JP2020139665A - Dirt prediction system - Google Patents

Abstract

To provide a dirt prediction system which has high precision of prediction on dirt progression.SOLUTION: A dirt prediction system (SA) is configured to predict dirt progression in an air conditioner, and comprises a computer (P) which acquires information associated with dirt. The computer (P) comprises: an acquisition unit (4) which acquires installation environment data on the air conditioner and dirt data related to the installation environment data; and an estimation unit (5) which uses a dirt prediction model generated based upon the installation environment data and dirt data to estimate progress of dirt from the installation environment data.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to a dirt prediction system for predicting dirt.

As a technique related to stains, the technique described in Patent Document 1 is known. The technique described in Patent Document 1 detects the turbidity of unfiltered water and the turbidity of wash wastewater.

Japanese Unexamined Patent Publication No. 11-290614

By the way, if the dirt in the future is known, countermeasures or countermeasures can be prepared in advance. Therefore, it is preferable that the progress of dirt can be predicted. However, since dirt progresses due to various factors, it is not possible to easily estimate the progress of dirt. An object of the present disclosure is to provide a stain prediction system having high prediction accuracy for the progress of stains.

The dirt prediction system that solves this problem is a dirt prediction system that predicts the progress of dirt in the air conditioner, and includes a computer that acquires information about the dirt. The computer includes the installation environment data of the air conditioner and the installation environment data of the air conditioner. The degree of dirt progress is estimated from the installation environment data by using the acquisition unit that acquires the dirt data related to the installation environment data and the dirt prediction model generated based on the installation environment data and the dirt data. It is provided with an estimation unit. According to this configuration, the dirt prediction model is related not only to the dirt data but also to the installation environment data, so that the prediction accuracy of the dirt progress can be improved.

In the dirt prediction system, the dirt prediction model is generated by machine learning in association with the installation environment data and the dirt data. According to this configuration, the dirt prediction model is generated by machine learning, so that the prediction accuracy can be improved.

In the dirt prediction system, the installation environment data is at least one of temperature, humidity, atmospheric pressure, air cleanliness, area information of the installation location, climate information of the installation location, usage information of the installation location, and peripheral information of the installation location. Includes one. According to this configuration, since these installation environment data are taken into consideration in the prediction of dirt, the prediction accuracy can be improved.

In the dirt prediction system, the dirt data includes at least one of the elapsed time from installation, the operation data of the air conditioner, and the amount of dirt. According to this configuration, information on these stains is added to the prediction of stains, so that the prediction accuracy can be improved.

The dirt prediction system further includes a maintenance time calculation unit that estimates the time when the amount of dirt exceeds the dirt threshold as the maintenance time by using the dirt prediction model. According to this configuration, an appropriate maintenance time can be provided.

In the dirt prediction system, the maintenance time calculation unit outputs the maintenance time to the user terminal. According to this configuration, the user can know the maintenance time without having to go to the information and get it by himself / herself.

Schematic diagram of the dirt prediction system. Top view of the internal structure of the indoor unit. Side view of the internal structure of the indoor unit. The figure which shows the range of adhesion dirt and turbidity in a color wheel. The figure which shows the photographed image. The figure which shows the mask. The figure of the photographed image in which the mask is overlapped. The figure which shows the matching of the template photographed image and the photographed image. The figure which shows the relationship between a template mask and a mask.

Hereinafter, the dirt prediction system SA according to the present embodiment will be described. The dirt prediction system SA predicts the progress of dirt in the air conditioner 20. The dirt prediction system SA includes a computer P for acquiring information on dirt of the air conditioner 20.

The information regarding the dirt of the air conditioner 20 includes at least one of the dirt of the drain pan 26 of the indoor unit 21, the dirt of the bottom frame of the outdoor unit, the dirt of the heat exchanger, and the dirt of the filter. In the present embodiment, the dirt prediction system SA acquires information on the dirt on the drain pan 26 of the indoor unit 21 and predicts the dirt on the drain pan 26.

The computer P may be any computer P that can be calculated based on the data. The computer P may be a server or a personal computer. The computer P is composed of a program and a calculation circuit. Computer P may be connected to network N. In this embodiment, the computer P is connected to the network N.

The computer P includes an acquisition unit 4 and an estimation unit 5.
The acquisition unit 4 may be an input unit including a keyboard, or may be configured as a communication device that communicates with another device via the network N. The other device is, for example, a device for detecting dirt (hereinafter, referred to as “dirt detection device 1”). The acquisition unit 4 may be configured as a storage medium reading device that acquires information from the storage medium, or may be configured to include a communication device and a storage medium reading device. In the present embodiment, the acquisition unit 4 communicates with the calculation unit 12 of the dirt detection device 1 described later via the network N.

The acquisition unit 4 acquires the installation environment data of the air conditioner 20 and the dirt data associated with the installation environment data.
The installation environment data is information on the environment in which the air conditioner 20 is installed. The installation environment data is a set of information in which information on the environment of each of the plurality of air conditioners 20 is collected. In one example, the identification number of the air conditioner 20 and the information on the environment of the air conditioner 20 having the identification number are managed as a set of data. Specifically, the installation environment data is at least one of temperature, humidity, atmospheric pressure, air cleanliness, area information of the installation site, climate information of the installation site, usage information of the installation site, and peripheral information of the installation site. including.

The air temperature, humidity, atmospheric pressure, and air cleanliness may be detected values detected by the air conditioner 20, estimated values estimated from other parameters, or these values. It may be a physical quantity that correlates with the parameter. The area information of the installation location is information on topography such as plains, forests, and coastal areas, and addresses. The climate information of the installation site is information that affects the temperature, rainfall, snowfall, or humidity. The usage information of the installation location is information on the usage of the property in which the air conditioner 20 is installed and information on the usage in the room. Information on the use of the property is, for example, information on restaurants, sports gyms, and the like. Information on indoor uses is, for example, information on kitchens, entrances, conference rooms, and the like. The information around the installation location is information indicating whether or not a dust generation location such as a factory or a road is nearby.

This information may be encoded. Numerical values such as temperature are coded by ranking. The area information of the installation location is distinguished and coded based on the terrain. The climate information of the installation site is distinguished and coded based on the climate. The usage information of the installation location is coded, for example, by distinguishing the usage in descending order of bacterial growth. Information around the installation location is coded, for example, distinguished by the amount of dust. The installation environment data is collected from the calculation unit 12 of the dirt detection device 1 connected to the network N. In addition, the installation environment data is collected by input via the input unit or by reading from the storage medium. The installation environment data obtained from the air conditioner 20 and the identification number of the air conditioner 20 are associated with each other.

The dirt data is information about the dirt of the air conditioner 20. The pollution data is a set of information in which information on the pollution of each of the plurality of air conditioners 20 is collected, and is related to the information on the environment. In one example, the identification number of the air conditioner 20, the information about the environment of the air conditioner 20 having the identification number, and the data about the pollution of the air conditioner 20 having the identification number are managed as a set of data. .. Specifically, the dirt data includes at least one of the elapsed time from installation, the operation data of the air conditioner 20, and the amount of dirt. Examples of the operation data include the operation frequency of the air conditioner 20, the cumulative operation time of the air conditioner 20 from the time of installation, and the cumulative operation time for each operation mode. An example of the amount of dirt is the degree of dirt progress described later. The dirt data is collected from the calculation unit 12 of the dirt detection device 1 connected to the network N. Further, the dirt data is collected by input via the input unit or by reading from the storage medium. The dirt data obtained from the air conditioner 20 and the identification number of the air conditioner 20 are associated with each other.

The estimation unit 5 of the computer P estimates the degree of dirt progress from the installation environment data using the prediction model. The prediction model is generated based on the installation environment data and the dirt data. Specifically, the prediction model is generated by machine learning by associating the installation environment data with the dirt data. The association between the installation environment data and the dirt data indicates that the installation environment data and the dirt data of one air conditioner 20 are managed as a set of data. The prediction model is not generated by machine learning, but may be a rule in which installation environment data and dirt data are associated with each other. The rules are pre-created by the designer based on the correlation between the installation environment data and the dirt data.

In the present embodiment, machine learning shows that the relationship between the installation environment data and the dirt is derived by calculation based on the data including the installation environment data and the dirt data. Examples of machine learning include linear regression, logistic regression, support vector machine, neural network, and the like.

(A) The first example of machine learning using linear regression will be described.
The estimation unit 5 acquires the amount of dirt at different times as dirt data for each environment type. The environment type is a type classified by at least one of the installation environment data, the area information of the installation place, the climate information of the installation place, the usage information of the installation place, and the surrounding information of the installation place. Since the way of progressing dirt changes depending on the environment, dirt data is aggregated for each environment type in this way. For example, the estimation unit 5 acquires these data from the acquisition unit 4. The acquisition unit 4 acquires the amount of dirt from the air conditioner 20 at predetermined time intervals. The estimation unit 5 uses the amount of dirt in the elapsed time from the time of installation as learning data. The estimation unit 5 generates a prediction model by a regression calculation on the amount of dirt with respect to the time. In one example, the prediction model is a linear equation that shows the relationship between the amount of dirt and the time. The estimation unit 5 generates a prediction model for each environment type based on the pollution data for each environment type collected from the plurality of air conditioners 20.

The environment type is a combination of codes assigned to the installation environment data. In the present embodiment, a code is attached to each of the area information of the installation location, the climate information of the installation location, the usage information of the installation location, and the peripheral information of the installation location. The environment type is a combination of these codes. As an example of the environment type, the code name is "ABCD", A indicates the area information of the installation location (for example, a mountain), B indicates the climate information of the installation location (Seto Inland Sea climate), and C indicates the climate. , Indicates the usage information of the installation location (for example, the entrance), and D indicates the peripheral information of the installation location (for example, along the main road). The number of environment types is a number obtained by multiplying the number of codes of A, the number of codes of B, the number of codes of C, and the number of codes of D.

A second example of machine learning using linear regression will be described.
The second example is a modification of the first example. In this example, the pollution data is data acquired for each environment type, and includes the elapsed time from the installation of the air conditioner 20, the operation data of the air conditioner 20, and the amount of pollution.

The estimation unit 5 acquires the operation data of the air conditioner 20 for each elapsed time in addition to the elapsed time from the time of installation and the amount of dirt for each elapsed time. For example, the estimation unit 5 acquires the amount of dirt and operation data from the air conditioner 20. The operation data includes the cumulative operation time after the installation. The estimation unit 5 uses the amount of dirt and operation data in the elapsed time from the time of installation as learning data.

The estimation unit 5 uses the installation environment data and the dirt data as learning data to generate a prediction model for predicting the amount of dirt by machine learning. The prediction model shows the relationship between the amount of dirt and the time. The estimation unit 5 generates a prediction model for each rank of the environment type and the operation status based on the environment type and the operation data collected from the plurality of air conditioners 20.

The rank of the driving situation is set based on the driving data. The higher the cumulative operating time, the higher the rank. The rank of the operating condition may be determined based on the elapsed time from the time of installation and the operating frequency of the air conditioner 20. In one example, the code name for the driving status rank is defined as X. In the second example, the code is defined for each class by classifying according to the environment type and the rank of the driving situation. An example of a class code defined for each environment type and driving status rank is ABCDX. In the second example, a prediction model is generated for each class as described above. That is, the air conditioners 20 in the same environment but different operating conditions are classified into different classes. In this way, since the prediction model is generated for each subdivided class, the prediction accuracy is improved.

(B) Machine learning using logistic regression will be described. Logistic regression predicts the probability that the amount of dirt will exceed the threshold. In logistic regression, the predictive model is a probability function. Learning to obtain a probability function is performed by a known method based on the objective variable and the explanatory variable. In the present embodiment, the objective variable is a value indicating whether or not the dirt amount exceeds the threshold value for the air conditioner 20, and is "1" when the dirt amount is larger than the threshold value, and the dirt amount is If it is below the threshold value, it is "0". The explanatory variables are various installation environment data of the air conditioner 20. The explanatory variables may include the installation environment data of the air conditioner 20 and the operation data of the air conditioner 20.

The estimation unit 5 calculates the probability that the amount of dirt exceeds the threshold value from the installation environment data using the prediction model. For example, in the case of logistic regression, the estimation unit 5 calculates the probability that the amount of dirt exceeds the threshold value by inputting the installation environment data into the probability function.

(C) Machine learning using a support vector machine will be described. The support vector machine predicts the probability that the amount of dirt will exceed the threshold. In a support vector machine, the prediction model is a separation plane (hyperplane). Learning to obtain the separation plane (hyperplane) of the support vector machine is performed by a known method based on the data divided into A class and the data divided into B class. In the present embodiment, the A class includes installation environment data in which the amount of dirt exceeds the threshold value after a predetermined period from the installation of the air conditioner 20, and the B class includes the amount of dirt after a predetermined period from the installation of the air conditioner 20. Includes installation environment data where is less than or equal to the threshold. In this example, the training data for dividing into A class and B class is the installation environment data of the air conditioner 20, but the training data is the installation environment data of the air conditioner 20 and the operation data of the air conditioner 20. There may be.

In the case of the support vector machine, the estimation unit 5 calculates whether the installation environment data belongs to the A group or the B group based on the relationship between the installation environment data and the separation surface. In the present embodiment, the distance between the installation environment data and the separation surface is defined as the probability that the amount of dirt exceeds the threshold value.

(D) Machine learning using a neural network will be described. The neural network predicts the probability that the amount of dirt will exceed the threshold. In a neural network, a prediction model is a neural network of a plurality of units. Learning to obtain the variables (weight variables and bias variables) of the neural network unit is to minimize the sum of the output errors for the output obtained by inputting multiple input data into the training model. The output error is the difference between the teacher data and the output. The method of minimization is performed by a known method. The plurality of input data includes the installation environment data and the pollution data of each of the air conditioners 20. The teacher data is data indicating whether or not the amount of dirt in the air conditioner 20 exceeds the threshold value, is "1" when the threshold value is exceeded, and is "0" when the threshold value is not exceeded.

In the case of a neural network, an output can be obtained by inputting the installation environment data as an input value to the learning model. In the example of the neural network, the output takes a value of 0 or more and 1 or less. In the present embodiment, the output of the learning model is defined as the probability that the amount of dirt exceeds the threshold value.

Preferably, the estimation unit 5 includes a maintenance time calculation unit 6. The maintenance time calculation unit 6 estimates the time when the amount of dirt exceeds the threshold value of dirt as the maintenance time by using the dirt prediction model.

(A) In the first and second examples of linear regression described above, the prediction model is a linear expression with time as a variable. The maintenance time calculation unit 6 calculates the time by selecting one from a plurality of prediction models generated for each environment type and substituting a threshold value into the output term of the selected prediction model. The selection of the prediction model performed by the maintenance time calculation unit 6 is determined by a command based on the user. The threshold value in the output term of the prediction model is determined by a command based on the user.

(B) In the example of learning by logistic regression, the maintenance time calculation unit 6 predicts the time when the amount of dirt exceeds the threshold value based on the probability. In one example, the maintenance time calculation unit 6 calculates the prediction time as a value obtained by multiplying the reciprocal of the probability obtained from the probability function by a time coefficient. The probability obtained from the probability function is a value obtained by inputting the installation environment data of the air conditioner 20 into the probability function.

(C) In the example of learning by the support vector machine, the maintenance time calculation unit 6 predicts the time when the amount of dirt exceeds the threshold value based on the distance between the installation environment data and the separation surface. In one example, the maintenance time calculation unit 6 calculates the predicted time as a value obtained by multiplying the distance between the installation environment data and the separation surface by a time coefficient.

(D) In the example of learning by the neural network, the maintenance time calculation unit 6 may predict the time when the amount of dirt exceeds the threshold value based on the output of the learning model. In one example, the maintenance time calculation unit 6 calculates the predicted time as a value obtained by multiplying the reciprocal of the output by a time coefficient. The output is a value obtained by inputting the installation environment data of the air conditioner 20 into the learning model.

Preferably, when the maintenance time calculation unit 6 calculates the maintenance time, the maintenance time calculation unit 6 outputs the maintenance time to the user terminal 16. Further, the maintenance time calculation unit 6 may output the maintenance time to the user terminal 16 in response to a request from the user terminal 16. More preferably, the maintenance time calculation unit 6 may calculate the maintenance time in consideration of the operation status and the operation plan of the maintenance worker.

The user terminal 16 is, for example, a terminal that can be connected to the network N. The user terminal 16 includes a mobile phone, a notebook-type personal computer, a personal computer, and a tablet-type personal computer.

<Dirt detection device>
An example of the dirt detection device 1 will be described below. The dirt detection device 1 detects dirt on the object 2. The stains in this embodiment include at least one of adherent stains and water turbidity. In the detection of stains, there are cases where adhered stains are detected, cases where turbidity is detected, and cases where adhered stains and turbidity are detected without distinction.

Preferable examples of the object 2 for dirt detection are a container for storing water and a device to which water easily adheres. For example, the object 2 for dirt detection includes the drain pan 26 of the indoor unit 21 of the air conditioner 20, the drain pan of the outdoor unit, the heat exchanger 23 of the indoor unit 21, the heat exchanger of the outdoor unit, the dehumidifying / humidifying water tank, and , The filter of the air conditioner 20. In the present embodiment, the dirt detection device 1 detects dirt on the drain pan 26 of the indoor unit 21 of the air conditioner 20. In this embodiment, the object 2 is a drain pan 26.

The dirt detection device 1 includes a control unit 10. The control unit 10 acquires the captured image 40 of the object 2. The control unit 10 calculates the degree of dirt progress based on the color component of the captured image 40 of the object 2.

The control unit 10 includes an acquisition unit 11 that acquires a captured image 40 of the object 2, and a calculation unit 12 that calculates the degree of stain progress based on the color component of the captured image 40 of the object 2. The acquisition unit 11 is connected to the camera 30. The acquisition unit 11 and the calculation unit 12 may be housed in a case and packaged as one device, and as described below, the acquisition unit 11 and the calculation unit 12 are connected to the network N. , Each installation location may be dispersed. The components of the control unit 10 according to the present embodiment are distributed over the network N.

The acquisition unit 11 is provided on the air conditioner 20 itself or around the air conditioner 20.
The acquisition unit 11 acquires the captured image 40 sent from the camera 30 and stores the captured image 40. The acquisition unit 11 holds the identification information of the object 2 or the device including the object 2. In the present embodiment, the acquisition unit 11 holds the identification information of the air conditioner 20. Preferably, the acquisition unit 11 holds the object 2 or the position information of the device including the object 2. The location information includes the location (latitude and longitude, or address) of the object 2. In the present embodiment, the acquisition unit 11 holds the position information of the air conditioner 20 including the drain pan 26. More preferably, the acquisition unit 11 holds usage information of the device including the object 2. The usage information is information on the usage of the room in which the object 2 is installed, and includes, for example, the type of store. The acquisition unit 11 acquires identification information, position information, and usage information by an input operation. The acquisition unit 11 is connected to the communication unit 13. The communication unit 13 may be a component of the control unit 10.

The communication unit 13 controls communication between the acquisition unit 11 and the calculation unit 12. The communication unit 13 outputs the captured image 40 held in the acquisition unit 11 to the calculation unit 12 based on the internal command and the external command. Preferably, the communication unit 13 outputs at least one of the identification information, the position information, and the usage information held in the acquisition unit 11 to the calculation unit 12 based on the internal command and the external command. The internal command is a command formed at a preset time. For example, the internal command is formed by the internal circuit of the communication unit 13 when a predetermined condition (for example, the reception sensitivity is higher than a predetermined value in radio) is satisfied, or is formed periodically. The external command is a command based on a request from the calculation unit 12 of the cloud server 15. The communication unit 13 and the acquisition unit 11 may be housed in one case.

The installation location of the calculation unit 12 is not limited as long as information can be obtained from the acquisition unit 11. For example, the calculation unit 12 is provided in the cloud server 15 connected to the network N.

As shown in FIG. 1, the dirt detection device 1 may be a component of the air conditioning system S. For example, the air conditioner system S includes a dirt detection device 1 and an air conditioner 20. The air conditioner 20 is connected to the network N via the communication unit 13 of the control unit 10 of the dirt detection device 1.

The air conditioner 20 will be described with reference to FIGS. 2 and 3. FIG. 2 is a plan view of the internal structure of the indoor unit 21 as viewed by removing the upper wall of the indoor unit 21 of the air conditioner 20. FIG. 3 is a side view of the internal structure of the indoor unit 21 as viewed by removing the side wall of the indoor unit 21 of the air conditioner 20.

The model of the air conditioner 20 subject to the dirt inspection is not limited. For example, the ceiling-embedded air conditioner 20 is subject to a dirt inspection. The indoor unit 21 of the ceiling-embedded air conditioner 20 requires time and effort for internal inspection. Therefore, camera monitoring of the indoor unit 21 of the ceiling-embedded air conditioner 20 contributes to improvement of maintenance work efficiency. Therefore, in the present embodiment, the indoor unit 21 of the air conditioner 20 which is a ceiling-embedded type and is connected to the duct behind the ceiling will be described. The indoor unit 21 is connected to the outdoor unit via a refrigerant pipe. The indoor unit 21 is installed behind the ceiling.

As shown in FIGS. 2 and 3, the indoor unit 21 is arranged under the air conditioning control unit 22, the heat exchanger 23, the fan 24, the fan motor 25 for rotating the fan 24, and the heat exchanger 23. The drain pan 26 is provided, a drain pump 27 for discharging the water in the drain pan 26, and a case 28 having a suction port 28a and an outlet 28b. The color of the wall of the drain pan 26 is preferably a color in which stains are conspicuous. The color of the wall of the drain pan 26 is preferably white or a color close to white.

The case 28 is provided with an inspection lid 28c for inspecting the inside of the case 28. The inspection lid 28c is provided near the drain pan 26 and the drain pump 27. The camera 30 is attached to the inside of the inspection lid 28c. The camera 30 is attached to the inspection lid 28c so that at least a part of the bottom of the drain pan 26 is photographed.

The camera 30 includes a photographing unit 31 and a photographing control unit 32 (see FIG. 1). The photographing unit 31 photographs a part of the drain pan 26 at a timing controlled by the photographing control unit 32 to form a captured image 40.

In one example, the photographing unit 31 photographs the drain pan 26 under the condition of a still water surface. The photographing control unit 32 determines whether or not the condition of the still water surface state is satisfied. The still water surface state indicates a state in which the water surface in the drain pan 26 does not move. The imaging control unit 32 determines whether or not the surface is still water, among the changes in the captured image 40 obtained by the operation of the drain pump 27, the rotation of the fan 24, and the comparison of the plurality of continuously captured images 40. , At least one. When the condition of the still water surface state is satisfied, the photographing control unit 32 issues an imaging instruction to the photographing unit 31. For example, the imaging control unit 32 determines the condition of the still water surface state when detecting the adhered dirt.

In another example, the photographing unit 31 photographs the drain pan 26 under the condition of running water. The photographing control unit 32 determines whether or not the condition of the running water state is satisfied. The running water state indicates a state in which the water in the drain pan 26 moves. The photographing control unit 32 determines whether or not the water is flowing based on at least one of the operation of the drain pump 27 and the change in the captured image 40 obtained by comparing the plurality of captured images 40 continuously captured. To do. The shooting control unit 32 issues a shooting instruction to the shooting unit 31 when the condition of running water is satisfied. For example, the photographing control unit 32 determines the condition of the running water state when detecting turbidity as dirt.

The shooting control unit 32 controls the shooting timing as described above. Further, the photographing control unit 32 transmits the photographed image 40 formed by the photographing unit 31 to the acquisition unit 11. The photographing control unit 32 transmits the photographed image 40 to the acquisition unit 11 based on the internal command. The internal command is a preset command.

The captured image 40 is transmitted to the calculation unit 12 as follows. The captured image 40 formed by the photographing unit 31 of the camera 30 is output to the acquisition unit 11 and stored in the storage unit 11a of the acquisition unit 11. The captured image 40 stored in the acquisition unit 11 is transmitted to the calculation unit 12 of the cloud server 15 via the network N by an internal command or an external command of the communication unit 13.

The calculation unit 12 of the control unit 10 will be described with reference to FIG.
The calculation unit 12 quantifies the dirt on the object 2 at the user's command or a predetermined timing. Specifically, the calculation unit 12 calculates the hue for each pixel constituting the captured image 40 of the drain pan 26. When the captured image 40 is an image formed in the RGB format, the calculation unit 12 converts the captured image 40 based on the conversion formula from the RGB format to the HSV format, and determines the hue (H) value for each pixel. obtain.

The dirt on the drain pan 26 will be described. Analyzing the hue of the stain on the drain pan 26, the stain has a reddish yellow-green color (hue 10-30) or green (hue 30-60). The hue of the stain is in the range of 10 or more and 60 or less. The adhered stain is green or a color around green, and the hue of the adhered stain is in the range of 30 or more and 60 or less. The turbidity is yellowish green close to red, and the hue of the turbidity is in the range of 10 or more and less than 30. The hue of the adhered stains and turbidity of the drain pan 26 is different from the hue of the wall of the drain pan 26. Therefore, dirt on the drain pan 26 can be detected based on the hue. Further, since the hue of the adhered stain and the hue of the turbidity are different, the adhered stain and the turbidity can be discriminated by the hue.

In order to accurately detect the dirt on the drain pan 26, it is preferable that the target range 40a for which the dirt is detected is set in the captured image 40. The captured image 40 may include a part of the heat exchanger 23 and a part of the drain pump 27. In this case, the area where the heat exchanger 23 and the drain pump 27 are removed from the captured image 40 is set as the target range 40a for detecting dirt. The target range 40a is preset. The calculation unit 12 detects dirt in the target range 40a.

An example of setting the target range 40a will be described with reference to FIGS. 5 to 9. FIG. 5 is a diagram showing a captured image 40. FIG. 6 is a diagram showing a mask 41. FIG. 7 is a view of the captured image 40 on which the mask 41 is superimposed. In FIG. 7, the dark dot region indicates the adherent dirt region, and the light dot region indicates the turbid region. In the captured image 40 of FIG. 7, it is not possible to clearly distinguish between the area of adhered stains and the area of thin dots visually. FIG. 8 is a diagram showing matching between the template captured image 43 and the captured image 40. FIG. 9 is a diagram showing the relationship between the template mask 42 and the mask 41.

The calculation unit 12 holds a mask 41 for overlaying the captured image 40. The area other than the target range 40a of the photographed image 40 on the mask 41 is black without hue. In the mask 41, the inside of the target range 40a of the captured image 40 is transparent. In the captured image 40 on which the mask 41 is superimposed, the portion other than the target range 40a becomes black. Since the hues of black cannot be associated with each other, the area of the black portion is 0 when the hue area is calculated with respect to the captured image 40. Therefore, when the calculation unit 12 calculates the area of each hue in the entire captured image 40 on which the mask 41 is superimposed, as a result, the area of each hue within the target range 40a of the captured image 40 is calculated. By using the mask 41 in this way, it becomes easy to calculate the area of each hue within the target range 40a of the captured image 40.

The calculation unit 12 holds a template captured image 43 prepared in advance for each model of the air conditioner 20 and a template mask 42 prepared in advance for each model of the air conditioner 20. Even if the model of the air conditioner 20 is the same, the position of the drain pan 26 in the captured image 40 differs depending on the mounting variation of the camera 30. Therefore, it is preferable to use a mask 41 matched to the drain pan 26 of each air conditioner 20 in order to accurately detect the stain on the drain pan 26 that is the target of dirt detection. For example, the calculation unit 12 matches the feature points of the template captured image 43 with the feature points of the captured image 40 to be detected as stains (see FIG. 8), and forms a projective transformation matrix based on the matching result. To do. The calculation unit 12 forms the mask 41 by converting the template mask 42 by the formed projective transformation matrix (see FIG. 9).

The calculation unit 12 calculates the degree of dirt progress as follows. In one example, dirt progression is assessed by enlargement of the dirty area.
(A) In the first example, the calculation unit 12 calculates the degree of dirt progress based on the area of a region within a predetermined hue range in the target range 40a of the captured image 40. Specifically, the calculation unit 12 forms a mask 41 suitable for the captured image 40 based on the template mask 42 as described above. The calculation unit 12 calculates the area of the region within the predetermined hue range in the target range 40a based on the captured image 40 on which the mask 41 is superimposed. For example, when calculating the area of adhered stains, the calculation unit 12 counts the number of pixels having a hue of 30 or more and 60 or less with respect to the captured image 40 on which the mask 41 is superimposed, thereby counting the area of adhered stains. Ask for. When calculating the turbidity area, the calculation unit 12 obtains the turbidity area by counting the number of pixels having a hue of 10 or more and less than 30 with respect to the captured image 40 on which the mask 41 is superimposed. Further, the calculation unit 12 may calculate the total of the area of adhered dirt and the area of turbidity as the area of dirt. The calculation unit 12 outputs the area of dirt as the progress of dirt. The calculation unit 12 may output the area of the adhered dirt as the "progress of the adhered dirt", or the calculation unit 12 may output the area of the turbidity as the "progress of the turbidity".

(B) In the second example, the calculation unit 12 is based on the area ratio of the area of the target range 40a of the captured image 40 to the area of the region within the predetermined hue range in the target range 40a of the captured image 40. Calculate the degree of dirt progress. In this case, the degree of dirt progress is expressed as a percentage. When the degree of dirt progress is 100%, it indicates that the dirt is most progressing.

The operation of this embodiment will be described. The computer P of the dirt prediction system SA acquires the installation environment data of the air conditioner 20 and the dirt data associated with the installation environment data. The computer P has a dirt prediction model generated based on the installation environment data and the dirt data. The computer P estimates the degree of dirt progress from the installation environment data and the dirt data using the prediction model. Installation environment data has been found to have a significant impact on dirt. For example, the progress of dirt on the air conditioner 20 installed in a restaurant is faster than the progress of dirt on the air conditioner 20 installed in an office. Such a difference in the progress of stains is caused by various factors. Therefore, it is difficult to accurately predict the dirt of the air conditioner 20 simply by looking at the change in dirt. In this regard, the dirt prediction model is generated based on the installation environment data and the dirt data. Since the prediction system SA uses such a dirt prediction model, it can predict the progress of dirt with high accuracy.

The effect of this embodiment will be described.
(1) The computer P of the dirt prediction system SA includes an acquisition unit 4 and an estimation unit 5. The acquisition unit 4 acquires the installation environment data of the air conditioner 20 and the dirt data associated with the installation environment data. The estimation unit 5 estimates the degree of dirt progress from the installation environment data by using the dirt prediction model generated based on the installation environment data and the dirt data. According to this configuration, the dirt prediction model is related not only to the dirt data but also to the installation environment data, so that the prediction accuracy of the dirt progress can be improved.

(2) In the dirt prediction system SA, the dirt prediction model is generated by machine learning by associating the installation environment data with the dirt data. According to this configuration, the dirt prediction model is generated by machine learning, so that the prediction accuracy can be improved.

(3) In the dirt prediction system SA, the installation environment data includes temperature, humidity, atmospheric pressure, air cleanliness, area information of the installation location, climate information of the installation location, usage information of the installation location, and peripheral information of the installation location. Includes at least one of. According to this configuration, since these installation environment data are taken into consideration in the prediction of dirt, the prediction accuracy can be improved.

(4) In the dirt prediction system SA, the dirt data includes at least one of the elapsed time from installation, the operation data of the air conditioner 20, and the amount of dirt. According to this configuration, information on these stains is added to the prediction of stains, so that the prediction accuracy can be improved.

(5) Preferably, the dirt prediction system SA further includes a maintenance time calculation unit 6. The maintenance time calculation unit 6 estimates the time when the amount of dirt exceeds the threshold value of dirt as the maintenance time by using the dirt prediction model. According to this configuration, an appropriate maintenance time can be provided.

(6) In the dirt prediction system SA, the maintenance time calculation unit 6 outputs the maintenance time to the user terminal 16. According to this configuration, the user can know the maintenance time without having to go to the information and get it by himself / herself.

<Modification example>
In addition to the above-described embodiments, the stain detection device 1 of the present disclosure may be a combination of, for example, the following modifications and at least two modifications that do not contradict each other.

-In the above embodiment, the machine learning is performed by the computer P of the dirt prediction system SA, but the learning after the prediction model is first generated may be performed by another device. For example, transfer learning may be performed on the prediction model by a computer other than the computer P.

The dirt prediction system SA may be configured to include a computer P and a dirt detection device 1. The dirt prediction system SA may be configured to include a computer P and an air conditioning system S. Further, the air conditioning system S may be configured to include a pollution prediction system SA.

The calculation unit 12 of the dirt detection device 1 may be configured as follows. The calculation unit 12 is configured to be available to a plurality of users. Specifically, the calculation unit 12 is capable of communicating with a plurality of objects 2 and is capable of communicating with a plurality of user terminals 16. The calculation unit 12 holds an address book for managing information transmission between the plurality of objects 2 and the plurality of user terminals 16. The address book associates the identification number of the air conditioner 20 with the user terminal 16 of the user of the air conditioner 20 related to this identification number. When the calculation unit 12 acquires the captured image 40 of the object 2, the shooting time, and the identification number from the acquisition unit 11 and calculates the progress of the stain and the notification item, the calculation unit 12 refers to the address book and stains. The progress and notification items of the above are output to the user terminal 16.

The acquisition unit 11 and the control unit 10 of the dirt detection device 1 may be configured as one unit. Such a dirt detection device 1 is arranged near the air conditioner 20. In this case, the dirt detection device 1 may directly communicate with the user terminal 16 without going through the network N.

The calculation unit 12 of the dirt detection device 1 may be provided in the user terminal 16. The calculation unit 12 may be composed of an application installed in the user terminal 16 and a calculation circuit in the user terminal 16.

The acquisition unit 11 and the calculation unit 12 of the dirt detection device 1 may be provided in the user terminal 16. For example, a personal computer is provided with an acquisition unit 11 and a calculation unit 12. In this case, the acquisition unit 11 is configured as a recording medium reading device or communication device. The calculation unit 12 may be composed of an application and a calculation circuit. The personal computer acquires the captured image 40 by the input operation of the user.

Although the embodiments of this device have been described above, it will be understood that various modifications of the form and details are possible without departing from the purpose and scope of the device described in the claims. ..

SA ... Dirt prediction system P ... Computer 4 ... Acquisition unit 5 ... Estimating unit 6 ... Maintenance time calculation unit 16 ... User terminal 20 ... Air conditioner

Claims (6)

A dirt prediction system (SA) that predicts the progress of dirt on an air conditioner.
Equipped with a computer (P) that acquires information about dirt
The computer (P) has an acquisition unit (4) that acquires the installation environment data of the air conditioner and the dirt data associated with the installation environment data.
A dirt prediction system including an estimation unit (5) that estimates the degree of dirt progress from the installation environment data using a dirt prediction model generated based on the installation environment data and the dirt data. The dirt prediction system according to claim 1, wherein the dirt prediction model is generated by machine learning in association with the installation environment data and the dirt data. The installation environment data includes at least one of temperature, humidity, atmospheric pressure, air cleanliness, regional information of the installation site, climate information of the installation site, usage information of the installation site, and peripheral information of the installation site. The dirt prediction system according to 1 or 2. The dirt prediction system according to any one of claims 1 to 3, wherein the dirt data includes at least one of the elapsed time from installation, the operation data of the air conditioner, and the amount of dirt. The dirt prediction system according to any one of claims 1 to 4, further comprising a maintenance time calculation unit (6) that estimates a time when the amount of dirt exceeds the dirt threshold as a maintenance time using the dirt prediction model. .. The dirt prediction system according to claim 5, wherein the maintenance time calculation unit (6) outputs the maintenance time to the user terminal.