CN115307255B - 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 negative ion generator is started, detecting and acquiring the concentration of negative ions in the environment where the eye-protecting lamp is positioned 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 that the concentration data is in the negative ion concentration interval; and when the concentration data is in the negative ion concentration interval, sending a rate locking instruction to the negative ion generator. The automatic negative ion generating device has the advantages that the automatic negative ion generating rate adjustment is realized, and the stable and high-quality air quality effect can be achieved in the environment where the eye-protection lamp is located.

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 sum of negatively charged single gas molecules and hydrogen ion groups; at present, the intelligent eye-protection lamp is provided with the negative ion generator, so that the negative ion generator generates negative ions in the starting process of the eye-protection lamp, bacteria in air are adsorbed, the air quality is improved, and the intelligent eye-protection lamp can be greatly helpful to the respiratory system and the nervous system of a human body.

When the user starts the eye-protection lamp, the anion generator starts and generates anions, so that the concentration of anions in the air is increased, and when the anions in the air reach a certain concentration, the air quality is better, but because the air replacement degree of the environment where the eye-protection lamp is positioned and the oxygen consumption of the user are easy to change, the concentration of anions in the air is always changed, so that the air quality of the environment where the eye-protection lamp is positioned is unstable, and the user is inconvenient to monitor and adjust the anion generation rate in real time, so that the environment where the eye-protection lamp is positioned is harder to obtain stable and better air quality.

Disclosure of Invention

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

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

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

when the negative ion generator is started, detecting and acquiring the concentration of negative ions in the environment where the eye-protecting lamp is positioned 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 in the anion concentration interval;

comparing the real-time concentration data with a 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 that the concentration data is in the negative ion concentration interval;

and when the concentration data is in the negative ion concentration interval, sending a rate locking instruction to the negative ion generator.

By adopting the technical scheme, when a user turns on the eye-protection lamp, the negative ion generator is started, generates negative ions at a fixed rate, detects the negative ion concentration of the environment where the eye-protection lamp is positioned in real time, compares the negative ion concentration with a preset concentration interval, and judges whether the air quality is in a high-quality state or not by comparing the negative ion concentration in the air.

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 negative ion concentration interval, then an adjusting instruction is sent to increase the negative ion generation rate so as to improve the concentration of the negative ions in the air; when the replacement degree or oxygen consumption of the ambient air is reduced, an adjusting instruction is sent out to reduce the generation rate of negative ions, when the concentration of the negative ions in the air is in a 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 electric energy can be saved, so that the negative ion generation rate 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 in the negative ion concentration interval, and the environment where the eye protection lamp is located can be conveniently controlled to obtain stable high-quality air.

In a better example, the present application: 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, comprising the following steps:

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

when the concentration data is greater than the upper limit value of the negative ion concentration section, a deceleration instruction for reducing 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 ion generator can be increased by the speed-increasing instruction, so that the number of the negative ions generated in unit time of the negative ion generator is increased, the concentration of the negative ions in the air is increased, the environment where the eye-protection lamp is positioned 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 generation rate of negative ions is reduced by sending out a deceleration instruction until the concentration of the negative ions is positioned in the negative ion concentration interval, and the environment where the eye-protection lamp is positioned can obtain better air quality and simultaneously save the electric energy consumed by the negative ion generator.

In a better example, the present application: when the negative ion generator is started, the negative ion concentration of the environment where the eye-protection lamp is positioned is detected and obtained in real time, and the following steps are executed before the step of obtaining the concentration data:

When a rate setting request sent by a user terminal is received, an input port for setting a speed increasing level and a speed decreasing level is sent to the user terminal;

when the speed increasing level and the speed decreasing level input by the user side 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 decreasing level is associated with the speed decreasing instruction so that the speed of generating negative ions when the negative ion generator receives the speed decreasing instruction is decreased by one speed decreasing level.

By adopting the technical scheme, the speed increasing level and the speed reducing level are respectively used for controlling the speed increasing and the speed reducing level of the negative ions generated by the negative ion generator, the speed increasing level and the speed reducing level are set by user definition, and if the user has a larger requirement on the change of the negative ion generating speed, the larger speed increasing level and the speed reducing level can be set so as to accelerate the change of the concentration of the negative ions of the air flushing; if the user has a larger requirement on the accuracy of the concentration of the negative ions in the air, a smaller accelerating level and a lower decelerating 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 better example, the present application: the eye-protection lamp is preset with a plurality of mode identifications, the brightness and the color temperature of the lamp light corresponding to each mode identification are different, when the negative ion generator is started, the negative ion concentration of the environment where the eye-protection lamp is positioned is detected and obtained 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, binding each mode identifier with an anion concentration interval, wherein the anion concentration intervals bound by the mode identifiers are different;

transmitting 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 the negative ion concentration interval bound by the identification model by the concentration judgment model based on the identification model.

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

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 brightness and the color temperature of the light of the eye-protection lamp in different modes are different, so that different eye use conditions of a user can be met, for example, when the user performs leisure sports or sleeps, the brightness and the color temperature of the light of the two corresponding eye-protection lamps are different, for example, when the user sleeps, the brightness of the eye-protection lamp is low, the color temperature is warm, the brightness is relatively high during leisure sports, and the color temperature is cold; 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 use condition and behavior of a user, for example, when the user selects a mode identification of leisure sports, the action behavior of the user with the possibility of sports or large oxygen consumption is judged, and the matched anion concentration interval is higher than the normal office and reading modes at the moment, so that the user can inhale more high-quality air; when the user selects the sleep mode mark, the relative oxygen consumption of the user is low, and the relative anion concentration interval is lower than the office and reading modes, so that the user is guaranteed 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 anion concentration interval is screened out based on the selected mode identification, and the comparison and calculation are carried out on the concentration interval and the received concentration data, so that the function of anion concentration adjustment according to different mode identifications is realized.

In a better example, 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 period is still smaller than the lower limit value of the negative ion concentration interval, acquiring the current speed increasing level of the speed increasing instruction;

the speed increasing level is increased based on the current speed increasing level of the negative ion generator;

and/or the number of the groups of groups,

when the concentration data is greater than the upper limit value of the negative ion concentration section, after the step of sending a deceleration instruction for reducing the negative ion generation rate to the negative ion generator, the steps of:

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

and the speed reducing level is further increased based on the current speed reducing level of the negative ion generator.

By adopting the technical scheme, when the negative ion generator receives the speed increasing instruction and the concentration data is still smaller than the lower limit value of the negative ion concentration interval in the preset time, the negative ion generator is started for a period of time, and the high-quality air quality cannot be obtained due to the fact that the air replacement degree is large or the oxygen consumption of a user is large, and at the moment, the speed of generating the negative ions is increased by increasing the speed increasing level, so that the environment where the eye protection lamp is located can obtain the high-quality air.

When the negative ion generator receives the speed reducing instruction and the concentration data is still larger than the upper limit value of the negative ion concentration interval, the negative ion generator proves that the concentration of the negative ions in the air is sufficient at the moment, and the generation rate of the negative ions can be reduced so that the negative eye-protection lamp is more energy-saving.

The setting that can overlap automatically after preset time of the level of slowing down, the level of speeding up for the environment that eye-protection lamp is located can obtain stable comparatively high-quality air quality more fast.

In a better example, the present application: after the step of increasing the acquired acceleration level, the following steps are performed:

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

And sending the prompt signal to the user side.

Through adopting above-mentioned technical scheme, when the speed-up level reached the upper limit, when can't promote the production rate of anion again promptly, if the anion concentration in the ambient air that eye-protection lamp was located this moment still is less than anion concentration interval, then prove that the ambient air that eye-protection lamp was located is displaced the degree greatly, and the air quality of the air that just displaces 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 in order to further change the environment, or improve the environment that is located.

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

an eye-protection lamp control system with an anion purification function, comprising:

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 positioned 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 into a concentration judgment model preset with an anion concentration interval in real time, and the air quality is high when the concentration of anions in the air is in the anion 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 regulation module is used for sending a regulation instruction for controlling the negative ion generation rate to the negative ion generator when the concentration data is not in the negative ion concentration interval based on the comparison result, so that the concentration data is 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.

By adopting the technical scheme, when a user turns on the eye-protection lamp, the negative ion generator is started, generates negative ions at a fixed rate, detects the negative ion concentration of the environment where the eye-protection lamp is positioned in real time, compares the negative ion concentration with a preset concentration interval, and judges whether the air quality is in a high-quality state or not by comparing the negative ion concentration in the air.

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 negative ion concentration interval, then an adjusting instruction is sent to increase the negative ion generation rate so as to improve the concentration of the negative ions in the air; when the replacement degree or oxygen consumption of the ambient air is reduced, an adjusting instruction is sent out to reduce the generation rate of negative ions, when the concentration of the negative ions in the air is in a 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 electric energy can be saved, so that the negative ion generation rate 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 in the negative ion concentration interval, and the environment where the eye protection lamp is located can be conveniently controlled to obtain stable high-quality air.

Optionally, the speed regulation module includes:

the speed reducing module is used for sending a speed increasing instruction for increasing the negative ion generation rate 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 increasing instruction for transmitting a speed decreasing instruction for decreasing the negative ion generation rate to the negative ion generator when the concentration data is greater than the upper limit value of the negative ion concentration section.

The third object of the present application is achieved by the following technical solutions:

a computer device comprising a memory, a processor and a computer program stored in the memory and executable on the processor, the processor implementing the steps of the above eye-protection lamp control method with anion purification function when executing the computer program.

The fourth object 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-described 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 generation rate is automatically regulated through the regulation instruction, so that the stability regulation of the negative ion concentration in the air is realized, namely the negative ion concentration in the environment where the eye-protection lamp is positioned can be automatically controlled in a negative ion concentration interval, and the environment where the eye-protection lamp is positioned 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 generation rate of negative ions is reduced by sending out a deceleration instruction until the concentration of the negative ions is positioned in the negative ion concentration interval, and the environment where the eye-protection lamp is positioned can obtain better air quality and simultaneously save the electric energy consumed by the negative ion generator;

3. if a user has a larger demand for the change of the negative ion generation rate, a larger acceleration level and a deceleration level can be set to accelerate the change of the air anion concentration; if the user has a larger requirement on the accuracy of the concentration of the negative ions in the air, a smaller acceleration level and a smaller deceleration 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 of an embodiment of an eye-protection lamp control method with anion cleaning function;

FIG. 2 is a flowchart of another implementation of an embodiment of an eye-protection lamp control method with anion cleaning function of the present application;

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

FIG. 4 is a schematic block diagram of an eye-protection lamp control system with anion purification function of 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 in conjunction with figures 1-5.

In the embodiment, as shown in fig. 1, the application discloses an eye-protection lamp control method with an anion purification function, which specifically includes the following steps:

s10: when the negative ion generator is started, detecting and acquiring the concentration of negative ions in the environment where the eye-protecting lamp is positioned in real time to obtain concentration data;

in this embodiment, when the negative ion generator is started, negative ions are generated and output to the air in the environment where the eye-protection lamp is located, the negative ion concentration detection is performed through the negative oxygen ion sensor, and the analog signal obtained through detection is converted into a digital signal, so that concentration data is obtained, and the concentration data is the number of negative ions in a unit cube, namely, one/cm.

Specifically, when the eye-protection lamp is started, the negative ion generator is started, and the negative oxygen ion sensor configured by the eye-protection lamp starts to detect the concentration of negative ions in the ambient air where the eye-protection lamp is positioned, 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 in the anion concentration interval;

in this embodiment, when the negative ion concentration interval represents that the air quality is high, the concentration judgment model is used to judge whether the received concentration data falls within the negative ion concentration interval.

Specifically, concentration data obtained 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, wherein the negative ion concentration interval is a manually preset concentration interval value, the manually preset concentration interval value 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 a 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 section, the concentration data is located in the negative ion concentration section, and the concentration data is larger than the upper limit value of the negative ion concentration section.

Specifically, the concentration judgment model receives and sequentially judges whether the concentration data is positioned in the negative ion concentration interval in real time, 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 that the concentration data is in the negative ion concentration interval;

in this embodiment, the adjustment instruction is used to adjust the rate at which the negative ions are generated by the negative ion generator, i.e., to adjust the power of the negative ion generator.

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

another case is: the concentration data is larger than the maximum value of the negative ion concentration interval, when the replacement degree or oxygen consumption of the ambient air is reduced, an adjusting instruction is sent out 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, and 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 in the negative ion concentration interval, sending a rate locking instruction to the negative ion generator.

In this embodiment, when the negative ion generator receives the rate locking command, the concentration data is located in the negative ion concentration interval, and the negative ion generator operates at the rate when the rate locking command is received, for example, 500 negative ions are generated in a unit time at the rate when the concentration data is 1300 pieces/cm, and when the concentration interval of the negative ions is 1200-1500 pieces/cm, the concentration data is located in the negative ion concentration interval, and at this time, the negative ion generator operates at the power of 500 generated in a unit time.

Specifically, when the concentration data is located in the negative ion concentration interval, the air quality is high, the power of the negative ion generator is not required to be further reduced, and then a rate locking instruction is sent out to control the negative ion generator to operate and output negative ions with the current power, namely, the concentration of negative ions in the air can be maintained, so that the air is maintained in a high-quality state, and meanwhile, the negative ion generator is 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-up instruction for increasing the negative ion generation rate to the negative ion generator;

S42: when the concentration data is greater than the upper limit value of the negative ion concentration section, a deceleration instruction for reducing the negative ion generation rate is sent to the negative ion generator.

In this embodiment, the acceleration instruction is used to control the negative ion generator to increase the number of negative ions output in a unit time, that is, to increase the power of the negative ion generator. The speed reducing instruction is used for reducing the speed of generating negative ions by the negative ion generator, namely reducing the power of the negative ion generator, so that the number of the negative ions output to the air by the negative ion generator in unit time is reduced.

Specifically, under the condition that the negative ion generator is just started or under the condition that the air replacement degree is high and the oxygen consumption of users in the environment is high, the condition that concentration data is smaller than the lower limit value of the negative ion concentration interval is easy to occur, namely the air quality is lower, at the moment, the generation rate of the negative ion generator is accelerated by sending a speed-up instruction to the negative ion generator, so that the number of negative ions in the air is increased, and the condition that the negative ion generator is just started or under the condition that the air replacement degree is high and the oxygen consumption of users in the environment is high can be promoted, so that the air quality of the environment where the eye protection lamp is located reaches a higher quality state.

When the environment where the eye protection lamp is located is started for a period of time, and the replacement degree of the environment air where the eye protection lamp is located is small or the oxygen consumption of a user is reduced, the concentration data is larger than the upper limit value of the negative ion concentration interval, then the generation rate of negative ions is reduced by sending a speed reduction instruction, and the speed reduction is stopped when the concentration data is located in the negative ion concentration interval, so that the air quality of the environment where the eye protection lamp is located is in a high-quality state, and the energy consumption of the negative ion generator is reduced.

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

s101: when a rate setting request sent by a user terminal is received, an input port for setting a speed increasing level and a speed decreasing level is sent to the user terminal;

s102: when the speed increasing level and the speed decreasing level input by the user side 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 decreasing level is associated with the speed decreasing instruction so that the speed of generating negative ions when the negative ion generator receives the speed decreasing instruction is decreased by one speed decreasing level.

In this embodiment, the user terminal is a mobile terminal or a PC terminal that is used to perform wireless communication connection with the eye-protection lamp and the anion generator, so as to control the eye-protection lamp and the anion generator, and the mobile terminal binds information of the user. The input port is a text box used for filling in the speed increasing level and the speed reducing level, the speed increasing level and the speed reducing level are both provided with an upper limit interval and a lower limit interval, the speed increasing level and the speed reducing level are only regulated in the upper limit interval and the lower limit interval, for example, the speed increasing level comprises a first-stage speed increasing speed, a second-stage speed increasing speed, a third-stage speed increasing speed and the like, the speed increased by the second-stage speed increasing speed is twice that of the first-stage speed increasing speed, the first-stage speed increasing speed enables the negative ion generator to generate 20 negative ions in unit time, and the second-stage speed increasing speed enables the negative ion generator to generate 40 negative ions in unit time.

Specifically, before the negative ion generator is started, the user side can set the change amplitude of the negative ion generator generating negative ion rate each time, namely, set the power change amplitude of the negative ion generator, input the speed increasing level and the speed decreasing level through the input port, correlate the speed increasing level with the speed increasing instruction, and correlate the speed decreasing level with the speed decreasing instruction.

Further, when the negative ion generator receives the speed increasing instruction, the speed of generating negative ions is increased by one speed increasing level, for example, the negative ion generator originally generates 500 negative ions per unit time, and after receiving the speed increasing instruction, 520 negative ions per unit time are generated, and the speed increasing level is that 20 negative ions are generated in more than one unit time. The rate at which negative ions are generated by the negative ion generator when receiving the speed command is reduced by one speed-reducing level.

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

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

S12: transmitting 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: the identification mode is sent to a concentration judgment model, and the concentration judgment model screens out a negative ion concentration interval bound by the identification model based on the identification model;

in this embodiment, the plurality of mode identifiers include four modes of sleep, reading, office, leisure (sports), and 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 sleep, the light brightness and the color temperature are warmer; when the user is in motion, brighter light brightness and colder color temperature are needed to fully illuminate, and the light brightness should be proper to protect 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 such as office, reading and sleeping under normal conditions, 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 anion concentration interval is higher than the sleep mode and lower than the leisure (sports) mode, so that the refreshing effect is achieved on the user, and the refreshing effect is beneficial to improving the effort of the user in the office and reading process.

When the user selects the sleep mode mark, 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 guaranteed to breathe high-quality air and the effect of saving electric energy is achieved.

Specifically, four mode identifiers of the eye-protection lamp are obtained, and the four mode identifiers are respectively bound with negative ion concentration intervals with different numerical values, wherein the numerical values of the negative ion concentration intervals corresponding to the four mode identifiers are arranged from large to small as follows: leisure (sports) mode, office mode, reading mode, sleep mode.

And further transmitting the four mode identifiers to a user side, acquiring the mode identifier selected by the user, and transmitting the mode identifier to a concentration judgment model, wherein the concentration judgment model screens out the bound anion concentration interval based on the mode identifier so as to compare the bound anion concentration interval with the received concentration data.

After step S20, the following steps are also performed:

S21: 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 identifier, the concentration determination model performs comparison and the calculated anion threshold value also perform corresponding switching synchronously, for example, the user originally selects the leisure (sports) mode, the corresponding anion concentration interval is 3000 anions/cm, and when the user switches to the sleep mode, the corresponding anion concentration interval is 1300 anions/cm.

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

In one embodiment, as shown in fig. 3, for four mode identifiers displayed on the user side, including reading, office, leisure and sleep modes, the user can select the corresponding anion concentration interval by clicking the corresponding mode identifier on the user side; meanwhile, the user side also displays an air quality index, and the change of the air quality index is based on the change of the concentration data. The user can know the operation time of the negative ion generator and control the starting or stopping of the negative ion generator through the user terminal, and further, after the user selects the mode identification, the brightness and the color temperature of the eye-protecting lamp can be regulated through the user terminal, and the regulation is flexible.

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

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

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

In this embodiment, the preset duration is a duration customized by a user, and whether the obtained concentration data is in the negative ion concentration interval is analyzed once every one end preset duration so as to trigger a function of automatically increasing the deceleration level;

specifically, when the air replacement degree of the environment where the eye-protection lamp is located is large, or the air quality obtained by replacement is low, concentration data in a preset time period is easy to exist and is smaller than an anion concentration interval, and the difference value between the concentration data and the anion concentration interval is still larger than or equal to a standard difference value, namely high-quality air cannot be obtained after the anion generator is started for a certain time; at this time, the acceleration data is increased, and each time, an acceleration level is increased, for example, the original acceleration level is that 20 anions are generated more than the original rate in unit time, and after the acceleration level is increased, the acceleration level is that 40 anions are generated more than the original rate in unit time.

And/or, after step S42, the following steps are performed:

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

s423: and the speed reducing level is further increased based on the current speed reducing level of the negative ion generator.

Specifically, when the air quality of the environment where the eye protection lamp is located is high-quality, the negative ion generator is controlled to reduce the rate of generating negative ions through the speed reducing instruction, if the difference value between the concentration data and the negative ion concentration interval is not smaller than the standard difference value in the preset time, the speed reducing data is increased, and one speed reducing level is increased each time, for example, 20 negative ions are generated in the unit time at a lower speed than the original speed, and after the speed reducing level is increased, 40 negative ions are generated in the unit time at a lower speed than the original speed.

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 the preset time period is still smaller than the lower limit value of the negative ion concentration interval, a prompt signal is generated;

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

Specifically, when the acceleration level reaches the upper limit, that is, when the generation rate of negative ions cannot be increased any more, if the concentration of 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, the air quality of the replaced air is low, and the user is in the environment, even if the negative ion generator is started, the user cannot obtain high-quality air, so that prompt information 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 the environment is improved.

In an embodiment, a user wants to move in a room in the home, starts an eye protection lamp to illuminate, at the moment, the user should select a leisure (movement) mode, starts the eye protection lamp and an anion generator through an APP interface of a mobile phone of the user, at the moment, the anion generator recognizes the leisure (movement) mode, a concentration range of anions screened by a concentration judgment model is 2900-3200/cm, more than one of the anion generators continuously outputs anions at a shutdown rate, when the concentration data is detected to be in the concentration range of anions at 2900/cm, a rate locking instruction is sent to control the anion generator to generate anions at a current rate, the concentration data is continuously increased at the current rate, when the concentration data is 3300 cm, a speed reducing instruction is sent to control the anion generator to reduce the anion generation rate, and when the concentration data is again in the concentration range of anions, a rate locking instruction is sent again to control the anion generator to generate anions at the current rate. So that a stable and better air quality is obtained in the room.

It should be understood that the sequence number of each step in the foregoing embodiment does not mean that the execution sequence of each process should be determined by the function and the internal logic of each process, and should not limit the implementation process of the embodiment of the present application in any way.

In one embodiment, an eye-protecting lamp control system with an anion purification function is provided, which corresponds to the eye-protecting lamp control method with an anion purification function in the above embodiment. As shown in fig. 4, the eye-protection lamp control system with the 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 positioned 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 into a concentration judgment model preset with an anion concentration interval in real time, and the air quality is high when the concentration of anions in the air is in the anion 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 regulation module is used for sending a regulation instruction for controlling the negative ion generation rate to the negative ion generator when the concentration data is not in the negative ion concentration interval based on the comparison result, so that the concentration data is 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 reducing module is used for sending a speed increasing instruction for increasing the negative ion generation rate 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 increasing instruction for transmitting a speed decreasing instruction for decreasing the negative ion generation rate to the negative ion generator when the concentration data is greater than the upper limit value of the negative ion concentration section.

Optionally, the method further comprises:

the instruction setting module is used for sending an input port for setting the speed increasing level and the speed decreasing level to the 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 when receiving the speed increasing level and the speed decreasing level input by the user side, 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 associating the speed decreasing level with the speed decreasing instruction, so that the speed of generating negative ions when the negative ion generator receives the speed decreasing instruction is reduced by one speed decreasing level.

Optionally, the eye-protection lamp is preset with a plurality of mode marks, and the light brightness and the colour temperature that every mode mark corresponds are different, still include:

the mode binding module is used for acquiring a plurality of mode identifiers of the eye-protection lamp, binding each mode identifier with an anion concentration interval, and enabling the anion concentration intervals bound by the mode identifiers to be different;

The mode sending module is used for sending a plurality of mode identifiers to the user side;

the mode acquisition module is used for acquiring a mode identifier selected by a user based on a 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 judging model.

Optionally, the method further comprises:

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

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

the speed-down level acquisition module is used for acquiring the current speed-down level of the speed-down instruction if the concentration data in the preset time period is still larger than the upper limit value of the negative ion concentration interval;

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

Optionally, the method further comprises:

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

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

The specific limitation concerning the eye-protecting lamp control system with the negative ion purification function can be referred to as the limitation concerning the eye-protecting lamp control method with the negative ion purification function hereinabove, and the detailed description thereof will be omitted. The modules in the eye-protection lamp control system device with the anion purification function can be all or partially realized by software, hardware and a combination thereof. The above modules may be embedded in hardware or may be independent of a processor in the computer device, or may be stored in software in a memory in the computer device, so that the processor may call and execute operations corresponding to the above 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 includes a non-volatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, computer programs, and a database. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The database of the computer equipment is used for storing concentration data, anion concentration intervals corresponding to the four mode identifiers, acceleration level, deceleration level and standard deviation value. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program, when executed by a processor, implements a method for controlling an eye-protection lamp with an anion purification function.

In one embodiment, a computer device is provided that includes a memory, a processor, and a computer program stored on the memory and executable on the processor, the processor implementing a method for controlling an eye-protecting lamp with an anion cleaning function when executing the computer program.

In one embodiment, a computer readable storage medium having a computer program stored thereon, the computer program when executed by a processor implementing a method of controlling an eye-protecting lamp with a negative ion purification function is provided.

Those skilled in the art will appreciate that implementing all or part of the above described methods may be accomplished by way of a computer program stored on a non-transitory computer readable storage medium, which when executed, may comprise the steps of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in the various embodiments provided herein may include non-volatile and/or volatile memory. The nonvolatile 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), memory bus direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM), among others.

It will be apparent to those skilled in the art that, for convenience and brevity of description, only the above-described division of the functional units and modules is illustrated, and in practical application, the above-described functional distribution may be performed by different functional units and modules according to needs, i.e. the internal structure of the apparatus is divided into different functional units or modules to perform all or part of the above-described functions.

The above embodiments are only for illustrating the technical solution of the present application, and are not limiting; 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 scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present application, and are intended to be included in the scope of the present application.

Claims (7)

1. An eye-protection lamp control method with an anion purification function is characterized in that: the eye-protection lamp is preset with a plurality of mode identifications, and the brightness and the color temperature of the lamp light corresponding to each mode identification are different, and the method comprises the following steps:

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

transmitting 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;

the mode identification is sent to a concentration judgment model, and the concentration judgment model screens out a negative ion concentration interval bound by the mode identification based on the identification model;

when the negative ion generator is started, detecting and acquiring the concentration of negative ions in the environment where the eye-protecting lamp is positioned 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 in the anion concentration interval;

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;

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

based on the comparison result, when the concentration data is not within the negative ion concentration interval, sending an adjustment instruction for controlling the negative ion generation rate to the negative ion generator so that the concentration data is within the negative ion concentration interval, comprising:

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

when the concentration data is larger than the upper limit value of the negative ion concentration interval, a speed reducing instruction for reducing the negative ion generation rate is sent to the negative ion generator;

and when the concentration data is in the negative ion concentration interval, sending a rate locking instruction to the negative ion generator.

2. The method for controlling an eye-protecting lamp with an anion purifying function according to claim 1, wherein: when the negative ion generator is started, the negative ion concentration of the environment where the eye-protection lamp is positioned is detected and obtained in real time, and the following steps are executed before the step of obtaining the concentration data:

when a rate setting request sent by a user terminal is received, an input port for setting a speed increasing level and a speed decreasing level is sent to the user terminal;

when the speed increasing level and the speed decreasing level input by the user side 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 decreasing level is associated with the speed decreasing instruction so that the speed of generating negative ions when the negative ion generator receives the speed decreasing instruction is decreased by one speed decreasing level.

3. The eye-protection lamp control method with the negative ion purification function according to claim 2, wherein the method comprises the following steps: 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 performed:

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

the speed increasing level is increased based on the current speed increasing level of the negative ion generator;

and/or the number of the groups of groups,

when the concentration data is greater than the upper limit value of the negative ion concentration section, after the step of sending a deceleration instruction for reducing the negative ion generation rate to the negative ion generator, the steps of:

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

and the speed reducing level is further increased based on the current speed reducing level of the negative ion generator.

4. The method for controlling an eye-protecting lamp with an anion purification function according to claim 3, wherein: after the step of increasing the acquired acceleration level, the following steps are performed:

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

and sending the prompt signal to the user side.

5. An eye-protection lamp control system with an anion purification function, which is characterized in that the eye-protection lamp is preset with a plurality of mode marks, and the brightness and the color temperature of the lamp light corresponding to each mode mark are different, comprising:

the mode binding module is used for acquiring a plurality of mode identifiers of the eye-protection lamp, binding each mode identifier with an anion concentration interval, and enabling the anion concentration intervals bound by the mode identifiers to be different;

the mode sending module is used for sending a plurality of mode identifiers to the user side;

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

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

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 positioned 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 into a concentration judgment model preset with an anion concentration interval in real time, and the air quality is high when the concentration of anions in the air is in the anion concentration interval;

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 judging model;

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 regulation module is used for sending out a regulating instruction for controlling the negative ion generation rate to the negative ion generator when the concentration data is not in the negative ion concentration interval based on the comparison result so that the concentration data is in the negative ion concentration interval, and the speed regulation module comprises:

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

a speed increasing instruction for transmitting a speed decreasing instruction for decreasing the negative ion generation rate to the negative ion generator when the concentration data is greater than the upper limit value of 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.

6. A computer device comprising a memory, a processor and a computer program stored in the memory and executable on the processor, characterized in that the processor, when executing the computer program, realizes the steps of the eye-protection lamp control method with negative ion purification function as claimed in any one of claims 1 to 4.

7. A computer-readable storage medium storing a computer program, wherein the computer program when executed by a processor realizes the steps of the eye-protection lamp control method with an anion cleaning function as set forth in any one of claims 1 to 4.

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