CN114717605B - Oxyhydrogen gas production state regulation and control method and oxyhydrogen gas production equipment - Google Patents

Abstract

The application provides a method for regulating and controlling an oxyhydrogen gas production state and oxyhydrogen gas production equipment. The method comprises the steps of obtaining a regulating and controlling electric signal of an oxyhydrogen gas production device; acquiring a gas control electric control value according to the regulating and controlling electric signal; carrying out electric color filtering treatment on the gas making electric control value and a preset electric control value to obtain an electric color difference component; and sending a corresponding gas making state regulating and controlling signal to the oxyhydrogen gas making control system according to the electric color difference component so as to adjust the working state of the gas making state monitor. Through the regulation and control electrical signal that gathers oxyhydrogen gas making device, be convenient for acquire the current electric signal of adjusting the gas output of oxyhydrogen gas making device, later handle gas making automatically controlled value and predetermine automatically controlled value, confirm the degree of difference between the two, finally according to the degree of difference that the electric face difference quantity shows, adjust the operating condition of gas making state watch-dog, be convenient for confirm the current gas making state of oxyhydrogen gas making device.

Description

Oxyhydrogen gas production state regulation and control method and oxyhydrogen gas production equipment

Technical Field

The invention relates to the technical field of oxyhydrogen preparation, in particular to an oxyhydrogen gas production state regulation and control method and oxyhydrogen gas production equipment.

Background

An electronic atomizer is a device for atomizing a liquid (e.g., tobacco tar) into smoke, and is widely used in various fields, such as medical treatment, electronic cigarette, etc. The medical electronic atomization device only performs physical transformation on liquid, namely, a medium to be atomized is converted into smoke with extremely small particle size, and the smoke is mixed with air for inhalation, for example, the application patent with the application number of CN202220505642.7 has the function of respectively generating hydrogen and oxygen, and can also adjust the independent or mixed use modes of the hydrogen and the oxygen.

However, when oxygen and hydrogen are generated, the conventional medical electronic atomization device continuously outputs the generated gas, and the user experiences the generated gas completely, so that the gas outlet rate cannot be determined sometimes, and the gas outlet rate cannot be adjusted.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provides an oxyhydrogen gas production state regulation method and oxyhydrogen gas production equipment which are convenient for determining the current oxyhydrogen gas production state.

The aim of the invention is realized by the following technical scheme:

A method for regulating and controlling the state of oxyhydrogen gas production, comprising:

Acquiring a regulating and controlling electric signal of an oxyhydrogen gas production device;

acquiring a gas control electric control value according to the regulating and controlling electric signal;

Carrying out electric color filtering treatment on the gas making electric control value and a preset electric control value to obtain an electric color difference component;

And sending a corresponding gas making state regulating and controlling signal to the oxyhydrogen gas making control system according to the electricity color difference quantity so as to adjust the working state of the gas making state monitor.

In one embodiment, the obtaining the control electric signal of the oxyhydrogen gas generating device includes: and acquiring a dynamic electric signal of the oxyhydrogen gas production device, wherein the dynamic electric signal is an electric signal of real-time change of gas production of the oxyhydrogen gas production device.

In one embodiment, the obtaining the gas control electrical value according to the regulation electrical signal includes: and acquiring a braking pneumatic electronic control value according to the dynamic electric signal.

In one embodiment, the brake pneumatic electronic control value includes a brake pneumatic voltage value or a brake pneumatic current value.

In one embodiment, the performing the electric color filtering process on the gas making electric control value and a preset electric control to obtain an electric color difference component further includes: acquiring a steady-state electric signal of the oxyhydrogen gas generating device; and acquiring the preset electric control value according to the steady-state electric signal.

In one embodiment, the obtaining the preset electrical control value according to the steady-state electrical signal includes: acquiring a steady-state electric control value according to the steady-state electric signal; and acquiring a reference electric control value corresponding to the air control electric control value according to the steady-state electric control value.

In one embodiment, the sending a corresponding gas making state adjusting signal to the oxyhydrogen gas making control system according to the electric color difference value to adjust the working state of the gas making state monitor includes: detecting whether the electrical color difference component is smaller than a first difference component; and when the electric Yan Chafen quantity is smaller than the first difference quantity, sending a gas production shortage state signal to the oxyhydrogen gas production control system.

In one embodiment, the detecting whether the electrical color difference component is smaller than a first difference component further includes: detecting whether the electric color difference component is smaller than a second difference component when the electric color difference component is larger than or equal to the first difference component; and when the electric Yan Chafen quantity is smaller than the second differential quantity, sending a gas saturation quantity state signal to the oxyhydrogen gas control system.

In one embodiment, the detecting whether the electrical color difference component is smaller than a first difference component further includes: and when the electricity-to-gas differential quantity is larger than or equal to the second differential quantity, sending a gas excess state signal to the oxyhydrogen gas control system.

An oxyhydrogen gas production apparatus comprising: the hydrogen-oxygen gas production device, a gas production central control main board and a gas production state monitor; the oxyhydrogen gas making piece is used for generating hydrogen and oxygen through electrolysis; the input end of the gas production center control main board is connected with the oxyhydrogen gas production device, and the gas production center control main board is used for acquiring a regulating and controlling electric signal of the oxyhydrogen gas production device; acquiring a gas control electric control value according to the regulating and controlling electric signal; carrying out electric color filtering treatment on the gas making electric control value and a preset electric control value to obtain an electric color difference component; sending a corresponding gas making state regulating and controlling signal to a hydrogen-oxygen gas making control system according to the electricity color difference quantity; the gas making state monitor is used for adjusting the working state according to the gas making state regulating and controlling signal.

Compared with the prior art, the invention has at least the following advantages:

The electric signal of the current regulation air outlet amount of the oxyhydrogen air making device is conveniently acquired by collecting the regulation electric signal of the oxyhydrogen air making device, so that the corresponding air making electric control value is conveniently acquired, namely the air making electric control value corresponds to the regulation electric signal, then the air making electric control value is processed with the preset electric control value, the difference degree between the air making electric control value and the preset electric control value is determined, namely the electric color difference quantity is determined, finally the working state of the air making state monitor is adjusted according to the difference degree reflected by the electric color difference quantity, the air making speed of the oxyhydrogen air making device is conveniently determined according to the working state of the air making state monitor, the air making speed of the oxyhydrogen air making device is conveniently determined, and the current air making state of the oxyhydrogen air making device is conveniently determined.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a flow chart of a method for controlling the status of oxyhydrogen gas production in an embodiment.

Detailed Description

In order that the invention may be readily understood, a more complete description of the invention will be rendered by reference to the appended drawings. The drawings illustrate preferred embodiments of the invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

The invention relates to a method for regulating and controlling the state of oxyhydrogen gas production. In one embodiment, the oxyhydrogen gas production state regulation method includes obtaining a regulation electric signal of an oxyhydrogen gas production device; acquiring a gas control electric control value according to the regulating and controlling electric signal; carrying out electric color filtering treatment on the gas making electric control value and a preset electric control value to obtain an electric color difference component; and sending a corresponding gas making state regulating and controlling signal to the oxyhydrogen gas making control system according to the electricity color difference quantity so as to adjust the working state of the gas making state monitor. Through the regulation and control electrical signal that gathers oxyhydrogen gas making device, be convenient for acquire the current electric signal of adjusting the gas output of oxyhydrogen gas making device, thereby be convenient for acquire corresponding gas making automatically controlled value, gas making automatically controlled value and regulation and control electric signal correspond, later handle gas making automatically controlled value and preset automatically controlled value, confirm the difference degree between the two, the electric face differential quantity, finally according to the difference degree that electric face differential quantity embodied, adjust the operating condition of gas making state watch-dog, be convenient for confirm the gas making speed of oxyhydrogen gas making device according to the operating condition of gas making state watch-dog, thereby be convenient for confirm the gas making rate of oxyhydrogen gas making device, and then be convenient for confirm the current gas making state of oxyhydrogen gas making device.

Please refer to fig. 1, which is a flowchart illustrating a method for adjusting and controlling a hydrogen-oxygen production state according to an embodiment of the present invention. The oxyhydrogen gas production state regulation method comprises part or all of the following steps.

S100: and obtaining the regulation and control electric signal of the oxyhydrogen gas production device.

In this embodiment, the oxyhydrogen gas generating device is configured to generate oxygen and hydrogen, where the speed of the gas generated by the oxyhydrogen gas generating device corresponds to the regulation electrical signal, that is, the regulation electrical signal corresponds to the gas generating speed of the oxyhydrogen gas generating device one by one, so that the current gas generating speed of the oxyhydrogen gas generating device is determined by collecting the regulation electrical signal, and the working state of the gas generating state monitor is adjusted according to the regulation electrical signal, so that a user knows the gas generating speed of the oxyhydrogen gas generating device by adjusting the change of the working state of the gas generating state monitor.

S200: and acquiring an air control electric control value according to the regulating and controlling electric signal.

In this embodiment, the adjusting and controlling electrical signal is used as a signal for adjusting the gas making speed of the oxyhydrogen gas making device, and the corresponding physical attribute in the adjusting and controlling electrical signal is collected, that is, the gas making electrical control value is acquired, and the gas making electrical control value corresponds to the adjusting and controlling electrical signal one by one, so that the gas making electrical control value corresponds to the gas making speed of the oxyhydrogen gas making device, and the gas making electrical control value is used for reflecting the gas making speed of the oxyhydrogen gas making device, so that the working state of the gas making state monitor can be conveniently adjusted according to the gas making electrical control value, and the gas making speed change condition of the oxyhydrogen gas making device can be conveniently determined.

S300: and carrying out electric color filtering treatment on the gas making electric control value and a preset electric control value to obtain an electric color difference component.

In this embodiment, the preset electric control value also corresponds to the gas production speed of the oxyhydrogen gas production device, and specifically, the preset electric control value corresponds to the standard gas production rate of the oxyhydrogen gas production device. And carrying out electric color filtering treatment on the gas making electric control value and the preset electric control value, namely comparing the current gas making electric control value of the oxyhydrogen gas making device with a standard gas making electric control value to determine the degree of difference between the current gas making rate of the oxyhydrogen gas making device and the standard gas making rate, namely the electric color difference quantity. Therefore, through the obtained electricity color difference quantity, whether the working state of the gas making state monitor is to be adjusted or not is conveniently determined according to the difference, and therefore the gas making speed of the oxyhydrogen gas making device is conveniently determined according to the change condition of the working state of the gas making state monitor.

S400: and sending a corresponding gas making state regulating and controlling signal to the oxyhydrogen gas making control system according to the electricity color difference quantity so as to adjust the working state of the gas making state monitor.

In this embodiment, the electric Yan Chafen is used to represent the degree of difference between the current gas production rate of the oxyhydrogen gas production device and the standard gas production rate, and the numerical value of the electric color difference directly determines the current gas production speed of the oxyhydrogen gas production device, and the larger the electric Yan Chafen is, the larger the gas production rate of the oxyhydrogen gas production device is, and the smaller the conversely is. Therefore, based on the condition of the electricity Yan Chafen, the working state of the gas making state monitor is convenient to adjust, so that a user can conveniently determine the gas making speed of the oxyhydrogen gas making device according to the change condition of the working state of the gas making state monitor.

In this embodiment, the electrical signal of the current adjustment gas outlet amount of the oxyhydrogen gas production device is conveniently acquired by collecting the electrical signal of the oxyhydrogen gas production device, so that the corresponding gas production electrical control value is conveniently acquired, that is, the gas production electrical control value corresponds to the electrical signal of the oxyhydrogen gas production device, then the gas production electrical control value is processed with the preset electrical control value, the difference degree between the two is determined, that is, the electric color difference quantity, and finally the working state of the oxyhydrogen gas production state monitor is adjusted according to the difference degree reflected by the electric color difference quantity, so that the gas production speed of the oxyhydrogen gas production device is conveniently determined according to the working state of the oxyhydrogen gas production state monitor, and the current gas production state of the oxyhydrogen gas production device is conveniently determined. The working state of the gas making state monitor can be phenomena of sound, light, electricity, smell and the like which are convenient for users to observe or perceive, and specific selection can be set according to actual requirements.

In one embodiment, the obtaining the control electric signal of the oxyhydrogen gas generating device includes: and acquiring a dynamic electric signal of the oxyhydrogen gas production device, wherein the dynamic electric signal is an electric signal of real-time change of gas production of the oxyhydrogen gas production device. In this embodiment, the adjusting and controlling electrical signal includes the dynamic electrical signal, where the dynamic electrical signal is a real-time electrical signal of the oxyhydrogen gas generator during gas production, and the dynamic electrical signal is a signal that has an adjusting effect on a gas production speed of the oxyhydrogen gas generator, that is, the dynamic electrical signal is used to adjust a gas production rate of the oxyhydrogen gas generator. Thus, the dynamic electric signal is an electric signal which changes in real time during the gas production of the oxyhydrogen gas production device, and the current gas production speed state of the oxyhydrogen gas production device is conveniently determined through the acquisition of the dynamic electric signal, so that the electric signal for determining the gas production speed of the oxyhydrogen gas production device is conveniently determined, and the working state of the gas production state monitor is conveniently adjusted according to the dynamic electric signal.

Further, the obtaining the gas control electric control value according to the regulating electric signal includes: and acquiring a braking pneumatic electronic control value according to the dynamic electric signal. In this embodiment, the dynamic electrical signal is an electrical signal that changes in real time during gas production by the oxyhydrogen gas production device, that is, the dynamic electrical signal is a real-time electrical signal during gas production by the oxyhydrogen gas production device, and the dynamic electrical signal is a signal that has an adjusting effect on the gas production speed of the oxyhydrogen gas production device, that is, the dynamic electrical signal is used for adjusting the gas production rate of the oxyhydrogen gas production device. The dynamic electric signal corresponds to the pneumatic dynamic electric control value, the pneumatic dynamic electric control value is a numerical value for representing the speed of gas production in the dynamic electric signal, the numerical value of the pneumatic dynamic electric control value directly determines the current gas production rate of the oxyhydrogen gas production device, and the working state of the gas production state monitor can be conveniently adjusted according to the pneumatic dynamic electric control value.

Still further, the brake pneumatic electronic control value includes a brake pneumatic voltage value or a brake pneumatic current value. In this embodiment, the pneumatic dynamic electric control value may be a pneumatic dynamic voltage value or a pneumatic dynamic current value, that is, by analyzing a signal of the dynamic electric signal, the voltage or the current which changes in the dynamic electric signal is obtained, and these voltages and currents change in real time and correspond to the gas production rate of the oxyhydrogen gas production device, so that the gas production speed of the oxyhydrogen gas production device is determined according to the change condition of the voltage or the current of the oxyhydrogen gas production device during gas production.

In one embodiment, the performing the electric color filtering process on the gas making electric control value and a preset electric control to obtain an electric color difference component further includes: acquiring a steady-state electric signal of the oxyhydrogen gas generating device; and acquiring the preset electric control value according to the steady-state electric signal. In this embodiment, the gas producing process of the oxyhydrogen gas producing device is basically implemented by electrolysis of the electrolyte by a power supply, that is, the electrolyte in the oxyhydrogen gas producing device needs to be electrolyzed by means of voltage or current to produce oxygen and hydrogen. In the actual gas production process of the oxyhydrogen gas production device, part of electric signals are fixed, specifically, when a power supply is a constant voltage source, the voltage of electrolyte is constant voltage when electrolysis is carried out, namely the electrolysis voltage is the voltage corresponding to the steady-state electric signals, at the moment, the preset electric control value corresponds to the electrolysis voltage output by the constant voltage source, so that the preset electric control value is convenient to determine, under the condition that the electrolysis voltage is constant, the gas production speed of the oxyhydrogen gas production device is determined by the dynamic electric control value of the oxyhydrogen gas production device, even under the condition that the electrolysis voltage is constant, the gas production speed of the oxyhydrogen gas production device is determined by the electrolysis current; when the power supply is a constant current source, the current when the electrolyte is electrolyzed is constant current, namely the electrolysis current is the corresponding current in the steady-state electric signal, at the moment, the preset electric control value corresponds to the electrolysis current output by the constant current source, so that the preset electric control value is convenient to determine, and the gas making speed of the oxyhydrogen gas making device is convenient to determine through the pneumatic electric control value under the condition that the electrolysis current is constant, namely, the gas making speed of the oxyhydrogen gas making device is determined through the electrolytic voltage under the condition that the electrolysis current is constant.

Further, the obtaining the preset electric control value according to the steady-state electric signal includes: acquiring a steady-state electric control value according to the steady-state electric signal; and acquiring a reference electric control value corresponding to the air control electric control value according to the steady-state electric control value. In this embodiment, after the type of the steady-state electrical signal is determined, a steady-state electrical control value corresponding to the steady-state electrical signal may be obtained, for example, in the case of power supply by a constant voltage source, the steady-state electrical signal is a constant voltage signal, the steady-state electrical control value is a constant voltage output by the constant voltage source, and at this time, the reference electrical control in the gas-making electrical control value is determined according to the constant voltage, so that the constant voltage is conveniently set to the preset electrical control value, and thus, the gas-making speed of the oxyhydrogen gas-making device is conveniently determined according to the difference of electrolytic currents.

In one embodiment, the sending a corresponding gas making state adjusting signal to the oxyhydrogen gas making control system according to the electric color difference value to adjust the working state of the gas making state monitor includes: detecting whether the electrical color difference component is smaller than a first difference component; and when the electric Yan Chafen quantity is smaller than the first difference quantity, sending a gas production shortage state signal to the oxyhydrogen gas production control system. In this embodiment, the first difference component is used as a first standard judgment value for the magnitude of the electrical Yan Chafen quantity, and it is detected whether the electrical color difference component is smaller than the first difference component, and is a primary comparison for the degree of difference between the current gas production rate of the oxyhydrogen gas production device and the standard gas production rate, and is also a comparison for the gas production rate corresponding to the first difference component, where the electrical Yan Chafen quantity is smaller than the first difference component, which indicates that the current gas production rate of the oxyhydrogen gas production device is lower than the gas production rate corresponding to the first difference component, that is, indicates that the current gas production rate of the oxyhydrogen gas production device is too low, and at this time, sends a gas production under-condition signal to the oxyhydrogen gas production control system, so as to adjust the working state of the gas production state monitor according to the gas production under-condition signal. Specifically, under the condition that the constant current source supplies power, namely the constant current output by the constant current source is 1A, the preset electric control value is real-time voltage, the preset electric control value is 3.7V, the first difference value is 0, the electric Yan Chafen quantity is smaller than the first difference value, namely the voltage corresponding to the gas control value is smaller than 3.7V, namely the current electrolytic voltage of the oxyhydrogen gas device is smaller than 3.7V, at the moment, the gas production rate of the oxyhydrogen gas device is too low, a gas production underquantity state signal is sent to the oxyhydrogen gas control system, the working state of the gas production state monitor is adjusted to be in an underquantity state, and the LED lamp of the gas production state monitor is displayed to be yellow; under the condition that a constant voltage source supplies power, namely constant voltage output by the constant voltage source is 3.7V, the preset electric control value is real-time current, the preset electric control value is 0.5A, the first difference value is 0, the electric Yan Chafen quantity is smaller than the first difference value, namely current corresponding to the gas control value is smaller than 0.5A, namely current electrolysis current of the oxyhydrogen gas device is smaller than 0.5A, at the moment, the gas control rate of the oxyhydrogen gas device is too low, a gas shortage state signal is sent to the oxyhydrogen gas control system, the working state of the gas control state monitor is adjusted to be in a shortage state, and an LED lamp of the gas control state monitor is purple. Therefore, according to the color displayed by the LED lamp of the hydrogen making state monitor, a user can know that the hydrogen making speed of the hydrogen making device is too low in time, so that the hydrogen making speed of the hydrogen making device is increased.

Further, the detecting whether the electric color difference component is smaller than a first difference component further includes: detecting whether the electric color difference component is smaller than a second difference component when the electric color difference component is larger than or equal to the first difference component; and when the electric Yan Chafen quantity is smaller than the second differential quantity, sending a gas saturation quantity state signal to the oxyhydrogen gas control system. In this embodiment, the electric color difference is greater than or equal to the first difference, which indicates that the gas production rate of the oxyhydrogen gas production apparatus is normal, but there is a case where the gas production rate is too fast at this time, and in order to distinguish the two cases, the distinction is made by setting the second difference. Specifically, under the condition that the constant current source supplies power, namely the constant current output by the constant current source is 1A, the preset electric control value is real-time voltage, the preset electric control value is 3.7V, the second difference value is 0.3, the electric Yan Chafen quantity is smaller than the second difference value, namely the voltage corresponding to the gas control value is between 3.7V and 4V, namely the current electrolytic voltage of the oxyhydrogen gas device is larger than 3.7V and smaller than 4V, at the moment, the gas production rate of the oxyhydrogen gas device is normal, a gas production saturation state signal is sent to the oxyhydrogen gas control system, the working state of the gas production state monitor is adjusted to be in a saturation state, and the LED lamp of the gas production state monitor is orange; under the condition that a constant voltage source supplies power, namely constant voltage output by the constant voltage source is 3.7V, the preset electric control value is real-time current, the preset electric control value is 0.5A, the second difference value is 1, the electric Yan Chafen quantity is smaller than the second difference value, namely current corresponding to the gas making electric control value is between 0.5A and 1.5A, namely the current electrolysis current of the oxyhydrogen gas making device is larger than 0.5A and smaller than 1.5A, at the moment, the gas making speed of the oxyhydrogen gas making device is normal, a gas making saturation state signal is sent to the oxyhydrogen gas making control system, the working state of the gas making state monitor is adjusted to be in a saturation state, and the LED lamp of the gas making state monitor is displayed in blue.

Still further, the detecting whether the electric color difference component is smaller than the first difference component further includes: and when the electricity-to-gas differential quantity is larger than or equal to the second differential quantity, sending a gas excess state signal to the oxyhydrogen gas control system. In this embodiment, the electric color difference is greater than or equal to the first difference, which indicates that the gas production rate of the oxyhydrogen gas production apparatus is normal, but there is a case where the gas production rate is too fast at this time, and in order to distinguish the two cases, the distinction is made by setting the second difference. Specifically, under the condition that the constant current source supplies power, namely the constant current output by the constant current source is 1A, the preset electric control value is real-time voltage, the preset electric control value is 3.7V, the second difference value is 0.3, the electric Yan Chafen quantity is smaller than the second difference value, namely the voltage corresponding to the gas making electric control value is larger than 4V, namely the current electrolytic voltage of the oxyhydrogen gas making device is higher than 4V, at the moment, the gas making speed of the oxyhydrogen gas making device is overlarge, a gas making excessive state signal is sent to the oxyhydrogen gas making control system, the working state of the gas making state monitor is adjusted to be in an excessive state, and the LED lamp of the gas making state monitor is displayed as red; under the condition that a constant voltage source supplies power, namely constant voltage output by the constant voltage source is 3.7V, the preset electric control value is real-time current, the preset electric control value is 0.5A, the second difference value is 1, the electric Yan Chafen quantity is smaller than the second difference value, namely current corresponding to the gas making electric control value is larger than 1.5A, namely current electrolytic current of the oxyhydrogen gas making device is higher than 1.5A, at the moment, the gas making speed of the oxyhydrogen gas making device is overlarge, a gas making excessive state signal is sent to the oxyhydrogen gas making control system, the working state of the gas making state monitor is adjusted to be an excessive state, and the LED lamp of the gas making state monitor is displayed to be green. Therefore, according to the color displayed by the LED lamp of the hydrogen making state monitor, a user can know that the hydrogen making speed of the hydrogen making device is too high in time, so that the hydrogen making speed of the hydrogen making device is reduced.

It can be understood that after the gas production rate of the oxyhydrogen gas production device is adjusted to a normal rate, the electrolysis voltage and the electrolysis current of the oxyhydrogen gas production device are kept stable, that is, the electrolysis voltage of the oxyhydrogen gas production device is maintained at a constant voltage, and the electrolysis current of the oxyhydrogen gas production device is maintained at a constant current. However, as the gas production time increases, the amount of gas produced by the oxyhydrogen gas production apparatus is excessive, and the electrolyte and the electric energy of the power supply in the oxyhydrogen gas production apparatus are excessively wasted.

In order to reduce the possibility of excessive gas produced by the oxyhydrogen gas production device, the method sends a corresponding gas production state regulation signal to the oxyhydrogen gas production control system according to the electric color difference amount so as to adjust the working state of the gas production state monitor, and then the method further comprises the following steps:

Acquiring the gas making time of the oxyhydrogen gas making device;

detecting whether the gas making time is longer than a preset time;

And when the gas making time is longer than the preset time, sending a gas making machine closing signal to the oxyhydrogen gas making control system so as to adjust the vibration frequency of the gas making state monitor.

In this embodiment, when the oxyhydrogen gas generating device performs normal gas generation, the gas rates of oxygen and hydrogen generated by the oxyhydrogen gas generating device are stable, and the oxyhydrogen gas generating device keeps stable output of oxygen and hydrogen. The gas producing time is the gas producing time of the oxyhydrogen gas producing device under the normal gas producing state, the preset time is the production time under the normal condition, and the preset time is the standard gas producing time of the oxyhydrogen gas producing device under the normal gas producing condition. The gas producing time is longer than the preset time, which indicates that the gas producing time of the oxyhydrogen gas producing device in the normal gas producing state is longer than the standard gas producing time, namely, the gas producing time of the oxyhydrogen gas producing device in the normal gas producing state exceeds the standard gas producing time, namely, the gas producing time of the oxyhydrogen gas producing device in the normal gas producing state is overlong, at the moment, the gas quantities of oxygen and hydrogen produced by the oxyhydrogen gas producing device are overlarge, and a gas producing machine closing signal is sent to the oxyhydrogen gas producing control system so as to stop the oxyhydrogen gas producing device from producing gas, and meanwhile, the vibration frequency of the gas producing state monitor is convenient to adjust, particularly, the gas producing state monitor starts vibrating, and the vibration frequency of the gas producing state monitor gradually increases, so that a user can know about to be about to shut down in advance, and the probability of excessive gas produced by the oxyhydrogen gas producing device is effectively reduced.

Further, when the user is in a hydrogen-rich environment, the amount of the inhaled hydrogen is not easy to be excessively large, and once the amount of the inhaled hydrogen is excessively large, the oxygen deficiency suffocation can be caused, and the alveolus can be expanded to press the heart, so that the body is damaged. In order to reduce the probability of excessive hydrogen inhalation, the method for obtaining the gas making time of the oxyhydrogen gas making device further comprises the following steps:

Acquiring gas to be detected in the environment where the oxyhydrogen gas production device is located;

Performing ion detection treatment on the gas to be detected to obtain the concentration of hydrogen ions;

detecting whether the hydrogen ion concentration is greater than a preset ion concentration;

and reducing and updating the preset time when the hydrogen ion concentration is larger than the preset ion concentration.

In this embodiment, the oxyhydrogen gas generating device includes a hydrogen ion detector, where the hydrogen ion detector is configured to collect a gas to be detected in an environment where the oxyhydrogen gas generating device is located, and the hydrogen ion detector performs ion detection on the gas to be detected, so as to detect a hydrogen-containing gas in the gas to be detected, so as to determine a percentage of hydrogen ion content in the gas to be detected, that is, the hydrogen ion concentration. The preset ion concentration is the standard hydrogen ion concentration of the oxyhydrogen gas production device in the use environment, and the hydrogen ion concentration is larger than the preset ion concentration, which indicates that the hydrogen ion concentration of the oxyhydrogen gas production device in the current use environment is larger than the standard hydrogen ion concentration, namely that the hydrogen ion concentration of the oxyhydrogen gas production device in the current use environment is overlarge, namely that the oxyhydrogen gas production device is in the hydrogen-rich environment. In this way, the preset time is reduced under the condition that the hydrogen-rich environment where the oxyhydrogen gas production device is located is determined, so that the preset time is reduced, and the reduced preset time is updated to be the latest preset time, so that the gas production time of the oxyhydrogen gas production device in the hydrogen-rich environment is shortened, and the hydrogen quantity generated by the oxyhydrogen gas production device in the hydrogen-rich environment is reduced.

In one embodiment, the present application also provides an oxyhydrogen gas production apparatus, comprising: the hydrogen-oxygen gas production device, a gas production central control main board and a gas production state monitor; the oxyhydrogen gas making piece is used for generating hydrogen and oxygen through electrolysis; the input end of the gas production center control main board is connected with the oxyhydrogen gas production device, and the gas production center control main board is used for acquiring a regulating and controlling electric signal of the oxyhydrogen gas production device; acquiring a gas control electric control value according to the regulating and controlling electric signal; carrying out electric color filtering treatment on the gas making electric control value and a preset electric control value to obtain an electric color difference component; sending a corresponding gas making state regulating and controlling signal to a hydrogen-oxygen gas making control system according to the electricity color difference quantity; the gas making state monitor is used for adjusting the working state according to the gas making state regulating and controlling signal. In this embodiment, the gas central control main board is convenient to acquire the current electrical signal for adjusting the air outlet amount of the oxyhydrogen gas generating device by acquiring the electrical signal for adjusting the oxyhydrogen gas generating device, so that the gas central control main board is convenient to acquire the corresponding gas electric control value, that is, the gas electric control value corresponds to the electrical signal for adjusting, then the gas central control main board processes the gas electric control value and the preset electric control value to determine the difference degree between the two, that is, the electric color difference, and finally the gas central control main board adjusts the working state of the oxyhydrogen gas generating state monitor according to the difference degree reflected by the electric color difference, so that the gas making speed of the oxyhydrogen gas generating device is convenient to determine according to the working state of the oxyhydrogen gas generating state monitor, and the current gas generating state of the oxyhydrogen gas generating device is convenient to determine.

The above examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (6)

1. The method for regulating and controlling the state of hydrogen and oxygen production is characterized by comprising the following steps:

Acquiring a regulating and controlling electric signal of an oxyhydrogen gas production device;

acquiring a gas control electric control value according to the regulating and controlling electric signal;

Carrying out electric color filtering treatment on the gas making electric control value and a preset electric control value to obtain an electric color difference component;

sending a corresponding gas making state regulating and controlling signal to a hydrogen-oxygen gas making control system according to the electricity color difference quantity so as to adjust the working state of a gas making state monitor;

the method comprises the steps of sending a corresponding gas making state regulating signal to a hydrogen-oxygen making control system according to the electricity color difference value so as to adjust the working state of a gas making state monitor, and then further comprising the following steps:

Acquiring the gas making time of the oxyhydrogen gas making device;

detecting whether the gas making time is longer than a preset time;

When the gas making time is longer than the preset time, sending a gas making machine closing signal to the oxyhydrogen gas making control system so as to adjust the vibration frequency of the gas making state monitor;

the step of sending a corresponding gas making state regulating and controlling signal to the oxyhydrogen gas making control system according to the electricity color difference amount so as to adjust the working state of the gas making state monitor, comprises the following steps:

Detecting whether the electrical color difference component is smaller than a first difference component;

when the electric Yan Chafen quantity is smaller than the first difference quantity, sending a gas production underquantity state signal to the oxyhydrogen gas production control system;

Detecting whether the electric color difference component is smaller than a second difference component when the electric color difference component is larger than or equal to the first difference component;

when the electric Yan Chafen quantity is smaller than the second differential quantity, sending a gas saturation quantity state signal to the oxyhydrogen gas control system;

When the electricity-to-gas differential component is greater than or equal to the second differential component, sending a gas excess state signal to the oxyhydrogen gas control system;

The method for obtaining the gas making time of the oxyhydrogen gas making device further comprises the following steps:

Acquiring gas to be detected in the environment where the oxyhydrogen gas production device is located;

Performing ion detection treatment on the gas to be detected to obtain the concentration of hydrogen ions;

detecting whether the hydrogen ion concentration is greater than a preset ion concentration;

and reducing and updating the preset time when the hydrogen ion concentration is larger than the preset ion concentration.

2. The oxyhydrogen gas production state control method according to claim 1, wherein the acquiring the control electric signal of the oxyhydrogen gas production device includes:

And acquiring a dynamic electric signal of the oxyhydrogen gas production device, wherein the dynamic electric signal is an electric signal of real-time change of gas production of the oxyhydrogen gas production device.

3. The method for controlling the state of hydrogen and oxygen production according to claim 2, wherein the obtaining the electrical control value of the production according to the control electrical signal comprises:

And acquiring a braking pneumatic electronic control value according to the dynamic electric signal.

4. The method according to claim 3, wherein the control value of the hydrogen-oxygen production state includes a control dynamic voltage value or a control dynamic current value.

5. The method for regulating and controlling the state of oxyhydrogen gas production according to claim 1, wherein the step of performing electric color filtering processing on the gas production electric control value and a preset electric control to obtain an electric color difference component further comprises the following steps:

acquiring a steady-state electric signal of the oxyhydrogen gas generating device;

And acquiring the preset electric control value according to the steady-state electric signal.

6. The oxyhydrogen gas production state control method according to claim 5, wherein the obtaining the preset electric control value according to the steady-state electric signal includes:

Acquiring a steady-state electric control value according to the steady-state electric signal; and acquiring a reference electric control value corresponding to the air control electric control value according to the steady-state electric control value.