first liquid outlet 305 and a second liquid outlet 405, wherein the first liquid outlet 305 is connected to the first liquid storage chamber 30 and/or the first metering pump 90, and is used for discharging the first electrolyte in the first liquid storage chamber 30 and/or the first metering pump 90 out of the body; a second liquid drain 405 is connected to the second liquid storage chamber 40 and/or the second metering pump 100, and is used for draining the second electrolyte in the second liquid storage chamber 40 and/or the second metering pump 100.

Here, the apparatus further comprises a waste liquid collection tank 150 connected to liquid discharge ports (305, 405) on the first and second liquid storage chambers 30, 40, respectively, for collecting waste liquid from the first and second liquid storage chambers 30, 40.

In the present application, the apparatus further comprises: a display 160, the display 160 being connectable to the processor 80 for displaying detection data for the first electrolyte and the second electrolyte;

in the present application, the apparatus further comprises: and a memory 170, wherein the memory 170 is connected with the processor 80 and is used for storing detection data of the first electrolyte and the second electrolyte.

In the present application, the apparatus may further include a controller (not shown), and the electrolysis device 20, the first liquid storage chamber 30, the second liquid storage chamber 40, the first circulation device 50, the second circulation device 60, the detection device 70, and the processor 80 may be connected to the controller, for controlling the electrolysis device 20, the first liquid storage chamber 30, the second liquid storage chamber 40, the first circulation device 50, the second circulation device 60, the detection device 70, and the processor 80 to perform operation by controlling the switch of the controller.

In the present application, the bottom of the body 10 of the apparatus may be further provided with a pulley assembly (not shown) for adjusting the current position of the apparatus. The device can be conveniently moved by a user according to the use requirement.

Here, a stopper (not shown) may be further provided on the pulley assembly to block the pulley assembly to prevent the pulley assembly from moving when the apparatus is moved to the target position. Thereby improving the stability of the apparatus.

The detection equipment provided by the application can be suitable for detecting any byproduct salt, can detect waste salt rapidly and conveniently in a short time, can verify the quality of brine and the running stability of the equipment, and can also verify the performance of the equipment and the electrode performance, and because the byproduct brine is complex in composition, if entering a chlor-alkali device, the byproduct brine can run stably only by being mixed with industrial refined brine basically in proportion, the operation is economical and stable, the proportion of the mixed brine is important data, and the detection equipment can find out the proper proportion (such as 10%,20%,30% and the like) in the shortest time according to the situation, so that the byproduct brine detection period and the brine consumption are greatly shortened. The detection equipment also has the advantages of small volume, small occupied area, flexible movement and convenient salt water replacement. The operation is simple, all the electrical equipment is concentrated on the controller, the detection can be operated by only one-key operation, and the safety protection device such as temperature control, voltage early warning and gas detection is provided, so that the safety is high; the real-time recording of the data saves labor cost, saves the cost of brine pretreatment, and avoids the pollution of impurities such as organic matters in the brine to industrial equipment and irreversible damage.

The foregoing is merely illustrative of the present application, and the present application is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (11)

1. A detection apparatus, the apparatus comprising:

the body is provided with a first accommodating cavity and a second accommodating cavity;

the electrolysis device comprises an electrode film, a first storage cavity and a second storage cavity, wherein the electrode film is arranged in the first storage cavity and is used for dividing the first storage cavity into an anode cavity and a cathode cavity;

the first liquid storage chamber is arranged in the body and is used for storing a first electrolyte and is provided with a first liquid inlet and a first liquid outlet;

the second liquid storage chamber is arranged in the body and is used for storing a second electrolyte and is provided with a second liquid inlet and a second liquid outlet; the second electrolyte is different from the first electrolyte in composition;

the first circulating device is arranged in the second accommodating cavity, one end of the first circulating device is connected with the first liquid storage chamber through the first liquid inlet, and the other end of the first circulating device is connected with the electrolysis device through the first liquid outlet and the anode chamber and is used for realizing loop circulation of the first electrolyte;

the second circulating device is arranged in the second accommodating cavity, one end of the second circulating device is connected with the second liquid storage chamber through the second liquid inlet, and the other end of the second circulating device is connected with the electrolysis device through the second liquid outlet and the cathode chamber and is used for realizing loop circulation of the second electrolyte;

the detection device is arranged in the body and is respectively connected with the electrolysis device, the anode chamber and the second cathode chamber and is used for detecting the electric parameters of the electrolysis device, the anode chamber and the cathode chamber in the running state of the detection equipment;

and the processor is arranged in the body and connected with the detection device, and is used for analyzing the first electrolyte and the second electrolyte according to the electric parameters to obtain detection data of the first electrolyte and the second electrolyte.

2. The apparatus of claim 1, wherein the body is further provided with:

the first metering pump is connected with the first liquid storage chamber, and is used for supplementing the first liquid storage chamber with the first electrolyte with preset concentration under the condition that the concentration of the first electrolyte is reduced in the electrolysis process of the electrolysis device;

the second metering pump is connected with the second liquid storage chamber, and the second metering pump is used for supplementing the second liquid storage chamber with the second electrolyte with preset concentration under the condition that the concentration of the second electrolyte is reduced in the electrolysis process of the electrolysis device.

3. The apparatus of claim 1, wherein the body is further provided with:

the first overflow device is connected with the first liquid storage chamber, is arranged at a preset position of the first liquid storage chamber and is used for limiting the first electrolyte in the first liquid storage chamber;

the second overflow device is connected with the second liquid storage chamber, is arranged at a preset position of the second liquid storage chamber and is used for limiting the second electrolyte in the second liquid storage chamber.

4. The apparatus of claim 1, wherein the body is further provided with:

the first gas discharge port is connected with the first liquid storage chamber and is used for discharging the first electrolyte out of the body through waste gas generated in the electrolysis process of the electrolysis device;

and the second gas discharge port is connected with the second liquid storage chamber and is used for discharging the second electrolyte out of the body through waste gas generated in the electrolysis process of the electrolysis device.

5. The apparatus of claim 1, wherein the detection device is further configured to detect a gas concentration generated by the first electrolyte and the second electrolyte during electrolysis;

and the body is internally provided with an alarm device which is connected with the detection device and used for outputting an alarm signal under the condition that the gas concentration and the electric parameter meet alarm conditions.

6. The apparatus of claim 1, wherein the detection device is further configured to detect temperatures within the first and second chambers;

and the heating device is further arranged in the body and connected with the detection device and is used for heating the first accommodating cavity and the second accommodating cavity under the condition that the temperature is smaller than a preset value.

7. The apparatus of claim 2, wherein the detection device is further configured to detect a concentration of the first electrolyte within the first reservoir and a liquid concentration of the second electrolyte within the second reservoir;

the device further comprises an adjusting device, one end of the adjusting device is connected with the detecting device, the other end of the adjusting device is connected with the first metering pump and the second metering pump respectively, and the adjusting device is used for adjusting the liquid concentration supplied by the first metering pump and the second metering pump according to the liquid concentration.

8. The apparatus of claim 2, wherein the body is further provided with:

the first liquid outlet is connected with the first liquid storage chamber and/or the first metering pump and is used for discharging the first electrolyte in the first liquid storage chamber and/or the first metering pump out of the body;

and the second liquid outlet is connected with the second liquid storage chamber and/or the second metering pump and is used for discharging the second electrolyte in the second liquid storage chamber and/or the second metering pump out of the body.

9. The apparatus of claim 1, wherein the first circulation means comprises: the first circulating pump is used for supplying power to the loop circulation of the first electrolyte;

the second circulation device includes: the second circulating pump, second liquid supply pipeline and second return line, the second return line with the second liquid supply pipeline respectively with the second inlet with the second liquid outlet is connected, through the second circulating pump with electrolytic device connects, the second circulating pump is used for the return circuit circulation power of second electrolyte.

10. The apparatus of claim 1, wherein the apparatus further comprises:

and the waste liquid collecting groove is respectively connected with the first liquid storage chamber and the second liquid storage chamber and is used for collecting waste liquid from the first liquid storage chamber and the second liquid storage chamber.

11. The apparatus of claim 1, wherein the apparatus further comprises:

the display is connected with the processor and used for displaying detection data for the first electrolyte and the second electrolyte;

and the memory is connected with the processor and used for storing detection data for the first electrolyte and the second electrolyte.