KR20130044437A - Device of automatic spore collection for air born pathogene - Google Patents

Abstract

PURPOSE: A manless spore collection device for aerial infectious pathogenic microorganism is provided to prevent aerial infections by collecting pathogen air spore in a real-time basis and obtain an accurate monitoring data. CONSTITUTION: A manless spore collection device for aerial infectious pathogenic microorganism comprises a base(110), a container cover sliding shuttle(130), and a lifting shuttle(120). The container cover sliding shuttle is mounted on a case(101). If a cover of a culture media which is descended into the case is hung and put on, the container cover sliding shuttle can slide the cover in the right or left side. The base elevation shuttle is mounted on the case. The base elevation shuttle can vertically elevate the base by penetrating through the container cover sliding shuttle. [Reference numerals] (AA) Solar cell board; (BB) Battery

Description

Airborne Pathogenic Microorganisms Unmanned Spore Collection Device {Device of automatic spore collection for air born pathogene}

The present invention relates to an airborne pathogenic microorganism unmanned spore collection device, and more specifically to the airborne diseases generated in the crops by early observation through the spores of the pathogens causing airborne fungal diseases and bacterial diseases occurring in various crops The present invention relates to an airborne pathogenic microorganism unmanned spore collecting device for timely control.

Currently, many plants at home and abroad are known to have caused various bacterial and fungal diseases such as ear blight, spot pattern, wilted, soft, and ulcer disease. There is a trend.

Accordingly, the costs for controlling airborne fungal diseases and bacterial diseases occurring in various crops are increasing.

Therefore, there is a demand for proper control of airborne diseases in a timely manner by predicting pathogens that cause airborne fungal diseases and bacterial diseases.

The present invention has been made in view of the above point, by collecting the airborne fungal disease and bacterial disease pathogen scattering spores occurring in various crops in real time to ensure accurate prediction data to control airborne diseases in a timely manner The purpose of the present invention is to provide an airborne pathogenic microorganism unmanned spore collecting device.

In order to achieve the above object, the present invention comprises a spore collector for collecting pathogen spores scattered in the air, the spore collector,

A base mounted on the case and having a badge container containing a spore collecting medium; A container cover sliding shuttle mounted on the case and capable of sliding the container cover to one side left and right when the container cover of the discharge container moved downward into the case is mounted on the case; And a base elevating shuttle mounted on the case and capable of elevating and moving the base up and down by passing through the container cover sliding shuttle. The airborne pathogenic microorganism unmanned spore collecting device is characterized in that it comprises a.

In addition, the case is built in the case, it characterized in that it comprises a protective cover opening and closing unit which is capable of opening and closing the discharge port by lifting and rotating the discharge protective cover for opening and closing the discharge port of the case.

Preferably, the base lifting shuttle, the support is integrally coupled to the lower end of the base; First driving means for moving the support up and down; And a guide panel fixedly mounted to one side of the case and guiding the lifting movement of the support.

Also preferably, the container cover sliding shuttle, the cradle to be mounted on the container cover of the discharge container is moved down into the case; Slide rail for guiding the left and right movement of the cradle; And second driving means for sliding the cradle to the left and right.

Also preferably, the protective cover opening and closing unit, the first friction gear having a first gear shaft integrally coupled to the wing portion of the medium protective cover; A driving rod in contact with a lower end of the first friction gear; Third driving means for moving the driving rod up and down; A second friction gear in contact with the lifted first friction gear by friction; And fourth driving means for rotating the second gear shaft of the second friction gear.

More preferably, the spore collector is characterized in that it is equipped with a rain sensor that can automatically shut down (shutdown) the operation of the spore collector by detecting rain.

In addition, it comprises a power supply for supplying power to the spore collector, the power supply is characterized in that consisting of a solar cell for generating electrical energy using sunlight.

In addition, the spore collector is characterized in that the control device for controlling the operation of the spore collector and the input device for transmitting the user's operation command to the control device is mounted.

The airborne pathogenic microorganism unmanned spore collecting device according to the present invention by early precision inspection (can be collected for the desired time at the exact time you want to collect the pathogen) airborne pathogens that cause airborne bacterial and fungal diseases on the crops By ensuring accurate forecasting data, airborne diseases can be responded to in a timely manner, minimizing the occurrence and damage of airborne diseases, and reducing the misuse of pesticides to prevent airborne diseases.

1 is a block diagram showing an airborne pathogenic microorganism unmanned spore collecting device according to an embodiment of the present invention
2 is a view showing the internal configuration of the spore collector according to an embodiment of the present invention
Figure 3 is a perspective view showing a protective cover opening and closing unit of the spore collector according to an embodiment of the present invention
Figure 4 is a combination configuration showing the base lifting shuttle and container cover sliding unit of the spore collector according to an embodiment of the present invention
Figure 5 is a plan view showing a container cover sliding unit of the spore collector according to an embodiment of the present invention
Figure 6 is a view showing the operating state of the protective cover opening and closing unit for the lifting and rotation movement of the discharge protective cover according to an embodiment of the present invention
Figure 7a is a view showing the discharge vessel placed in the spore collecting position of the spore collector in order to put the discharge container in the spore collector according to an embodiment of the present invention
Figure 7b is a view showing the operating state of the base lifting shuttle to move the container down to the discharge position of the spore collector according to an embodiment of the present invention
Figure 7c is a view showing the operating state of the base lifting shuttle for opening the container cover of the discharge container in the spore collector according to an embodiment of the present invention
Figure 7d is a view showing the operating state of the container cover sliding unit for opening the container cover of the discharge container in the spore collector according to an embodiment of the present invention
Figure 7e is a view showing the operating state of the base lifting shuttle to move up to the spores collecting position of the discharge container open the container cover in the spores collector according to an embodiment of the present invention
8 is a schematic flowchart of an operation process of a spore collector according to an embodiment of the present invention as viewed from the outside of the case;

The present invention relates to an airborne pathogenic microorganism unmanned spore collecting device for automatically collecting pathogen spores scattered in the air, by collecting the pathogen spores that cause airborne diseases in various crops to ensure accurate prediction information early on airborne diseases It allows timely response, minimizing the occurrence of airborne diseases and the resulting damages, and enabling the use of pesticides to reduce misuse.

Hereinafter, preferred examples are provided to help understanding of the present invention, but the following examples are provided only for easy understanding of the present invention, and the present invention is not limited thereto.

The airborne pathogenic microorganism unmanned spore collecting device according to the present invention is a spore collector 100 for collecting pathogen spores largely scattered in the air and a power supply device for supplying power to the spore collector 100 It consists of

As shown in Figures 1 and 2, the spore collector 100 is a base 110, the base container 10 is mounted on the medium container containing the spore collecting medium, it can be moved up and down the base 110 The base lifting shuttle 120, the container cover sliding shuttle 130 that can be opened by sliding the container cover 11 of the discharge container 10 is configured, these components have an internal space It is mounted in the case 101.

The base 110 is formed in such a structure that the lower end of the discharge container 10 can be seated and inserted in order to fix the discharge container 10 mounted on the upper end so as not to be separated. For example, as shown in FIG. 2, the guide protrusion 111 protrudes from the upper end of the base 110 to fix the discharge container 10.

The discharge container 10 is fitted between the guide protrusion 111 disposed in the circumferential direction on the upper edge of the base 110 is seated.

The base elevating shuttle 120 is to move the base 110 mounted in the case 101 to move up or out of the case 101 or to move down into the case 101. FIGS. 4 and 7a. As shown in FIG. 1, the first drive pulley 123 and the first drive pulley 123 which are connected to the first motor 122 and the drive shaft of the first motor 122 to supply power and rotate integrally with each other. It is configured to include a support 121 which is in surface contact and is moved up and down by the rotation of the first drive pulley (123).

The first driving pulley 123 is a first rubber ring 124 is mounted on the outer peripheral surface to increase the friction between the first driving pulley 123 and the support 121, the first rubber ring 124 is a support In contact with one side of the 121 is rotated by the drive of the first motor 122 to move the support 121 is moved up and down by the friction force.

The base 110 is integrally coupled to the upper end of the support 121 so that the base 110 moves up and down together with the support 121 as the first motor 122 is driven.

In addition, a guide panel 125 is mounted and fixed to one side of the case 101 in order to guide the lifting movement of the support 121.

The guide panel 125 has a guide hole through which the support 121 penetrates, so that the support 121 moves linearly up and down through the guide panel 125.

The first rubber ring 124 may use a high friction material and is not limited to a rubber material.

As described above, the base elevating shuttle 120 is a first drive for moving up and down the support 121 such as a first motor 122, a first driving pulley 123, and a first rubber ring 124 as an assembly. It comprises a means.

Meanwhile, the container cover sliding shuttle 130 slides the container cover 11 of the discharge container 10 (mounted on the top of the base) to the left and right one side, which is moved downwardly into the case 101 by the base lifting shuttle 120. As a sliding unit for opening by opening, as shown in Figures 4 and 5, the second motor 133 for supplying power and the second connected to the drive shaft of the second motor 133 is integrally rotated Guides the left and right movement of the cradle 131 and the cradle 131 which is in surface contact with the drive pulley 134 and the second drive pulley 134 to slide left and right by the rotation of the second drive pulley 134. It is configured to include a slide rail (132).

The second driving pulley 134 is a second rubber ring 135 is mounted on the outer circumferential surface in order to increase the friction between the second driving pulley 134 and the cradle 131, the second rubber ring 135 is a cradle It is in contact with one side of the 131 is rotated by the drive of the second motor 133 to move the cradle 131 to the left and right by a frictional force, the container cover 11 of the discharge container 10 is moved downwards ) Is moved to the left and right with the cradle 131 as it is mounted on the cradle 131.

The cradle 131 is formed so as to penetrate the center portion is configured to move up and down the base 110 and the discharge container 10 passes through the cradle 131.

As described above, the container cover sliding shuttle 130 is a second motor 133, the second driving pulley 134, the second rubber ring 135, and the like for sliding the cradle 131 to the left and right as an assembly; It includes a drive means.

The medium container 10 is a container for accommodating and storing the spore collecting medium, and collects all the microorganism spores scattered in the air through the contained medium in a natural free fall method.

In addition, the container cover 11 opens and closes the opened upper end of the medium container 10, thereby opening the medium container 10 only at a desired time, thereby exposing the medium to air to collect pathogen spores.

The container cover 11 is formed to have a larger diameter than the opened center portion of the holder 131, so that when the container cover 11 is moved downward into the case 101 together with the base 110, the container cover 11 cannot descend by passing through the holder 131. The cradle 131 is placed over the top.

Accordingly, when the discharge container 10 is placed on the base 110 and lowered into the case 101, the container cover 11 is mounted on the holder 131 at a predetermined height (a position where the container cover is caught on the top of the holder and opened). ) At the top, you can hear it and open it.

The open container cover 11 is moved to the left and right one side through the container cover sliding shuttle 130 and completely removed from the upper part of the discharge container 10, and then moved upward to move the discharge container 10 out of the case 101. By returning, spores of microorganisms scattered in the air can be collected.

Here, the spore collection medium is made of a material that is beneficial for the cultivation of the pathogen spores, and when spores of the microorganisms in the air are collected by dropping naturally in the medium contained in the medium container 10, the pathogen spores are relatively superior In this way, accurate forecasting information on the corresponding airborne diseases can be obtained.

The culture vessel 10 is collected by the pathogen spores for a set time and then moved back down into the case 101 is stored inside the case 101, wherein the culture vessel 10 recovered into the case 101 In order to protect the external from the case 101, the top of the discharge protective cover 105 is mounted.

The discharge protective cover 105 is for opening and closing the discharge opening 103 formed on the upper end of the case 101, the lifting and rotating movement is installed on the upper case 101.

Accordingly, the case 101 has a protective cover opening and closing unit 140 for lifting and rotating the discharge protective cover 105 is built.

The protective cover opening and closing unit 140 is for lifting and rotating the discharge protective cover 105 is installed on the top of the case 101, for the lifting movement of the discharge protective cover 105, Figures 3 and 6 As shown in FIG. 3, the third motor 141 for supplying power, the third drive pulley 142 and the third drive pulley 142 which are integrally rotated by being connected to the drive shaft of the third motor 141. It is configured to include a drive rod 144 which is in surface contact with and is moved up and down by the rotation of the third drive pulley 142.

The third driving pulley 142 is a third rubber ring 143 is mounted on the outer circumferential surface in order to increase the friction between the third driving pulley 142 and the driving rod 144, the third rubber ring 143 is In contact with one side of the drive rod 144 is rotated by the drive of the third motor 141 to move the drive rod 144 up and down with friction.

The first friction gear 145 is rotatably connected to the upper end of the driving rod 144, and the first friction gear 145 is driven as the third motor 141 is driven. 144) is pushed up to move.

In addition, an auxiliary spring 148 is mounted at the lower end of the driving rod 144 to assist the upward movement of the driving rod 144 by the third motor 141.

The auxiliary spring 148 is initially compressed and then assists the initial raising of the driving rod 144 when the third motor 141 is started and the driving rod 144 tries to ascend.

At the upper end of the first friction gear 145, a first gear shaft 146 integrally coupled to the wing of the discharge protection cover 105 is integrally formed so that the first friction gear is driven by the driving rod 144. When the 145 is moved upward, the discharge protection cover 105 is raised together.

The wing portion is a portion extending from the edge of the discharge protection cover 105 to protrude outward, the first gear shaft 146 is integrally coupled to the bottom surface of the discharge protection cover 105 is the first It is rotated with respect to the gear shaft 146 to open and close the discharge opening 103 of the case 101.

 In addition, the upper end of the first friction gear 145 is provided with a return spring 147 that is penetrated by the first gear shaft 146, the return spring 147 of the first friction gear 145 During the upward movement, it is compressed between the first friction gear and the mounting table to have an elastic restoring force. When the first friction gear 145 is moved downward by the reverse rotation of the third motor 141, the first restoring force is first moved by the elastic restoring force. The initial lowering of the friction gear 145 is assisted.

In addition, the protective cover opening and closing unit 140 of the fourth motor 151, the fourth motor 151 for supplying power as shown in Figure 6 for the rotational movement of the discharge protective cover 105 The fourth driving pulley 152 connected to the drive shaft and rotated integrally, and the second friction gear 155 installed to rotate about the second gear shaft 154 by the rotation of the fourth driving pulley 152. It is configured to include.

The second gear shaft 154 is installed to be rotatable integrally with the second friction gear 155 through the second friction gear 155, the second friction gear 155 is the second gear shaft 154 ) Is in surface contact with the fourth driving pulley 152 to be interlocked and rotated simultaneously when the fourth motor 151 is driven.

The fourth driving pulley 152 is provided with a fourth rubber ring 153 on the outer circumferential surface of the fourth driving ring 153 to increase friction between the fourth driving pulley 152 and the second friction gear 155. ) Is in direct contact with one side of the second gear shaft 154 to rotate by the driving of the fourth motor 151 to rotate the second friction gear 155 about the second gear shaft 154 with frictional force. do.

Each of the first and second friction gears 145 and 155 is tapered and is tapered in opposite directions so that the first and second friction gears 145 and 155 are in surface contact with each other when the first friction gear 145 is moved upward. The friction gears 145 and 155 are connected to each other by friction, so that the rotational force of the second friction gear 155 is transmitted to the first friction gear 145, so that when the fourth motor 151 is driven, the second friction gear ( As the 155 is rotated, the first friction gear 145 is rotated, and the discharge protection cover 105 is rotated in one direction based on the first gear shaft 146 of the first friction gear 145.

As described above, the protective cover opening and closing unit 140 includes a third motor 141, a third driving pulley 142, a third rubber ring 143, and the like as an assembly to move the driving rod 144 up and down. A fourth motor 151, a fourth driving pulley 152, and a fourth rubber ring 153 as an assembly for rotating the second gear shaft 154 of the second friction gear 155. ) As the fourth driving means.

For reference, most of the protective cover opening and closing unit 140 including the third and fourth motors 141 and 151, the driving rod 144, the first and second gear shafts 146 and 154, and the auxiliary spring 148 are described. The components of the mount 150 are mounted and supported, and the third and fourth motors 141 and 151, the driving rod 144, the first and second gear shafts 146 and 154, and the like are mounted on the mount 150. Bearings are installed between and.

In addition, the spore collector 100 has a control device 160 for controlling the operation of the spore collector 100 and the input device 170 for transmitting the operation command of the user to the control device case 101 ) It is mounted inside.

The control device 160 is programmed and configured to control all operations of the spore collector for collecting spores of microorganisms scattered in the air, the spore collector 100 is operated by the control device 160 The function can be performed through control.

For example, the control device 160 adopts a programmable logic control (PLC) that performs a control operation such as a logical operation, a sequence operation, a timer, a counter, an arithmetic operation, etc. It can be implemented to run a spore collector.

Specifically, the control device 160 may control the operation of the spore collector 100 by controlling the power supply and supply time / period to the first to fourth motors 122, 133, 141 and 151.

The input device 170 is an interface for transmitting an operation command input by the user to the control device 160, and may be implemented as various buttons or a touch screen, and when the user's command is input, the control device 160 The first to fourth motors 122, 133, 141 and 151 are operated for a set time and period in a predetermined order.

The input device 170 is installed to be exposed to one side of the case 101 for inputting a user's operation command, and is also set by inputting a spore collecting time and period desired by the user using the input device 170. can do.

In addition, the spore collector 100 may automatically shut down the operation of the spore collector 100 by detecting rain in order to automatically stop spore collection to prevent contamination of the medium during rainfall. The rain sensor (not shown) is configured to be mounted.

Although not shown in the drawings, the rain sensor is mounted to be connected to the control device 160 at one side of the spore collector 100, and automatically detects the strength and quantity of rainwater even if the user does not separately operate in rainy weather. By transmitting a detection signal to the control device 160 to stop the operation of the spore collector 100.

On the other hand, the power supply device 200 may itself be implemented as a solar cell that generates electrical energy using sunlight in order to supply drive power to the spore collector 100 by itself.

The solar cell includes a battery and a controller capable of charging and discharging, and thus the electric energy accumulated in the day can be used at night to enable continuous operation.

Since the power supply device 200 generates electricity by an automatic charging method using a solar cell method, the spore collector 100 can be used even in an area without electricity, and power for spore collection without sunlight is about 3 days. It consists of a low power device that can be supplied.

Therefore, the spore collecting device of the present invention can be operated only by the power using solar light, and can be operated unattended for at least 15 days.

Spore collector 100 of the present invention is configured as described above is a time for the spores collection to put the medium container 10 containing the spores collection medium of the pathogen desired by the user at the medium input position of the spore collector 100 And setting the period automatically collects spores at the time and period, and at other times, moves the discharge container 10 back to the discharge position, and stores the spores. Spore collection is performed only for the correct time by the point, it can be operated unattended so that the spores can be collected at any time desired by the user, in case of rain, the spores can be stopped to prevent contamination of the badge, and the desired time Since only spore collection is carried out, it is possible to prevent contamination and dryness of the medium.

Referring to Figure 7b and 8 (g), the discharge position of the case 101 by placing the discharge container 10 containing the spores collection medium on the base 110 and close the discharge protective cover 105 The base 110 is lowered to the inside of the case 101 so as to close the discharge inlet 103, and is a basic position for storing the medium injected into the spore collector 100 when not collecting spores. This is the default location for starting (or starting) the spore picker for collecting spores.

On the other hand, the medium protective cover 105 is made of a transparent material that can pass through sunlight for the cultivation of the pathogen spores collected while stored in the spores collector 100 without performing spores collection .

Hereinafter, the operation of the unmanned spore collecting device according to the present invention with reference to FIGS.

First, by pressing the discharge button of the input device to open the discharge protective cover 105, as shown in Figure 7a or 8 (b) and moves the base 110 up out of the case 101.

Put the discharge container 10 containing the spore collecting medium on the base 110 and press the input button of the input device 170 to discharge the discharge container 10 as shown in Figure 7b or 8 (d) Move down to the feeding position. At this time, after the discharge container 10 is moved to the discharge position, the discharge protection cover 105 closes the discharge hole 103 of the case 101, whereby the spore collector 100 prepares for collecting spores. It becomes a state.

The discharge container 10 which is moved downward in the case 101 and is positioned at the discharge position of the discharge container is positioned close to the bottom surface of the discharge protection cover 105 which is closed.

The time and period to be collected are set in advance before starting spore collection (or pressing the start button of the input device).

As described above, the spore collector 100 of the present invention is operated and controlled by the control device 160 to automatically perform spore collection only for a predetermined time and period.

Accordingly, when the start button of the input device 170 is pressed, the spore collector 100 collects spores of microorganisms scattered in the air only for a set time and period.

Looking in detail, when the time and period is set by pressing the start button, the base 110 is moved downward to the position to open the container cover 11 of the discharge container 10 by the base lifting shuttle 120 To this end, the discharge container 10 passes through the container cover sliding shuttle 130 and the container cover 11 is caught by the holder 131 of the container cover sliding shuttle 130.

In this case, as the base 110 continues to move downward, as shown in FIG. 7C, the container cover 11 is opened and separated from the discharge container 10, and the holder 131 on which the container cover 11 is seated and stacked is shown in FIG. 7C. As shown in FIG. 7D and FIG. 8E, the container cover 11 is detached from the upper portion of the discharge container 10 as the slide cover slides to the left and right sides along the slide rail 132, and the discharge container 10 is the container cover. In the open state 11, the container cover sliding shuttle 130 is moved up to the collecting position as shown in FIGS. 7E and 8E to collect spores of microorganisms scattered in the air for a predetermined time.

The collecting position is a basic position for spore collection of the medium, the medium container 10 is moved up out of the medium inlet 103 of the spore collector 100 by the base lifting shuttle 120 for spore collection, The spores of the microorganisms in the air are collected by dropping naturally in the medium contained in the medium container (10).

When the spore collection is completed for a set time, the discharge container 10 is moved in the reverse order to move down into the case 101 of the spore collector 100 as shown in FIG. 105 is also operated in the reverse order to close the discharge inlet 103.

That is, when the spore collection is completed, the discharge container 10 is moved downward to the position that can close the container cover 11 by the base lifting shuttle 120, the container cover 11 to the container cover sliding shuttle 130 The slide is moved to the upper portion of the discharge container (10). Next, the container cover 11 is closed by moving the discharge container 10 upward through the holder 131, and the discharge container 10 closing the container cover 11 is discharged from the discharge position to the next spore collection time. Will be stored.

100: spore collector 101: case
103: discharge port 105: discharge protective cover
110: base 120: base lifting shuttle
121: support base 122: the first motor
123: first drive pulley 124: first rubber ring
125: guide panel 130: container cover sliding shuttle
131: holder 132: slide rail
133: second motor 134: second drive pulley
135: second rubber ring 140: protective cover opening and closing unit
141: third motor 142: third drive pulley
143: third rubber ring 144: driving rod
145: first friction gear 146: first gear shaft
147: return spring 148: auxiliary spring
150: mounting base 151: fourth motor
152: fourth drive pulley 153: fourth rubber ring
154: second gear shaft 155: second friction gear
160: control device 170: input device
200: power supply

Claims (8)

It comprises a spore collector for collecting pathogen spores scattered in the air, the spore collector,
A base mounted on the case and having a badge container containing a spore collecting medium;
A container cover sliding shuttle mounted on the case and capable of sliding the container cover to one side left and right when the container cover of the discharge container moved downward into the case is mounted on the case; And
A base elevating shuttle mounted on the case and capable of elevating and moving the base up and down through the container cover sliding shuttle;
Airborne pathogenic microorganism unmanned spore collecting device, characterized in that comprises a.
The method according to claim 1,
Embedded in the case, airborne pathogenic microorganism unmanned, characterized in that it comprises a protective cover opening and closing unit to open and close the medium inlet by lifting and rotating the medium protective cover for opening and closing the medium inlet of the case Spore collection device.
The method according to claim 1,
The base lifting shuttle, the support is integrally coupled to the lower end of the base;
First driving means for moving the support up and down; And
A guide panel fixedly mounted at one side of the case and guiding the lifting movement of the support;
Airborne pathogenic microorganism unmanned spore collecting device, characterized in that comprises a.
The method according to claim 1, wherein the container cover sliding shuttle,
A cradle to which the container cover of the discharge container is moved down into the case and is mounted on the case;
Slide rail for guiding the left and right movement of the cradle; And
Second driving means for sliding the holder from side to side;
Airborne pathogenic microorganism unmanned spore collecting device, characterized in that comprises a.
The method according to claim 2, The protective cover opening and closing unit,
A first friction gear having a first gear shaft integrally coupled to the wing of the discharge protection cover;
A driving rod in contact with a lower end of the first friction gear;
Third driving means for moving the driving rod up and down;
A second friction gear in contact with the lifted first friction gear by friction;
And fourth driving means for rotating the second gear shaft of the second friction gear.
Airborne pathogenic microorganism unmanned spore collecting device, characterized in that comprises a.
The method according to claim 1,
The spore collector is an airborne pathogenic microorganism unmanned spore collecting device, characterized in that the rain sensor that can detect the rain to automatically shut down (shutdown) the operation of the spore collector.
The method according to claim 1,
Comprising a power supply for supplying power to the spore collector, the power supply is an airborne pathogenic microorganism unmanned spore collecting device, characterized in that consisting of a solar cell for generating electrical energy using sunlight.
The method according to claim 1,
The spore collector is an airborne pathogenic microorganism unmanned spore collecting device, characterized in that the control device for controlling the operation of the spore collector and the input device for transmitting the operation command of the user to the control device is mounted.

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