JP2003106981A - Pollution degree investigation system, pollution degree investigation method and detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pollution degree investigation system, a pollution degree investigation method and a detector capable of easily investigating a pollution degree in an air conditioner duct. SOLUTION: A personal computer 2 is provided in an office. The personal computer 2 is a communication terminal and it is connected with the Internet 10. A mapping device 4 is connected to the personal computer 2. The detector for adhering dust included in air blown out from the air conditioner duct is provided on the air conditioner duct of the office. Image data of a dust adhering face of the detector is captured by the mapping device 4 and output to the personal computer 2. The personal computer 2 sends the image data to an analyzing server 100 via the Internet. The analyzing server 100 analyzes the pollution degree from the image data and sends an analysis result to the personal computer 2.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pollution degree inspection system suitable for use in investigating the degree of contamination in an air conditioning duct,
The present invention relates to a pollution degree investigation method and a detection device.

[0002]

2. Description of the Related Art In recent years, air pollution has become a problem not only outdoors but also indoors such as offices and homes. One of the major causes of indoor air pollution is air conditioning system pollution. Specifically, this air conditioning system sends air into the room through an air conditioning duct using an air conditioner, and over time, the air conditioner becomes dirty, dust and rust accumulate in the air conditioning duct, and The air flowing in the air-conditioning duct is polluted by the generation of gas from the deposits.

When the air is polluted, it may have various adverse effects on the human body of the person in the room (for example, allergic diseases, bronchitis, etc.), and in a workplace handling fire, inside the air conditioning duct. A fire may occur due to the ignition of sparks on the sediments. Therefore, in recent years,
It is becoming important to regularly check the degree of pollution in the air conditioning duct.

In the investigation of the degree of pollution in the air conditioning duct,
Approximately 90% or more of the air conditioning duct is blocked by the ceiling or walls, and the entire air conditioning duct cannot be seen directly from the air outlet, so observation is performed using a dedicated surveying device such as a small robot equipped with a mapping device or an endoscope. Is being done.

[0005]

As described above, in order to investigate the degree of pollution in the air conditioning duct, a dedicated device for investigation is often required, and a specialist must be entrusted with the inspection of the degree of pollution in the air conditioning duct. However, there is a problem that it is not something that an individual can easily investigate because he cannot obtain it. In addition, because it is difficult to conduct an individual-level survey, many buildings do not have a contamination inspection inside the air-conditioning duct. As a result, as described above, indoor air pollution progresses more and more. May be adversely affected and may cause an unexpected disaster.

The present invention has been made in view of the above-mentioned circumstances, and an object of the present invention is to provide a pollution degree inspection system, a pollution degree inspection method, and a pollution degree inspection method capable of easily inspecting the pollution degree in an air conditioning duct. It is to provide a detection device.

[0007]

In order to achieve the above object, a pollution degree survey system according to the present invention is a system for examining the degree of pollution in an air conditioning duct, and is installed near the outside of the air outlet of the air conditioning duct. The detection device for detecting the state of the air blown out from the air outlet, the communication terminal to obtain the detection result from the detection device, and the detection result via the network from the communication terminal, the detection result from the An analysis server for analyzing the degree of pollution in the air conditioning duct and transmitting the analysis result to a specific communication terminal via a network.

In order to achieve the above-mentioned object, the pollution degree investigation method of the present invention is a method for investigating the pollution degree in an air conditioning duct, in which an analysis server is attached near the outside of the air outlet of the air conditioning duct. A first step of acquiring a detection result of a detection device that detects the state of air blown from the air outlet from a communication terminal via a network, and analyzing the degree of pollution in the air conditioning duct from the acquired detection result. And a third step of transmitting the analysis result to the communication terminal via the network.

In order to achieve the above object, the detection device of the present invention is a detection device for detecting the state of the air blown from the air outlet of the air-conditioning duct. A fixing portion fixed by viscous, a support portion provided on the fixing portion, and a detection portion that is supported by the supporting portion and detects the state of the air, and is arranged to face the blowout surface. And a detector.

In order to achieve the above object, another pollution degree inspection system of the present invention is a system for inspecting the pollution degree in an air conditioning duct, which is installed in the vicinity of the outside of the air outlet of the air conditioning duct. A detection device that records information according to the degree of pollution of the air blown from the outlet, a communication terminal that captures the information of the detection device, and the detection result is acquired from the communication terminal via a network, and the detection result. And an analysis server for analyzing the degree of contamination in the air conditioning duct and transmitting the analyzed result to a specific communication terminal via a network.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. In the following description, a case of investigating the degree of contamination in the air conditioning duct installed in the office will be described.

FIG. 1 is a view showing the arrangement of a pollution degree survey system according to this embodiment. In FIG. 1, a personal computer (hereinafter referred to as “personal computer”) 2 is
It is a communication terminal installed in the office and is connected to the Internet 10. A mapping device 4 is connected to the personal computer 2. The mapping device 4 is, for example, a scanner or a digital camera, and outputs a mapping of a subject to the personal computer 2 as image data.

Further, as shown in FIG. 2, a diffuser 20 is provided at the air outlet of an air conditioning duct (not shown) arranged in the office. The diffuser 20 is a frame member 2
Equipped with 2. The frame member 22 is made of a paramagnetic metal material such as iron, and a large number of fins 24 are provided on the inner periphery of the frame member 22. The fins 24 are thin plate-shaped members extending in the left-right direction in the drawing, and both ends thereof are attached to the inner peripheral side of the frame member 22 so as to be rotatable around the longitudinal direction as an axis. The direction of the air flow blown from the air outlet is adjusted according to the inclination angle of the fins 24.

As shown in FIGS. 2 and 3, a detecting device 50 is attached to the lower side of the front surface of the frame member 22. The detection device 50 collects dust contained in the air blown from the air outlet. To explain further,
If dust accumulates in the air conditioning duct, the accumulated dust is re-scattered due to the effects of vibration and wind pressure when the air conditioning system is started or stopped, and the air is blown out from the air outlet in the air conditioning duct. Come on. In addition, even if dust is accumulated on the air conditioner itself for sending air to the air conditioning duct, this dust also blows out from the air conditioning duct. Therefore, in the present embodiment, the dust blown out from the air outlet is sampled by the detection device 50 over a predetermined period, and the pollution degree in the air conditioning duct is analyzed from the sampled result.

FIG. 4 is a diagram showing the structure of the detection device 50. As shown in FIG.
Have ten. The fixing portion 510 includes a base 512, and a magnet 514 is provided on the bottom surface (the lower surface in the drawing) of the base 512, and the fixing portion 510 is fixed on the frame member 22 by the magnetism of the magnet 514. . Although the fixing portion 510 is magnetically fixed to the frame member 22 in the present embodiment, for example, an adhesive may be applied to the bottom surface of the base 512 to fix the fixing portion 510 by viscous.
Since the fixing portion 510 is magnetically or viscously attached to the diffuser 20, that is, to the outside of the air outlet of the air-conditioning duct in this manner, no complicated attachment work is required when attaching the detection device 50. Work can be performed easily.

On the other hand, as shown in the figure, a supporting portion 520 is provided above the fixing portion 510 in the drawing. The support portion 520 includes, for example, a rod-shaped plastic material 524 such as wire and a hollow cylindrical resin material 522 made of hard vinyl resin or the like.
And the upper end of the plastic material 524 (the upper end in the drawing) is inserted into the resin material 522. Plastic material 52
A lower end portion (an end portion on the lower side of the drawing) of 4 is inserted into the base 512 from the upper side of the drawing and fixed by an adhesive or the like. The plastic material 524 is bendable and can be bent in any direction at any angle.

A detection section 530 is provided at the upper end of the support section 520 (resin material 522). Specifically, as shown in the figure, the upper end portion of the plastic material 524 is made of the resin material 522.
Of the resin material 522, the insertion portion 534 of the detection plate 530 is detachably and loosely inserted.

Further, the detecting section 530 is provided with an adhesive section 532. The adhesive portion 532 is coated with an adhesive and is arranged so as to face the blowout surface of the diffuser 20, and collects the dust contained in the air blown from the diffuser 20 by the adhesive. Further, since the support portion 520 is provided with the plastic material 524 and is deformable, it is necessary to adjust the adhesive portion 532 so as to face the blow surface when the base 512 is attached near the blow outlet of the diffuser 20. You can

Here, as shown in FIG.
It is desirable that the adhesive surface (the surface of the adhesive portion 532) of is held inclined with respect to the direction S of the air flow blown from the air outlet. When the adhesive surface is arranged so as to be orthogonal to the direction S of the air flow, a turbulent flow that prevents the progress of the air flow occurs near the adhesive surface, and it becomes difficult for dust contained in the air flow to adhere to the adhesion surface. .

Therefore, the detection device 50 according to the present embodiment.
Has the following structure in order to hold the adhesive surface so as to be inclined with respect to the direction S of the air flow. That is, as shown in FIG. 6, a cutout portion 522a is provided on the inner peripheral side surface of the resin material 522, while a protrusion portion 534a is provided on the side surface of the insertion portion 534. The detection unit 530 is rotatable within the angle range shown. With this configuration, when the detection unit 530 is arranged to face the air outlet, the detection unit 530 rotates due to the wind pressure of the air flow blown from the air outlet, and the direction S of the air flow is rotated.
It is held in a posture inclined with respect to. As a result, the dust contained in the air flow easily adheres to the adhesive section 532 of the detection section 530.

Now, returning to FIG. 1 again, the pollution degree survey system of this embodiment will be described. In FIG. 1, the mapping device 4 outputs the mapping of the surface of the adhesive portion 532 included in the detection device 50 to the personal computer 2 as image data. The analysis server 100 acquires image data from the personal computer 2,
The degree of contamination in the air conditioning duct is analyzed from this image data. In detail, this analysis server 100 is connected to the Internet 10, and this Internet 1
Image data is acquired from the personal computer 2 via 0, the contamination degree in the air conditioning duct is analyzed from this image data, and the analysis result is transmitted to the personal computer 2. In addition, when exchanging data between the personal computer 2 and the analysis server 100, if the personal computer 2 and the analysis server 100 can recognize each other, for example, HTTP (Hypertext Transfer Protocol).
Any communication protocol such as l) or SMTP (Simple Mail Transfer Protocol) can be used.

FIG. 7 is a diagram showing a functional configuration of the analysis server 100. As shown in the figure, the analysis server 10
In 0, the control unit 210 including a CPU (Central Processing Unit) and the like controls each unit. In addition, the control unit 210 has a RAM (Random Access Mem).
memory and a storage medium such as a ROM (Read Only Memory) for inputting / outputting data, performing various calculations, and temporarily storing data.

Further, the communication I / F unit 230 includes a control unit 21.
Under the control of 0, the transfer of data performed between the analysis server 100 and another communication terminal via the Internet 10 is controlled. Next, the storage unit 240 includes a storage medium such as a magnetic disk or a ROM, and stores and stores the following programs and data. That is, the storage unit 240 stores the control program and the analysis program. Here, the control program indicates a control operation procedure of the control unit 210. The analysis program causes the analysis server 100 to function as a computer that analyzes the degree of contamination in the air conditioning duct based on the detection result of the detection device 50.

FIG. 8 is a sequence diagram showing the operation of the personal computer 2 and the analysis server 100. The operation of this embodiment will be described below with reference to FIG. When investigating the degree of pollution in the air-conditioning duct installed in the office, an employee of the office fixes the detection device 50 to the diffuser 20 and then detects the detection device 5 for a predetermined number of days as shown in FIG.
Leave 0. Then, while the detection device 50 is left unattended, the dust contained in the air blown from the air outlet adheres to the adhesive portion 532 of the detection device 50. Here, the detection device 5
The number of days to leave 0 can be arbitrarily set as long as it is the number of days that the dust contained in the air adheres to the adhesive section 532 to the extent necessary for analysis.

After a predetermined number of days has passed, the employee operates the personal computer 2 to obtain image data of the adhesive surface of the adhesive portion 532 of the detection device 50 (hereinafter referred to as "adhesive surface image data"). Operate the section. When detecting such an operation, the personal computer 2 acquires the adhesive surface image data from the mapping device 4 (step A1). Next, the employee operates the personal computer 2 to send the adhesive surface image data to the analysis server 100. When such an operation is detected, the personal computer 2
Transmits the adhesive surface image data to the analysis server 100 via the Internet 10 (step A2).

Upon acquiring the adhesive surface image data, the control unit 210 of the analysis server 100 executes an analysis process for analyzing the degree of contamination in the air conditioning duct from the adhesive surface image data according to the analysis program. FIG. 9 is a flowchart showing an analysis processing procedure executed by the control unit 210 according to the analysis program. In this analysis process, the control unit 210
Analyzes the contamination degree in the air-conditioning duct from the ratio of the dust area occupied by the adhesive surface indicated by the adhesive surface image data. More specifically, first, the control unit 210 divides the adhesive surface image into image areas in a matrix of m rows and n columns (step B1). Next, the control unit 210 counts the number A of image areas including the dust image, and the count result is the number of image areas m ×
Ratio of dust area to adhesive surface by dividing by n R
(Hereinafter, referred to as pollution degree index R) is determined.

More specifically, first, the control section 210 determines whether or not each of the image areas included in the n-th column contains a dust image. That is, the control unit 210 sets the variable A for counting the number of image areas including the dust image to "0" (step B2), and then sets the variable N for designating the column of the image area to "1". After setting (step B3),
The variable M for designating the row of the image area is set to "1" (step B4). Then, the control unit 210 determines whether or not a dust image is included in the image area designated by the coordinates (M, N) (step B5). Here, since the dust image has a dark color in the adhesive surface image, in step B5, the total number of pixels forming the image region and the number of pixels showing the dark color (for example, each value of RGB is substantially “0”). It is determined that the dust image is included in the image area when the ratio of the pixel image to the image area exceeds a predetermined value (for example, 0.5).

Now, the determination result of step B5 is "Ye
In the case of “s”, the control unit 210 increments the variable A by “1” (step B6), and sets the variable M to “S” in order to make the determination in step B5 for the image area of the next row in the nth column. 1 "is incremented (step B7). On the other hand, if the determination result in step B5 is “No”, it is not necessary to increment the variable A, so the control unit 210 executes the processing procedure in step B5.
Proceed to 7.

Next, the control section 210 determines whether or not the determination in step B5 has been performed for all the image areas included in the nth column. That is, it is determined whether or not the variable M is larger than m (step B8). If the result of this determination is “No”, there is an image region for which the determination has not been made in step B5 in the nth column, so control section 210 returns the processing procedure to step B5.

On the other hand, if the result of the determination in step B8 is "Yes", the control section 210 should perform the determination in step B5 for the image area included in the next column.
Increments the variable N by "1" (step B9). Next, the control unit 210 determines whether the determination in step B5 has been performed for all the columns. That is, it is determined whether or not the variable N is larger than n (step B10). If the result of this determination is “No”, there is still a column for which the determination in step B5 should be made, so the control unit 210 returns the processing procedure to step B5.

On the other hand, if the determination result in step B10 is "Yes", step B5 is performed for all image regions.
Therefore, the control unit 210 sets the variable A to the total number of image areas m × n in order to calculate the contamination index R from the ratio of the dust area occupying the adhesive surface indicated by the adhesive surface image data. The division is performed (step B11). Then
The control unit 210 identifies the pollution degree in the air conditioning duct from the pollution degree index R (step B12), and ends the analysis process.

Here, the degree of contamination in the air conditioning duct in step B12 is specified as follows. That is, the pollution degree in the air-conditioning duct is evaluated in, for example, three levels (three levels of high, normal, and low levels), and the pollution level of each level and the corresponding pollution index R are stored in advance in the storage unit 240.
To remember. Specifically, the pollution degree index R of 0 or more and less than 30 corresponds to "low pollution degree", and is 30 or more and 60 or more.
A pollution degree index R of less than corresponds to "the pollution degree is normal", and a pollution degree index R of 60 or more and 100 or less is stored in the storage unit 240 so as to correspond to "the pollution degree is high".
In this configuration, the control unit 210 stores the contamination degree corresponding to the contamination degree index R obtained in step B11 in the storage unit 2.
It is read from 40 and the contamination degree is specified.

Now, when the pollution degree in the air conditioning duct is specified, the control section 210 transmits the specified pollution degree to the personal computer 2 as an analysis result as shown in FIG. 8 (step A).
4). Here, the control unit 210 may transmit not only the degree of contamination in the specified air conditioning duct but also a comment according to the identified degree of pollution as the analysis result. Specifically, when the control unit 210 specifies that the contamination degree is “high contamination degree”, the control unit 210 sends a comment recommending that the air conditioning duct cleaning be performed. In addition, the control unit 21
No. 0 sends a comment that recommends a more detailed pollution degree survey such as an endoscopic survey even when the pollution degree is specified as “normal pollution degree”. In this way, the analysis server 1
00 sends not only the analysis result but also a comment according to the analysis result, so that it is possible to provide the user with advice according to the analysis result.

As described above, according to the embodiment,
The degree of pollution in the air conditioning duct can be easily investigated.
That is, when investigating the degree of pollution in the air conditioning duct,
The user may install the detection device 50 at the outlet of the air conditioning duct, and transmit the adhesive surface image data of the detection device 50 to the analysis server 100, which is a hassle of requesting a trader to investigate the degree of pollution in the air conditioning duct. There is no need for special work. As a result, in order to investigate the air conditioning duct of the office,
There is no need to interrupt office work. In addition, since the detection device 50 is configured to be magnetically attached near the outside of the air outlet of the air conditioning duct, the user can easily fix the fixing portion 510 of the detection device 50 to the air outlet. Furthermore, as described in the present embodiment, in the detection device 50 that collects dust using an adhesive material,
Even if the user does not operate it, the adhesive portion 532 has a structure in which the adhesive portion 532 is held at an appropriate angle with respect to the flow direction of the air, so that the attaching work becomes easier.

<Modifications and Applications> The above-described embodiments are merely examples, and modifications and applications are possible within the scope of the spirit of the present invention. Therefore, various modifications and applications of the embodiment will be described below.

(1) For example, in the present embodiment, the case where the pollution degree of the air conditioning duct arranged in the office is investigated has been exemplified, but the present invention is not limited to this. That is, it can also be applied to the case of investigating the degree of pollution in a room air conditioner (room air conditioner) system including an air conditioner such as a passenger car.

(2) Further, for example, in the present embodiment, the analysis server 100 calculates the contamination degree index R from the adhesive surface image data to specify the contamination degree in the air conditioning duct. Since the hue of the adhesive surface changes depending on the amount of dust attached to the adhesive portion 532, so-called colorimetric method may be used for analysis. That is, the adhesive portion 53
As the amount of dust adhering to 2 increases, the hue of the adhesive surface becomes
The color changes from light to dark. Therefore, the analysis server 100
The control unit 210 identifies the hue of the adhesive surface from the adhesive surface image data acquired from the personal computer 2 by, for example, taking the average value of the RGB values of the adhesive surface image, and determines the degree of contamination in the air conditioning duct from this hue. Can be specified.

By the way, the mapping device 4 causes the adhesive section 532 to
When the image of the adhesive surface of is converted into data, the RGB values of the data-formed adhesive surface image depend on the characteristics of the mapping device 4. Therefore, even if the analysis server 100 obtains the average of the RGB values of the entire adhesive surface image, the average value also includes the characteristics of the mapping device 4, and thus the average value is used to specify the degree of contamination in the air conditioning duct. You cannot do it. Therefore, in the detection device 50, the vicinity of the adhesive portion 532 is colored in advance with a predetermined color, and when the mapping device 4 converts the mapping into data, this colored part is also included in the mapping (or separately,
Prepare a color sample so that it will be included in the mapping). On the other hand, the analysis server 100 stores RGB values (hereinafter referred to as reference RGB values) of the colored portion in advance, and when analyzing the adhesive surface image data, the RGB value of the colored portion included in the adhesive surface image. The color correction of the entire adhesive surface image data is performed so that becomes the reference RGB value. As a result, the RGB of the adhesive surface image is excluded without including the characteristics of the mapping device 4.
The average value can be calculated.

In this example, the case in which the analysis server 100 specifies the contamination degree in the air conditioning duct from the hue of the adhesive surface image has been described. For example, a color sample in which the hue and the contamination degree are associated with each other is prepared in advance. It may be distributed to users. By doing so, the user can easily know the degree of contamination in the air conditioning duct by checking the hue of the adhesive portion 532 of the detection device 50 with the color sample.

(3) Further, the detecting device 50 of the present embodiment may have the following structure. Figure 1
FIG. 0 is a perspective view showing the configuration of the detection device 60 according to the modified example of the present embodiment. In the figure, the detection plate 600 is
It is a substantially rectangular plate member, and an adhesive material is applied to the plane below the drawing. The detection plate 600 includes the first support member 62.
0 and the second support member 630 detachably hold it in a posture inclined with respect to the flow direction S of the air blown from the outlet of the air conditioning duct.

Specifically, the first support member 620 includes rod members 622a, 622b, 622c assembled in a U-shape, and further includes a column portion 626. The column portion 6
One end of the rod 26 is fixed near the left end of the rod member 626a in the drawing, and the other end of the support column 626 is attached to the rod member 626a.
It is fixed near the left end of the drawing of c. The column 626 holds the upper part of the detection plate 600.

On the other hand, the second support member 630 is provided with rod members 632a, 632b, 632c assembled in a U shape. In addition, the second support member 630 includes a holding plate 634 that is a rectangular plate member, and has an inner circumference of a U-shape and a rod member 6.
It is fixed to the side surface of 32b. The holding plate 634 holds the lower side of the detection plate 600.

Further, the first supporting member 620 and the second supporting member 630 are provided with a fixing portion 610 composed of a magnet, and the first supporting member 620 and the second supporting member 630 are connected to the outlet of the air conditioning duct. It is magnetically fixed to the provided diffuser 20. In such a configuration, the detection plate 6
Since the lower part of 00 is held at a position separated from the upper part of the detection plate 600 in the right direction in the drawing, when the detection device 60 is fixed to the diffuser 20, the adhesive surface of the detection plate 600 is It is held in a posture inclined with respect to the air flow direction S, which prevents the dust from becoming difficult to adhere to the adhesive surface.

Further, the detecting device 50 may be constructed as shown in FIG. FIG. 11 is a perspective view showing a configuration of a detection device 70 according to a modified example of the present invention, and FIG. 12 is a top view of the detection device 70. 11 and 12, the fixing portion 710 is a rectangular plate member, and a plate magnet 710a is provided on the plane on the left side of the drawings. As a result, the fixing portion 710 is fixed to the diffuser by the magnetism of the plate magnet 710a.

On the other hand, a supporting member 720 is provided on the plane portion on the right side of the fixing portion 710 in the drawing. This support material 720
Is an L-shaped bar member, and one side thereof is provided so as to be elongated in the upward direction of the drawing. Further, a detection plate holder 730 formed by folding a flat plate member in a U-shape is provided at the upper end of the support member 720 in the drawing so that the opening is located above the drawing. Further, when the detection plate 600 of the plate member is inserted into the opening of the detection plate holder 730, the flat portion (adhesive surface) of the detection plate 600 is inclined with respect to the direction S of the air flow from the air outlet of the air conditioning duct. As described above, the detection plate 600 is held, so that it is possible to prevent the dust from being difficult to adhere to the adhesive surface.

Further, although the detecting device 50 has a structure in which the dust is collected by using the adhesive material, the dust may be collected by using the air filter. FIG. 13 is a perspective view showing the configuration of the detection device 80 according to the modified example of the present invention. In the figure, the fixed portion 810 is a rectangular plate member, and a plate-shaped magnet 810a is provided on the plane portion on the left side of the drawing. Due to the magnetism of the plate-shaped magnet 810a, the fixing portion 810 is fixed to the diffuser provided at the air outlet of the air conditioning duct. Further, a support member 812 is provided on the flat surface portion of the fixing portion 810 on the right side of the drawing. Support material 8
Reference numeral 12 denotes an L-shaped rod member, which is provided on the fixing portion 810 so that one side is elongated in the upper part of the drawing. Support material 8
A cylindrical member 820 is fixed to the upper end portion of 12.

A detecting portion 830 is detachably provided on the cylindrical member 820. More specifically, the detection unit 8
The ring 30 is provided with a ring-shaped joint 834 made of an elastic material such as rubber. The outer diameter of the joint portion 834 is
The inner diameter of the cylindrical member 820 is approximately the same as that of the cylindrical member 820, and the joint portion 834 is
By being fitted into the support member 820, it is detachably fixed.

The detector 830 has a holding member 836a which is a cylindrical member having a diameter substantially the same as the inner diameter of the joint 834, and a holding member 836b which is a cylindrical member having a diameter substantially the same as the outer diameter of the joint 834.
It has and. In addition, the joint portion 830 has a holding portion 836.
A sheet-like air filter 834 having an area larger than the sectional area of a is provided. This air filter 834
Is provided so as to cover the left end surface of the holding portion 836a in the drawing, and when the holding portion 836a is fitted to the inner peripheral side of the joint portion 832, the air filter 834 and the holding portion 836 are provided.
and a are detachably fixed to the joint. On the other hand, the joint portion 834 is fitted into the holding portion 836b, which makes it easy to grip the detection portion 834.

In such a structure, when the fixing portion 810 is fixed to the diffuser, the air blown out from the air outlet is
Since it passes through the air filter 834, dust contained in the air adheres to the air filter 834. As described above, dust can be easily collected only by providing the detection device 80 on the blowing surface (on the diffuser) of the air outlet of the air conditioning duct. Alternatively, an adhesive material may be used for the fixing portion 810 to attach the detection device 80 to the diffuser due to viscosity.

(4) Next, in the present embodiment, the one in which dust is deposited on the detection portion 530 of the detection device 50 is used, but other than this, for example, a CO ₂ detection sensor or a CO ₂ detection sensor is used.
Various sensors such as a detection sensor and a NOx detection sensor can be used. In this case, the sensor and the personal computer 2 are connected to each other by a signal cable or wirelessly, and the personal computer 2
May obtain the detection signal from the sensor.

[0051]

As described above, according to the present invention, there is provided a pollution degree investigation system, a pollution degree investigation method, and a detection apparatus capable of easily inspecting the pollution degree in the air conditioning duct.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a pollution degree survey system according to an embodiment of the present invention.

FIG. 2 is a diagram for explaining an outlet of the air conditioning duct.

FIG. 3 is a diagram showing a configuration of the detection device.

FIG. 4 is a perspective view showing a configuration of the detection device.

FIG. 5 is a diagram for explaining a mounting mode of the detection device.

FIG. 6 is a diagram for explaining the structure of the detection device.

FIG. 7 is a diagram showing a functional configuration of the analysis server.

FIG. 8 is a sequence diagram showing the operation of the present embodiment.

FIG. 9 is a flowchart showing the operation of the present embodiment.

FIG. 10 is a diagram showing a configuration of a detection device according to a modified example of the present invention.

FIG. 11 is a perspective view showing a configuration of a detection device according to the modification.

FIG. 12 is a top view showing a configuration of a detection device according to the modification.

FIG. 13 is a perspective view showing a configuration of a detection device according to the modification.

[Explanation of symbols]

2 ... Personal computer, 4 ... Mapping device, 10 ... Internet, 50 ... Detection device, 100 ... Analysis server,
210 ... Control part, 230 ... Communication I / F part, 240 ... Storage part, 510 ... Fixed part, 520 ... Support part, 530 ... Detection part

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Kazuhiko Omare             14-24, Otsuka-cho, Yukiya, Ota-ku, Tokyo Japan             Inton Co., Ltd. (72) Inventor Shin Shimizu             14-24, Otsuka-cho, Yukiya, Ota-ku, Tokyo Japan             Inton Co., Ltd. (72) Inventor Makoto Komuro             14-24, Otsuka-cho, Yukiya, Ota-ku, Tokyo Japan             Inton Co., Ltd. F term (reference) 2G052 AA03 AA04 AA05 AC12 AD02                       AD32 AD52 BA05 BA22 BA23                       CA02 EA03 GA11 JA07

Claims (13)

[Claims] 1. A system for investigating the degree of pollution in an air-conditioning duct, comprising: a detection device, which is mounted near the outside of the air-conditioning duct and detects the state of air blown out from the air-conditioning duct; A communication terminal that obtains a detection result, obtains the detection result from the communication terminal via a network, analyzes the contamination degree in the air conditioning duct from the detection result, and outputs the analyzed result to a specific communication terminal. A pollution degree survey system, comprising: an analysis server for transmitting via a network. 2. A method for investigating the degree of pollution in an air conditioning duct, wherein an analysis server is installed near the outside of the air outlet of the air conditioning duct, and the detection result of a detection device for detecting the state of the air blown from the air outlet is provided. First from a communication terminal via a network
And a second step of analyzing the degree of pollution in the air conditioning duct from the obtained detection result, and a third step of transmitting the analysis result to the communication terminal via a network. Pollution degree investigation method characterized by. 3. The detection device includes a dust accumulation plate that accumulates dust contained in the air, the analysis server acquires surface image data of the dust accumulation plate in the first step, The pollution degree investigation method according to claim 2, wherein the pollution degree in the air conditioning duct is analyzed from the surface image data in the second step. 4. In the second step, the analysis server divides the surface image indicated by the acquired surface image data into a plurality of image areas, and whether or not each image area contains a dust image. The number of image areas including a dust image is counted, and the contamination degree in the air conditioning duct is analyzed from the count result and the ratio of the total number of image areas. Pollution degree survey method described in. 5. The storage means stores the hue change of the dust accumulation plate of the detection device and the degree of pollution in the air conditioning duct in association with each other, and in the second step, the analysis server acquires the acquired information. The contamination degree investigation method according to claim 3, wherein the contamination degree of the air conditioning duct is analyzed from the hue of the surface image represented by the surface image data. 6. A detection device for detecting a state of air blown from an outlet of an air-conditioning duct, the fixing portion being fixed by magnetism or viscosity near the outside of an outlet surface of the outlet, and provided in the fixing portion. A detection device comprising: a support part; and a detection part, which is supported by the support part and detects the state of the air, and which is arranged to face the blowout surface. 7. The detection unit according to claim 6, further comprising an adhesive surface coated with an adhesive, the adhesive surface being inclined with respect to a flow direction of the air. Detection device. 8. The detection device according to claim 7, wherein the support portion is made of a substantially rod-shaped plastic material and rotatably supports the dust accumulation plate within a predetermined angle range. . 9. The supporting portion is a holding portion provided at one end of the member, the holding portion having a member extending in parallel with the blowing surface when the fixing portion is fixed, and the extending portion of the portion. The detection device according to claim 7, further comprising a holding unit that holds the dust accumulation plate in a posture in which the dust accumulation surface is inclined by a predetermined angle with respect to the present direction. 10. The dust accumulation plate has a substantially rectangular shape, and the fixing portion has a first fixing portion fixed on the blowing surface and a second fixing portion, and The first fixing portion is provided with a first supporting portion that supports an upper end portion of the dust accumulation plate, while the second fixing portion has a posture in which the dust accumulation surface is inclined with respect to the blowing surface. The detection device according to claim 7, further comprising: a second support portion that supports a lower end portion of the dust accumulation plate. 11. A detection device for detecting dust contained in air blown out from an outlet of an air-conditioning duct, comprising: a fixed portion fixed on the blowout surface of the outlet by magnetism or viscosity; A detection device comprising: a support portion provided; and an air filter portion, which is supported by the support portion so as to face the blowout surface and captures dust contained in permeating air. 12. A system for investigating the degree of pollution in an air conditioning duct, the detection device being mounted in the vicinity of the outside of the air outlet of the air conditioning duct and recording information according to the degree of pollution of the air blown from the air outlet. And a communication terminal that captures the information of the detection device, obtain the detection result from the communication terminal via a network, analyze the degree of contamination in the air conditioning duct from the detection result, and specify the analyzed result. And an analysis server for transmitting the same to a communication terminal of the same via a network. 13. The information is recorded as a change in the surface state of a specific portion of the detection device, the communication terminal reads the surface state as image information, and the analysis server reads the image information from the air conditioning duct. 13. The pollution degree survey system according to claim 12, wherein the pollution degree inside is analyzed.