CN112815487A - Control method and device of humidifier, equipment and storage medium - Google Patents

Abstract

The embodiment of the invention discloses a control method, a control device, equipment and a storage medium of a humidifier, the method can acquire the initial humidity value acquired by the humidity acquisition device positioned in the effective humidification range of the humidifier and the distance value between the humidity acquisition device and the humidifier, wherein, the humidity acquisition device comprises at least one humidity acquisition device with the distance value not equal to zero with the humidifier, so that the initial humidity value collected in the effective humidification range of the humidifier can be normalized by simulating and calculating the target humidity value when the humidity collection device is positioned at the position of the humidifier, and the humidifier is used for realizing accurate humidification control of the humidifier, so that the whole humidity condition in the effective humidification range of the humidifier can be considered in the humidification control process, and the humidification effect of humidification control is effectively improved.

Description

Control method and device of humidifier, equipment and storage medium

Technical Field

The invention relates to the technical field of humidifiers, in particular to a control method, a control device, control equipment and a storage medium of a humidifier.

Background

Along with the development of economy and the improvement of the living standard of people, the requirements of people on the quality of life and health are higher and higher, and when the air is dry, people can use the humidifier to increase the humidity of the living environment so as to improve the environmental comfort level.

However, the existing control method of the humidifier has the problem of poor humidification effect.

Disclosure of Invention

The invention mainly aims to provide a control method and device of a humidifier, equipment and a storage medium, which can improve the accuracy of humidification control and improve the humidification effect.

To achieve the above object, a first aspect of the present invention provides a method for controlling a humidifier, the method including:

acquiring an initial humidity value acquired by a humidity acquisition device positioned in an effective humidification range of the humidifier and a distance value between the humidity acquisition device and the humidifier, wherein the humidity acquisition device comprises at least one far-end humidity acquisition device, and the far-end humidity acquisition device is a humidity acquisition device of which the distance value between the far-end humidity acquisition device and the humidifier is not equal to zero;

according to the initial humidity value and the distance value of the humidity acquisition device, simulating and calculating a target humidity value when the humidity acquisition device is located at the position of the humidifier;

and carrying out humidification control on the humidifier according to the target humidity value of the humidity acquisition device.

In order to achieve the above object, a second aspect of the present invention provides a control apparatus of a humidifier, the apparatus including:

the system comprises an acquisition module, a control module and a control module, wherein the acquisition module is used for acquiring an initial humidity value acquired by a humidity acquisition device positioned in an effective humidification range of the humidifier and a distance value between the humidity acquisition device and the humidifier, the humidity acquisition device comprises at least one far-end humidity acquisition device, and the far-end humidity acquisition device is a humidity acquisition device of which the distance value between the far-end humidity acquisition device and the humidifier is not equal to zero;

the simulation module is used for simulating and calculating a target humidity value when the humidity acquisition device is positioned at the position of the humidifier according to the initial humidity value and the distance value of the humidity acquisition device;

and the control module is used for carrying out humidification control on the humidifier according to the target humidity value of the humidity acquisition device.

To achieve the above object, a third aspect of the present invention provides a computer-readable storage medium storing a computer program which, when executed by a processor, causes the processor to execute the control method of a humidifier according to the first aspect.

To achieve the above object, a fourth aspect of the present invention provides a computer apparatus comprising a memory and a processor, the memory storing a computer program, the computer program, when executed by the processor, causing the processor to execute the control device of the humidifier according to the first aspect.

The embodiment of the invention has the following beneficial effects:

the invention provides a control method of a humidifier, which can acquire an initial humidity value acquired by a humidity acquisition device positioned in an effective humidification range of the humidifier and a distance value between the humidity acquisition device and the humidifier, wherein the humidity acquisition device comprises at least one humidity acquisition device of which the distance value between the humidity acquisition device and the humidifier is not equal to zero, and a target humidity value of the humidity acquisition device positioned at the position of the humidifier can be simulated and calculated according to the initial humidity value and the distance value of the humidity acquisition device, so that the humidifier can be subjected to humidification control according to the target humidity value of the humidity acquisition device. The humidity acquisition device comprises at least one humidity acquisition device with a distance value not equal to zero from the humidifier, so that an initial humidity value of the humidity acquisition device in an effective range of the humidifier can be acquired, normalization processing can be performed on the initial humidity value acquired in the effective humidification range in a mode of simulating and calculating a target humidity value when the humidity acquisition device is located at the position of the humidifier, accurate humidification control over the humidifier can be achieved conveniently based on the target humidity value, driving control can be performed in consideration of the overall humidity condition in the effective humidification range of the humidifier, the accuracy of humidification control is effectively improved, and the humidification effect is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Wherein:

fig. 1 is a schematic flow chart illustrating a method for controlling a humidifier according to an embodiment of the present invention;

FIG. 2 is a schematic view of a humidifier in an embodiment of the present invention;

FIG. 3 is a schematic view of a humidity acquisition device within the effective humidification range of the humidifier of FIG. 2;

FIG. 4 is a schematic diagram of the normalized humidifier of the humidity acquisition device of FIG. 3;

fig. 5 is another schematic flow chart of a control method of a humidifier according to an embodiment of the invention;

FIG. 6 is a schematic flow chart of the step of refining step 505 in the embodiment shown in FIG. 5;

FIG. 7 is another flow chart illustrating the step of refining step 505 in the embodiment shown in FIG. 5;

fig. 8 is a block diagram of a control device of the humidifier according to the embodiment of the present invention;

fig. 9 is a block diagram of a computer device according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, a schematic flow chart of a method for controlling a humidifier according to an embodiment of the present invention is shown, where the method includes:

step 101, acquiring an initial humidity value acquired by a humidity acquisition device located in an effective humidification range of a humidifier and a distance value of the humidity acquisition device from the humidifier, wherein the humidity acquisition device comprises at least one far-end humidity acquisition device, and the far-end humidity acquisition device is a humidity acquisition device with the distance value from the humidifier not equal to zero;

in an embodiment of the present invention, the above-mentioned control method of the humidifier may be implemented by a control device of the humidifier, where the control device is a program module and is stored in a computer-readable storage medium of the apparatus, and a processor in the apparatus may call the control device and execute the control device to implement the above-mentioned control method.

The above-mentioned device may be a humidifier, or may also be other devices capable of interacting with the humidifier and controlling the humidifier, such as a central control system, which is not limited herein, and in the embodiment of the present invention, the technical solution will be described by taking the humidifier as an example to implement the above-mentioned method, and will not be described in detail later.

Wherein the humidifier has an effective humidification range, and the effective humidification range is determined based on an effective humidification radius of the humidifier. In a feasible implementation manner, the farthest distance (the distance from the humidifier) that can bring about humidity change under the condition of the maximum atomization power and the maximum wind speed of the humidifier can be tested, the distance can be used as the effective humidification radius of the humidifier, the humidifier is used as the center, and a space area determined by taking the effective humidification radius as the radius can be used as the effective humidification range of the humidifier.

In the embodiment of the invention, the initial humidity value acquired by the humidity acquisition device in the effective humidification range of the humidifier and the distance value between the humidity acquisition device and the humidifier can be acquired.

Wherein, the humidity acquisition device at least comprises a humidity acquisition device with a distance value not equal to zero with the humidifier. The humidity acquisition device with a distance value different from zero from the humidifier is generally a humidity acquisition device not included in the humidifier, and may also be referred to as a remote humidity acquisition device, for example, a humidity sensor disposed in an effective humidification range of the humidifier but with a distance value different from zero from the humidifier, or other equipment with a humidity acquisition function. It should be noted that the humidity acquisition device whose distance value from the humidifier is equal to zero generally refers to a humidity acquisition device included in the humidifier, and may also be referred to as a near-end humidity acquisition device, for example, a humidity sensor disposed on the surface of the humidifier may be used to detect a humidity value at a position where the humidifier is located.

It is understood that all humidity collection devices within the effective humidification range of the humidifier may be obtained, and besides at least one far-end humidity collection device, if the humidifier has a near-end humidity collection device, the near-end humidity collection device is also included in the humidity collection device. For example, if there are 3 far-end humidity acquisition devices in the effective humidification range of the humidifier, and the humidifier does not include a near-end humidity acquisition device, the initial humidity values and the distance values between the initial humidity values and the humidifier acquired by the 3 far-end humidity acquisition devices may be acquired, if there are 2 far-end humidity acquisition devices in the effective humidification range of the humidifier, and the humidifier includes 4 near-end humidity acquisition devices, the initial humidity values and the distance values between the 2 far-end humidity acquisition devices and the initial humidity values and the distance values between the 4 near-end humidity acquisition devices may be acquired, and the distance values between the near-end humidity acquisition devices are all 0. It can be understood that the near-end humidity acquisition device and the far-end humidity acquisition device can be distinguished through the distance value, or the near-end humidity acquisition device and the far-end humidity acquisition device can also be distinguished through the mode of setting up the identification, for example, the type identification of the near-end humidity acquisition device can be set up to be 0 in advance, the type identification of the far-end humidity acquisition device is 1, when the initial humidity value and the distance value acquired by the humidity acquisition device are acquired, the type identification can also be acquired, and the type identification is recognized first, the initial humidity value and the distance value with the type identification 0 are determined to be the initial humidity value and the distance value of the near-end humidity acquisition device, and the initial humidity value and the distance value with the type identification 1 are used as the initial humidity value and the distance value of the far-end humidity. In practical application, the far-end humidity acquisition device and the near-end humidity acquisition device can be distinguished according to other modes, which is not limited herein.

The near-end humidity acquisition device is electrically connected with a control chip in the humidifier, the acquired humidity data can be sent to a processor in the humidifier to obtain the initial humidity value, and the distance value of the initial humidity value received by the humidifier and sent by the near-end humidity acquisition device in the humidifier can be determined to be zero. Far-end humidity collection system can be connected with humidifier radio communication, for example, can be bluetooth connection, wifi connects etc., the initial humidity value that far-end humidity collection system gathered can send for the humidifier through radio communication connection, and can confirm the distance value between far-end humidity collection system and the humidifier based on radio communication's signal strength isoparametric or through the mode of location, in practical application, the mode that the humidifier confirms far-end humidity collection system rather than the distance value can have the multiple, can select corresponding calculation mode according to specific circumstances, it does not describe here any more.

102, simulating and calculating a target humidity value when the humidity acquisition device is positioned at the position of the humidifier according to the initial humidity value and the distance value of the humidity acquisition device;

and 103, carrying out humidification control on the humidifier according to the target humidity value of the humidity acquisition device.

In the embodiment of the invention, the target humidity value of the humidity acquisition device at the position of the humidifier can be calculated in a simulation mode according to the initial humidity value and the distance value of the humidity acquisition device, wherein the simulation calculation refers to converting the initial humidity value acquired by the humidity acquisition device according to the distance value, and converting the humidity value acquired by the humidity acquisition device at the position of the humidifier as the target humidity value of the humidity acquisition device, and the position of the humidity acquisition device at the position of the humidifier refers to the fact that the distance value between the humidity acquisition device and the humidifier is zero. Through the mode of the analog calculation, the initial humidity value of the humidity acquisition device can be normalized, and the humidification control can be carried out on the humidifier by referring to the humidity value acquired by the far-end humidity acquisition device, so that the accuracy of the humidification control and the humidification effect of the humidifier are improved.

In the embodiment of the invention, the humidity acquisition device comprises at least one humidity acquisition device with a distance value not equal to zero from the humidifier, so that an initial humidity value of the humidity acquisition device in an effective range of the humidifier can be acquired, and a target humidity value of the humidity acquisition device in the position of the humidifier is calculated through simulation, so that the initial humidity value acquired in the effective humidification range can be normalized, the initial humidity value can be used for realizing accurate humidification control of the humidifier, the humidity condition in the effective humidification range of the humidifier can be considered, and the humidification effect can be effectively improved.

It can be understood that, in the embodiment of the present invention, if the near-end humidity acquisition device is included in the effective humidification range of the humidifier, the initial humidity value of the near-end humidity acquisition device is used as the target humidity value of the near-end humidity acquisition device, and analog calculation is not required.

And to better understand the principle of the simulation calculation in the embodiment of the present invention, please refer to fig. 2, fig. 2 is a schematic diagram of a humidifier including a near-end humidity acquisition device J1 to J4, wherein the distance values of the near-end humidity acquisition devices are all zero. Please refer to fig. 3, which is a schematic diagram of the humidity acquisition devices existing within the effective humidification range of the humidifier shown in fig. 2, and includes the near-end humidity acquisition devices J1 to J4 and the far-end humidity acquisition devices Y1 to Y4, and the schematic diagram of the humidifier shown in fig. 4 can be obtained by performing analog calculation on the far-end humidity acquisition devices in fig. 3, and fig. 4 is a schematic diagram of the humidifier simulating the humidity values acquired by the far-end humidity acquisition devices when the far-end humidity acquisition devices are located at the position of the humidifier, so as to obtain the target humidity value of the far-end humidity acquisition devices.

Further, in a possible implementation manner, in order to implement normalization of the initial humidity value of the remote humidity acquisition device, the step 102 may specifically include:

A. acquiring a preset normalization coefficient value, wherein the normalization coefficient value is a humidity adjustment coefficient value used when the simulation remote humidity acquisition device is positioned at the position of the humidifier;

B. if the distance value of the humidity acquisition device is not equal to zero, determining that the humidity acquisition device is a far-end humidity acquisition device, calculating the product of the distance value of the far-end humidity acquisition device and the normalized coefficient value, and taking the sum of the product and the initial humidity value of the humidity acquisition device as the target humidity value of the far-end humidity acquisition device;

C. and if the distance value of the humidity acquisition device is equal to zero, determining that the humidity acquisition device is a near-end humidity acquisition device, and taking the initial humidity value of the near-end humidity acquisition device as the target humidity value.

In the embodiment of the present invention, a normalization coefficient value may be preset, where the normalization coefficient value is used for a humidity adjustment coefficient value used when the simulated humidity acquisition device is located at the position of the humidifier, where the normalization coefficient value may be obtained through a test, and it can be understood that the normalization coefficient value is different in magnitude in different simulation calculation processes.

Specifically, to each humidity acquisition device in the humidification effective range of humidifier, probably near-end humidity acquisition device, also the distal end humidity acquisition device that can be, and only need normalize distal end humidity acquisition device's humidity value, and to near-end humidity acquisition device, need not normalize it, can regard near-end humidity acquisition device's initial humidity value as its target humidity value. Wherein, the way of normalizing the initial humidity value of the far-end humidity acquisition device can be as follows: and (3) performing product calculation on the distance value of the far-end humidity acquisition device and the normalization coefficient value, namely simulating the deviation of the humidity value when the distance value between the far-end humidity acquisition device and the humidifier is zero, and summing the deviation (product) and the initial humidity value of the far-end humidity acquisition device to obtain the normalized target humidity value of the far-end humidity acquisition device.

In one possible implementation, the normalization can be performed using the following formula, including:

H_local≈rD_remote+H_remote

wherein H_localRepresenting the target humidity value, D_remteRepresents a distance value, H_remoteRepresenting an initial humidity value, r representing a normalized coefficient value, and optionally, normalizedThe quantization index value r may be 2/7.12.

In this way, the preset normalization coefficient value can be utilized, the initial humidity value and the distance value of the far-end humidity acquisition devices are normalized, the target humidity value of each far-end humidity acquisition device in the position of the humidifier is obtained, the humidifier is convenient to carry out humidification control based on the normalized target humidity value, the far-end humidity acquisition devices are normalized, the humidity value collected by the far-end humidity acquisition devices can be referred to in the humidification control process, and the humidification control accuracy and the humidification effect are improved.

In order to better understand the technical solution in the embodiment of the present invention, the following will describe the process of humidification control in detail, please refer to fig. 5, which is a schematic flow chart of a control method of a humidifier in the embodiment of the present invention, including:

step 501, acquiring an initial humidity value acquired by a humidity acquisition device located in an effective humidification range of a humidifier and a distance value between the humidity acquisition device and the humidifier, wherein the humidity acquisition device comprises at least one humidity acquisition device with a distance value not equal to zero from the humidifier;

502, simulating and calculating a target humidity value when the humidity acquisition device is positioned at the position of the humidifier according to the initial humidity value and the distance value of the humidity acquisition device;

step 503, acquiring a user humidity value set by a user and an optimal humidity value matched with the current time;

step 504, performing weighted calculation by using the user humidity value and the optimal humidity value to obtain an expected humidity value of the humidifier;

and 505, performing humidification control on the humidifier according to the expected humidity value and the target humidity value of the humidity acquisition device.

In the embodiment of the present invention, the step 501 and the step 502 are described in the foregoing embodiment, and specific reference may be made to relevant contents in the foregoing embodiment, which is not described herein again.

In the embodiment of the invention, a user humidity value set by the user can be obtained, the user humidity value refers to a humidity value which can be reached by a space which the user expects the humidifier to humidify, the user humidity value is considered to be a humidity value which is subjectively felt by the user, there is a deviation from the actual humidity value generated by the humidifier, so, in order to avoid the influence of the deviation on the humidity and the user experience, the user humidity value set by the user can be adjusted, specifically, the optimal humidity value matched with the current time can be used, the optimal humidity value is utilized to adjust the user humidity value to obtain the expected humidity value, the expected humidity value is an actual humidity value of the humidifier during humidification, so that a user can feel a comfortable effect brought by the humidity value of the user when the humidifier performs humidification control according to the expected humidity value.

In one possible implementation, the optimal humidity value may be determined based on different seasons, for example, the optimal humidity value matching the current time may be determined with reference to the following formula:

wherein M is_recommandAnd d represents the optimal humidity value, and d represents the corresponding days of the current time in one year, specifically, the current time can be converted to determine the corresponding days, for example, if the current time is 2021 year, 1 month and 5 days, which indicates that the current time is the 5 th day of 2021 year, then d has a value of 5. It is understood that 44%, 47%, 45%, and 48% of the above formulas are humidity values in a feasible implementation manner, and in practical applications, the above optimal humidity value may also be adjusted according to practical situations, and further, different formulas may also be set for different regions to match the humidity variation trend generated by the local geographic environment, which is not described herein again.

It should be noted that the humidity values referred to are relative humidity, which is the percentage of the water vapor pressure in the air to the saturated water vapor pressure at the same temperature.

In a possible implementation manner, the user humidity value set by the user may be adjusted by using the optimal humidity value as follows: the user humidity value and the optimal humidity value are used for weighting calculation to obtain an expected humidity value of the humidifier, wherein the weighting calculation may use weighting coefficients corresponding to the user humidity value and the optimal humidity value respectively, and specifically, the weighting calculation may be performed according to the following formula:

M_final＝p·M_user+q·M_recommand

wherein M is_ftnalRepresenting a desired humidity value, M, of the humidifier_userIndicating a user-set user humidity value, M_recommandRepresenting the best humidity value to match the current time, p and q are weighting factors, and in one possible approach p may be 0.7 and q may be 0.3.

In the embodiment of the present invention, after obtaining the desired humidity value, the humidifier performs humidification control according to the desired humidity value and the target humidity value of the humidity acquisition device, where the humidification control includes air speed adjustment, atomization direction adjustment, and atomization power adjustment, which will be described below.

Referring to FIG. 6, a flow chart of the step of refining step 505 in the embodiment shown in FIG. 5 is shown, which includes:

601, sequencing target humidity values of a remote humidity acquisition device in the humidity acquisition devices in a descending order to obtain a first humidity value sequence;

step 602, adjusting the wind speed of the humidifier according to the first humidity value sequence and the expected humidity value.

In the embodiment of the invention, the target humidity values of all the far-end humidity acquisition devices in the humidity acquisition devices are used for adjusting the wind speed, and the target humidity values of the near-end humidity acquisition devices are not needed, because the target humidity values of the far-end humidity acquisition devices can better reflect the influence of the change of the wind speed on the humidity values, and the influence of the change of the wind speed on the humidity values acquired by the near-end humidity acquisition devices is very small and even can be ignored, therefore, the target humidity values of the far-end humidity acquisition devices are used for adjusting the wind speed of the humidifier, the accuracy of controlling the humidifier can be effectively improved, and the humidification control effect is improved.

In a possible implementation manner, when the value of K is 1, it indicates that a remote humidity acquisition device is present, and it may be determined whether a target humidity value of the first humidity value sequence is greater than or equal to the desired humidity value, and if the target humidity value is greater than or equal to the desired humidity value, the wind speed of the fan may be controlled to be adjusted to a preset first wind speed, where the wind speed value of the first wind speed is lower. In addition, if the target humidity value is less than the desired humidity value, the wind speed of the fan may be controlled to be adjusted to a third wind speed, and the third wind speed is greater than the first wind speed, for example, the third wind speed may be a high-grade wind speed.

In another possible implementation manner, when the value of K is 2, the target humidity values of the two humidity acquisition devices exist in the first humidity value sequence, the magnitude relationship between the 2 nd target humidity value and the expected humidity value may be determined first, and if the 2 nd target humidity value is greater than or equal to the expected humidity value, the wind speed of the fan is controlled to be adjusted to the preset first wind speed, for example, the first wind speed may be the low-gear wind speed. If the 2 nd target humidity value is less than the expected humidity value, the magnitude relationship between the 1 st target humidity value and the expected humidity value is further determined, and if the 1 st target humidity value is greater than or equal to the expected humidity value, the wind speed of the fan can be controlled to be adjusted to a preset second wind speed, wherein the second wind speed is greater than the first wind speed, and the second wind speed is less than a third wind speed, for example, the second wind speed can be a middle-gear wind speed. If the 2 nd target humidity value is smaller than the desired humidity value, and the 1 st target humidity value is also smaller than the desired humidity value, it indicates that the humidity value of the humidifier is low, and at this time, the humidity value needs to be increased.

In another possible implementation manner, when K is greater than or equal to 3, the step 602 may include:

a1, obtaining a Kth target humidity value, an [ s X K ] th target humidity value and an [ m X K ] th target humidity value in the first humidity value sequence, wherein K is the total number of the target humidity values contained in the first humidity value sequence, K is not less than 3, m and s are both less than 1 and greater than 0, s is greater than m, and the symbol [ ] represents a rounded operator;

a2, adjusting the wind speed of the humidifier according to the Kth target humidity value, [ s x K ] th target humidity value, [ m x K ] th target humidity value and the expected humidity value.

In the embodiment of the present invention, if there are K target humidity values in the first humidity value sequence and K is greater than or equal to 3, a kth target humidity value, an [ s × K ] th target humidity value, and an [ m × K ] th target humidity value in the first humidity value sequence may be obtained, where s and m are both numerical values smaller than 1 and greater than 0 and s is greater than m, where the symbol [ ] indicates a rounding operator, for example, if m × K is 4.2, then [ m × K ] is 5, and if m × K is 5.8, then [ m × K ] is 6.

In a possible implementation manner, s may be 2/3, m may be 1/3, and in this case, the target humidity value is taken as three equal parts, and in practical applications, the values of s and m may also be determined as needed, which is not limited herein.

After the Kth target humidity value, the [ s X K ] th target humidity value and the [ m X K ] th target humidity value are obtained, the Kth target humidity value and the expected humidity value can be compared, when the Kth target humidity value is larger than or equal to the expected humidity value, the minimum humidity value is larger than the expected humidity value, the humidity value needs to be reduced, and the operation of closing the fan can be executed; when the Kth target humidity value is smaller than the expected humidity value, the relation between the [ s X K ] th target humidity value and the expected humidity value is further determined, and when the [ s X K ] th target humidity value is larger than or equal to the expected humidity value, the target humidity values in the first humidity value sequence are indicated to be larger overall, and at this time, the humidity values can be reduced appropriately, and the wind speed of the fan can be controlled to be adjusted to a preset first wind speed, wherein the wind speed value of the first wind speed is smaller, such as the low-gear wind speed.

When the [ s × K ] th target humidity value is smaller than the expected humidity value, the magnitude relation between the [ m × K ] th target humidity value and the expected humidity value is further judged, when the [ s × K ] th target humidity value is smaller than the expected humidity value and the [ m × K ] th target humidity value is larger than or equal to the expected humidity value, the current humidity value is indicated to be proper, the wind speed of the fan can be controlled to be adjusted to a preset second wind speed, and the second wind speed is larger than the first wind speed and can be the middle-gear wind speed. When the [ m × K ] th target humidity value is smaller than the expected humidity value, it indicates that the humidity value in the effective humidification range of the humidifier is low, and the humidity value needs to be increased, and the wind speed of the fan can be controlled to be adjusted to a preset third wind speed, for example, the third wind speed can be a high-grade wind speed.

It can be understood that the first humidity value sequence is obtained by sorting the target humidity values of the remote humidity acquisition device from large to small, and three target humidity values capable of representing the humidity value change trend are extracted from the first humidity value sequence.

In the embodiment of the invention, the aim of adjusting the wind speed by using the target humidity value of the remote humidity acquisition device can be effectively fulfilled by the mode, and the adjustment accuracy is high and the effect is good.

Referring to FIG. 7, a flow chart of another step of the step 505 of the embodiment shown in FIG. 5 is shown, which includes:

step 701, sequencing target humidity values of the humidity acquisition devices in a descending order to obtain a second humidity value sequence;

step 702, obtaining an nth target humidity value, an [ a × N ] th target humidity value and a [ b × N ] th target humidity value in the second humidity value sequence;

wherein N is the total number of target humidity values contained in the second humidity value sequence, a and b are both less than 1 and greater than 0, a is greater than b, and the symbol [ ] represents a rounded operator;

step 703, adjusting the atomization power of the humidifier according to the nth target humidity value, the [ a × N ] th target humidity value, the [ b × N ] th target humidity value and the expected humidity value.

In the embodiment of the present invention, for the humidity acquisition devices within the effective humidification range of the humidifier, the target humidity values of the humidity acquisition devices are sorted in descending order to obtain the second humidity value sequence, and it can be understood that, if the humidity acquisition devices within the effective humidification range of the humidifier are far-end humidity acquisition devices, the target humidity values of the far-end humidity acquisition devices are sorted, and if near-end humidity acquisition devices are further included, the target humidity values of the far-end humidity acquisition devices and the target humidity values of the near-end humidity acquisition devices are sorted.

If there are N target humidity values in the second humidity value sequence, then the nth target humidity value, the [ a × N ] th target humidity value, and the [ b × N ] th target humidity value in the second humidity value sequence may be obtained, where a and b are both numerical values smaller than 1 and larger than 0, and a is larger than b, where the symbol [ ] represents a rounded-up operator, for example, if a × N is 4.2, then [ a × N ] is 5, and if a × N is 5.8, then [ a × N ] is 6.

In a possible implementation manner, a may be 2/3, and b may be 1/3, and in this case, the target humidity value is taken as three equal parts, and in practical applications, the values of a and b may also be determined as needed, which is not limited herein.

In the embodiment of the invention, the magnitude relation between the Nth target humidity value and the expected humidity value is firstly judged, when the Nth target humidity value is greater than or equal to the expected humidity value, the minimum humidity value is larger than the expected humidity value, the humidity value in the effective humidification range of the humidifier is overhigh, and in order to reduce the humidity value in the effective humidification range, the operation of closing the atomizing sheet can be executed.

When the nth target humidity value is smaller than the expected humidity value, the magnitude relation between the [ a × N ] th target humidity value and the expected humidity value is judged, when the nth target humidity value is smaller than the expected humidity value, if the [ a × N ] th target humidity value is larger than or equal to the expected humidity value, the current humidity value in the effective humidification range of the humidifier is indicated to be higher, in order to reduce the humidity value in the effective humidification range, the power of the atomizing sheet can be controlled to be adjusted to be the preset first power, in a feasible implementation mode, the atomizing power of the humidifier can be divided into three levels, namely low-level power, middle-level power and high-level power, when the nth target humidity value is smaller than the expected humidity value and the [ a × N ] th target humidity value is larger than or equal to the expected humidity value, the current humidity value in the effective humidification range is indicated to be higher, but the atomizing sheet does not need to be closed, at this time, the power of the atomizing plate may be adjusted to a low power, that is, the first power may be a preset low power.

Under the condition that the Nth target humidity value is smaller than the expected humidity value, if the [ a x N ] th target humidity value is determined to be smaller than the expected humidity value, the magnitude relation between the [ b x N ] th target humidity value and the expected humidity value is further judged, and when the [ a x N ] th target humidity value is smaller than the expected humidity value and the [ b x N ] th target humidity value is larger than or equal to the expected humidity value, the humidity value in the effective humidification range of the humidifier is not too high or too low at the moment, and in order to realize smooth reduction of the humidity value in the effective humidification range, the power of the atomizing sheet can be controlled to be adjusted to be the preset second power; the second power is greater than the first power, and in an implementation manner, the second power may be a predetermined middle power.

Further, when the nth target humidity value is smaller than the desired humidity value and the [ a × N ] th target humidity value is also smaller than the desired humidity value, if it is determined that the [ b × N ] th target humidity value is also smaller than the desired humidity value, which indicates that the maximum humidity value is also smaller than the desired humidity value, the humidity within the effective humidification range of the humidifier is low, and in order to enable the humidity value to be increased quickly, the power of the atomizing plate may be controlled to be adjusted to a preset third power, where the third power is greater than the second power, and in an implementation manner, the third power may be a preset high-level power.

It can be understood that, by sorting the target humidity values in descending order to obtain a second humidity value sequence, and extracting three target humidity values capable of representing the trend of humidity value change from the second humidity value sequence, in a feasible manner, the three target humidity values can be extracted in three equal parts according to the number in the second humidity value sequence, so that the three target humidity values can be used to realize the adjustment of power, and the adjustment of power follows the principle that the higher the humidity value is, the lower the power is, so that the adjustment of power to the atomizing plate can be effectively realized.

It is understood that the above describes the way to realize the power adjustment of the atomizing plate when N is greater than 3, and in other scenarios, N may also be 1 or 2, which will be described below.

If N is equal to 1, it indicates that there is one humidity acquisition device, the target humidity value of the humidity acquisition device may be compared with the desired humidity value, and if the target humidity value is greater than or equal to the desired humidity value, the power of the atomizing plate may be adjusted to the first power, which may be the low-grade power, for example, and if the target humidity value is less than the desired humidity value, the power of the atomizing plate may be adjusted to the third power, which may be the high-grade power, for example.

When N is equal to 2, it indicates that two humidity acquisition devices exist, the target humidity value of the 2 nd humidity acquisition device is compared with the expected humidity value, if the target humidity value of the 2 nd humidity acquisition device is greater than or equal to the expected humidity value, the power of the atomizing sheet is adjusted to be the first power, if the target humidity value of the 2 nd humidity acquisition device is less than the expected humidity value, the target humidity value of the 1 st humidity acquisition device is further compared with the expected humidity value, if the target humidity value of the 1 st humidity acquisition device is greater than or equal to the expected humidity value, the power of the atomizing sheet is adjusted to be the second power, for example, the middle-grade power, if the target humidity value of the 1 st humidity acquisition device is less than the expected humidity value, the power of the atomizing sheet is adjusted to be the third power, for example, the high-grade power mentioned above.

Further, the atomization direction adjustment can be realized by utilizing the second humidity value sequence, for example, the target direction of the humidity acquisition device corresponding to the nth target humidity value in the second humidity value sequence relative to the humidifier can be acquired, and the atomization direction is adjusted to the target direction.

It can be understood that, when the humidifier is subjected to humidification control, one type of adjustment, or any two types of adjustments, or both types of adjustments may be implemented in the above-mentioned air velocity adjustment, atomization power adjustment, and atomization direction adjustment, and in practical applications, which adjustments are to be performed may be determined according to specific needs, which is not limited herein.

Please refer to fig. 8, which is a schematic structural diagram of a control device of a humidifier in an embodiment of the present invention, including:

an obtaining module 801, configured to obtain an initial humidity value and a distance value between a humidity acquisition device and a humidifier, where the initial humidity value and the distance value are acquired by the humidity acquisition device within an effective humidification range of the humidifier, the humidity acquisition device includes at least one far-end humidity acquisition device, and the far-end humidity acquisition device is a humidity acquisition device whose distance value to the humidifier is not equal to zero;

the simulation module 802 is configured to simulate and calculate a target humidity value when the humidity acquisition device is located at the position of the humidifier according to the initial humidity value and the distance value of the humidity acquisition device;

and the control module 803 is configured to perform humidification control on the humidifier according to the target humidity value of the humidity acquisition device.

In the embodiment of the present invention, the obtaining module 801, the simulating module 802, and the control module 803 included in the control device of the humidifier may refer to the related contents in the foregoing method embodiments, which are not described herein again.

In the embodiment of the invention, the control device of the humidifier can acquire the initial humidity value acquired by the humidity acquisition device positioned in the effective humidification range of the humidifier and the distance value between the humidity acquisition device and the humidifier, wherein the humidity acquisition device comprises at least one humidity acquisition device with a distance value not equal to zero from the humidifier, so that the initial humidity value acquired in the effective humidification range of the humidifier can be normalized in a mode of calculating a target humidity value when the humidity acquisition device is positioned at the position of the humidifier through simulation, and the initial humidity value is used for realizing accurate humidification control of the humidifier, so that the overall humidity condition in the effective humidification range of the humidifier can be considered in the humidification control process, and the humidification effect of the humidification control is effectively improved.

Further, the simulation module includes:

the coefficient acquisition module is used for acquiring a preset normalization coefficient value, wherein the normalization coefficient value is a humidity adjustment coefficient value used for simulating that the humidity acquisition device is positioned at the position of the humidifier;

and the target determination module is used for calculating the product of the distance value of the far-end humidity acquisition device and the normalization coefficient value, and taking the sum of the product and the initial humidity value of the far-end humidity acquisition device as the target humidity value of the far-end humidity acquisition device.

Further, the control device of the humidifier further includes:

a humidity value obtaining module, configured to obtain a user humidity value set by a user and an optimal humidity value matched with the current time after the simulation module 802;

the calculation module is used for performing weighting calculation by utilizing the user humidity value and the optimal humidity value to obtain an expected humidity value of the humidifier;

and the control module 803 is specifically configured to: and carrying out humidification control on the humidifier according to the expected humidity value and the target humidity value of the humidity acquisition device.

Further, the control module 803 includes:

the first sequencing module is used for sequencing target humidity values of a far-end humidity acquisition device in the humidity acquisition devices from large to small to obtain a first humidity value sequence;

and the wind speed adjusting module is used for adjusting the wind speed of the humidifier according to the first humidity value sequence and the expected humidity value.

Wherein, the wind speed adjustment module specifically includes:

a first obtaining module, configured to obtain a kth target humidity value, an [ s × K ] th target humidity value, and an [ m × K ] th target humidity value in the first humidity value sequence, where K is a total number of target humidity values included in the first humidity value sequence, and K is not less than 3, m and s are both less than 1 and greater than 0, s is greater than m, and a symbol [ ] represents a round-to-the-large operator;

and the first adjusting module is used for adjusting the wind speed of the humidifier according to the Kth target humidity value, the [ s ] K ] th target humidity value, the [ m ] K ] th target humidity value and the expected humidity value.

The first adjusting module is specifically configured to:

performing an operation of turning off the fan when the Kth target humidity value is greater than or equal to a desired humidity value;

when the Kth target humidity value is smaller than the expected humidity value and the [ s x K ] th target humidity value is larger than or equal to the expected humidity value, controlling the wind speed of the fan to be adjusted to a preset first wind speed;

when the [ s x K ] th target humidity value is smaller than the expected humidity value and the [ m x K ] th target humidity value is larger than or equal to the expected humidity value, controlling the wind speed of the fan to be adjusted to a preset second wind speed; the second wind speed is greater than the first wind speed;

and when the [ m × K ] th target humidity value is smaller than the expected humidity value, controlling the wind speed of the fan to be adjusted to a preset third wind speed, wherein the third wind speed is larger than the second wind speed.

In addition, the control module 803 further includes:

the second sorting module is used for sorting the target humidity values of the humidity acquisition device from large to small to obtain a second humidity value sequence;

a second obtaining module, configured to obtain an nth target humidity value, an [ a × N ] th target humidity value, and a [ b × N ] th target humidity value in the second humidity value sequence, where N is a total number of target humidity values included in the second humidity value sequence, N is not less than 3, a and b are both less than 1 and greater than 0, a is greater than b, and a [ ] indicates a round-to-large operator;

and the power adjusting module is used for adjusting the atomization power of the humidifier according to the Nth target humidity value, the [ a ] th target humidity value, the [ b ] th target humidity value and the expected humidity value.

Wherein, the power adjustment module is specifically configured to:

when the Nth target humidity value is larger than or equal to the expected humidity value, the operation of closing the atomizing sheet is executed;

when the Nth target humidity value is smaller than the expected humidity value and the [ a x N ] th target humidity value is larger than or equal to the expected humidity value, controlling the power of the atomizing sheet to be adjusted to a preset first power;

when the [ a × N ] th target humidity value is smaller than the expected humidity value and the [ b × N ] th target humidity value is greater than or equal to the expected humidity value, controlling the power of the atomizing sheet to be adjusted to a preset second power;

and when the [ b × N ] th target humidity value is smaller than the expected humidity value, controlling the power of the atomizing plate to be adjusted to a preset third power, wherein the first power is smaller than the second power, and the second power is smaller than the third power.

Further, the control device may further include:

the direction determining module is used for determining the target direction of the far-end humidity acquisition device corresponding to the Nth target humidity value in the second humidity value sequence relative to the humidifier;

and the direction adjusting module is used for adjusting the atomizing direction of the humidifier to be the target direction.

It can be understood that, the relevant contents of each module in the control device of the humidifier are described in detail in the foregoing method embodiments, and specific reference may be made to the contents in the foregoing method embodiments, which are not described herein again.

In an embodiment of the present invention, a computer-readable storage medium is further provided, which stores a computer program, and when the computer program is executed by a processor, the computer program causes the processor to execute the relevant steps in the foregoing method embodiments.

The embodiment of the present invention further provides a computer device, which includes a memory and a processor, where the memory stores a computer program, and when the computer program is executed by the processor, the processor is enabled to execute the relevant steps in the foregoing method embodiments.

FIG. 9 is a diagram illustrating an internal structure of a computer device in one embodiment. The computer device may specifically be a humidifier, or may be another device capable of interacting with the humidifier to control the humidifier. As shown in fig. 9, the computer device includes a processor, a memory, and a network interface connected by a system bus. Wherein the memory includes a non-volatile storage medium and an internal memory. The non-volatile storage medium of the computer device stores an operating system and may also store a computer program, which, when executed by the processor, causes the processor to carry out the steps of the above-described method embodiments. The internal memory may also store a computer program, which, when executed by the processor, causes the processor to perform the steps of the above-described method embodiments. Those skilled in the art will appreciate that the architecture shown in fig. 9 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, which can be stored in a non-volatile computer-readable storage medium, and can include the processes of the embodiments of the methods described above when the program is executed. Any reference to memory, storage, database, or other medium used in the embodiments provided herein may include non-volatile and/or volatile memory, among others. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDRSDRAM), Enhanced SDRAM (ESDRAM), Synchronous Link DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

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

Claims (12)

1. A method of controlling a humidifier, the method comprising:

acquiring an initial humidity value acquired by a humidity acquisition device positioned in an effective humidification range of the humidifier and a distance value between the humidity acquisition device and the humidifier, wherein the humidity acquisition device comprises at least one far-end humidity acquisition device, and the far-end humidity acquisition device is a humidity acquisition device of which the distance value between the far-end humidity acquisition device and the humidifier is not equal to zero;

according to the initial humidity value and the distance value of the humidity acquisition device, simulating and calculating a target humidity value when the humidity acquisition device is located at the position of the humidifier;

and carrying out humidification control on the humidifier according to the target humidity value of the humidity acquisition device.

2. The method according to claim 1, wherein the simulating calculation of the target humidity value when the humidity acquisition device is located at the position of the humidifier according to the initial humidity value and the distance value of the humidity acquisition device comprises:

acquiring a preset normalization coefficient value, wherein the normalization coefficient value is a humidity adjustment coefficient value used for simulating that the far-end humidity acquisition device is positioned at the position of the humidifier;

calculating the product of the distance value of the far-end humidity acquisition device and the normalization coefficient value, and taking the sum of the product and the initial humidity value of the far-end humidity acquisition device as the target humidity value of the far-end humidity acquisition device;

and if the humidity acquisition device further comprises a near-end humidity acquisition device, taking the initial humidity value of the near-end humidity acquisition device as the target humidity value of the near-end humidity acquisition device.

3. The method of claim 1, wherein the controlling humidification of the humidifier according to the target humidity value of the humidity acquisition device further comprises:

acquiring a user humidity value set by a user and an optimal humidity value matched with the current time;

performing weighting calculation by using the user humidity value and the optimal humidity value to obtain an expected humidity value of the humidifier;

then, performing humidification control on the humidifier according to the target humidity value of the humidity acquisition device, including:

and carrying out humidification control on the humidifier according to the expected humidity value and the target humidity value of the humidity acquisition device.

4. The method of claim 3, wherein said controlling humidification of said humidifier based on said desired humidity value and said target humidity value of said humidity acquisition device comprises:

sequencing target humidity values of a far-end humidity acquisition device in the humidity acquisition devices in a descending order to obtain a first humidity value sequence;

and adjusting the wind speed of the humidifier according to the first humidity value sequence and the expected humidity value.

5. The method of claim 4, wherein the adjusting the wind speed of the humidifier according to the first sequence of humidity values and the desired humidity value comprises:

acquiring a Kth target humidity value, an [ s X K ] th target humidity value and an [ m X K ] th target humidity value in the first humidity value sequence, wherein K is the total number of the target humidity values contained in the first humidity value sequence, K is not less than 3, m and s are both less than 1 and greater than 0, s is greater than m, and a symbol [ ] represents a rounded operator;

and adjusting the wind speed of the humidifier according to the Kth target humidity value, the [ s X K ] th target humidity value, the [ m X K ] th target humidity value and the expected humidity value.

6. The method of claim 5, wherein said adjusting the wind speed of the humidifier based on the Kth target humidity value, the [ s X K ] th target humidity value, the [ m X K ] th target humidity value, and the desired humidity value comprises:

performing an operation of turning off the fan when the Kth target humidity value is greater than or equal to a desired humidity value;

when the Kth target humidity value is smaller than the expected humidity value and the [ s x K ] th target humidity value is larger than or equal to the expected humidity value, controlling the wind speed of the fan to be adjusted to a preset first wind speed;

when the [ s x K ] th target humidity value is smaller than the expected humidity value and the [ m x K ] th target humidity value is larger than or equal to the expected humidity value, controlling the wind speed of the fan to be adjusted to a preset second wind speed; the second wind speed is greater than the first wind speed;

and when the [ m × K ] th target humidity value is smaller than the expected humidity value, controlling the wind speed of the fan to be adjusted to a preset third wind speed, wherein the third wind speed is larger than the second wind speed.

7. The method according to any one of claims 3 to 6, wherein the humidification controlling the humidifier according to the desired humidity value and the target humidity value of the humidity acquisition device further comprises:

sequencing the target humidity values of the humidity acquisition device from large to small to obtain a second humidity value sequence;

acquiring an Nth target humidity value, an [ a ] N target humidity value and an [ b ] N target humidity value in the second humidity value sequence, wherein N is the total number of the target humidity values contained in the second humidity value sequence, N is not less than 3, a and b are both less than 1 and greater than 0, a is greater than b, and a [ ] represents a rounded operator;

and adjusting the atomization power of the humidifier according to the Nth target humidity value, the [ a ] th target humidity value, the [ b ] th target humidity value and the expected humidity value.

8. The method of claim 7, wherein said adjusting the nebulizing power of the humidifier based on the nth target humidity value, the [ a x N ] th target humidity value, the [ b x N ] th target humidity value, and the desired humidity value comprises:

when the Nth target humidity value is larger than or equal to the expected humidity value, the operation of closing the atomizing sheet is executed;

when the Nth target humidity value is smaller than the expected humidity value and the [ a x N ] th target humidity value is larger than or equal to the expected humidity value, controlling the power of the atomizing sheet to be adjusted to a preset first power;

when the [ a × N ] th target humidity value is smaller than the expected humidity value and the [ b × N ] th target humidity value is greater than or equal to the expected humidity value, controlling the power of the atomizing sheet to be adjusted to a preset second power;

and when the [ b × N ] th target humidity value is smaller than the expected humidity value, controlling the power of the atomizing plate to be adjusted to a preset third power, wherein the first power is smaller than the second power, and the second power is smaller than the third power.

9. The method of claim 7, further comprising:

determining a target direction of a humidity acquisition device corresponding to the Nth target humidity value in the second humidity value sequence relative to the humidifier;

adjusting the atomization direction of the humidifier to the target direction.

10. A control device for a humidifier, the device comprising:

the system comprises an acquisition module, a control module and a control module, wherein the acquisition module is used for acquiring an initial humidity value acquired by a humidity acquisition device positioned in an effective humidification range of the humidifier and a distance value between the humidity acquisition device and the humidifier, the humidity acquisition device comprises at least one far-end humidity acquisition device, and the far-end humidity acquisition device is a humidity acquisition device of which the distance value between the far-end humidity acquisition device and the humidifier is not equal to zero;

the simulation module is used for simulating and calculating a target humidity value when the humidity acquisition device is positioned at the position of the humidifier according to the initial humidity value and the distance value of the humidity acquisition device;

and the control module is used for carrying out humidification control on the humidifier according to the target humidity value of the humidity acquisition device.

11. A computer-readable storage medium, in which a computer program is stored which, when being executed by a processor, causes the processor to carry out the steps of the method according to any one of claims 1 to 9.

12. A computer device comprising a memory and a processor, characterized in that the memory stores a computer program which, when executed by the processor, causes the processor to carry out the steps of the method according to any one of claims 1 to 9.

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