CN115307255A - Eye-protecting lamp control method, system, equipment and medium with anion purification function - Google Patents

Abstract

The application relates to an eye-protection lamp control method, system, equipment and medium with an anion purification function, which comprises the following steps: when the anion generator is started, detecting and acquiring the anion concentration of the environment where the eye protection lamp is located in real time to obtain concentration data; inputting the concentration data into a concentration judgment model preset with an anion concentration interval in real time, and comparing the real-time concentration data with the anion concentration interval to obtain a comparison result; based on the comparison result, when the concentration data is not in the negative ion concentration interval, sending an adjusting instruction for controlling the negative ion generation rate to the negative ion generator so as to enable the concentration data to be in the negative ion concentration interval; and when the concentration data is within the negative ion concentration interval, sending a speed locking instruction to the negative ion generator. This application has the automatically regulated that real anion produced speed for the eye-protecting lamp place environment can obtain the effect of stable comparatively high-quality air quality.

Description

Eye-protecting lamp control method, system, equipment and medium with anion purification function

Technical Field

The application relates to the technical field of intelligent lamps, in particular to an eye-protection lamp control method, system, equipment and medium with an anion purification function.

Background

Negative ions, namely air negative (oxygen) ions, refer to the general name of single gas molecules with negative charges and hydrogen ion groups; at present, intelligence eye-protecting lamp disposes anion generator to in eye-protecting lamp launches the in-process, make anion generator produce the anion, adsorb the bacterium in the air, improve air quality, can have huge help to human respiratory and nervous system simultaneously.

When the user starts eye-protecting lamp, anion generator starts and produces the anion, make anion concentration increase in the air, then obtain better quality air quality when anion reaches certain concentration in the air, but because the air replacement degree of eye-protecting lamp place environment and user oxygen consumption easily appear changing, make anion concentration change often in the air, the air quality that leads to eye-protecting lamp place environment is unstable, the user also does not make things convenient for real time monitoring to adjust anion production rate, therefore, the difficult better quality air quality that obtains stable of eye-protecting lamp place environment.

Disclosure of Invention

In order to realize the automatic adjustment of the anion generation rate and ensure that the environment where the eye-protection lamp is located can obtain stable and high-quality air quality, the application provides an eye-protection lamp control method, system, equipment and medium with an anion purification function.

The above object of the present invention is achieved by the following technical solutions:

an eye-protection lamp control method with an anion purification function comprises the following steps:

when the anion generator is started, detecting and acquiring the anion concentration of the environment where the eye protection lamp is located in real time to obtain concentration data;

inputting the concentration data into a concentration judgment model preset with an anion concentration interval in real time, wherein the air quality is high when the concentration of anions in the air is within the anion concentration interval;

comparing the real-time concentration data with the negative ion concentration interval to obtain a comparison result;

based on the comparison result, when the concentration data is not in the negative ion concentration interval, sending an adjusting instruction for controlling the generation rate of negative ions to the negative ion generator so as to enable the concentration data to be in the negative ion concentration interval;

when the concentration data is within the negative ion concentration interval, a rate locking instruction is sent to the negative ion generator.

Through adopting above-mentioned technical scheme, start anion generator when the user opens the eye-protecting lamp, anion generator produces the anion with fixed rate and the anion concentration of real-time detection eye-protecting lamp place environment to compare anion concentration and predetermined concentration interval, judge whether air quality is in comparatively high-quality state through the anion concentration in the comparison air promptly.

When the air replacement degree of the environment is large or the consumption in the environment is large, so that the concentration data is smaller than the minimum value of the anion concentration interval, sending an adjusting instruction to increase the anion generation rate to improve the anion concentration in the air; after environmental air replacement degree or oxygen consumption diminish, send adjustment command and reduce the production rate of anion, then produce the anion with current rate when anion concentration is in anion concentration interval in the air, can control anion concentration this moment in order to obtain better quality air instruction, can save the electric energy again, consequently, through adjustment command automatically regulated anion production rate, realize the stability regulation of anion concentration in the air, can be automatic in anion concentration interval with the anion concentration control of eye-protecting lamp place environment promptly, conveniently control eye-protecting lamp place environment and obtain stable comparatively high-quality air quality.

In a superior example of the present application: the step of sending an adjustment instruction for controlling the generation rate of negative ions to the negative ion generator when the concentration data is not within the negative ion concentration interval based on the comparison result includes:

when the concentration data is smaller than the lower limit value of the negative ion concentration interval, sending a speed increasing instruction for increasing the negative ion generating speed to the negative ion generator;

when the concentration data is larger than the upper limit value of the negative ion concentration interval, a deceleration instruction for decelerating the negative ion generation rate is sent to the negative ion generator.

By adopting the technical scheme, when the concentration data is smaller than the lower limit value of the negative ion concentration interval, the speed of the negative ions generated by the negative ion generator can be increased through the speed increasing instruction, so that the quantity of the negative ions generated by the negative ion generator in unit time is increased, the concentration of the negative ions in the air is increased, the environment where the eye-protecting lamp is located is accelerated to obtain high-quality air quality, and a user can be in the environment with high-quality air quality more quickly; when the concentration data is larger than the upper limit value of the negative ion concentration interval, the speed reduction instruction is sent to reduce the generation rate of the negative ions until the concentration of the negative ions is within the negative ion concentration interval, and at the moment, the environment where the eye protection lamp is located can obtain high-quality air quality, and meanwhile, the electric energy consumed by the negative ion generator is saved.

In a superior example of the present application: when the anion generator is started, the anion concentration of the environment where the eye protection lamp is located is detected and acquired in real time, and the following steps are executed before the step of acquiring concentration data:

when receiving a speed setting request sent by a user side, sending an input port for setting an acceleration level and a deceleration level to the user side;

when the speed increasing level and the speed reducing level input by the user terminal are received, the speed increasing level is associated with the speed increasing instruction so that the speed of generating negative ions when the negative ion generator receives the speed increasing instruction is increased by one speed increasing level, and the speed reducing level is associated with the speed reducing instruction so that the speed of generating the negative ions when the negative ion generator receives the speed reducing instruction is reduced by one speed reducing level.

By adopting the technical scheme, the speed-up level and the speed-down level are respectively used for controlling the speed of the negative ions generated by the negative ion generator to be increased and decreased, and are set by a user in a self-defined manner, so that if the user has a large demand on the change of the negative ion generation speed, the user can set the large speed-up level and the large speed-down level to accelerate the change of the air impact negative ion concentration; if the user has a great demand on the accuracy of the concentration of the negative ions in the air, a small speed increasing level and a small speed reducing level can be set, so that the automatic adjustment of the generation rate of the concentration of the negative ions is more accurate, the high-quality air quality is obtained, and meanwhile, the electric energy is saved.

In a preferred example of the present application: a plurality of mode identifications are preset for the eye-protecting lamp, the brightness and the color temperature of the light corresponding to each mode identification are different, when the anion generator is started, the anion concentration of the environment where the eye-protecting lamp is located is detected and acquired in real time, and the following steps are executed before the step of obtaining concentration data:

acquiring a plurality of mode identifiers of the eye-protection lamp, and binding each mode identifier to an anion concentration interval, wherein the anion concentration intervals bound by the mode identifiers are different;

sending a plurality of mode identifiers to a user side;

when a selection instruction from a user side is received, acquiring a mode identifier selected by the user based on the selection instruction;

and sending the identification mode to a concentration judgment model, and screening out the negative ion concentration range bound by the identification model by the concentration judgment model based on the identification model.

After the step of inputting the concentration data into the concentration judgment model preset with the negative ion concentration interval in real time, the following steps are also executed:

and the concentration judgment model compares the concentration data received in real time with the negative ion concentration interval bound by the mode identifier selected by the user.

By adopting the technical scheme, the light brightness and the color temperature of the eye-protecting lamp in different modes are different, so that different eye-using conditions of a user are met, for example, when the user performs leisure sports or sleep, the light brightness and the color temperature of the two corresponding eye-protecting lamps are different, for example, when the user sleeps, the brightness of the eye-protecting lamp is low and the color temperature is warmer, the brightness is relatively higher during the leisure sports and the color temperature is cooler; furthermore, different identification modes are matched with different anion concentration intervals, so that the air anion concentration of the environment where the eye protection lamp is located can be adapted to the specific eye using condition and behavior of a user, for example, when the user selects the mode identification of leisure sports, the action behavior that the user may do sports or consume a large amount of oxygen is judged, and the matched anion concentration interval is higher than the office and reading mode under the normal condition, so that the user can inhale more high-quality air; when the user selects the sleep mode identification, the relative oxygen consumption of the user is low, and the relative anion concentration interval is lower than the office and reading mode, so that the user is ensured to breathe high-quality air, and the effect of saving electric energy is achieved.

Before the concentration data is input into the concentration judgment model, the mode identification selected by the user is judged, the bound negative ion concentration interval is screened out based on the selected mode identification and is compared and calculated with the received concentration data, and the function of regulating the negative ion concentration according to different mode identifications is realized.

In a preferred example of the present application: when the concentration data is smaller than the lower limit value of the negative ion concentration interval, after the step of sending a speed-up instruction for increasing the negative ion generation rate to the negative ion generator, the following steps are executed:

if the concentration data in the preset time is still smaller than the lower limit value of the negative ion concentration interval, acquiring the current speed-up level of the speed-up instruction;

increasing a speed increasing level on the basis of the current speed increasing level of the negative ion generator;

and/or the presence of a gas in the gas,

after the step of sending a deceleration instruction for decelerating the generation rate of negative ions to the negative ion generator when the density data is larger than the upper limit value of the negative ion density zone, the following steps are performed:

if the concentration data in the preset time is still larger than the upper limit value of the negative ion concentration interval, acquiring the current speed reduction level of the speed reduction instruction;

and increasing the speed reduction level based on the current speed reduction level of the negative ion generator.

By adopting the technical scheme, when the anion generator receives the speed-up instruction, but the concentration data is still smaller than the lower limit value of the anion concentration interval in the preset time, the anion generator is started for a period of time, the air quality with high quality can not be obtained due to the reason that the air replacement degree is large or the oxygen consumption of a user is large, and the speed-up level is increased to accelerate the generation speed of anions so that the environment where the eye-protection lamp is located can obtain high-quality air.

When the negative ion generator receives the speed reduction instruction and the concentration data is still larger than the upper limit value of the negative ion concentration interval, the result proves that the concentration of the negative ions in the air is sufficient, and the generation rate of the negative ions can be reduced to enable the negative eye protection lamp to save more energy.

The setting that can arrive back automatic stack, reduction in the time of predetermineeing of deceleration rank, speed-up rank for the environment of eyeshield lamp place can obtain stable comparatively high-quality air quality more fast.

In a preferred example of the present application: after the step of increasing the acquired speed-up level, the following steps are performed:

when the speed-up level reaches a preset speed-up upper limit level, if the concentration data in a preset time period is still smaller than a lower limit value of a negative ion concentration interval, generating a prompt signal;

and sending the prompt signal to the user side.

Through adopting above-mentioned technical scheme, when the speed-up rank reaches the upper limit, can't promote the production rate of anion again promptly, if the anion concentration in the ambient air that the eye-protecting lamp was located at this moment still is less than the anion concentration interval, then prove that the ambient air replacement degree that the eye-protecting lamp is located is big, and the air quality of the air replaced is low, the user is in under this environment, even if anion generator starts also can't obtain high-quality air, consequently send prompt message to the user side in order to remind the user, so that the user knows the air quality of environment and in order to further change the environment, or improve the environment of locating.

The second objective of the present invention is achieved by the following technical solutions:

the utility model provides a take anion purification performance's eyeshield lamp control system, includes:

the concentration acquisition module is used for detecting and acquiring the concentration of the negative ions in the environment where the eye protection lamp is located in real time when the negative ion generator is started to obtain concentration data;

the model input module is used for inputting the concentration data to a concentration judgment model with a preset negative ion concentration interval in real time, and the air quality is high when the concentration of negative ions in the air is within the negative ion concentration interval;

the comparison calculation module is used for comparing the real-time concentration data with the negative ion concentration interval to obtain a comparison result;

the speed regulating module is used for sending a regulating instruction for controlling the generation rate of the negative ions to the negative ion generator based on the comparison result when the concentration data is not in the negative ion concentration interval so as to enable the concentration data to be in the negative ion concentration interval;

and the speed locking module is used for sending a speed locking instruction to the negative ion generator when the concentration data is positioned in the negative ion concentration interval.

Through adopting above-mentioned technical scheme, start anion generator when the user opens the eye-protecting lamp, anion generator produces the anion with fixed rate and the anion concentration of real-time detection eye-protecting lamp place environment to compare anion concentration and predetermined concentration interval, judge whether air quality is in comparatively high-quality state through the anion concentration in the comparison air promptly.

When the air replacement degree of the environment is large or the consumption in the environment is large, so that the concentration data is smaller than the minimum value of the anion concentration interval, sending an adjusting instruction to increase the anion generation rate to improve the anion concentration in the air; after environmental air replacement degree or oxygen consumption diminish, send adjustment command and reduce the production rate of anion, then produce the anion with current rate when anion concentration is in anion concentration interval in the air, can control anion concentration this moment in order to obtain better quality air instruction, can save the electric energy again, consequently, through adjustment command automatically regulated anion production rate, realize the stability regulation of anion concentration in the air, can be automatic in anion concentration interval with the anion concentration control of eye-protecting lamp place environment promptly, conveniently control eye-protecting lamp place environment and obtain stable comparatively high-quality air quality.

Optionally, the speed regulation module includes:

the speed reduction module is used for sending a speed increasing instruction for increasing the generation speed of the negative ions to the negative ion generator when the concentration data is smaller than the lower limit value of the negative ion concentration interval;

and a speed-up instruction for sending a speed-down instruction for reducing the generation rate of the negative ions to the negative ion generator when the concentration data is greater than the upper limit value of the negative ion concentration interval.

The third purpose of the application is realized by the following technical scheme:

a computer device comprises a memory, a processor and a computer program which is stored in the memory and can run on the processor, wherein the processor executes the computer program to realize the steps of the eye protection lamp control method with the anion purification function.

The fourth purpose of the present application is achieved by the following technical solutions:

a computer-readable storage medium storing a computer program, which when executed by a processor, implements the steps of the above eye-protection lamp control method with anion purification function.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the negative ion generating speed is automatically adjusted through the adjusting instruction, the stability adjustment of the concentration of the negative ions in the air is realized, namely the concentration of the negative ions in the environment where the eye-protection lamp is located can be automatically controlled within the negative ion concentration range, and the environment where the eye-protection lamp is located is conveniently controlled to obtain stable and high-quality air quality;

2. when the concentration data is larger than the upper limit value of the negative ion concentration interval, the speed reduction instruction is sent to reduce the generation rate of negative ions until the concentration of the negative ions is within the negative ion concentration interval, and at the moment, the environment where the eye protection lamp is located can obtain high-quality air quality, and meanwhile, the electric energy consumed by the negative ion generator is saved;

3. if a user has a large demand on the change of the generation rate of the negative ions, a large speed-up level and a large speed-down level can be set so as to accelerate the change of the concentration of the negative ions in the air blast; if the user has a great demand on the accuracy of the concentration of the negative ions in the air, a small speed-up level and a small speed-down level can be set, so that the automatic adjustment of the generation rate of the concentration of the negative ions is more accurate;

4. and sending prompt information to the user side to remind the user so that the user can know the air quality of the environment to further replace the environment or improve the environment.

Drawings

FIG. 1 is a flowchart illustrating an embodiment of a method for controlling an eye-protection lamp with an anion purification function according to the present disclosure;

FIG. 2 is another flow chart of an embodiment of the method for controlling an eye-protection lamp with an anion purification function according to the present application;

fig. 3 is an interface diagram of a user terminal in an embodiment of the eye-protection lamp control method with anion purification function according to the present application;

fig. 4 is a functional block diagram of an eye-protection lamp control system with anion purification function according to the present application;

FIG. 5 is a functional block diagram of a computer device of the present application.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

In an embodiment, as shown in fig. 1, the application discloses a control method of an eye-protection lamp with a negative ion purification function, which specifically comprises the following steps:

s10: when the anion generator is started, detecting and acquiring the anion concentration of the environment where the eye protection lamp is located in real time to obtain concentration data;

in this embodiment, produce the anion when anion generator starts and export to the air of eyeshield lamp place environment, anion concentration detects and convert the analog signal who obtains to digital signal through negative oxygen ion sensor, and then obtains concentration data, and concentration data is the number that has the anion in the unit cube the inside, is a plurality of/cm and trains.

Specifically, when the eye-protecting lamp is started, the negative ion generator is started, and the negative oxygen ion sensor arranged on the eye-protecting lamp starts to detect the concentration of negative ions in the ambient air where the eye-protecting lamp is located, so that the concentration data of the negative ions are obtained.

S20: inputting the concentration data into a concentration judgment model preset with an anion concentration interval in real time, wherein the air quality is high when the concentration of anions in the air is within the anion concentration interval;

in this embodiment, when the negative ion concentration interval represents that the air quality is high, the concentration value of the negative ions in the air, and the concentration determination model is used to determine whether the received concentration data falls within the negative ion concentration interval.

Specifically, the concentration data acquired in real time is input into a concentration judgment model to further judge whether the concentration data is located in a negative ion concentration interval, the negative ion concentration interval is an artificially preset concentration interval value and comprises an upper limit value and a lower limit value, and the concentration judgment model can preset a plurality of different negative ion concentration intervals.

S30: comparing the real-time concentration data with the negative ion concentration interval to obtain a comparison result;

in this embodiment, the comparison result includes that the concentration data is smaller than the lower limit value of the negative ion concentration interval, the concentration data is located in the negative ion concentration interval, and the concentration data is greater than the upper limit value of the negative ion concentration interval.

Specifically, the concentration judgment model receives the concentration data in real time and sequentially judges whether the concentration data are located in the negative ion concentration interval, and outputs a comparison result.

S40: based on the comparison result, when the concentration data is not in the negative ion concentration interval, sending an adjusting instruction for controlling the negative ion generation rate to the negative ion generator so as to enable the concentration data to be in the negative ion concentration interval;

in this embodiment, the adjustment command is used to adjust the rate at which the ionizer generates negative ions, i.e., adjust the power of the ionizer.

Specifically, the concentration data does not include two cases in the negative ion concentration interval, and one case is: when the air replacement degree of the environment is large or the consumption of a user in the environment is large, so that the concentration data is smaller than the minimum value of the negative ion concentration interval, sending an adjusting instruction to increase the negative ion generating rate so as to improve the negative ion concentration in the air;

the other condition is as follows: the concentration data is larger than the maximum value of the negative ion concentration interval, when the replacement degree of the ambient air or the oxygen consumption is reduced, an adjusting instruction is sent to reduce the generation rate of negative ions, when the concentration of the negative ions in the air is in the negative ion concentration interval, the negative ions are generated at the current rate, at the moment, the concentration of the negative ions can be controlled to obtain a high-quality air instruction, and the electric energy can be saved.

S50: and when the concentration data is within the negative ion concentration interval, sending a speed locking instruction to the negative ion generator.

In this embodiment, when the anion generator receives the rate lock command, the concentration data is within the anion concentration interval, and the anion generator operates at the rate when the rate lock command is received, for example, when the concentration data is 1300 th/cm th, 500 anions are generated within a unit time, and when the anion concentration interval is 1200-1500 th/cm th, the concentration data is within the anion concentration interval, and at this time, the anion generator operates at a power of 500 anions generated within a unit time.

Specifically, when the concentration data is within the anion concentration interval, the air quality is proved to be high, the power of the anion generator does not need to be further reduced, a speed locking instruction is sent to control the anion generator to operate at the current power to output anions, the anion concentration in the air can be maintained, the air can be maintained in a high-quality state, and meanwhile, the anion generator is enabled to be more energy-saving.

In one embodiment, step S40 includes:

s41: when the concentration data is smaller than the lower limit value of the negative ion concentration interval, sending a speed increasing instruction for increasing the negative ion generating speed to the negative ion generator;

s42: when the concentration data is larger than the upper limit value of the negative ion concentration interval, a deceleration instruction for decelerating the negative ion generation rate is sent to the negative ion generator.

In this embodiment, the speed-up command is used to control the anion generator to increase the number of anions output per unit time, i.e. to increase the power of the anion generator. The speed reduction command is used for reducing the speed of the anion generator for generating anions, namely reducing the power of the anion generator, so that the number of the anions output to the air by the anion generator in unit time is reduced.

Specifically, under the condition that anion generator just started or because of the air replacement degree is big, under the condition that user's oxygen consumption is big in the environment, the condition that concentration data is less than anion concentration interval lower limit value easily appears, air quality is lower promptly, through sending out the speed-raising instruction to anion generator this moment and accelerating anion generator's production rate for anion number in the air increases, can be under the condition that anion generator just started or because of the air replacement degree is big, under the condition that user's oxygen consumption is big in the environment, promote the air quality of eye-protecting lamp place environment and reach comparatively high-quality state.

And after the environment of the eye-protecting lamp is started for a period of time, when the air replacement degree of the environment of the eye-protecting lamp is small or the oxygen consumption of a user is reduced, the concentration data is larger than the upper limit value of the anion concentration interval, the generation rate of anions is reduced by sending a speed reduction instruction, and the speed reduction is stopped when the concentration data is located in the anion concentration interval, so that the air quality of the environment of the eye-protecting lamp is in a high-quality state, and meanwhile, the energy consumption of an anion generator is reduced.

In one embodiment, before step S10, the following steps are performed:

s101: when receiving a speed setting request sent by a user side, sending an input port for setting an acceleration level and a deceleration level to the user side;

s102: when the speed increasing level and the speed reducing level input by the user terminal are received, the speed increasing level is associated with the speed increasing instruction so that the speed of generating negative ions when the negative ion generator receives the speed increasing instruction is increased by one speed increasing level, and the speed reducing level is associated with the speed reducing instruction so that the speed of generating the negative ions when the negative ion generator receives the speed reducing instruction is reduced by one speed reducing level.

In this embodiment, the user side is a mobile terminal or a PC side for performing wireless communication connection with the eye-protecting lamp and the anion generator to control the eye-protecting lamp and the anion generator, and the mobile terminal is bound with information of a user. The input port is a text box used for filling a speed-up level and a speed-down level, the speed-up level and the speed-down level are both provided with upper and lower limit intervals, the regulation of the speed-up level and the speed-down level can only be limited in the upper and lower limit intervals, for example, the speed-up level comprises first-level speed-up, second-level speed-up, third-level speed-up and the like, the speed increased by the second-level speed-up is twice of that of the first-level speed-up, the first-level speed-up enables the anion generator to generate 20 more anions in unit time, and the second-level speed-up enables the anion generator to generate 40 more anions in unit time.

Specifically, before the anion generator is started, the user side can set the variation amplitude of the rate of generating the anions by the anion generator each time, namely, the power variation amplitude of the anion generator is set, the speed-up level and the speed-down level are input through the input port, the speed-up level is associated with the speed-up instruction, and the speed-down level is associated with the speed-down instruction.

Further, when the speed increasing command is received by the anion generator, the speed of generating anions is increased by one speed increasing level, for example, the anion generator originally generates 500 anions per unit time, and after the speed increasing command is received, 520 anions per unit time are generated, and the speed increasing level is that 20 more anions are generated per unit time. Similarly, the speed of the negative ions generated by the negative ion generator is reduced by a speed reduction level when the negative ion generator receives the speed command.

In an embodiment, a plurality of mode identifiers are preset in the eye-protection lamp, and the brightness and the color temperature of the lamp corresponding to each mode identifier are different, referring to fig. 2, before step S10, the following steps are performed:

s11: acquiring a plurality of mode identifiers of the eye-protection lamp, and binding each mode identifier to an anion concentration interval, wherein the anion concentration intervals bound by the mode identifiers are different;

s12: sending a plurality of mode identifiers to a user side;

s13: when a selection instruction from a user side is received, acquiring a mode identifier selected by the user based on the selection instruction;

s14: sending the identification mode to a concentration judgment model, and screening out the negative ion concentration range bound by the identification model by the concentration judgment model based on the identification model;

in this embodiment, the plurality of mode identifiers include four modes, such as sleeping, reading, working, leisure (sports), and the like, each mode corresponds to different light brightness and color temperature to meet different eye use conditions of the user, for example, when the user turns on an eye protection lamp during sleeping, the light brightness and the color temperature are warmer; when a user is in motion, the user needs brighter light brightness and cooler color temperature to fully illuminate, and the light brightness is proper to protect the eyes of the user during reading and working.

Further, the anion concentration intervals corresponding to each mode identifier are different, for example, when the user selects the mode identifier of leisure sports, the oxygen consumption of the user is judged to be larger at the moment, and the matched anion concentration interval is higher than the modes of office work, reading, sleeping and the like under the normal condition, so that the user can inhale more anions, and the nervous system and the respiratory system of the user can be facilitated.

When the user is in a reading and office mode, the matched negative ion concentration interval is higher than the sleep mode and lower than the leisure (sports) mode, so that the refreshing effect is achieved for the user, and the improvement of the working and reading vigor of the user is facilitated.

When the user selects the sleep mode identification, the relative oxygen consumption of the user is low, and the relative anion concentration interval is lower than the leisure (sports), office and reading modes, so that the user is ensured to breathe high-quality air and the effect of saving electric energy is achieved.

Specifically, obtain four mode identifications of eye-protecting lamp to bind the anion concentration interval of different numerical values size respectively with four mode identifications, wherein the anion concentration interval numerical value that four mode identifications correspond is arranged from big to small: leisure (sports) mode, office mode, reading mode, sleeping mode.

And further sending the four mode identifications to a user side, acquiring the mode identification selected by the user, sending the mode identification to a concentration judgment model, and screening out the bound negative ion concentration interval by the concentration judgment model based on the mode identification so as to compare the negative ion concentration interval with the received concentration data.

After step S20, the following steps are also performed:

s21: and the concentration judgment model compares the concentration data received in real time with the negative ion concentration interval bound by the mode identifier selected by the user.

In this embodiment, when the user switches the mode sign, the concentration judgment model compares and the negative ion threshold value of calculation also carries out corresponding switching in step, for example the user originally selects leisure (motion) mode, and corresponding negative ion concentration interval is 3000/cm and ethanol, when switching to sleep mode, then corresponding negative ion concentration interval is 1300/cm and ethanol.

Specifically, after the concentration judgment model screens out the negative ion concentration range corresponding to the mode identifier, when the concentration data is received, the concentration data is compared with the screened negative ion concentration range.

In one embodiment, as shown in fig. 3, for the four mode identifiers displayed on the user side, including reading, working, leisure, and sleeping modes, the user can select the corresponding negative ion concentration interval by clicking the corresponding mode identifier on the user side; meanwhile, the user side also displays the air quality index, and the change of the air quality index is based on the change of the concentration data. The user can learn the time of anion generator operation and control anion generator's start-up or stop through the user side, and further, the user still can adjust the luminance and the colour temperature of eye-protecting lamp through the user side after selecting the mode sign, and the regulation is given with me in a flexible way.

In one embodiment, after step S41, the following steps are performed:

s411: if the concentration data in the preset time is still smaller than the lower limit value of the negative ion concentration interval, acquiring the current speed-up level of the speed-up instruction;

s412: and increasing the speed increasing level based on the current speed increasing level of the negative ion generator.

In this embodiment, the preset duration is a user-defined duration, and whether the acquired concentration data is within the negative ion concentration interval is analyzed once every other end of the preset duration to trigger whether the function of automatically increasing the speed reduction level is performed;

specifically, when the air replacement degree of the environment where the eye protection lamp is located is large, or the quality of the air obtained through replacement is low, the situation that the concentration data is smaller than the negative ion concentration interval within the preset time length and the difference value between the concentration data and the negative ion concentration interval is still larger than or equal to the standard difference value easily exists, namely, high-quality air cannot be obtained after the negative ion generator is started for a period of time; at this time, the speed-up data is increased, and each time, the speed-up level is increased, for example, the original speed-up level is 20 more negative ions than the original rate in a unit time, and after the speed-up level is increased, the speed-up level is 40 more negative ions than the original rate in a unit time.

And/or after the step S42, executing the following steps:

s422: if the concentration data in the preset time is still larger than the upper limit value of the negative ion concentration interval, acquiring the current speed reduction level of the speed reduction instruction;

s423: and increasing the speed reduction level based on the current speed reduction level of the negative ion generator.

Specifically, when the air quality of the environment where the eye-protection lamp is located is high, the speed reduction command is used for controlling the anion generator to reduce the speed of generating anions, if the difference between the concentration data and the anion concentration interval is not smaller than the standard difference within the preset time, the speed reduction data is increased, and one speed reduction level is increased each time, for example, the original speed reduction level generates 20 anions less than the original speed within unit time, and after the speed reduction level is increased, the speed reduction level generates 40 anions less than the original speed within unit time.

In one embodiment, after step S412, the following steps are performed:

s413: when the speed-up level reaches a preset speed-up upper limit level, if the concentration data in a preset time period is still smaller than a lower limit value of a negative ion concentration interval, generating a prompt signal;

s414: and sending the prompt signal to the user terminal.

Specifically, when the speed-up level reaches the upper limit, that is, the generation rate of the negative ions can not be increased, if the concentration of the negative ions in the ambient air where the eye-protection lamp is located is still smaller than the negative ion concentration interval at this time, it is proved that the replacement degree of the ambient air where the eye-protection lamp is located is large, and the air quality of the replaced air is low, and the user is in the environment, and even if the negative ion generator is started, high-quality air can not be obtained, so that a prompt message is sent to the user side to remind the user, so that the user can know the air quality of the environment to further replace the environment, or improve the environment where the user is located.

In an embodiment, a user wants to move in a room of the user, the eye-protection lamp is turned on for illumination, the user should select a leisure (movement) mode at the moment, the eye-protection lamp and the anion generator are started through an APP interface of a mobile phone of the user, the anion generator identifies the leisure (movement) mode at the moment, the anion concentration interval screened by the concentration judgment model is 2900-3200/cm year, the anion generator continuously outputs anions at the speed of the last one of the anion generators during shutdown, when the anion concentration in the room is 2900/cm year, the concentration data are located in the anion concentration interval, the anion generator is controlled to generate the anions at the current speed by sending a speed locking instruction, the anion generator is controlled to continuously increase the concentration data at the speed, when the concentration data are 3300 cm year, the anion generator is controlled to reduce the anion generation speed by sending a speed reduction instruction, and when the concentration data are located in the anion concentration interval again, the anion locking instruction is sent again to control the anion generator to generate the anions at the current speed. So that stable and high-quality air quality in the room is obtained.

It should be understood that, the sequence numbers of the steps in the foregoing embodiments do not imply an execution sequence, and the execution sequence of each process should be determined by its function and inherent logic, and should not constitute any limitation to the implementation process of the embodiments of the present application.

In an embodiment, an eye-protection lamp control system with an anion purification function is provided, and the eye-protection lamp control system with the anion purification function corresponds to the eye-protection lamp control method with the anion purification function in the above embodiment. As shown in fig. 4, the eye-protection lamp control system with negative ion purification function includes:

the concentration acquisition module is used for detecting and acquiring the concentration of the negative ions in the environment where the eye protection lamp is located in real time when the negative ion generator is started to obtain concentration data;

the model input module is used for inputting the concentration data to a concentration judgment model with a preset negative ion concentration interval in real time, and the air quality is high when the concentration of negative ions in the air is within the negative ion concentration interval;

the comparison calculation module is used for comparing the real-time concentration data with the negative ion concentration interval to obtain a comparison result;

the speed regulating module is used for sending a regulating instruction for controlling the generation rate of the negative ions to the negative ion generator based on the comparison result when the concentration data is not in the negative ion concentration interval so as to enable the concentration data to be in the negative ion concentration interval;

and the speed locking module is used for sending a speed locking instruction to the negative ion generator when the concentration data is positioned in the negative ion concentration interval.

Optionally, the speed regulation module includes:

the speed reduction module is used for sending a speed increasing instruction for increasing the generation speed of the negative ions to the negative ion generator when the concentration data is smaller than the lower limit value of the negative ion concentration interval;

and the speed increasing instruction is used for sending a speed reducing instruction for reducing the negative ion generating rate to the negative ion generator when the concentration data is larger than the upper limit value of the negative ion concentration interval.

Optionally, the method further includes:

the instruction setting module is used for sending an input port for setting a speed-up level and a speed-down level to a user side when receiving a speed setting request sent by the user side;

and the instruction association module is used for associating the speed increasing level with the speed increasing instruction so as to enable the speed of generating negative ions to be increased by one speed increasing level when the negative ion generator receives the speed increasing instruction and associating the speed reducing level with the speed reducing instruction so as to enable the speed of generating the negative ions to be reduced by one speed reducing level when the negative ion generator receives the speed reducing instruction.

Optionally, a plurality of mode identifications are preset to the eye-protecting lamp, and the light brightness and the color temperature that each mode identification corresponds are different, still include:

the mode binding module is used for acquiring a plurality of mode identifications of the eye-protecting lamp and binding each mode identification to a negative ion concentration interval, and the negative ion concentration intervals bound by the mode identifications are different;

the mode sending module is used for sending the mode identifications to the user side;

the mode acquisition module is used for acquiring the mode identifier selected by the user based on the selection instruction when the selection instruction from the user side is received;

the pattern recognition module is used for sending the identification pattern to the concentration judgment model, and the concentration judgment model screens out the negative ion concentration interval bound by the identification model based on the identification model;

and the mode screening module is used for comparing the concentration data received in real time with the negative ion concentration interval bound by the mode identifier selected by the user by the concentration judgment model.

Optionally, the method further includes:

the acceleration level acquisition module is used for acquiring the current acceleration level of the acceleration instruction if the concentration data in the preset time is still less than the lower limit value of the negative ion concentration interval;

the speed-increasing level speed-regulating module is used for increasing a speed-increasing level on the basis of the current speed-increasing level of the negative ion generator;

the deceleration grade acquisition module is used for acquiring the current deceleration grade of the deceleration instruction if the concentration data in the preset time is still greater than the upper limit value of the negative ion concentration interval;

and the speed-reducing level speed-regulating module is used for increasing a speed-reducing level on the basis of the current speed-reducing level of the negative ion generator.

Optionally, the method further includes:

the prompt generation module is used for generating a prompt signal if the concentration data in the preset time is still smaller than the lower limit value of the negative ion concentration interval when the speed increasing level reaches the preset speed increasing upper limit level;

and the prompt sending module is used for sending the prompt signal to the user side.

For specific limitations of the eye-protection lamp control system with the negative ion purification function, reference may be made to the above limitations of the eye-protection lamp control method with the negative ion purification function, and details thereof are not repeated herein. All modules in the eye-protection lamp control system device with the anion purification function can be completely or partially realized through software, hardware and a combination thereof. 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. 5. The computer device includes a processor, a memory, a network interface, and a database 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 concentration data, negative ion concentration intervals corresponding to the four mode identifications, speed increasing levels, speed decreasing levels and standard difference values. 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 realize the eye-protection lamp control method with the anion purification function.

In one embodiment, a computer device is provided, which comprises a memory, a processor and a computer program stored in the memory and capable of running on the processor, wherein the processor executes the computer program to realize an eye protection lamp control method with a negative ion purification function.

In one embodiment, a computer-readable storage medium is provided, on which a computer program is stored, which, when executed by a processor, implements an eye-protection lamp control method with anion purification.

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 may include non-volatile and/or volatile memory, among others. Non-volatile memory can include read-only memory (ROM), programmable ROM (PROM), electrically Programmable ROM (EPROM), electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double Data Rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous Link DRAM (SLDRAM), rambus (Rambus) direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).

It should be clear to those skilled in the art that, for convenience and simplicity of description, the foregoing division of the functional units and modules is only used for illustration, and in practical applications, the above function distribution may be performed by different functional units and modules as needed, that is, the internal structure of the apparatus may be divided into different functional units or modules to perform all or part of the above described functions.

The above-mentioned embodiments are only used to illustrate the technical solutions of the present application, and not to limit the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the spirit and scope of the embodiments of the present application and are intended to be included within the scope of the present application.

Claims (10)

1. The utility model provides a take anion purification performance's eye-protecting lamp control method which characterized in that: the method comprises the following steps:

when the anion generator is started, detecting and acquiring the anion concentration of the environment where the eye protection lamp is located in real time to obtain concentration data;

inputting the concentration data into a concentration judgment model preset with an anion concentration interval in real time, wherein the air quality is high when the concentration of anions in the air is within the anion concentration interval;

comparing the real-time concentration data with the negative ion concentration interval to obtain a comparison result;

based on the comparison result, when the concentration data is not in the negative ion concentration interval, sending an adjusting instruction for controlling the negative ion generation rate to the negative ion generator so as to enable the concentration data to be in the negative ion concentration interval;

when the concentration data is within the negative ion concentration interval, a rate locking instruction is sent to the negative ion generator.

2. The eye-protection lamp control method with the anion purification function according to claim 1, characterized in that: based on the comparison result, when the concentration data is not in the negative ion concentration interval, a step of sending an adjustment instruction for controlling the negative ion generation rate to the negative ion generator includes:

when the concentration data is smaller than the lower limit value of the negative ion concentration interval, sending a speed increasing instruction for increasing the negative ion generating rate to the negative ion generator;

when the concentration data is larger than the upper limit value of the negative ion concentration interval, a deceleration instruction for decelerating the negative ion generation rate is sent to the negative ion generator.

3. The eye-protection lamp control method with the anion purification function according to claim 2, characterized in that: when the anion generator is started, the anion concentration of the environment where the eye protection lamp is located is detected and acquired in real time, and the following steps are executed before the step of acquiring concentration data:

when receiving a speed setting request sent by a user side, sending an input port for setting an acceleration level and a deceleration level to the user side;

when the speed increasing level and the speed reducing level input by the user terminal are received, the speed increasing level is associated with the speed increasing instruction so that the speed of generating negative ions when the negative ion generator receives the speed increasing instruction is increased by one speed increasing level, and the speed reducing level is associated with the speed reducing instruction so that the speed of generating the negative ions when the negative ion generator receives the speed reducing instruction is reduced by one speed reducing level.

4. The eye-protection lamp control method with the anion purification function according to claim 1, characterized in that: a plurality of mode identifications are preset for the eye-protecting lamp, the brightness and the color temperature of the light corresponding to each mode identification are different, when the anion generator is started, the anion concentration of the environment where the eye-protecting lamp is located is detected and acquired in real time, and the following steps are executed before the step of obtaining concentration data:

acquiring a plurality of mode identifiers of the eye-protection lamp, and binding each mode identifier to an anion concentration interval, wherein the anion concentration intervals bound by the mode identifiers are different;

sending a plurality of mode identifiers to a user side;

when a selection instruction from a user side is received, acquiring a mode identifier selected by the user based on the selection instruction;

sending the identification mode to a concentration judgment model, and screening out the negative ion concentration range bound by the identification model by the concentration judgment model based on the identification model;

after the step of inputting the concentration data into the concentration judgment model preset with the negative ion concentration interval in real time, the following steps are also executed:

and the concentration judgment model compares the concentration data received in real time with the negative ion concentration interval bound by the mode identifier selected by the user.

5. The eye-protection lamp control method with the anion purification function according to claim 3, characterized in that: when the concentration data is less than the lower limit value of the negative ion concentration interval, after the step of sending a speed-up instruction for increasing the negative ion generation rate to the negative ion generator, the following steps are executed:

if the concentration data in the preset time is still smaller than the lower limit value of the negative ion concentration interval, acquiring the current speed-up level of the speed-up instruction;

increasing a speed increasing level on the basis of the current speed increasing level of the negative ion generator;

and/or the presence of a gas in the atmosphere,

after the step of sending a deceleration instruction for decelerating the generation rate of negative ions to the negative ion generator when the density data is larger than the upper limit value of the negative ion density zone, the following steps are performed:

if the concentration data in the preset time is still larger than the upper limit value of the negative ion concentration interval, acquiring the current speed reduction level of the speed reduction instruction;

and increasing the speed reduction level based on the current speed reduction level of the anion generator.

6. The eye-protection lamp control method with the anion purification function according to claim 5, characterized in that: after the step of increasing the acquired speed-up level, the following steps are performed:

when the speed-up level reaches a preset speed-up upper limit level, if the concentration data in a preset time period is still smaller than a lower limit value of a negative ion concentration interval, generating a prompt signal;

and sending the prompt signal to the user terminal.

7. The utility model provides a take anion purification performance's eyeshield lamp control system which characterized in that includes:

the concentration acquisition module is used for detecting and acquiring the concentration of the negative ions in the environment where the eye protection lamp is located in real time when the negative ion generator is started to obtain concentration data;

the model input module is used for inputting the concentration data to a concentration judgment model with a preset negative ion concentration interval in real time, and the air quality is high when the concentration of negative ions in the air is within the negative ion concentration interval;

the comparison module is used for comparing the real-time concentration data with the negative ion concentration interval to obtain a comparison result;

the speed regulating module is used for sending a regulating instruction for controlling the generation rate of the negative ions to the negative ion generator based on the comparison result when the concentration data is not in the negative ion concentration interval so as to enable the concentration data to be in the negative ion concentration interval;

and the speed locking module is used for sending a speed locking instruction to the negative ion generator when the concentration data is positioned in the negative ion concentration interval.

8. The eye-protection lamp control system with the anion purification function of claim 7, wherein the speed regulation module comprises:

the speed reduction module is used for sending a speed increasing instruction for increasing the generation speed of the negative ions to the negative ion generator when the concentration data is smaller than the lower limit value of the negative ion concentration interval;

and the speed increasing instruction is used for sending a speed reducing instruction for reducing the negative ion generating rate to the negative ion generator when the concentration data is larger than the upper limit value of the negative ion concentration interval.

9. A computer device comprising a memory, a processor and a computer program stored in the memory and executable on the processor, wherein the processor executes the computer program to implement the steps of the eye-protection lamp control method with anion purification function according to any one of claims 1 to 6.

10. A computer-readable storage medium storing a computer program, wherein the computer program is executed by a processor to implement the steps of the method for controlling an eye-protection lamp with anion purification function according to any one of claims 1 to 6.

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