CN117704588A - Environment sensing regulation and control equipment, humidification control method thereof, corresponding device and product - Google Patents

Abstract

The application relates to an environment induction regulation and control device, a humidification control method thereof, a corresponding device and a product, wherein the method comprises the following steps: acquiring sensing data of timing detection of a predetermined target humidity and a temperature and humidity sensor; based on the target humidity, determining a humidifying progress corresponding to the ambient humidity carried by the sensing data of the temperature and humidity sensor; and adjusting the working gear of the atomizing device according to an associated regulation strategy reflecting the corresponding relation among the ambient temperature, the humidification progress and the working gear, and adjusting the light effect display state displayed by the atmosphere lamp to reflect the humidification progress. According to the humidifier, the original functions of the humidifier and the original functions of the atmosphere lamp are organically integrated through the humidification progress, so that new environment induction regulation and control equipment is formed, human-computer interaction experience is optimized, and product upgrading of the humidifier and the atmosphere lamp is achieved.

Description

Environment sensing regulation and control equipment, humidification control method thereof, corresponding device and product

Technical Field

The application relates to the field of indoor electrical appliances, in particular to environment induction regulation and control equipment, a humidification control method thereof, a corresponding device and a corresponding product.

Background

In modern life, mood lamps and humidifiers are common household devices. The humidifier generally humidifies the indoor space according to preset target humidity, the high frequency is applied to night scenes, and the atmosphere lamp can play a role in decoration in the night scenes, so that the two use scenes basically coincide, and the effect of one object with multiple purposes can be achieved by arranging the atmosphere lamp in the humidifier.

However, simply integrate humidifier and atmosphere lamp, make its each time apply its job, can cause some inconvenience and waste of resource in fact, therefore, how to organically integrate the function of humidifier and atmosphere lamp, realize the product upgrading in order to promote user experience, need to make corresponding exploration.

Disclosure of Invention

The application aims to provide an environment induction regulation and control device, a humidification control method thereof, a corresponding device and a corresponding product.

According to one aspect of the present application, there is provided a humidification control method, including:

acquiring sensing data of timing detection of a predetermined target humidity and a temperature and humidity sensor;

based on the target humidity, determining a humidifying progress corresponding to the ambient humidity carried by the sensing data of the temperature and humidity sensor;

And adjusting the working gear of the atomizing device according to an associated regulation strategy reflecting the corresponding relation among the ambient temperature, the humidification progress and the working gear, and adjusting the light effect display state displayed by the atmosphere lamp to reflect the humidification progress.

According to another aspect of the present application, there is provided a humidification control device including:

the initial processing module is used for acquiring preset target humidity and sensing data detected by the temperature and humidity sensor at fixed time;

the progress determining module is used for determining the humidification progress corresponding to the ambient humidity carried by the sensing data of the temperature and humidity sensor based on the target humidity;

the progress response module is used for adjusting the working gear of the atomizing device according to an associated regulation strategy reflecting the corresponding relation among the ambient temperature, the humidification progress and the working gear, and adjusting the light effect display state displayed by the atmosphere lamp to enable the humidification progress to be reflected.

According to another aspect of the application, an environmental sensing regulation and control device is provided, which comprises a control unit, a temperature and humidity sensor, an atmosphere lamp and an atomization device, wherein the control unit is used for executing the steps in the humidification control method.

According to another aspect of the present application, there is provided a computer program product comprising computer programs/instructions which, when executed by a processor, perform the steps comprised by the humidification control method.

Compared with the prior art, the method and the device have the advantages that on the basis of determining the target humidity, the temperature and humidity sensor is utilized to continuously detect the obtained sensing data, the humidification progress of the sensing data relative to the target humidity is determined according to the environmental humidity in the sensing data, the working gear of the atomizing device is determined according to the combination of the environmental temperature and the humidification progress so as to timely adjust the mist output required by the environmental humidification, the lamp effect display state of the atmosphere lamp is adjusted according to the humidification progress so as to reflect the humidification progress, the original functions of the humidifier and the original functions of the atmosphere lamp are organically integrated through the humidification progress, a new environment sensing regulation and control device is formed, the man-machine interaction experience is optimized, and the product upgrading of the humidifier and the atmosphere lamp is realized.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of an electrical structure of an environmental sensing control device according to an embodiment of the present application;

Fig. 2 is a schematic flow chart of a humidification control method according to an embodiment of the present application;

FIG. 3 is a flow chart illustrating a method for adjusting a light effect display status based on a brightness ratio according to an embodiment of the present application;

FIG. 4 is a flowchart illustrating a method for adjusting a light effect display status based on a color value according to an embodiment of the present application;

fig. 5 is a schematic flow chart of controlling the operation of the atomizing device according to the humidification schedule and the ambient temperature in the embodiment of the present application;

FIG. 6 is a schematic flow chart of controlling the operation of the atomizing device according to the geographic location information in the embodiment of the present application;

fig. 7 is a schematic structural diagram of a humidification control device in an embodiment of the present application;

fig. 8 is a schematic structural diagram of a computer device in an embodiment of the present application.

Detailed Description

An exemplary environment sensing regulation and control device is provided, and the circuit principle of the environment sensing regulation and control device is shown in fig. 1. The environment sensing regulation and control equipment comprises a control unit, a temperature and humidity sensor, an atmosphere lamp and an atomization device. In some embodiments, a control panel may also be provided, on which a display screen may also be integrated. The control unit is realized mainly by a control chip, which can carry the communication components if necessary, or in which the communication components are arranged independently.

The control chip typically includes a central processor and a memory, which are used to store and execute program instructions, respectively, to implement the corresponding functions. The control Chip can be realized by various embedded chips, such as a Chip of a self-communication module, such as a Bluetooth SoC (System on Chip), a WiFi SoC and the like; alternatively, other types of control chips may be used, such as various types of chips such as MCU (Micro Controller Unit, microcontroller), DSP (Digital Signal Processing ), and the like. Considering the case where the control chip is a control chip adapted to process digital signal input and the signals provided by the temperature and humidity sensor are analog signals, such a chip may be provided with a corresponding analog-to-digital converter (a/D) to convert the analog signals of the temperature and humidity sensor into digital signals. Of course, some control chips, such as MCUs, typically incorporate analog-to-digital converters without the need for separate provision of analog-to-digital converters.

The temperature and humidity sensor takes a temperature and humidity integrated probe as a temperature measuring element to collect temperature and humidity signals, and the temperature and humidity signals are converted into current signals or voltage signals which are in linear relation with the temperature and the humidity after being processed by circuits such as voltage stabilizing filtering, operational amplification, nonlinear correction, V/I conversion, constant current and reverse protection and the like, and can also be directly output through interfaces such as 485 or 232 and the like. The temperature and humidity sensor detects corresponding basic data of the corresponding ambient humidity and the corresponding ambient temperature through a humidity sensitive element and a temperature sensitive element to form sensing data, and the sensing data is provided for the control unit to determine the corresponding ambient humidity and the corresponding ambient temperature.

The atomizing device is used for atomizing liquid contained in a water tank of the environment-sensing regulation and control equipment, and two types are commonly used, one type is used for atomizing liquid by an ultrasonic oscillation principle and generating mist by beating an immersion part, and the other type is used for atomizing the liquid by means of a negative pressure generated by an air pump after the liquid is led into an atomizing core to collide with gas. The atomizing device can be controlled by the control unit to work in different working gears, and each working gear corresponds to different working powers and different mist output per unit time, so that humidifying effects of different degrees are realized. The control chip can adjust the working gear of the atomizing device so as to realize effective control of the mist output in unit time.

An atmosphere lamp typically comprises a plurality of beads, each bead typically comprising light emitting elements, which may be light emitting diodes, corresponding to respective primary colors. A single control chip can be arranged in the atmosphere lamp to carry out centralized control on each lamp bead, and a single control chip can also be arranged for each lamp bead to carry out control. The control unit can send light control data to the atmosphere lamp, and a control chip in the atmosphere lamp controls each lamp bead to emit light according to the light control data so as to present a corresponding light effect display state. Generally, the light control data includes control data corresponding to each bead in the atmosphere lamp, and for each bead, the corresponding control data is adopted to generate a corresponding light control signal to control the corresponding light emitting element to emit corresponding color light.

In some embodiments, the environmental induction regulation device may further be provided with a power module, where the power module is configured to supply power to the complete machine, and is responsible for converting the mains supply into direct current through a corresponding power adapting circuit, providing a constant voltage to the temperature and humidity sensor, providing a working current to the control unit, supplying power to the atmosphere lamp, providing a working power to the air pump of the atomizing device, and so on.

The display screen can be used for displaying various control information so as to be matched with keys in the control panel and support the realization of man-machine interaction functions. For example, the display screen may be used to display any data of the current ambient temperature, the current ambient humidity, the target humidity, the humidification progress, etc., or display various data inputted by the user during the user configuration operation, etc. The control panel typically provides one or more keys for performing control and setup operations, etc., on the environmental-sensing regulatory device. In some embodiments, the control panel and the display screen may be integrated into the same touch display screen.

The communication component may be used for communicating with an external device, for example, may communicate with a personal computer or various terminal devices such as a smart phone, so that after a user issues various configuration instructions through the terminal device thereof, the control chip of the control unit may receive the configuration instructions through the communication component to complete the basic configuration.

According to the product structure and the working principle of the environment-sensing regulation and control equipment, the humidification control method can be realized as a computer program product, and the humidification control method is stored in a memory of a control chip in a control unit of the environment-sensing regulation and control equipment, and a central processing unit of the control chip is called from the memory and then runs, so that corresponding functions are realized.

Referring to fig. 2, in one embodiment, the humidification control method of the present application is executed by a control chip of the humidifier functioning as a control unit, and includes:

step S5100, acquiring sensing data of timing detection of a predetermined target humidity and a temperature and humidity sensor;

the environmental induction regulation and control equipment can be realized by additionally arranging the atmosphere lamp controlled by the control unit of the humidifier on the basis of the traditional humidifier. The environment sensing regulation and control equipment can preset a target humidity, the target humidity can be automatically generated by the control unit according to preset business logic, and the target humidity can be manually set by a user through the control panel, and when humidification work needs to be started, the target humidity is correspondingly called.

On the other hand, in order to control the operation of the environmental sensing and controlling device according to the environmental temperature and the environmental humidity, sensing data detected by the temperature and humidity sensor in the environmental sensing and controlling device is also required to be acquired.

According to the temperature and humidity sensor, the sensing data are generated at certain intervals according to the preset timing, the sensing data comprise resistance data corresponding to the thermistor and the humidity resistor, and the control unit can determine corresponding environment temperature and environment humidity according to the resistance data, so that the sensing data are equivalent to the fact that the corresponding environment temperature and environment humidity are carried. The timing of sensing data by the temperature and humidity sensor is generally set to any value between 4 and 10 seconds, and corresponding time slots are set according to the needs. And when each time slot is finished, the temperature and humidity sensor submits corresponding sensing data, and the control unit can determine the ambient temperature and the ambient humidity at corresponding moments according to the sensing data.

Step S5200, determining a humidifying progress corresponding to the ambient humidity carried by the sensing data of the temperature and humidity sensor based on the target humidity;

the control unit characterizes the air humidity in the space environment where the environment sensing regulation and control equipment is located according to the environment humidity determined by the sensing data of the temperature and humidity sensor, and when the air humidity does not reach the target humidity, the control unit needs to control the atomizing device to continuously emit mist so as to enable the environment humidity to reach the target humidity; when the air humidity reaches the target humidity, the control unit can control the atomizing device to stop atomizing, or maintain the atomizing device at a lower working gear so as to discharge the mist according to the lower atomizing, and properly supplement the water vapor scattered in the space.

The humidity rate of the environment can be regarded as the humidification progress of the environment sensing regulation and control equipment relative to the target humidity, and accordingly, the humidity rate of the environment is divided by the target humidity, so that the humidification progress can be obtained. It is easy to understand that the humidification progress effectively measures the task completion degree in the humidification process of the environment-sensing regulation and control equipment.

Step S5300, adjusting the working gear of the atomizing device according to an association regulation strategy reflecting the corresponding relation among the ambient temperature, the humidification progress and the working gear, and adjusting the light effect display state displayed by the atmosphere lamp to reflect the humidification progress.

Humidification progress can be used for synchronous regulation atomizing device's working gear and atmosphere lamp's lamp effect display state to realize the organic integration to traditional humidifier and atmosphere lamp. When the working gear of the atomizing device is regulated according to the humidification progress, one or more corresponding associated regulation and control strategies can be formulated according to the associated ambient temperature, and the regulation and control of the working gear of the atomizing device are realized by applying the one or more associated regulation and control strategies.

The working gear of the atomizing device is usually set according to the requirement, and different working gears can correspond to different mist outlet rates, namely the mist outlet amount in unit time. For example, in one embodiment, three gears, high, medium, and low, may be set, corresponding to the maximum, medium, and minimum fog rates, respectively. Of course, more working gears may be provided, and the number of working gears may not be limited. The corresponding relation between the working gear and the environmental temperature and the humidifying progress is established in advance, so that a corresponding relation regulation strategy can be formed, one or more of the relation regulation strategies can be formulated according to different conditions, one or more of the relation regulation strategies is/are applied, the corresponding humidifying progress is determined according to the environmental temperature and the environmental humidity represented by the sensing data detected by the temperature and humidity sensor each time, and the working gear of the atomizing device is set according to the humidifying progress and the environmental temperature by applying the corresponding relation regulation strategy.

With reference to the foregoing disclosure, the ambient temperature can be determined according to the sensing data of the temperature and humidity sensor. In different ambient temperatures, the saturation of water molecules of air is generally inconsistent, and the human body's perception of air humidity under different ambient temperature conditions is also generally different, in which case the operating gear of the atomizing device can be adjusted in relation to ambient temperature and humidification schedule.

An exemplary first associated regulatory strategy may be processed as follows: under the condition that the humidification progress is lower than a preset first threshold value, when the ambient temperature belongs to a preset human body comfort temperature zone or a high temperature zone with drier air, the atomizing device can be controlled to work in a working gear with relatively higher mist output, for example, in the highest working gear; when the ambient temperature falls within a predetermined low temperature range, the atomizing device can be controlled to operate in a relatively low mist-emitting operating range, for example in a lowest operating range. The temperature critical values corresponding to the comfort temperature zone, the high temperature zone and the low temperature zone of the human body can be flexibly set according to actual conditions, for example: the comfort temperature region of human body can be set between 23 ℃ and 26 ℃, the high temperature region can be set above 26 ℃, and the low temperature region can be set below 23 ℃.

An exemplary second associated regulatory strategy may be processed as follows: when the humidification progress is higher than a preset second threshold value, for example, higher than 80%, and the environment temperature is in a high-temperature region, the atomization device can be controlled to work in a working gear with the mist quantity being centered so as to ensure that the mist quantity is enough to supplement the water loss in the air; when the environment temperature is in the comfortable temperature area and the low temperature area of the human body, the atomizing device can be controlled to work at the lowest working gear.

An exemplary third associated regulatory strategy may be processed as follows: when the humidification progress is between the first threshold value and the second threshold value, the atomization device is controlled to apply the lowest, middle and highest corresponding working gears respectively according to the environment temperature belonging to the high temperature region, the human body comfort temperature region and the low temperature region, so that the mist is discharged at a relatively uniform speed in the period.

An exemplary fourth associated regulatory strategy may be processed as follows: the control unit determines a reference gear applied by the atomizing device according to a preset rule, then determines whether the current humidifying progress exceeds a preset threshold, for example 80%, when the humidifying progress exceeds the threshold, then judges whether the ambient temperature exceeds a corresponding preset threshold, when the ambient temperature exceeds the threshold, one gear is adjusted to be used as the working gear actually applied by the atomizing device on the basis of the reference gear, otherwise, if the ambient temperature does not exceed the preset threshold, the reference gear is correspondingly adjusted or kept to be used as the working gear actually applied by the atomizing device.

An exemplary fifth associated regulatory strategy may be processed as follows: the method comprises the steps of firstly determining a current humidification progress according to a preset rule to determine a reference gear applied by the atomization device, then obtaining geographical position information of the humidifier through network address or global positioning information of the humidifier by a control unit, determining a climate type of a region corresponding to the address position information, and correspondingly turning up, turning down and keeping the reference gear according to different climate types to serve as a working gear actually applied by the atomization device.

According to the above examples of various associated regulation policies, it is easy to understand that the associated regulation policies between the ambient temperature, the humidification progress and the working gear of the atomizing device can be flexibly set, and according to actual requirements, one or any plurality of set associated regulation policies are applied to flexibly set the working gear of the atomizing device so as to finely match the working gear regulation requirements of the atomizing device under various complex ambient conditions, so that the atomizing process of the atomizing device is easier for the human body to feel comfortable, the humidification working efficiency is optimized as much as possible, and the user experience is preferably ensured.

The humidification progress not only can be used for controlling the working gear of the atomization device in association with the ambient temperature, but also can be used for controlling the lamp effect display state of the atmosphere lamp in association. The light effect display state corresponds to the display effect of the light effect presented by the atmosphere lamp at one moment or one time period, and the display effects presented by the light effect display states of different light effects can be different. For example, in a light effect with a gradual change in brightness, a change in the display state of the light effect may be manifested as a change in the light brightness of the atmosphere lamp; in a color graded light effect, the change of the display state of the light effect may be represented as a change of the light color of the atmosphere lamp. It is easy to understand that there is a correspondence between the humidification progress and the light effect display state, the light effect display state reflects the humidification progress, and the user can effectively grasp the humidification progress by observing the change of the light effect display state.

Therefore, according to the humidification progress, the working gear of the atomizing device can be adjusted, the switching of the lamp effect display state of the atmosphere lamp can be synchronously controlled, the control unit can synchronously control the atomizing device and the atmosphere lamp through the humidification progress, the organic association of the atmosphere lamp of the atomizing device is realized, and the traditional humidifier and the atmosphere lamp are organically integrated into the environment induction regulation and control equipment.

According to the embodiment, it can be known that, this application utilizes temperature and humidity sensor to continue to detect the response data that obtains on confirming the target humidity, confirm its humidification progress for target humidity according to the ambient humidity in the response data, confirm atomizing device's work gear in order to adjust the required play fog volume of ambient humidification in good time according to ambient temperature and humidification progress jointly, adjust the lamp effect display state of atmosphere lamp in order to reflect this humidification progress according to the humidification progress, carry out organic integration with the original function of humidifier and atmosphere lamp through the humidification progress, form new environmental induction regulation and control equipment, human-computer interaction experience has been optimized, realize the product upgrading to humidifier and atmosphere lamp.

On the basis of any embodiment of the method of the present application, please refer to fig. 3, and the adjusting the light effect display state displayed by the atmosphere lamp to reflect the humidification progress includes:

Step S6100, determining a brightness ratio corresponding to the humidification progress;

in this embodiment, a relationship between the humidification progress and the brightness ratio of the light effect of the atmosphere lamp is established in advance, and when the light effect display state of the atmosphere lamp needs to be adjusted, the corresponding brightness ratio is determined according to the humidification progress. For example, when the humidification progress is expressed as a percentage, the conversion may be correspondingly performed to a corresponding luminance ratio.

In this embodiment, considering that the use scenario of the environmental sensing regulation and control device is usually a night scenario, the user often sets the target humidity before sleeping, the user wants to observe the humidification progress through the atmosphere lamp, when the humidification is completed, the user wants the atmosphere lamp not to form light interference affecting sleeping, and in order to ensure the user experience under the use scenario, the embodiment establishes the corresponding relation between the humidification progress and the brightness ratio according to the mode that the higher the humidification progress is, the lower the brightness ratio is. For example, when the target humidity is determined and humidification is started, the difference between the ambient humidity and the target temperature at that time is taken as a denominator, and then the difference between the detected ambient humidity and the target humidity is taken as a numerator, and the numerator is divided by the denominator to be taken as a humidification progress a, whereby the luminance ratio can be set to b=1 to a, for example, the humidification progress is set to 0%, and the luminance ratio is set to 100%; setting the humidification progress as 20%, and setting the brightness ratio as 80%; assuming that the humidification progress is 100%, the luminance ratio is 0%.

It can be seen that the complementary relation in the same proportion space is between humidification progress and the luminance proportion, along with the promotion of humidification progress, the luminance proportion of atmosphere lamp is darker and darker, and when the humidification progress reached hundred percent and reached the humidification target, the atmosphere lamp just was in full dark state, to the user, not only can grasp the humidification progress through the lamp effect display state of atmosphere lamp, but also can ensure that the light of atmosphere lamp can not influence user's sleep.

Step S6200, when the brightness proportion changes relative to the brightness proportion currently applied by the atmosphere lamp, generating corresponding light control data according to the brightness proportion;

it will be appreciated that the change in the humidification schedule is necessarily reflected in a change in the brightness ratio, and when the brightness ratio changes relative to the brightness ratio currently being applied by the atmosphere lamp, the light control data required for controlling the emission of the atmosphere lamp can be regenerated according to the brightness ratio.

As disclosed in the foregoing, each bead of the atmosphere lamp needs to be controlled by respective corresponding control data, but for the brightness ratio, the control data can be uniformly applied to each bead, so that the control data corresponding to each bead under the redetermined brightness ratio can be generated based on the historical control data corresponding to each bead or the currently applied control data, and the control data are spliced together in order according to the sequence of the lamp beads in the luminous communication link to form the light control data corresponding to the atmosphere lamp.

And step S6300, transmitting the light control data to the atmosphere lamp to change the luminous brightness of the atmosphere lamp so as to adjust the light effect display state.

After the light control data is constructed, the light control data can be sent to the atmosphere lamp. The control chip in the atmosphere lamp, for example, the control chip of each lamp bead, extracts the corresponding control data of the lamp bead from the light control data, generates the corresponding control signal, for example, the corresponding light-emitting control signal of the duty ratio, according to the control data, controls the light-emitting element of the control chip to emit light according to the corresponding brightness proportion, at this time, the light-emitting brightness of the atmosphere lamp changes for the visual effect of human eyes, and in fact, the lamp effect display state of the atmosphere lamp is adjusted.

According to the embodiment, the change of the humidification progress is reflected by skillfully utilizing the brightness change of the atmosphere lamp, the organic integration degree between the traditional humidifier and the atmosphere lamp is further improved, when the humidification progress and the brightness proportion are associated and correspond according to a certain complementary relation, the humidification progress can be reflected by the atmosphere lamp, the requirement of a night use scene can be met through the logic that the brightness is gradually darkened along with the increase of the humidification progress, the user can timely grasp the humidification progress, interference of the atmosphere lamp light to human sleep can be avoided after the humidification is completed, and the product use experience of the environment-sensing regulation and control equipment of the application can be remarkably improved.

On the basis of any embodiment of the method of the present application, please refer to fig. 4, and the adjusting the light effect display state displayed by the atmosphere lamp to reflect the humidification progress includes:

step S7100, determining a corresponding color value of the humidifying progress in a preset tone interval;

in this embodiment, a tone interval may be predefined, and the tone interval may be defined by two colors, for example, red and green, from red to green, and a tone interval is formed, and the tone interval and the variation interval of the humidification progress are associated, so that the color value of the corresponding color in the tone interval may be determined according to the humidification progress.

For example, according to the three primary colors of RGB, red is RGB (255, 0), green is RGB (0, 255, 0), and according to the two color values, the respective color value variation ranges of red and green are normalized and divided into 100 hues, so as to form optional colors in the respective hue intervals. In this case, a scale value of the humidification schedule corresponds to a specific tone thereof, and the corresponding color value can be directly determined according to the scale value of the humidification schedule.

Step S7200, when the color value changes relative to the currently applied color value of the atmosphere lamp, generating corresponding light control data according to the color value;

It will be appreciated that the change in the humidification schedule may be reflected as a change in the hue interval, and that when a change occurs in accordance with the color value currently being applied with respect to the atmosphere lamp, the light control data required for controlling the emission of the atmosphere lamp may be regenerated in accordance with the changed color value.

As disclosed in the foregoing, each bead of the atmosphere lamp needs to be controlled by respective corresponding control data, but for the color value, the color value can be uniformly applied to each bead, so that the changed color value can be assigned to the light-emitting color attribute item of each bead again based on the historical control data corresponding to each bead or the currently applied control data to obtain the corresponding control data, and the control data are spliced together in order according to the order of the lamp beads in the light-emitting communication link to form the light control data corresponding to the atmosphere lamp.

Step S7300, transmitting the light control data to the atmosphere lamp to change the color value of the atmosphere lamp so as to adjust the light effect display state.

After the light control data is constructed, the light control data can be sent to the atmosphere lamp. The control chip in the atmosphere lamp, for example, the control chip of each lamp bead, extracts the corresponding control data of the lamp bead from the light control data, generates the corresponding control signal according to the control data, controls the self luminous element to emit light according to the corresponding color value, at this time, for the visual effect of human eyes, the luminous color of the atmosphere lamp is changed, and the lamp effect display state of the atmosphere lamp is actually adjusted.

According to the embodiment, the change of the humidification progress is reflected by skillfully utilizing the color change of the atmosphere lamp, the organic integration degree between the traditional humidifier and the atmosphere lamp is further improved, in practice, the tone interval can be defined by utilizing two colors with different warning effects, such as red and green, when humidification starts, the atmosphere lamp displays red, when humidification ends, the atmosphere lamp displays green, the intermediate process atmosphere lamp displays the tone between the red and the green, a user can grasp the humidification progress through color gradual change, and the product use experience of the environment-friendly control equipment can be remarkably improved.

On the basis of any embodiment of the method, the method for acquiring the predetermined target humidity comprises the following steps:

step S5110, detecting whether a preset mode field is in an intelligent mode or a manual mode;

in this embodiment, the environment sensing regulation device may provide a mode selection function, and open two modes, including an intelligent mode and a manual mode, for a user to select. After the user selects the mode, the control unit writes in the corresponding mode field, and the working mode of the environment-sensing regulation and control equipment can be identified by reading the mode field.

Step S5120, when the intelligent mode is in, determining the corresponding comfortable humidity as the target humidity according to the ambient temperature carried in the sensing data regularly submitted by the temperature and humidity sensor;

when the mode field is set in the state of intelligent mode, the environment sensing regulation and control equipment executes the preset corresponding business logic. According to the business logic, a comfortable humidity is determined as a target humidity according to the ambient temperature in the sensing data regularly submitted by the temperature and humidity sensor.

The body feeling of the human body on the same environmental humidity is usually different in different temperatures, accordingly, corresponding relation data between the environmental humidity and the comfortable humidity can be established in advance, and when the business logic operates, the corresponding comfortable humidity under the given environmental temperature can be inquired and determined according to the corresponding relation data.

In an exemplary one of the correspondence data, when the ambient temperature is less than 65 degrees Fahrenheit, the corresponding comfort humidity may be set to 55 degrees Celsius; when the ambient temperature is between 65 degrees Fahrenheit and 77 degrees Fahrenheit, the corresponding comfort humidity may be set to 50%; when the ambient temperature is above 77 degrees Fahrenheit, its corresponding comfort humidity is set to 45%. According to this example, the comfort humidity corresponding to each temperature zone can be flexibly adjusted, a certain tolerance range is allowed, and the comfort humidity can moderately float by about 2%.

Accordingly, a corresponding comfortable humidity can be obtained according to the ambient temperature, the comfortable humidity is directly used as the target humidity, and the target humidity can be used for determining the humidification progress subsequently.

Step S5130, when in the manual mode, receives the user-defined humidity input by the user as the target humidity.

When the mode field is in the state of manual mode, the environment sensing regulation and control equipment can acquire the user-input custom humidity through the control panel, the user can input the final humidity expected by the user into the custom humidity, and the control unit acquires the custom humidity to be directly used as the target humidity for determining the humidification progress.

In this embodiment, two modes for flexibly determining the target humidity are opened to the user, when the intelligent mode is adopted, the environment sensing regulation and control equipment can automatically determine the corresponding comfortable humidity as the target humidity according to the environment temperature actually detected by the temperature and humidity sensor, and the environment sensing regulation and control equipment is used as the basis for determining the humidification progress, so that the dimension of the humidification progress is unified, more intelligent service can be provided for the user through the intelligent mode, the relatively standard environment humidification effect can be obtained at various temperatures, and the user experience is further improved.

On the basis of any embodiment of the method of the present application, as disclosure of a working process of one of the associated regulation policies applied in the present application, please refer to fig. 5, the adjusting of the working gear of the atomizing device according to the associated regulation policy reflecting the corresponding relationship among the ambient temperature, the humidification progress and the working gear includes:

step S8100, determining a reference gear matched with the humidification progress;

in this embodiment, the environmental sensing regulation device is preset with mapping relationship data between the humidification progress and the working gear of the atomizing device in advance, so that each specific humidification progress can determine the corresponding working gear under the default condition. Accordingly, after the humidification progress is determined according to the ambient humidity measured by the temperature and humidity sensor, the mapping relation data is queried, and the corresponding working gear can be obtained as the reference gear.

Step S8200, judging whether the humidification progress is lower than a preset progress threshold, and when the humidification progress is lower than the progress threshold and the ambient temperature is higher than a preset temperature threshold, adjusting the reference gear by one gear to serve as a working gear of the atomization device;

the association regulation and control strategy applied in this embodiment is mainly to moderately adjust the working gear to accelerate the humidification process at a specific stage in the humidification process, for example, at the initial stage of starting humidification, so that this embodiment firstly determines whether the humidification process is lower than a preset progress threshold, where the progress threshold may be set to any value below 50%, and when the humidification process is lower than the progress threshold, that is, at the initial stage of humidification, further determines whether the ambient temperature is higher than a preset temperature threshold, where the temperature threshold may be a critical value between a comfortable temperature region and a low temperature region of a human body, and when the temperature threshold is higher than the temperature threshold, one gear may be adjusted on the basis of the reference gear, and the adjusted gear is set to be the working gear of the atomizing device in practical application. Of course, if the reference gear is already the highest gear, the reference gear may be maintained as the operating gear for the actual application of the atomizing device.

And step S8300, setting the working gear of the atomization device by the reference gear when the humidification progress is higher than the progress threshold or the ambient temperature does not exceed the temperature threshold.

In any other case where the step S8200 is not satisfied, the reference gear determined in the step S8100 is directly set as the operating gear of the atomizing device, and the atomizing device may be driven to operate.

In this embodiment, as disclosure of performance of a working process of one of the associated regulation policies, it can be seen that the associated regulation policy can rapidly determine a working gear applied by the atomizing device according to a humidification progress by default, and can jointly adjust the working gear of the atomizing device according to a humidification initial speed-up humidification requirement and according to a humidification progress and an ambient temperature to achieve speed-up of the humidification process, and after the humidification progress exceeds a corresponding progress threshold value in the speed-up process, the operation power of the atomizing device is balanced and the humidification efficiency is higher in the whole humidification process.

On the basis of any embodiment of the method of the present application, as disclosure of a working process of one of the associated regulation policies applied in the present application, please refer to fig. 6, the adjusting of the working gear of the atomizing device according to the associated regulation policy reflecting the corresponding relationship among the ambient temperature, the humidification progress and the working gear includes:

Step S9100, determining a reference gear matched with the humidification progress;

in this embodiment, the environmental sensing regulation device is preset with mapping relationship data between the humidification progress and the working gear of the atomizing device in advance, so that each specific humidification progress can determine the corresponding working gear under the default condition. Accordingly, after the humidification progress is determined according to the ambient humidity measured by the temperature and humidity sensor, the mapping relation data is queried, and the corresponding working gear can be obtained as the reference gear.

Step S9200, obtaining the current geographic position information and determining the climate type corresponding to the geographic position information;

the environment induction regulation and control equipment can be connected to the Internet, and can be provided with a functional module corresponding to a global navigation positioning system if necessary, so that geographic position information corresponding to a local network address or corresponding to the longitude and latitude of the local network address can be obtained from a server, and the geographic position information can be specific to a city level or a lower administrative division level.

It is to be understood that different geographical locations have different climate types, e.g. Shenzhen is in subtropical regions, the climate types are relatively humid; beijing is relatively north and its climatic type is relatively dry. In this way, the corresponding relation between each city and the climate type can be established in advance according to the actual geographic characteristics. In order to determine its corresponding climate type from the geographical location information.

Step S9300, setting a target gear matched with the climate type by referring to the reference gear, and setting the target gear as the working gear of the atomization device.

Different climate types are inconsistent in water molecule content in the air even under the same environmental temperature, so in the embodiment, the environment sensing regulation and control equipment writes corresponding relation data of whether one or more gears need to be regulated up or down relative to a reference gear under different climate types into a memory, after determining the climate type of the city where the environment is currently located, the corresponding relation data is queried to determine whether the gears of the corresponding quantity need to be regulated up or down, gear adjustment is carried out on the basis of the reference gear to obtain a target gear, and then the target gear is used as a working gear of an atomization device to control the atomization device to carry out fog output.

In this embodiment, as a disclosure of the performance of the working process of one of the associated regulation and control strategies, it can be seen that the associated regulation and control strategy can adapt to the geographical area where the environment-sensing regulation and control equipment is located to flexibly adjust the working gear of the atomizing device, so that the humidification process can adapt to the climate characteristics of the area where the environment-sensing regulation and control equipment is located, and more comfortable humidification experience is provided for a user, and the product use experience is further improved.

On the basis of any embodiment of the method, according to the association regulation strategy reflecting the corresponding relation among the ambient temperature, the humidification progress and the working gear, the working gear of the atomizing device is regulated, and before regulating the lamp effect display state displayed by the atmosphere lamp to reflect the humidification progress, the method comprises the following steps:

step S4100, judging whether the working gear applied by the atomization device and the maintenance time length of the lamp effect display state of the atmosphere lamp reach the preset threshold, and continuing to judge the next humidification progress after the follow-up steps are omitted when the maintenance time length does not reach the preset threshold;

in the humidification process, the working gear of the atomizing device is switched, the mist output is related to the magnitude of the mist output, under some typical conditions, the atomizing device is supposed to work at the highest working gear first, so that the humidification progress is triggered to be rapidly pushed, but at the moment, the humidification progress is suddenly lowered, the humidification progress is retreated, so that the shaking of the humidification progress occurs, in order to avoid the shaking, in the embodiment, the above embodiments can be further restrained, and whether the continuous execution of the steps S5200 and S5300 of the application is continued or not is determined by judging the working gear of the atomizing device and the maintenance duration of the lamp effect display state of the atmosphere lamp, so that the shaking is prevented.

Specifically, when the resetting of the working gear of the atomizing device and the light effect display state of the atmosphere lamp is completed each time, the maintenance time length of the resetting can be calculated, the maintenance time length can also be calculated corresponding to the working gear and the light effect display state respectively, when the temperature and humidity sensor submits the sensing data at the next time, and after determining the humidifying progress according to the ambient humidity of the sensing data, whether the maintenance time length reaches the preset threshold value is judged first, and when any one of the maintenance time lengths of the working gear and the light effect display state does not reach the preset threshold value corresponding to the setting, the next sensing data is not executed any more, and the next submitted sensing data is waited for to iterate again.

Step S4200, when all the humidification steps reach the preset threshold, continuing to judge the next humidification progress after executing the subsequent steps.

When the duration of the working gear and the light effect display state reach the preset threshold, it indicates that the dithering period has elapsed, and in this case, the steps S5200 and S5300 of the present application may be continuously executed, and then, the next submitted sensing data may be continuously awaited for further iteration.

According to the embodiment, the situation that the working gear and the lamp efficiency display state are frequently switched due to shaking of the humidification progress can be effectively prevented, on one hand, the humidification control logic of the atomizing device can be guaranteed to run more stably, and on the other hand, the lamp efficiency of the atmosphere lamp can be guaranteed to play a role of accurately reflecting the humidification progress information.

Referring to fig. 7, another embodiment of the present application further provides a humidification control device, which includes an initial processing module 5100, a progress determining module 5200, and a progress responding module 5300, wherein the initial processing module 5100 is configured to obtain predetermined target humidity and sensing data detected by a temperature and humidity sensor at regular time; the progress determining module 5200 is configured to determine a humidification progress corresponding to the ambient humidity carried by the sensing data of the temperature and humidity sensor based on the target humidity; the progress response module 5300 is configured to adjust a working gear of the atomizing device according to an association regulation policy reflecting a corresponding relationship among an ambient temperature, a humidification progress and the working gear, and adjust a light effect display state displayed by the atmosphere lamp to reflect the humidification progress.

On the basis of any embodiment of the apparatus of the present application, the progress response module 5300 includes: the brightness mapping module is used for determining the brightness proportion corresponding to the humidification progress; the first generation module is used for generating corresponding light control data according to the brightness proportion when the brightness proportion changes relative to the brightness proportion currently applied by the atmosphere lamp; the first control module is used for transmitting the light control data to the atmosphere lamp so as to change the luminous brightness of the atmosphere lamp and adjust the light effect display state.

On the basis of any embodiment of the apparatus of the present application, the progress response module 5300 includes: the color mapping module is used for determining a corresponding color value of the humidifying progress in a preset tone interval; the second generation module is used for generating corresponding light control data according to the color value when the color value changes relative to the color value currently applied by the atmosphere lamp; and the second control module is used for transmitting the light control data to the atmosphere lamp so as to change the color value of the atmosphere lamp and adjust the light effect display state.

On the basis of any embodiment of the apparatus of the present application, the initial processing module 5100 includes: the mode identification module is used for detecting whether a preset mode field is in an intelligent mode or a manual mode; the intelligent setting module is used for determining the corresponding comfortable humidity as the target humidity according to the ambient temperature carried in the sensing data regularly submitted by the temperature and humidity sensor when the intelligent setting module is in an intelligent mode; and the manual setting module is used for receiving the user-defined humidity input by the user as the target humidity when the manual setting module is in the manual mode.

On the basis of any embodiment of the apparatus of the present application, the progress response module 5300 includes: a reference determining module configured to determine a reference gear that matches the humidification schedule; the temperature control adjusting module is used for judging whether the humidifying progress is lower than a preset progress threshold value, and when the humidifying progress is lower than the progress threshold value and the ambient temperature is higher than a preset temperature threshold value, the reference gear is adjusted to be one gear higher as a working gear of the atomizing device; and the conventional adjusting module is used for setting the working gear of the atomizing device according to the reference gear when the humidification progress is higher than the progress threshold or the ambient temperature does not exceed the temperature threshold.

On the basis of any embodiment of the apparatus of the present application, the progress response module 5300 includes: a reference determining module configured to determine a reference gear that matches the humidification schedule; the geographic identification module is used for acquiring the current geographic position information and determining the climate type corresponding to the geographic position information; the gear setting module is used for setting a target gear matched with the climate type by referring to the reference gear, and setting the target gear as the working gear of the atomization device.

On the basis of any embodiment of the apparatus of the present application, prior to the operation of the progress response module 5300, the humidification control apparatus of the present application further includes: the maintenance identification module is used for judging whether the maintenance time length of the working gear applied by the atomization device and the lamp effect display state of the atmosphere lamp reach a preset threshold value or not, and when the maintenance time length does not reach the preset threshold value, the next step is omitted, and the next humidification progress is continuously judged; and the iteration decision module is used for continuously judging the next humidification progress after executing the subsequent steps when the preset threshold value is reached.

On the basis of any embodiment of the present application, please refer to fig. 8, another embodiment of the present application further provides a computer device, which may be used as a control unit in an environmental sensing regulation device, as shown in fig. 8, and an internal structure diagram of the computer device is shown. The computer device includes a processor, a computer readable storage medium, a memory, and a network interface connected by a system bus. The computer readable storage medium of the computer device stores an operating system, a database and a computer program packaged with computer readable instructions, the database can store a control information sequence, and the computer readable instructions can enable the processor to realize a humidification control method when the computer readable instructions are executed by the processor. The processor of the computer device is used to provide computing and control capabilities, supporting the operation of the entire computer device. The memory of the computer device may have stored therein computer readable instructions that, when executed by the processor, may cause the processor to perform the humidification control methods of the present application. The network interface of the computer device is for communicating with a terminal connection. It will be appreciated by those skilled in the art that the structure shown in fig. 8 is merely a block diagram of some of the structures associated with the present application and is not limiting of the computer device to which the present application may be applied, and that a particular computer device may include more or fewer components than shown, or may combine certain components, or have a different arrangement of components.

The processor in this embodiment is configured to execute specific functions of each module and its sub-module in fig. 7, and the memory stores program codes and various data required for executing the above modules or sub-modules. The network interface is used for data transmission between the user terminal or the server. The memory in the present embodiment stores program codes and data necessary for executing all modules/sub-modules in the humidification control device of the present application, and the server can call the program codes and data of the server to execute the functions of all sub-modules.

The present application also provides a storage medium storing computer readable instructions that, when executed by one or more processors, cause the one or more processors to perform the steps of the humidification control method of any of the embodiments of the present application.

The present application also provides a computer program product comprising computer programs/instructions which when executed by one or more processors implement the steps of the humidification control method of any of the embodiments of the present application.

Those skilled in the art will appreciate that implementing all or part of the above-described methods of embodiments of the present application may be accomplished by way of a computer program stored on a computer readable storage medium, which when executed, may comprise the steps of embodiments of the methods described above. The storage medium may be a computer readable storage medium such as a magnetic disk, an optical disk, a Read-Only Memory (ROM), or a random access Memory (Random Access Memory, RAM).

The foregoing is only a partial embodiment of the present application, and it should be noted that, for a person skilled in the art, several improvements and modifications can be made without departing from the principle of the present application, and these improvements and modifications should also be considered as the protection scope of the present application.

To sum up, this application carries out organic integration with the original function of humidifier and atmosphere lamp through the humidification progress, forms new environmental response regulation and control equipment, has optimized man-machine interaction and has experienced, realizes the product upgrading to humidifier and atmosphere lamp.

Claims (10)

1. A humidification control method, comprising:

acquiring sensing data of timing detection of a predetermined target humidity and a temperature and humidity sensor;

based on the target humidity, determining a humidifying progress corresponding to the ambient humidity carried by the sensing data of the temperature and humidity sensor;

and adjusting the working gear of the atomizing device according to an associated regulation strategy reflecting the corresponding relation among the ambient temperature, the humidification progress and the working gear, and adjusting the light effect display state displayed by the atmosphere lamp to reflect the humidification progress.

2. The humidification control method of claim 1, wherein adjusting a light effect display state displayed by an atmosphere lamp to reflect the humidification progress comprises:

Determining the brightness proportion corresponding to the humidification progress;

when the brightness proportion changes relative to the brightness proportion currently applied by the atmosphere lamp, corresponding light control data are generated according to the brightness proportion;

and transmitting the light control data to the atmosphere lamp to change the luminous brightness of the atmosphere lamp so as to adjust the light effect display state.

3. The humidification control method of claim 1, wherein adjusting a light effect display state displayed by an atmosphere lamp to reflect the humidification progress comprises:

determining a corresponding color value of the humidifying progress in a preset tone interval;

when the color value changes relative to the currently applied color value of the atmosphere lamp, corresponding light control data are generated according to the color value;

and transmitting the light control data to the atmosphere lamp to change the color value of the atmosphere lamp so as to adjust the light effect display state.

4. A humidification control method as claimed in any one of claims 1 to 3, wherein obtaining a predetermined target humidity comprises:

detecting whether a preset mode field is in an intelligent mode or a manual mode;

When the intelligent temperature sensor is in the intelligent mode, determining the corresponding comfortable humidity as the target humidity according to the ambient temperature carried in the sensing data regularly submitted by the temperature and humidity sensor;

when in the manual mode, the user-defined humidity input by the user is received as the target humidity.

5. A humidification control method as claimed in any one of claims 1 to 3, wherein adjusting the operating range of the atomizing device according to an associated regulation strategy reflecting the correspondence between ambient temperature, humidification schedule and operating range comprises:

determining a reference gear matched with the humidification progress;

judging whether the humidification progress is lower than a preset progress threshold value, and when the humidification progress is lower than the progress threshold value and the ambient temperature is higher than a preset temperature threshold value, adjusting the reference gear by one gear to serve as a working gear of the atomization device;

and when the humidification progress is higher than the progress threshold or the ambient temperature does not exceed the temperature threshold, setting the working gear of the atomization device by the reference gear.

6. A humidification control method as claimed in any one of claims 1 to 3, wherein adjusting the operating range of the atomizing device according to an associated regulation strategy reflecting the correspondence between ambient temperature, humidification schedule and operating range comprises:

Determining a reference gear matched with the humidification progress;

acquiring the current geographic position information and determining the climate type corresponding to the geographic position information;

and setting a target gear matched with the climate type by referring to the reference gear, and setting the target gear as the working gear of the atomization device.

7. A humidification control method according to any one of claims 1 to 3, characterized by comprising, before adjusting an operating range of an atomizing device according to an association regulation strategy reflecting a correspondence between an ambient temperature, a humidification progress, and the operating range, and adjusting a light effect display state displayed by an atmosphere lamp so as to reflect the humidification progress:

judging whether the working gear applied by the atomization device and the maintenance time length of the lamp effect display state of the atmosphere lamp reach a preset threshold value or not, and continuing to judge the next humidification progress after the follow-up steps are omitted when the maintenance time length does not reach the preset threshold value;

and when the next humidification progress reaches the preset threshold value, continuing to judge the next humidification progress after the subsequent steps are executed.

8. A humidification control device, comprising:

the initial processing module is used for acquiring preset target humidity and sensing data detected by the temperature and humidity sensor at fixed time;

The progress determining module is used for determining the humidification progress corresponding to the ambient humidity carried by the sensing data of the temperature and humidity sensor based on the target humidity;

the progress response module is used for adjusting the working gear of the atomizing device according to an associated regulation strategy reflecting the corresponding relation among the ambient temperature, the humidification progress and the working gear, and adjusting the light effect display state displayed by the atmosphere lamp to enable the humidification progress to be reflected.

9. An environmental sensing regulation apparatus comprising a control unit, a temperature and humidity sensor, an atmosphere lamp, and an atomizing device, wherein the control unit is configured to perform the steps in the humidification control method according to any one of claims 1 to 7.

10. A computer program product comprising computer programs/instructions which, when executed by a processor, perform the steps of the method of any of claims 1 to 7.