KR102005324B1 - Microorganism collecting device with electric dust collection type - Google Patents

Abstract

The present invention discloses an electrostatic precipitating microorganism collecting device. An electrostatic precipitating apparatus for collecting microorganisms according to an embodiment of the present invention may include an inlet formed with an air inlet including airborne microorganisms, and a charge unit configured to charge the airborne microorganisms flowing into the inlet; A collecting part coupled to the charged part and having a flow space part through which floating microorganisms flow; And at least one guide part having one side coupled to the charged part and guiding that the charged part and the collecting part are electrically connected. When the charged part is coupled to the collecting part, Is applied, and when the charged portion is separated from the collecting portion, electricity is not applied to the charged portion, and the collecting portion is provided with at least one electrically conductive member in contact with the guide portion. The conductive member is formed of at least an elastic material, the collection portion is formed with a guide portion insertion hole into which the guide portion is inserted, and the electrically conductive member is in contact with or separated from the end of the guide portion inserted through the guide portion insertion hole. Characterized in that the charge portion is moved vertically downwards so that the guide portion is the guy When the bottom surface of the charged portion and the upper surface of the collecting portion are in contact with each other, the charge portion is inserted into the charge portion insertion hole, and electricity is applied to the charged portion. When the electrical conductive member is separated from the electricity is not applied to the charged portion, the charged portion, a plurality of ground rods, a plurality of tungsten wire (tungsten wire) which is arranged spaced apart from the plurality of ground rods And a T-shaped collecting rod for collecting the suspended microorganisms charged at the charged portion, and the supporting portion is provided with a support portion coupled to the inlet to support the collecting rod, and the collecting rod passes through the collecting portion. The through hole is formed, the upper end of the collecting rod is formed with a engaging portion extending to both ends of the through hole It is formed larger than the size, characterized in that the lower end of the collecting rod is walked around the through hole through the through hole, the guide portion is provided with a rod of metal material, one side of the guide portion is the bottom surface of the charged portion Is coupled to, the other side of the guide portion is formed to extend vertically downward from the bottom of the charged portion, the electrically conductive member is installed directly below the guide portion insertion hole to be in contact with or separated from the end of the guide portion, the guide portion A first guide portion and a second guide portion, wherein the electrically conductive member comprises a first electrically conductive member in contact with or separated from an end of the first guide portion, and a second electrically conductive member in contact with or separated from an end of the second guide portion A member, the tungsten wire and the collecting part being provided in the collecting part; Further comprising a power supply for supplying electricity in the flow space, wherein one side of the power supply is connected to the first electrically conductive member, the other side of the power supply is connected to the flow space through the second electrically conductive member The collection part is provided with a flow generating unit for generating an air flow, one side of the flow generating unit is provided with an activated carbon fiber filter along the flow direction of air, the activated carbon fiber filter collects the airborne microorganisms in the collecting unit Removes ozone (O3) generated when the lower surface of the charged portion is in contact with the upper surface of the collecting portion, the electricity is applied to the charged portion from the power supply portion, the electricity is applied to the tungsten wire when electricity is applied to the charged portion Is applied and the flow generating unit is driven so that the airborne microorganisms in the air are charged while passing through the charged portion, and the charged portion The charged floating microorganisms flow in the collecting rod direction by an electric field formed around the collecting rod and are attached to the collecting rod, and the air introduced into the collecting portion from the charged portion collects the floating microorganisms in the collecting portion. After the discharge to the outside of the collecting unit, the collecting unit is further provided with a timer, the timer is characterized in that the power supply automatically turns off (off) after a set time.

Description

MICROORGANISM COLLECTING DEVICE WITH ELECTRIC DUST COLLECTION TYPE}

The present invention relates to an electrostatic precipitating microorganism collecting device, and more particularly, to minimize the complicated wiring by removing the wires directly connected to the charging unit, and installed in the rod and collecting unit of the metal material to guide the combination of the charging unit and the collecting unit The present invention provides an electrostatic precipitating type microorganism collecting device which can apply electricity or cut off electricity depending on the contact state between the electrically conductive members, thereby minimizing the risk of electric shock.

Recently, avian influenza and new influenza have been raised, causing air infection problems. Therefore, airborne microbial measurement is more important and the biosensor market is growing rapidly. to be.

Conventionally, airborne microorganisms are measured by collecting biological particles suspended in a sample gas on a solid or liquid surface suitable for propagation, incubating in a moderate temperature and humidity environment for a period of time, and then displaying the number of colonies on the surface. There was a culture method for obtaining the number of microorganisms collected at and a staining method using a fluorescence microscope after staining.

Recently, ATP (adenosine triphosphate) and luciferin / luciferase react with ATP bioluminescence method using the principle of emitting light. Although the process was reduced to about 30 minutes, it was possible to work quickly.However, in order to apply the ATP bioluminescence method, an ATP extractant is basically required, but when it is used in a gaseous floating microbial measurement system, it may adversely affect the human body. In addition, the ATP extractant must be continuously supplied in order to be applied to an automatic system, but there is a problem in that it is costly to continuously supply commercially available ATP extractant.

In addition, the conventional electrostatic precipitating type microorganism collecting device is a form in which the voltage is applied to the charger and the collector separately from the power supply, and since the wiring is separate from the charger, it is difficult to completely lift the charger. There was a risk of electric shock if the handheld was lifted and held by the hand to remove the collection rod without turning the switch off.

The present invention is to solve the conventional problems by eliminating the wiring directly connected to the charging unit to minimize the complicated wiring and to collect the electrostatic dust collection microorganisms that the user can lift the fully charged portion to take out the collection rod trapped by the airborne microorganisms To provide a device.

In addition, the present invention, according to the contact state between the metal rod connecting the charging unit and the collecting unit and the electrically conductive member installed in the collecting unit can be applied or cut off the electric dust collection type microorganisms to minimize the risk of electric shock of the user To provide a device.

An electrostatic precipitating apparatus for collecting microorganisms according to an embodiment of the present invention may include an inlet formed with an air inlet including airborne microorganisms, and a charge unit configured to charge the airborne microorganisms flowing into the inlet; A collecting part coupled to the charged part and having a flow space part through which floating microorganisms flow; And at least one guide part having one side coupled to the charged part and guiding that the charged part and the collecting part are electrically connected. When the charged part is coupled to the collecting part, Is applied, and when the charged portion is separated from the collecting portion, electricity is not applied to the charged portion, and the collecting portion is provided with at least one electrically conductive member in contact with the guide portion. The conductive member is formed of at least an elastic material, the collection portion is formed with a guide portion insertion hole into which the guide portion is inserted, and the electrically conductive member is in contact with or separated from the end of the guide portion inserted through the guide portion insertion hole. Characterized in that the charge portion is moved vertically downwards so that the guide portion is the guy When the bottom surface of the charged portion and the upper surface of the collecting portion are in contact with each other, the charge portion is inserted into the charge portion insertion hole, and electricity is applied to the charged portion. When the electrical conductive member is separated from the electricity is not applied to the charged portion, the charged portion, a plurality of ground rods, a plurality of tungsten wire (tungsten wire) which is arranged spaced apart from the plurality of ground rods And a T-shaped collecting rod for collecting the suspended microorganisms charged at the charged portion, and the supporting portion is provided with a support portion coupled to the inlet to support the collecting rod, and the collecting rod passes through the collecting portion. The through hole is formed, the upper end of the collecting rod is formed with a engaging portion extending to both ends of the through hole It is formed larger than the size, characterized in that the lower end of the collecting rod is walked around the through hole through the through hole, the guide portion is provided with a rod of metal material, one side of the guide portion is the bottom surface of the charged portion Is coupled to, the other side of the guide portion is formed to extend vertically downward from the bottom of the charged portion, the electrically conductive member is installed directly below the guide portion insertion hole to be in contact with or separated from the end of the guide portion, the guide portion A first guide portion and a second guide portion, wherein the electrically conductive member comprises a first electrically conductive member in contact with or separated from an end of the first guide portion, and a second electrically conductive member in contact with or separated from an end of the second guide portion A member, the tungsten wire and the collecting part being provided in the collecting part; Further comprising a power supply for supplying electricity in the flow space, wherein one side of the power supply is connected to the first electrically conductive member, the other side of the power supply is connected to the flow space through the second electrically conductive member The collection part is provided with a flow generating unit for generating an air flow, one side of the flow generating unit is provided with an activated carbon fiber filter along the flow direction of air, the activated carbon fiber filter collects the airborne microorganisms in the collecting unit Removes ozone (O3) generated when the lower surface of the charged portion is in contact with the upper surface of the collecting portion, the electricity is applied to the charged portion from the power supply portion, the electricity is applied to the tungsten wire when electricity is applied to the charged portion Is applied and the flow generating unit is driven so that the airborne microorganisms in the air are charged while passing through the charged portion, and the charged portion The charged floating microorganisms flow in the collecting rod direction by an electric field formed around the collecting rod and are attached to the collecting rod, and the air introduced into the collecting portion from the charged portion collects the floating microorganisms in the collecting portion. After the discharge to the outside of the collecting unit, the collecting unit is further provided with a timer, the timer is characterized in that the power supply automatically turns off (off) after a set time.

In addition, one side of the collecting rod is coupled to the support, and the other side of the collecting rod is characterized in that it is formed extending vertically downward from the support.

In addition, the plurality of ground rods and the plurality of tungsten wires are characterized in that they are alternately arranged.

According to the present invention, there is no need for separate electrical wiring connecting the charging unit and the power supply unit, the user can apply electricity by connecting the charging unit and the power supply unit with a simple operation of lifting or lowering the charging unit, and collecting and charging units Since it can be completely separated there is an advantage that can easily combine or separate the collection rod.

In addition, since the flow generator is provided as a fan, there is an advantage that the device can be made smaller and lighter than the conventional air pump.

In addition, it is possible to remove the ozone (O3) by the activated carbon fiber filter has an advantage that is harmless to the human body even when using the electrostatic precipitating microorganism collecting device for a long time.

1 is a perspective view showing an electrostatic precipitating microorganism collecting device according to an embodiment of the present invention.
Figure 2 is an exploded perspective view showing an electrostatic precipitating microorganism collecting device according to an embodiment of the present invention.
Figure 3 is a view from one side of the electrostatic precipitating type microorganism collecting device according to an embodiment of the present invention.
Figure 4 is a cross-sectional view of the electrostatic precipitating microorganism collecting device according to an embodiment of the present invention.
FIG. 5 is a plan view illustrating a flow generating unit and an activated carbon fiber filter coupled to the flow generating unit according to an embodiment of the present invention.

Hereinafter, with reference to the drawings will be described in detail a specific embodiment of the present invention. However, the spirit of the present invention is not limited to such an embodiment, and the spirit of the present invention may be proposed differently by the addition, change, deletion, etc. of the elements constituting the embodiment, but this is also included in the spirit of the present invention. Will be.

1 is a perspective view showing an electrostatic precipitating microorganism collecting device according to an embodiment of the present invention, Figure 2 is an exploded perspective view showing an electrostatic precipitating microorganism collecting device according to an embodiment of the present invention, Figure 3 is The electrostatic precipitating microorganisms collecting device according to an embodiment of the view from one side.

1 to 3, the electrostatic precipitating type microorganism collecting device 1 according to an embodiment of the present invention may include a charging unit 10, a collecting unit 20, and a guide unit 30.

The charging unit 10 may be formed with an inlet 110 through which air containing the floating microorganisms flows. When the flow generating unit 213 to be described later is driven to generate air flow, the air including the floating microorganisms may be introduced through the inlet 110.

The charging unit 10 may include a plurality of ground rods 112 and a plurality of tungsten wires 113. In this case, a plurality of ground rods 112 and a plurality of tungsten wires 113 may be provided. In this case, the plurality of ground rods 112 and the plurality of tungsten wires 113 may be alternately disposed to be spaced apart from each other by a predetermined interval.

In addition, the plurality of ground rods 112 and the plurality of tungsten wires 113 may be disposed above the inlet 110. When the charging unit 10 is driven while air containing the floating microorganisms is introduced into the inlet 110, the floating microorganisms may be charged and move into the collecting unit 20.

When the charging unit 10 is driven, a high voltage is applied from the power supply unit 60, which will be described later, to the tungsten wire 113, and a corona discharge (high voltage between the two electrodes) is caused by the voltage difference between the ground rod 112 and the tungsten wire 113. By applying (i) refers to a phenomenon in which only the strong electric field emits light to have conductivity).

The anion (-) or cation (+) generated during the corona discharge may be charged with the floating microorganisms (electrification, the charge balance is broken (-) electricity or (+) electric phenomenon), and thus the floating microorganisms Can be charged. Charged floating microorganisms may be collected in the collecting rod 50 to be described later by flowing into the collecting unit 20 through the inlet 110.

The charging unit 10 may be provided with a collecting rod 50 for collecting the charged floating microorganisms. At this time, one side of the inlet 110 may be provided with a support 111 for supporting the collecting rod (50).

One side of the collecting rod 50 may be coupled to the support 111, and the other side of the collecting rod 50 may extend vertically downward from the support 111. That is, one end of the collecting rod 50 may be coupled to the support 111, and the other end may be located inside the collecting unit 20.

In one example, the collecting rod 50 may be formed in a T-shape. In this case, a through hole (not shown) through which the collecting rod 50 penetrates may be formed in the support part 111, and the collecting rod 50 may be caught around the through hole.

In other words, the upper end of the collecting rod 50 is formed in the engaging portion extending to both sides can be formed larger than the size of the through-hole, the lower end is formed to a size that can penetrate the through-hole so that the user the collecting rod 50 ) Is inserted into the through hole from top to bottom, and the collecting rod 50 can be easily hooked around the through hole.

In addition, the collecting rod 50 may be disposed between the charge unit 10 and the flow generating unit 213 provided below the collecting unit 20 based on the movement path of the floating microorganisms.

Accordingly, when the flow generator 213 is driven, the airborne microorganisms may be charged in the charging unit 10 and collected in the collecting rod 50. In addition, the air flow may pass through the flow generating unit 213 to be discharged to the outside of the collecting unit 20.

The collecting rod 50 may extend vertically downward from an approximately central portion of the inlet 110 of the charged portion 10, and the floating microorganisms charged while passing through the inlet 110 may be easily collected in the collecting rod 50. Can be.

The collecting rod 50 may be supplied with electricity having a polarity opposite to that of the electricity applied to the tungsten wire 113. For example, when the electricity applied to the tungsten wire 113 is (+) electricity and the airborne microorganisms are charged to the (+) ions, negative electricity may be applied to the collecting rod 50. On the contrary, when the electricity applied to the tungsten wire 113 is (-) electricity and the floating microorganisms are charged to the (-) ions, positive electricity may be applied to the collecting rod 50.

The charging unit 10 may be provided with a guide unit 30 to guide the electrical connection between the charging unit 10 and the collecting unit 20.

The guide part 30 may be provided as a rod of metal material. In one example, a plurality of guide portion 30 may be coupled to both sides of the collecting rod (50).

One side of the guide part 30 may be coupled to the bottom of the charged portion 10, and the other side may be formed to extend vertically downward from the bottom of the charged portion 10.

The collecting unit 20 may be a flow space 210 through which the floating microorganisms flow. In one example, the flow space 210 may be formed in a substantially cylindrical shape, it may be formed in a diameter or size larger than the diameter of the collecting rod (50). The flow space 210 may have a size similar to that of the inlet 110 of the charging unit 10 and may form a space in which air introduced through the inlet 110 may flow.

In addition, the flow space 210 may form a space in which the electrostatic attraction that the floating microorganisms charged in the charging unit 10 can be collected in the collecting rod 50.

The collecting part 20 may be formed with guide part insertion holes 211 and 212 into which the guide part 30 is inserted.

The guide part insertion holes 211 and 212 may be formed to be recessed vertically downward from the upper surface of the collecting part 20, and formed slightly larger than the diameter of the guide part 30 so that the guide part 30 can be easily inserted. Can be.

Therefore, in the state in which the charged portion 10 and the collecting portion 20 are separated, the user inserts the guide portion 30 in accordance with the guide portion insertion holes 211 and 212 to thereby engage the charged portion 10. Can be easily identified.

When the guide part 30 is inserted into the guide part insertion holes 211 and 212, the collecting rod 50 may be accommodated into the flow space 210. In particular, the collecting rod 50 may be disposed along the center of the flow space 210 so that charged floating microorganisms may be introduced and easily collected in the collecting rod 50.

The collecting part 20 may be provided with an electrically conductive member 40 which contacts or separates the end of the guide part 30 inserted through the guide part insertion holes 211 and 212. Detailed description of the electrically conductive member 40 will be described with reference to FIG. 4 to be described later.

The lower portion of the collecting unit 20 may be provided with a flow generating unit 213 for generating an air flow. For example, the flow generating unit 213 may be provided as a fan, and thus there is an advantage that the device can be reduced in size and light weight as compared with the case of using a conventional air pump.

The flow generating unit 213 may provide a driving force for allowing external air to flow to the flow space 210 formed in the collecting unit 20 through the inlet 110 of the charging unit 10, and flow The air flow passing through the space 210 may be discharged to the outside of the collecting unit 20. In this case, an air outlet 21 through which the air passing through the flow generating unit 213 is discharged may be formed on one surface of the lower end of the collecting unit 20.

Figure 4 is a cross-sectional view of the electrostatic precipitating microorganism collecting device according to an embodiment of the present invention, Figure 5 is a flow generating unit of the electrostatic precipitating microbial collecting apparatus according to an embodiment of the present invention, activated carbon coupled to the flow generating unit It is a top view which shows a fiber filter.

4 and 5, the electrostatic precipitating microorganism collecting device 1 according to an embodiment of the present invention may have an electrically conductive member 40 installed in the collecting unit 20.

The electrically conductive member 40 may be installed below the collecting unit 20. In more detail, the electrically conductive member 40 may be installed directly under the guide part insertion holes 211 and 212 to be in contact with or separated from the end of the guide part 30.

At least two electrically conductive members 40 may be installed to be in contact with or separated from each end of each of the guide parts 310 and 311. For example, the electrically conductive member 40 may be formed of an elastic material (eg, a spring).

In more detail, the guide portions 310 and 311 may include a first guide portion 310 and a second guide portion 311, and the electrically conductive member 40 contacts the ends of the first guide portion 310. Or a second electrically conductive member 412 which contacts or is separated from an end of the first electrically conductive member 411 and the second guide part 311 which are separated.

The collecting unit 20 may be provided with a charging unit 10 and a power supply unit 60 for supplying electricity to the collecting unit 20.

The power supply unit 60 may supply electricity to the tungsten wire 113 of the charging unit 10 and the flow space 210 of the collecting unit 20. In more detail, one side of the power supply 60 may be connected to the first electrically conductive member 411, and the other side of the power supply 60 may be connected to the flow space 210 through the second electrically conductive member 412. .
Specifically, the power supply unit 60 may be electrically connected to the first electrically conductive member 411 through the first wire 61, and may be electrically connected to the second electrically conductive member 412 through the second wire 62. The second electrically conductive member 412 may be electrically connected to the flow space 210 through the third wire 63.

Accordingly, the electric charge unit 10 and the power supply unit 60 are connected to each other by a simple operation in which the user lifts or lowers the electric charge unit 10 without separately requiring an electric wire connecting the electric charge unit 10 and the power supply unit 60. Can be applied, and the collecting part 20 and the charging unit 10 can be completely separated there is an advantage that can easily combine or separate the collecting rod (50).

For example, when the charged part 10 moves vertically downward and each of the guide parts 310 and 311 is inserted into the guide part insertion holes 211 and 212 to contact the electrically conductive members 411 and 412, the charged part 10 Electricity may be applied to the charged portion 10. On the contrary, when the charged portion 10 moves vertically upward and the guide portions 310 and 311 and the electrically conductive members 411 and 412 are separated, the charged portion 10 is supplied with electricity. It may not be.

As shown in FIG. 4, when the charged portion 10 moves vertically downward to contact the bottom surface of the charged portion 10 and the upper surface of the collecting portion 20, the guide portion 30 coupled to the charged portion 10. May be in contact with the electrically conductive member 40, and electricity may be supplied from the power supply unit 60.

When (+) electricity is applied to the tungsten wire 113 of the charged portion 10 by contacting the guide portions 310 and 311 and the electrically conductive members 411 and 412, the floating microorganisms introduced through the inlet 110 are Charged by (+) ions may flow into the flow space 210 of the collecting portion 20, the positive space is applied to the inside of the flow space 210 and (-) electricity to the collecting rod 50 Suspended microorganisms charged with (+) ions may be attached to the collecting rod 50.

On the contrary, when the electricity applied to the tungsten wire 113 is (-) electricity and the floating microorganisms are charged to the (-) ions, the inside of the flow space 210 is applied with (-) electricity and the collecting rod 50 (+) Electricity may be applied to attach the floating microorganisms charged to the negative ions to the collecting rod 50.

On the other hand, the lower end of the collecting unit 20 may be provided with a flow generating unit 213. When the flow generating unit 213 is driven while the charged part 10 and the collecting part 20 are in contact with each other, air including floating microorganisms may be introduced through the inlet 110 formed in the charged part 10, At the same time, when electricity is applied from the power supply unit 60, the floating microorganisms charged by the charging unit 10 may be collected by the collecting unit 20.

For example, the collecting unit 20 may be provided with a timer (not shown) device. The user may set the operation time of the power supply unit 60 with the timer, and may collect the airborne microorganisms in the air for a predetermined time. Therefore, after the airborne microbial collecting process is completed, the charged part 10 and the collecting part 20 may be powered off.

One side of the flow generating unit 213 may be provided with an activated carbon fiber filter 214. The activated carbon fiber filter 214 may remove ozone (O3) generated when the charged airborne microorganisms are collected by the collecting unit 20, and the air from which the ozone (O3) has been removed may be removed from the flow generating unit 213. It may be discharged to the outside of the collecting unit 20 through.

For example, the activated carbon fiber filter 214 may be provided on any one of the upper and lower surfaces of the flow generating unit 213 along the air flow direction, and may be provided on both the upper and lower surfaces of the flow generating unit 213. have.

Therefore, the activated carbon fiber filter 214 can remove approximately 99% or more of ozone (O3), so that even when the electrostatic precipitating microorganism collecting device 1 is used for a long time, there is an advantage that it is harmless to the human body.

Hereinafter will be described the operation of the electrostatic precipitating microorganism collecting device 1 according to an embodiment of the present invention.

In more detail, the process of collecting the airborne microorganisms in the air by the electrostatic precipitating microorganism collecting device 1 according to an embodiment of the present invention is as follows.

When the user contacts the charging unit 10 and the collecting unit 20 so that the guide unit 30 and the electrically conductive member 40 contact each other, electricity may be applied from the power supply unit 60.

When electricity is applied from the power supply unit 60, electricity is applied to the tungsten wire 113 of the charge unit 10 to drive the charge unit 10 and the flow generator 213 to drive the airborne microorganisms in the air. It can be charged while passing all 10.

The floating microorganisms charged by the charging unit 10 may flow in the direction of the collecting rod 50 by an electric field formed around the collecting rod 50, and may be attached to the collecting rod 50.

The air introduced from the charging unit 10 may be discharged to the outside of the collecting unit 20 after the floating microorganisms are collected in the collecting unit 20. At this time, one side or the other side of the flow generating unit 213, that is, the activated carbon fiber filter 214 is provided along the flow direction of air can remove the ozone (O3) generated during the airborne microbial capture process. .

In addition, the user may completely separate the charged part 10 from the collecting part 20 after completion of the collection of the airborne microorganisms, and separate the collecting rod 50 from the separated charged part 10 to store a plurality of reagents. The concentration of the airborne microorganisms can be measured by introducing into a reagent vessel (not shown).

For example, a plurality of reagents stored in the reagent container include a lysis reagent for lysing the cells (or cell walls) of the suspended microorganisms collected in the collecting rod 50, and ATP (Adenosine Triphosphate, Adenosine Triphosphate) extracted from the lysed cells. It may include a light emitting material that generates light in response to the.

Therefore, the luminescent material is placed in the lower portion of the reagent container, and the dissolution reagent is positioned above the luminescent material, and the collecting rod 50 is put into the reagent container to collect the collecting rod 50. After the airborne microorganism reacts with the lysis reagent and the cells are lysed and the ATP is exposed or extracted, the concentration of the airborne microorganism can be measured as the extracted ATP reacts with the light emitting material to measure the intensity of light emitted. .

The scope of the present invention is not limited to the above-described embodiment, but may be embodied in various forms of embodiments within the scope of the appended claims. Without departing from the gist of the invention claimed in the claims, it is intended that any person skilled in the art to which the present invention pertains falls within the scope of the claims described in the present invention to various extents which can be modified.

1: electrostatic precipitating microorganism collecting device
10: charged part
20: collector
30: guide part
40: electrically conductive member
50: collection rod
60: power supply
111: support
112: ground rod
113: tungsten wire
210: flow space portion
211 and 212: guide insertion hole
213: flow generator
214: activated carbon fiber filter

Claims (3)

An inlet through which air including airborne microorganisms is formed, and a charge unit configured to charge airborne microorganisms flowing into the inlet;
A collecting part coupled to the charged part and having a flow space part through which floating microorganisms flow; And
At least one guide part having one side coupled to the charged part and guiding that the charged part and the collecting part are electrically connected to each other;
Including,
When the charged portion is coupled to the collecting portion, electricity is applied to the charged portion, and when the charged portion is separated from the collecting portion, the electricity is not applied to the charged portion.
At least one electrically conductive member in contact with the guide unit is installed in the collecting unit,
The electrically conductive member is formed of a spring of an elastic material,
The collection portion is formed with a guide portion insertion hole into which the guide portion is inserted,
The electrically conductive member is in contact with or separated from the end of the guide portion inserted through the guide portion insertion hole,
When the charged portion moves vertically downward and the guide portion is inserted into the guide portion insertion hole, and the bottom surface of the charged portion and the upper surface of the collecting portion contact each other, the guide portion contacts the electrically conductive member, Is authorized,
When the charged portion is moved vertically upward and the guide portion is separated from the electrically conductive member, electricity is not applied to the charged portion,
The charging unit includes a plurality of ground rods, and a plurality of tungsten wires spaced apart from the plurality of ground rods by a predetermined distance,
A T-shaped collecting rod for collecting the suspended microorganisms charged in the charged portion is provided,
The charge portion is coupled to the inlet is provided with a support for supporting the collecting rods,
The support part has a through hole through which the collecting rod penetrates, and a catching portion extending to both sides is formed at an upper end of the collecting rod to form a larger than the size of the through hole, and a lower end of the collecting rod penetrates the through hole. Characterized by walking around,
The guide portion is provided with a metal rod, one side of the guide portion is coupled to the bottom surface of the charged portion, the other side of the guide portion is formed extending vertically downward from the bottom surface of the charged portion,
The electrically conductive member is installed directly below the guide part insertion hole to be in contact with or separated from the end of the guide part.
The guide portion includes a first guide portion and a second guide portion,
The electrically conductive member includes a first electrically conductive member contacting or separating from an end of the first guide part, and a second electrically conductive member contacting or separating from an end of the second guide part,
When the end of the first guide portion is in contact with the first electrically conductive member, at the same time the end of the second guide portion is in contact with the second electrically conductive member,
When the end of the first guide portion is separated from the first electrically conductive member, at the same time the end of the second guide portion is separated from the second electrically conductive member,
A power supply unit provided in the collecting unit to supply electricity to the tungsten wire of the charging unit and the flow space of the collecting unit;
One side of the power supply unit is electrically connected to the first electrically conductive member through a first wire, and the other side of the power supply unit is electrically connected to the second electrically conductive member through a second wire, and the second electrically conductive member Is electrically connected to the flow space via a third wire,
The collecting unit is provided with a flow generating unit for generating an air flow, at least one of the upper and lower surfaces of the flow generating unit is provided with an activated carbon fiber filter along the flow direction of the air, the activated carbon fiber filter in the collecting unit Eliminates ozone (O3) generated when collecting suspended microorganisms,
The first wire extends through a space formed between the flow space portion and the flow generating portion,
When the bottom of the charged portion and the upper surface of the collecting portion is in contact with the electricity from the power supply to the charged portion, when electricity is applied to the charged portion is applied to the tungsten wire and the flow generator is driven to float in the air The microorganisms are charged while passing through the charged portion, the floating microorganisms charged in the charged portion flows in the collecting rod direction by an electric field formed around the collecting rod and is attached to the collecting rod, from the charged portion to the collecting portion The introduced air is discharged to the outside of the collecting unit after the airborne microorganisms are collected in the collecting unit,
The collector is further provided with a timer, the timer automatically turns off the power supply after a set time,
When the user lifts or lowers the charged part, the electric charge is disconnected from the power supply and the electric power is not applied, or the electric charge is connected to the power supply and the electric power is applied.
When (+) electricity is applied to the tungsten wire of the charged portion, the floating microorganisms introduced through the inlet are charged to (+) ions and flow into the flow space portion of the collecting portion, and the inside of the flow space portion is (+ ) The electricity is applied and (-) electricity is applied to the collection rod is attached to the collection rod floating microorganisms charged with (+) ions,
When (-) electricity is applied to the tungsten wire, the airborne microorganisms introduced through the inlet are charged with (-) ions and flow into the flow space part of the collecting part, and (-) electricity is applied inside the flow space part. And (+) electricity is applied to the collecting rod so that the floating microorganisms charged with (-) ions are attached to the collecting rod,
The charged part is an electrostatic precipitating type microorganism collecting device, characterized in that completely separated from the collecting part after the collection of the airborne microorganisms.
The method of claim 1,
One side of the collecting rod is coupled to the support portion, the other side of the collecting rod is an electrostatic precipitating type microorganism collecting device is formed extending vertically downward from the support.
The method of claim 1,
And the plurality of ground rods and the plurality of tungsten wires are alternately disposed.

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