CN115014446A - Oxyhydrogen airflow monitoring method, system, computer equipment and storage medium - Google Patents

Abstract

The application provides a oxyhydrogen gas flow monitoring method, a system, computer equipment and a storage medium. The method comprises the steps of obtaining the flow rate of oxyhydrogen gas of the oxyhydrogen gas generation device; performing flow compensation treatment on the oxyhydrogen airflow rate and a preset airflow rate to obtain the difference compensation amount of the oxyhydrogen airflow; and sending a flow control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation amount so as to adjust the gas outlet flow of the oxyhydrogen gas production device. The current gas production rate of the oxyhydrogen gas production device is convenient to determine through collecting the gas flow rate of the oxyhydrogen gas production device, and the current gas production rate and the preset gas flow rate are subjected to flow compensation treatment, so that the difference between the current total gas production rate and the standard total gas production rate of the oxyhydrogen gas production device is convenient to determine. According to the specific situation of the difference compensation amount of the oxyhydrogen gas flow, the total gas outlet amount of the oxyhydrogen gas production device is convenient to control by controlling the flow control signal of the gas production power supply device, the probability of excessive gas intake of a user is effectively reduced, and the safe use is ensured.

Description

Oxyhydrogen airflow monitoring method, system, computer equipment and storage medium

Technical Field

The invention relates to the technical field of airflow monitoring, in particular to a method and a system for monitoring oxyhydrogen airflow, computer equipment and a storage medium.

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 cigarettes, and the like. The medical electronic atomization device only carries out physical transformation on liquid, namely, the medium to be atomized has liquid state and is converted into smoke with extremely small particle size, the smoke is mixed with air for inhalation, the medical electronic atomization device has the function of respectively generating hydrogen and oxygen, and simultaneously, the single or mixed use mode of the hydrogen and the oxygen can be adjusted.

However, the conventional electronic medical atomization device is only responsible for preparing hydrogen and oxygen, and cannot monitor the safe intake of the user, which easily causes the amount of the gas to be taken to exceed the safe amount, thereby causing harm to the body.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provides a oxyhydrogen gas flow monitoring method, a system, computer equipment and a storage medium, which can effectively reduce the probability of excessive gas intake of a user.

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

a oxyhydrogen gas flow monitoring method, the method comprising:

acquiring the flow rate of oxyhydrogen gas of the oxyhydrogen gas production device;

performing flow compensation treatment on the oxyhydrogen airflow rate and a preset airflow rate to obtain the difference compensation amount of the oxyhydrogen airflow;

and sending a flow control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation amount so as to adjust the gas outlet flow of the oxyhydrogen gas production device.

In one embodiment, the obtaining of the flow rate of oxyhydrogen gas from the oxyhydrogen gas generation device comprises: and obtaining the gas outlet flow rate of the hydrogen and oxygen gas production device.

In one embodiment, the performing flow compensation processing on the oxyhydrogen gas flow rate and a preset gas flow rate to obtain the difference compensation amount of the oxyhydrogen gas flow comprises: and carrying out flow rate difference compensation operation on the outlet flow rate and a preset outlet flow rate to obtain a flow rate difference of the oxyhydrogen airflow.

In one embodiment, the sending a current control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation amount to adjust the gas outlet flow rate of the oxyhydrogen gas production device includes: detecting whether the difference compensation quantity of the oxyhydrogen gas flow is matched with a preset gas flow difference compensation quantity or not; and when the difference compensation amount of the hydrogen and oxygen gas flow is not matched with the preset gas flow difference compensation amount, a current maintenance signal is sent to the gas production power supply device.

In one embodiment, the sending a current maintenance signal to the gas production power supply device when the oxyhydrogen gas flow difference compensation amount is not matched with the preset gas flow difference compensation amount comprises: and when the difference compensation amount of the oxyhydrogen gas flow is less than the preset gas flow difference compensation amount, sending a flow rate maintaining signal to the gas production power supply device so as to keep the gas outlet flow rate of the oxyhydrogen gas production device the same as the previous flow rate.

In one embodiment, the detecting whether the difference compensation amount of the oxyhydrogen gas flow is matched with a preset gas flow difference compensation amount further comprises: and when the oxyhydrogen gas flow difference compensation quantity is matched with a preset gas flow difference compensation quantity, adjusting a gas flow modulation signal sent to the gas production power supply device.

In one embodiment, the adjusting the gas flow modulation signal sent to the gas production power supply device when the oxyhydrogen gas flow difference compensation amount is matched with a preset gas flow difference compensation amount comprises: and when the difference compensation amount of the oxyhydrogen gas flow is larger than the preset gas flow difference compensation amount, sending a stop signal to the gas production power supply device so as to stop gas outlet of the oxyhydrogen gas production device.

An oxyhydrogen gas flow monitoring system comprising: the hydrogen-oxygen gas production system comprises a gas production power supply device, a hydrogen-oxygen gas production device and a hydrogen-oxygen gas flow monitoring mainboard; the hydrogen-oxygen gas production device is used for preparing and producing hydrogen and oxygen; the input end of the oxyhydrogen airflow monitoring mainboard is connected with the monitoring end of the oxyhydrogen gas production device, the output end of the oxyhydrogen airflow monitoring mainboard is connected with the control end of the gas production power supply device, and the oxyhydrogen airflow monitoring mainboard is used for acquiring the oxyhydrogen gas flow rate of the oxyhydrogen gas production device; performing flow compensation treatment on the oxyhydrogen airflow rate and a preset airflow rate to obtain the difference compensation amount of the oxyhydrogen airflow; and sending a flow control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation amount so as to adjust the gas outlet flow of the oxyhydrogen gas production device.

A computer device comprising a memory storing a computer program and a processor implementing the following steps when the computer program is executed:

acquiring the flow rate of oxyhydrogen gas of the oxyhydrogen gas production device;

performing flow compensation treatment on the oxyhydrogen airflow rate and a preset airflow rate to obtain the difference compensation amount of the oxyhydrogen airflow;

and sending a flow control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation amount so as to adjust the gas outlet flow of the oxyhydrogen gas production device.

A computer-readable storage medium, on which a computer program is stored which, when executed by a processor, carries out the steps of:

acquiring the flow rate of oxyhydrogen gas of the oxyhydrogen gas production device;

performing flow compensation treatment on the oxyhydrogen airflow rate and a preset airflow rate to obtain the difference compensation amount of the oxyhydrogen airflow;

and sending a flow control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation quantity so as to adjust the gas outlet flow of the oxyhydrogen gas production device.

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

the current gas production rate of the oxyhydrogen gas production device is convenient to determine by collecting the gas flow rate of the oxyhydrogen gas production device, and the current gas production rate and the preset gas flow rate are subjected to flow compensation treatment, so that the difference between the current gas production total amount of the oxyhydrogen gas production device and the standard gas production total amount, namely the oxyhydrogen gas flow difference compensation amount, is convenient to determine. Therefore, according to the specific situation of the difference compensation amount of the oxyhydrogen gas flow, the current control signal of the gas production power supply device is controlled, so that the gas production power supply device can be conveniently controlled to supply power to the oxyhydrogen gas production device, the total gas outlet amount of the oxyhydrogen gas production device can be conveniently controlled, the probability of excessive gas intake of a user is effectively reduced, and the safe use is ensured.

Drawings

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

FIG. 1 is a flow chart of a hydrogen-oxygen flow monitoring method in one embodiment;

FIG. 2 is a diagram illustrating an internal structure of a computer device according to an embodiment.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. 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 "secured 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 as used herein are for illustrative purposes only and do not represent the only embodiments.

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. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The invention relates to a method for monitoring oxyhydrogen gas flow. In one embodiment, the oxyhydrogen gas flow monitoring method comprises the steps of obtaining the oxyhydrogen gas flow rate of an oxyhydrogen gas production device; performing flow compensation treatment on the oxyhydrogen airflow rate and a preset airflow rate to obtain the difference compensation amount of the oxyhydrogen airflow; and sending a flow control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation quantity so as to adjust the gas outlet flow of the oxyhydrogen gas production device. The current gas production rate of the oxyhydrogen gas production device is convenient to determine by collecting the gas flow rate of the oxyhydrogen gas production device, and the current gas production rate and the preset gas flow rate are subjected to flow compensation treatment, so that the difference between the current gas production total amount of the oxyhydrogen gas production device and the standard gas production total amount, namely the oxyhydrogen gas flow difference compensation amount, is convenient to determine. Therefore, according to the specific situation of the difference compensation amount of the oxyhydrogen gas flow, the current control signal of the gas production power supply device is controlled, so that the gas production power supply device can be conveniently controlled to supply power to the oxyhydrogen gas production device, the total gas outlet amount of the oxyhydrogen gas production device can be conveniently controlled, the probability of excessive gas intake of a user is effectively reduced, and the safe use is ensured.

Please refer to fig. 1, which is a flowchart illustrating a hydrogen-oxygen flow monitoring method according to an embodiment of the present invention. The oxyhydrogen gas flow monitoring method comprises part or all of the following steps.

S100: and obtaining the flow rate of the oxyhydrogen gas generating device.

In this embodiment, the oxyhydrogen gas flow rate is a gas flow rate corresponding to the oxyhydrogen gas generation device in an electrolysis gas generation process, that is, the oxyhydrogen gas flow rate is a gas flow rate of hydrogen or oxygen generated by the oxyhydrogen gas generation device, that is, the oxyhydrogen gas flow rate corresponds to a gas flow rate generated by the oxyhydrogen gas generation device. The collection of the oxyhydrogen gas flow rate is convenient for obtaining the flow rate of the gas generated by the oxyhydrogen gas generation device through a gas flow sensor in the oxyhydrogen gas generation device, so that the speed of the gas generated by the oxyhydrogen gas generation device is convenient to detect, the total amount of the gas generated by the oxyhydrogen gas generation device is convenient to determine, and the total volume of the gas generated by the oxyhydrogen gas generation device is convenient to collect. Specifically, the total output of the gas generated by the hydrogen-oxygen gas generating device can be obtained according to the integral of the flow rate and the time.

S200: and performing flow compensation treatment on the oxyhydrogen airflow rate and a preset airflow rate to obtain the difference compensation amount of the oxyhydrogen airflow.

In this embodiment, the oxyhydrogen gas flow rate is used as the current gas production rate of the oxyhydrogen gas production device, and the oxyhydrogen gas flow rate corresponds to the current gas quantities produced by hydrogen and oxygen per unit time. The preset gas flow rate is the normal gas production rate of the oxyhydrogen gas production device, namely the preset gas flow rate is the speed of the gas produced by the oxyhydrogen gas production device under the rated voltage and rated current, namely the corresponding standard gas flow rate under the normal gas production rate. And performing the flow compensation treatment on the oxyhydrogen gas flow rate and the preset gas flow rate by comparing the current gas output rate of the oxyhydrogen gas generation device with a standard gas generation rate, and then conveniently obtaining the difference of the gas generated by the oxyhydrogen gas generation device in the current time based on the gas generation time, so as to conveniently determine whether the total amount of the gas generated by the oxyhydrogen gas generation device currently has deviation, and further conveniently determine the difference degree between the total amount of the gas generated by the oxyhydrogen gas generation device currently and the standard gas generation total amount, namely the oxyhydrogen gas flow difference compensation amount. Therefore, whether the gas generated by the oxyhydrogen gas generation device is sufficient or not can be conveniently determined subsequently according to the difference condition of the oxyhydrogen gas flow difference compensation amount, so that the subsequent gas generation working state of the oxyhydrogen gas generation device can be conveniently controlled, and the subsequent gas generation flow of the oxyhydrogen gas generation device can be conveniently regulated and controlled.

S300: and sending a flow control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation amount so as to adjust the gas outlet flow of the oxyhydrogen gas production device.

In this embodiment, the oxyhydrogen gas flow difference compensation amount is used as a difference degree between the total amount of the gas currently generated by the oxyhydrogen gas generation device and the standard gas generation total amount, that is, the oxyhydrogen gas flow difference compensation amount is a reference value for detecting whether the total amount of the gas currently generated by the oxyhydrogen gas generation device is sufficient, and the size of the oxyhydrogen gas flow difference compensation amount directly determines the current gas generation total amount condition of the oxyhydrogen gas generation device. Based on the numerical value of the difference compensation amount of the oxyhydrogen gas flow, whether the current total gas production amount of the oxyhydrogen gas production device is insufficient, sufficient or excessive can be determined. Therefore, after the condition of the difference compensation amount of the oxyhydrogen gas flow is determined, the output current of the gas generation power supply device is conveniently controlled, namely the electrolysis current of the oxyhydrogen gas generation device is controlled, namely the current loaded by the electrolysis of the oxyhydrogen in the oxyhydrogen gas generation device is regulated and controlled, so that the gas outlet flow of the oxyhydrogen gas generation device is finally regulated, the subsequent gas output amount of the oxyhydrogen gas generation device is further conveniently regulated, and the probability of excessive hydrogen and oxygen intake of a user is effectively reduced.

In the above embodiment, the gas flow rate of the oxyhydrogen gas generation device is collected to facilitate determination of the current gas generation rate of the oxyhydrogen gas generation device, and the current gas generation rate is subjected to compensation processing with the preset gas flow rate, thereby facilitating determination of a difference between the current total gas generation amount of the oxyhydrogen gas generation device and the standard total gas generation amount, i.e. oxyhydrogen gas flow difference compensation amount. Therefore, according to the specific situation of the difference compensation amount of the oxyhydrogen gas flow, the current control signal of the gas production power supply device is controlled, so that the gas production power supply device can be conveniently controlled to supply power to the oxyhydrogen gas production device, the total gas outlet amount of the oxyhydrogen gas production device can be conveniently controlled, the probability of excessive gas intake of a user is effectively reduced, and the safe use is ensured.

In one embodiment, the obtaining of the oxyhydrogen gas flow rate of the oxyhydrogen gas generation device comprises: and acquiring the gas outlet flow rate of the hydrogen and oxygen gas production device. In this embodiment, the oxyhydrogen gas generation device is provided with a gas storage bin and an electrolysis bin, wherein the electrolysis bin is used for storing an electrolysis medium and electrolyzing the electrolysis medium through an electrolysis electrode to generate hydrogen and oxygen, and the generated gas is introduced into the gas storage bin through an air inlet. The gas storage bin stores gas for a short time, and the gas is led out through the gas outlet hole of the gas storage bin after being stored to a certain amount, so that a user can conveniently take the gas. The gas outlet flow velocity of the oxyhydrogen gas production device is the flow velocity of gas passing through the gas outlet holes of the gas storage bin, the gas outlet flow velocity is the difference value of the stored gas velocity in the gas storage bin and the derived gas velocity, namely the gas outlet flow velocity is influenced by the electrolysis efficiency of the electrolysis bin and the use condition of a user. Therefore, the gas flow rate of the gas outlet hole of the gas storage bin is detected, the gas quantity led out from the gas storage bin can be accurately obtained, the specific gas intake quantity of a user can be conveniently determined, and the accurate control of the gas outlet flow of the oxyhydrogen gas production device is improved.

Further, the flow compensation processing of the oxyhydrogen gas flow rate and a preset gas flow rate to obtain the difference compensation amount of the oxyhydrogen gas flow comprises: and carrying out flow rate difference compensation operation on the outlet flow rate and a preset outlet flow rate to obtain a flow rate difference of the oxyhydrogen airflow. In this embodiment, the gas outlet flow rate is the current gas production rate of the oxyhydrogen gas production device, for example, the gas outlet flow rate is the real-time gas production rate of the oxyhydrogen gas production device; for another example, the gas outlet flow rate is the average gas outlet rate of the hydrogen and oxygen gas production device in a specified time period. The preset gas outlet rate is a standard and constant gas outlet rate, namely the constant gas outlet rate of the oxyhydrogen gas generating device is used for reaching the standard total gas outlet amount in a specified time. And specifically, when the gas outlet flow rate is the real-time gas production rate of the oxyhydrogen gas production device, the time integral of the gas outlet flow rate in a specified gas production time period is obtained, so that the current gas production total amount of the oxyhydrogen gas production device is conveniently obtained, and the difference between the current gas production total amount and the standard gas production total amount, namely the oxyhydrogen gas flow difference compensation amount, is conveniently calculated. Therefore, after the difference compensation amount of the oxyhydrogen gas flow is determined, the difference value between the total gas production amount of the oxyhydrogen gas production device and the standard total gas production amount can be known, so that whether the current total gas production amount of the oxyhydrogen gas production device is enough or not can be known conveniently.

In one embodiment, the sending a current control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation amount to adjust the gas outlet flow rate of the oxyhydrogen gas production device includes: detecting whether the difference compensation quantity of the oxyhydrogen airflow is matched with a preset airflow difference compensation quantity; and when the difference compensation amount of the hydrogen and oxygen gas flow is not matched with the preset gas flow difference compensation amount, a current maintenance signal is sent to the gas production power supply device. In this embodiment, the oxyhydrogen gas flow difference compensation amount is used as a difference degree between the total amount of the gas currently generated by the oxyhydrogen gas generation device and the standard gas generation total amount, that is, the oxyhydrogen gas flow difference compensation amount is a reference value for detecting whether the total amount of the gas currently generated by the oxyhydrogen gas generation device is sufficient, and the size of the oxyhydrogen gas flow difference compensation amount directly determines the current gas generation total amount condition of the oxyhydrogen gas generation device. Based on the numerical value of the difference compensation amount of the oxyhydrogen gas flow, whether the current total gas production amount of the oxyhydrogen gas production device is insufficient, sufficient or excessive can be determined. The preset gas flow difference compensation amount is a standard oxyhydrogen gas flow difference compensation amount, namely the preset gas flow difference compensation amount is used as a judgment standard for the oxyhydrogen gas flow difference compensation amount, namely the preset gas flow difference compensation amount is used as a standard for judging whether the total gas production amount of the oxyhydrogen gas production device is sufficient or not. The difference compensation amount of the oxyhydrogen gas flow is not matched with the preset difference compensation amount of the gas flow, which indicates that the current total gas production amount of the oxyhydrogen gas production device does not reach the standard total gas production amount, namely indicates that the current total gas production amount of the oxyhydrogen gas production device is insufficient, namely indicates that the current total gas production amount of the oxyhydrogen gas production device is less. At the moment, a current maintaining signal is sent to the gas production power supply device so that the hydrogen and oxygen gas production device can continuously produce gas.

In another embodiment, the sending a current maintenance signal to the gas production power supply device when the oxyhydrogen gas flow difference compensation amount does not match the preset gas flow difference compensation amount includes: and when the difference compensation amount of the oxyhydrogen gas flow is less than the preset gas flow difference compensation amount, sending a flow rate maintaining signal to the gas production power supply device so as to keep the gas outlet flow rate of the oxyhydrogen gas production device the same as the previous flow rate. And the oxyhydrogen gas flow difference compensation amount is less than the preset gas flow difference compensation amount, the current total gas production amount of the oxyhydrogen gas production device is determined to be less than a standard value, and a flow rate maintaining signal is conveniently sent to the gas production power supply device to ensure that the gas production power supply device continuously supplies power to the oxyhydrogen gas production device, so that the oxyhydrogen gas production device is ensured to continuously produce hydrogen and oxygen.

In one embodiment, the detecting whether the difference compensation amount of the oxyhydrogen gas flow is matched with a preset gas flow difference compensation amount further comprises: and when the oxyhydrogen gas flow difference compensation quantity is matched with a preset gas flow difference compensation quantity, adjusting a gas flow modulation signal sent to the gas production power supply device. In this embodiment, the oxyhydrogen gas flow difference compensation amount is used as a difference degree between the total amount of the gas currently generated by the oxyhydrogen gas generation device and the standard gas generation total amount, that is, the oxyhydrogen gas flow difference compensation amount is a reference value for detecting whether the total amount of the gas currently generated by the oxyhydrogen gas generation device is sufficient, and the size of the oxyhydrogen gas flow difference compensation amount directly determines the current gas generation total amount condition of the oxyhydrogen gas generation device. Based on the numerical value of the difference compensation amount of the oxyhydrogen gas flow, whether the current total gas production amount of the oxyhydrogen gas production device is insufficient, sufficient or excessive can be determined. The preset gas flow difference compensation amount is a standard oxyhydrogen gas flow difference compensation amount, namely the preset gas flow difference compensation amount is used as a judgment standard for the oxyhydrogen gas flow difference compensation amount, namely the preset gas flow difference compensation amount is used as a standard for judging whether the total gas production amount of the oxyhydrogen gas production device is sufficient or not. The difference compensation amount of the oxyhydrogen gas flow is matched with the preset difference compensation amount of the gas flow, which indicates that the current total gas production amount of the oxyhydrogen gas production device reaches the standard total gas production amount, namely indicates that the current total gas production amount of the oxyhydrogen gas production device is sufficient, namely indicates that the current total gas production amount of the oxyhydrogen gas production device is more. And sending an air flow modulation signal to the gas production power supply device so as to adjust the gas production state of the hydrogen-oxygen gas production device.

In another embodiment, the adjusting the gas flow modulation signal sent to the gas production power supply device when the oxyhydrogen gas flow difference compensation amount is matched with a preset gas flow difference compensation amount comprises: and when the difference compensation amount of the oxyhydrogen gas flow is larger than the preset gas flow difference compensation amount, sending a stop signal to the gas production power supply device so as to stop gas outlet of the oxyhydrogen gas production device. In this embodiment, the oxyhydrogen gas flow difference compensation amount is matched with a preset gas flow difference compensation amount, that is, the oxyhydrogen gas flow difference compensation amount is greater than the preset gas flow difference compensation amount, that is, the oxyhydrogen gas flow difference compensation amount exceeds the oxyhydrogen gas flow difference compensation amount, that is, the oxyhydrogen gas flow difference compensation amount is greater than the standard gas flow difference compensation amount, which indicates that the standard total gas production amount of the current total gas production amount of the oxyhydrogen gas production device is excessive, and at this time, a stop signal is sent to the gas production power supply device to stop supplying power to the oxyhydrogen gas production device, so that the gas production of the oxyhydrogen gas production device is stopped, and the probability of excessive hydrogen and oxygen intake of a user is effectively reduced.

As can be understood, after the oxyhydrogen gas production device is electrified, the positive electrode and the negative electrode in the electrolysis bin are electrified so as to carry out electrolysis operation on the electrolysis medium in the electrolysis bin, so that hydrogen and oxygen with corresponding volume ratio can be produced through electrolysis. Wherein, electrolysis storehouse and gas storage storehouse intercommunication, produced gas temporary storage in the electrolysis storehouse is in the gas storage storehouse to the user uses gas through the gas storage storehouse that corresponds, specifically, the gas storage storehouse has two, and one is used for storing hydrogen, and another is used for storing oxygen.

However, in the actual use process, the volume of the gas in the gas storage bin increases with the time, the gas outlet of the gas storage bin is communicated with the suction nozzle, when the gas storage rate in the gas storage bin is greater than or equal to the gas outlet rate, a large part of the gas prepared by the oxyhydrogen gas generating device is wasted, for example, after the gas storage bin is opened by mistake, no one uses hydrogen or oxygen; as another example, during normal use, the rate at which a user inhales gas is slow. These conditions lead to unnecessary waste of gas and, in the worst case, to an overoxidation of the surrounding environment, i.e. to an intoxicated environment for the user.

In order to reduce the probability of excessive waste of gas, the method sends a flow control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation quantity so as to adjust the gas outlet flow of the oxyhydrogen gas production device, and then further comprises the following steps:

acquiring the separation pressure of a gas storage bin of the hydrogen and oxygen gas production device;

detecting whether the separation pressure is greater than or equal to a preset pressure;

and when the separation pressure is greater than or equal to the preset pressure, sending a first gas adjusting compensation signal to the gas production power supply device so as to reduce the gas preparation acceleration of the hydrogen-oxygen gas production device.

In this embodiment, the separation pressure is an internal air pressure of the gas storage bin, and specifically, the separation pressure is a pressure on an air outlet diaphragm of the gas storage bin. In the process of preparing gas by the hydrogen-oxygen gas production device through electrolysis, hydrogen and oxygen enter corresponding gas storage bins to be stored, the gas outlet diaphragm is positioned at the gas outlet of the gas storage bins and is extruded by the gas, so that the separation pressure is used for reflecting the pressure when the gas in the gas storage bins is stored, and the pressure on the gas outlet diaphragm is obtained through corresponding gas pressure sensors. The separation pressure is the real-time air pressure of the air in the air storage bin, and the separation pressure is used for displaying the current pressure on an air outlet diaphragm in the air storage bin, namely the separation pressure is used for displaying the current pressure of the air in the air storage bin. The preset pressure is the maximum air pressure of the gas stored in the gas storage bin, namely the preset pressure is the maximum air pressure which can be borne by the gas outlet diaphragm in the gas storage bin, namely the preset pressure is the corresponding air pressure when the gas in the gas storage bin is excessive. Thus, the separation pressure is greater than or equal to the preset pressure, which indicates that the current gas pressure of the gas in the gas storage bin is greater than the standard gas pressure, i.e., indicates that the current gas pressure of the gas in the gas storage bin reaches or greatly exceeds the maximum gas pressure which can be borne by the gas diaphragm, i.e., indicates that the current volume of the gas in the gas storage bin is greater than the maximum gas storage volume, and at this time, the gas in the gas storage bin is in an excessive amount, and simultaneously indicates that the gas preparation rate of the oxyhydrogen gas generation device is greater than the gas outlet rate. In this way, a first gas regulation compensation signal is sent to the gas production power supply device, and the first gas regulation compensation signal performs gas regulation on the gas regulation signal, for example, the increase rate of the gas production speed of the oxyhydrogen gas production device is reduced, that is, the increase amount of the gas production speed of the oxyhydrogen gas production device is reduced, so that the increase of the gas production speed of the oxyhydrogen gas production device is slowed, specifically, the increase amount of the increase rate of the electrolytic current output by the gas production power supply device is reduced, so that the increase amount of the gas production speed of the oxyhydrogen gas production device is reduced, further, the excessive gas probability of the oxyhydrogen gas production device is reduced, the excessive gas probability of the oxyhydrogen gas production device is effectively reduced, and meanwhile, the power consumption of the oxyhydrogen gas production device can also be reduced.

Furthermore, the casing of the oxyhydrogen gas production device is made of plastic, so that the heat insulation performance is poor, the temperature in the gas storage bin is easily influenced by the external environment, namely, the gas in the gas storage bin is easily subjected to heat exchange, and therefore, the temperature in the storage cavity is easily influenced by the external environment and the condition that the gas in the gas storage bin is excessive is easily judged by mistake in the environment with higher temperature.

In order to further reduce the probability of misjudgment, the method for detecting whether the temperature of the storage cavity is greater than or equal to a preset cavity temperature further comprises the following steps:

obtaining the surface environment temperature of the hydrogen and oxygen gas production device;

carrying out cavity-ring temperature compensation treatment on the outer surface ring temperature and the storage cavity temperature to obtain cavity-ring temperature compensation quantity;

detecting whether the cavity ring temperature compensation quantity is matched with a preset temperature compensation quantity or not;

and when the cavity ring temperature compensation quantity is matched with the preset temperature compensation quantity, sending a temperature updating signal to the oxyhydrogen preparation monitoring system so as to adjust the preset cavity temperature.

In this embodiment, the external surface temperature is the temperature of the environment where the housing of the oxyhydrogen gas generation device is located, and specifically, an environment temperature sensor is disposed on the housing of the oxyhydrogen gas generation device and is used for sensing the external surface temperature. The gas storage chamber is characterized in that the temperature of the storage chamber is the temperature of gas in the gas storage chamber, the surface ring temperature and the storage chamber temperature are subjected to chamber ring temperature compensation treatment, the temperature of the gas in the gas storage chamber is compared with the external environment temperature, so that the difference between the temperature of the gas in the gas storage chamber and the external environment temperature is obtained, namely the temperature difference between the temperature of the gas in the gas storage chamber and the external environment temperature is obtained, and the chamber ring temperature compensation quantity is also obtained. The preset temperature compensation amount is a temperature difference range between the gas temperature in the gas storage bin and the external environment temperature, namely the preset temperature compensation amount is the inter-cell temperature difference between the gas temperature in the gas storage bin and the external environment temperature. The cavity ring temperature compensation quantity is matched with the preset temperature compensation quantity, so that the fact that the difference between the gas temperature in the gas storage bin and the external environment temperature is too small is indicated, namely, the fact that the gas temperature in the gas storage bin is equivalent to the external environment temperature is indicated, namely, the fact that the gas temperature in the gas storage bin is influenced by the external environment temperature is indicated, at the moment, the difference exists between the storage cavity temperature in the gas storage bin and the actual temperature of the internal gas, the preset cavity temperature needs to be updated, accurate judgment of the storage cavity temperature is guaranteed, and therefore the misjudgment probability of the condition that the gas in the gas storage bin is excessive is reduced.

In another embodiment, the sending a warmer signal to the oxyhydrogen production monitoring system to adjust the preset cavity temperature comprises the following steps:

detecting whether the temperature of the storage cavity is greater than or equal to a first preset cavity temperature;

when the temperature of the storage cavity is greater than or equal to the first preset cavity temperature, a first temperature-raising signal is sent to an oxyhydrogen preparation monitoring system so as to increase the preset cavity temperature. And increasing the temperature of the preset cavity under the high-temperature environment, so that the temperature judgment standard of the temperature of the storage cavity is increased, and the erroneous judgment probability of excessive gas is reduced.

Whether the temperature of the storage cavity is larger than or equal to a first preset cavity temperature or not is detected, and then the method further comprises the following steps:

when the temperature of the storage cavity is lower than the first preset cavity temperature, detecting whether the temperature of the storage cavity is higher than or equal to a second preset cavity temperature;

and when the temperature of the storage cavity is greater than or equal to the second preset cavity temperature, sending a second temperature-raising signal to the hydrogen and oxygen preparation monitoring system so as to reduce the preset cavity temperature. And the second preset cavity temperature is lower than the first preset cavity temperature and is in a low-temperature environment at the moment, and the preset cavity temperature is reduced, so that the temperature judgment standard of the storage cavity temperature is reduced, and the misjudgment probability of excessive gas is reduced.

Furthermore, when the gas in the gas storage bin is stored, part of moisture in the electrolytic medium in the electrolytic bin is mixed with the gas and then is stored in the gas storage bin, and once the gas in the gas storage bin is excessive, the water drops are condensed on the diaphragm between the gas storage bin and the electrolytic bin, so that the gas in the electrolytic bin cannot be smoothly guided into the gas storage bin, the gas pressure in the electrolytic bin is easily too high, and the probability of explosion of the electrolytic bin is easily increased.

In order to reduce the probability of explosion of the electrolytic bin when the electrolysis is excessive, when the separation pressure is greater than or equal to the preset pressure, a first gas adjusting compensation signal is sent to the gas production power supply device to reduce the gas preparation acceleration of the oxyhydrogen gas production device, and then the method further comprises the following steps:

acquiring the humidity of a storage cavity of the gas storage bin;

detecting whether the humidity of the storage cavity is larger than the preset cavity humidity;

and when the humidity of the storage cavity is greater than the preset cavity humidity, sending an inhibition signal to the hydrogen-oxygen gas production device to stop supplying power to the hydrogen-oxygen gas production device.

In this embodiment, the separation pressure is higher than a standard pressure, that is, the air pressure in the air storage bin is higher than the maximum air pressure that the air outlet diaphragm can bear, at this time, the humidity of the storage cavity in the air storage bin needs to be detected, the humidity of the storage cavity is the current humidity in the air storage bin, and the humidity of the storage cavity is used for showing whether the moisture in the air storage bin is excessive. The preset cavity temperature is the corresponding cavity humidity when water molecules in the gas storage cavity are condensed into water drops and plug the through hole in the diaphragm between the electrolysis chamber and the gas storage chamber, and the preset cavity temperature is used as the standard humidity in the gas storage cavity and is used for comparing the current humidity in the gas storage cavity. The humidity of the storage cavity is greater than or equal to the preset cavity temperature, which indicates that the humidity in the storage cavity is too high, i.e. that water drops on the diaphragm in the storage cavity are too much, i.e. that the amount of water drops formed by condensation in the storage cavity is excessive. Therefore, a forbidden signal is sent to the gas production power supply device at the moment, the forbidden signal is used for carrying out rate adjustment on the first gas regulation compensation signal, specifically, the forbidden signal is used for reducing the gas production rate of the oxyhydrogen gas production device to 0, so that the water molecule production rate of the oxyhydrogen gas production device is reduced, the oxyhydrogen gas production device is forbidden to continue to produce gas, and an alarm is given out to avoid the situation of bin explosion of the electrolytic bin.

In one embodiment, the present application further provides an oxyhydrogen gas flow monitoring system, which is implemented by using the oxyhydrogen gas flow monitoring method described in any one of the above embodiments. In one embodiment, the oxyhydrogen gas flow monitoring system is provided with functional modules for realizing the corresponding steps of the oxyhydrogen gas flow monitoring method. The oxyhydrogen gas flow monitoring system comprises a gas production power supply device, an oxyhydrogen gas production device and an oxyhydrogen gas flow monitoring mainboard, wherein the power supply end of the oxyhydrogen gas production device is connected with the output end of the gas production power supply device, and the oxyhydrogen gas production device is used for preparing and producing hydrogen and oxygen; the input end of the oxyhydrogen airflow monitoring mainboard is connected with the monitoring end of the oxyhydrogen gas production device, specifically, the input end of the oxyhydrogen airflow monitoring mainboard is connected with an airflow sensor in the oxyhydrogen gas production device, the output end of the oxyhydrogen airflow monitoring mainboard is connected with the control end of the gas production power supply device, and the oxyhydrogen airflow monitoring mainboard is used for acquiring the oxyhydrogen gas flow rate of the oxyhydrogen gas production device; performing flow compensation treatment on the oxyhydrogen airflow rate and a preset airflow rate to obtain the difference compensation amount of the oxyhydrogen airflow; and sending a flow control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation amount so as to adjust the gas outlet flow of the oxyhydrogen gas production device.

In this embodiment, the oxyhydrogen gas flow monitoring main board is used for acquiring the gas flow rate of the oxyhydrogen gas production device, so as to determine the current gas production rate of the oxyhydrogen gas production device and perform flow compensation processing on the current gas production rate and the preset gas flow rate, thereby determining the difference between the current total gas production amount of the oxyhydrogen gas production device and the standard total gas production amount, i.e. the difference compensation amount of the oxyhydrogen gas flow. Therefore, according to the specific situation of the difference compensation amount of the oxyhydrogen gas flow, the current control signal of the gas production power supply device is controlled, so that the gas production power supply device can be conveniently controlled to supply power to the oxyhydrogen gas production device, the total gas outlet amount of the oxyhydrogen gas production device can be conveniently controlled, the probability of excessive gas intake of a user is effectively reduced, and the safe use is ensured.

For the specific definition of the hydrogen and oxygen flow monitoring system, reference may be made to the above definition of the hydrogen and oxygen flow monitoring system, which is not described herein again. The above-mentioned hydrogen and oxygen gas flow monitoring system can be realized by software, hardware and their combination. The modules can be embedded in a hardware form or independent from a processor in the computer device, and can also be stored in a memory in the computer device in a software form, so that the processor can call and execute operations corresponding to the modules.

In one embodiment, a computer device is provided, which may be a server, the internal structure of which may be as shown in fig. 2. The computer device includes a processor, a memory, and a network interface connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, a computer program, and a database. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The database of the computer equipment is used for storing data such as oxyhydrogen gas flow rate, preset gas flow rate, oxyhydrogen gas flow difference compensation amount and the like. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program is executed by a processor to implement a oxyhydrogen gas flow monitoring method.

Those skilled in the art will appreciate that the architecture shown in fig. 2 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

In one embodiment, the present application further provides a computer device, which includes a memory and a processor, where the memory stores a computer program, and the processor implements the steps in the above method embodiments when executing the computer program.

In one embodiment, the present application further provides a computer-readable storage medium on which a computer program is stored, which, when executed by a processor, implements the steps in the above-described method embodiments.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database or other medium used in the embodiments provided herein can include at least one of non-volatile and volatile memory. Non-volatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical storage, or the like. Volatile Memory can include Random Access Memory (RAM) or external cache Memory. By way of illustration and not limitation, RAM can take many forms, such as Static Random Access Memory (SRAM) or Dynamic Random Access Memory (DRAM), among others.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A oxyhydrogen gas flow monitoring method, comprising:

acquiring the flow rate of oxyhydrogen gas of the oxyhydrogen gas production device;

performing flow compensation treatment on the oxyhydrogen airflow rate and a preset airflow rate to obtain the difference compensation amount of the oxyhydrogen airflow;

and sending a flow control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation amount so as to adjust the gas outlet flow of the oxyhydrogen gas production device.

2. The oxyhydrogen gas flow monitoring method according to claim 1, wherein the obtaining of the oxyhydrogen gas flow rate of the oxyhydrogen gas generation device comprises:

and acquiring the gas outlet flow rate of the hydrogen and oxygen gas production device.

3. The oxyhydrogen gas flow monitoring method according to claim 2, wherein the flow-compensating the oxyhydrogen gas flow rate with a preset gas flow rate to obtain the difference compensation amount of the oxyhydrogen gas flow comprises:

and carrying out flow rate difference compensation operation on the outlet flow rate and a preset outlet flow rate to obtain a flow rate difference of the oxyhydrogen airflow.

4. The oxyhydrogen gas flow monitoring method according to claim 1, wherein the sending a flow control signal to a gas production power supply device according to the difference compensation amount of the oxyhydrogen gas flow to adjust the gas outlet flow of the oxyhydrogen gas production device comprises:

detecting whether the difference compensation quantity of the oxyhydrogen airflow is matched with a preset airflow difference compensation quantity;

and when the difference compensation amount of the hydrogen and oxygen gas flow is not matched with the preset gas flow difference compensation amount, a current maintenance signal is sent to the gas production power supply device.

5. The oxyhydrogen gas flow monitoring method according to claim 4, wherein the sending a flow maintenance signal to the gas generation power supply device when the oxyhydrogen gas flow difference compensation amount does not match the preset gas flow difference compensation amount comprises:

and when the difference compensation amount of the oxyhydrogen gas flow is less than the preset gas flow difference compensation amount, sending a flow rate maintaining signal to the gas production power supply device so as to keep the gas outlet flow rate of the oxyhydrogen gas production device the same as the previous flow rate.

6. The oxyhydrogen gas flow monitoring method according to claim 4, wherein the detecting whether the oxyhydrogen gas flow difference compensation amount matches with a preset gas flow difference compensation amount further comprises:

and when the oxyhydrogen gas flow difference compensation quantity is matched with a preset gas flow difference compensation quantity, adjusting a gas flow modulation signal sent to the gas production power supply device.

7. The oxyhydrogen gas flow monitoring method according to claim 6, wherein the adjusting the gas flow modulation signal sent to the gas generation power supply device when the oxyhydrogen gas flow difference compensation amount matches a preset gas flow difference compensation amount comprises:

and when the difference compensation amount of the oxyhydrogen gas flow is larger than the preset gas flow difference compensation amount, sending a stop signal to the gas production power supply device so as to stop gas outlet of the oxyhydrogen gas production device.

8. An oxyhydrogen gas flow monitoring system, comprising:

a gas-generating power supply device,

the hydrogen and oxygen gas production device is used for preparing and producing hydrogen and oxygen;

the input end of the oxyhydrogen gas flow monitoring mainboard is connected with the monitoring end of the oxyhydrogen gas generating device, the output end of the oxyhydrogen gas flow monitoring mainboard is connected with the control end of the gas generating power supply device, and the oxyhydrogen gas flow monitoring mainboard is used for acquiring the oxyhydrogen gas flow rate of the oxyhydrogen gas generating device; performing flow compensation treatment on the oxyhydrogen airflow rate and a preset airflow rate to obtain the difference compensation amount of the oxyhydrogen airflow; and sending a flow control signal to a gas production power supply device according to the oxyhydrogen gas flow difference compensation amount so as to adjust the gas outlet flow of the oxyhydrogen gas production device.

9. A computer device comprising a memory and a processor, the memory storing a computer program, wherein the processor implements the steps of the method of any one of claims 1 to 7 when executing the computer program.

10. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method according to any one of claims 1 to 7.

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