KR20220020539A - Conductive Filter for Mask and Mask Filter Module and Mask Mounted the Same - Google Patents

Abstract

The present invention relates to a conductive mask filter which is replaceable, can be washed and reused, and has an excellent collection function, a conductive mask filter module, and a mask on which the mask filter module is mounted. According to one embodiment of the present invention, disclosed is a conductive mask filter comprising: a first mesh of a conductive material connected to a positive electrode of a power source and formed in a mesh form through which air passes; a second mesh of a conductive material connected to a negative electrode of the power source, disposed to face the first mesh and spaced apart from each other, and formed in a mesh form through which air passes; and an insulating layer disposed between the first mesh and the second mesh, insulating the first mesh and the second mesh, and formed of a material through which air passes.

Description

Conductive Filter for Mask and Mask Filter Module and Mask Mounted the Same

The present invention relates to a conductive mask filter that is replaceable, can be washed and reused, and has an excellent collection function, and a conductive mask filter module and a mask on which the mask filter module is mounted.

A mask is a device that covers the user's respiratory tract, such as the nose and mouth, so that germs or dust are not inhaled by breathing or droplets containing germs are not scattered through the breathing of a patient or carrier.

Such a mask is worn in close contact with the user's face to cover the user's respiratory tract, and a structure such as fiber, non-woven fabric or mesh network is applied to filter germs or dust contained in the inhalation and exhalation generated during respiration. In addition, the mesh size of the filtration layer such as fibers or non-woven fabric may be adjusted according to the filtration performance.

However, in such a mask, intake resistance occurs when air passes through the filter layer during intake or exhaust, and such intake resistance tends to increase as the mask performance improves.

Therefore, when a high-performance mask is worn for a long time, breathing becomes difficult and wearing for a long time becomes difficult, and furthermore, there is a problem in that it is difficult to wear the mask when a large amount of respiration is required, such as during exercise.

In addition, most of the masks are disposable, and after washing, the initial performance is not exhibited, resulting in wastage.

An object of the present invention is to provide a conductive mask filter that is easy to breathe and can be washed after separation, and a mask on which the conductive mask filter module and the mask filter module are mounted.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to solve the above problems, according to one aspect of the present invention, the anode of the power source is connected, the first mesh of a conductive material formed in the form of a mesh through which air passes; a second mesh of a conductive material connected to the negative electrode of the power source and disposed to face the first mesh and spaced apart from each other and formed in a mesh shape through which air passes; Disclosed is a conductive mask filter comprising a; an insulating layer disposed between the first mesh and the second mesh, insulating the first mesh and the second mesh, and formed of a material through which air passes.

The first mesh, the second mesh and the insulating layer is mounted, the frame for separating the first mesh and the second mesh; may further include.

The insulating layer may be provided to block the foreign substances collected in the first mesh from moving toward the second mesh.

The second mesh may further include a gas filter layer that is provided on the opposite side of the surface facing the first mesh and removes harmful gases contained in the air passing therethrough.

It is provided on the opposite side of the side facing the first mesh of the second mesh, and may further include a moisture penetration prevention layer for preventing the penetration of moisture while allowing air permeation.

The first mesh or the second mesh may be formed of a copper or graphene material.

The first mesh or the second mesh may be fibers coated with a conductive material on the surface.

a positive terminal provided in the frame, the anode terminal of which the first mesh and the anode of the power source are in electrical contact; and a negative terminal provided in the frame to be spaced apart from the positive terminal and electrically contacting the second mesh and the positive electrode of the power source.

It is inserted into the insulating layer and may include a deposition sensor for detecting whether or not a predetermined amount or more of the foreign matter that has penetrated into the insulating layer is deposited.

The deposition sensor may include: a deposition substrate inserted into the insulating layer on which foreign substances penetrating into the insulating layer are deposited; A pair of sensing electrodes disposed on one surface of the deposition substrate to face each other and spaced apart from each other by a predetermined distance, and disposed to be electrically connected to each other as foreign substances penetrating into the insulating layer through the spaced-apart space are deposited.

On the other hand, according to another aspect of the present invention, a frame formed with an air permeation hole through which air is communicated; at least one pair of conductive mesh layers that are spaced apart from each other and mounted to face each other in the air permeation hole of the frame, are formed in a mesh shape through which air passes, and are provided to connect an anode or a cathode of a power source; an insulating layer provided between the conductive mesh layers of the frame, formed of a material through which air passes, and insulating between the conductive mesh layers; A conductive mask filter module comprising a; is provided in the air permeation port, the inhalation valve is provided so that air flows in only one direction is disclosed.

The conductive mesh layer may be a fiber coated with a conductive material on the surface.

The inhalation valve is provided in the frame and is opened when air flows in the inhalation direction, and may include a valve for closing the air permeation port when flowing in the reverse direction.

The inhalation valve, one or more spokes extending toward the center of the frame from the outer rim coupled to the frame; It is provided on the rear side of the spokes in the air flow direction based on when the air flows in the inhalation direction, is fixed to the spokes, and the edge-side portion forms a free end, so that when air flows in one direction, it is elastically deformed and opened, When the air flows in the reverse direction, it is supported by the spokes or the rim to close the air permeation hole; may include a.

It is provided in the frame and may include at least one pair of power terminal units provided to connect an anode or a cathode of a power source to the conductive mesh layer.

at least one pair of sensing terminal parts which are inserted into the insulating layer and are formed on the frame so that the deposition sensor is connected to an external control unit, including a deposition sensor for detecting whether or not a predetermined amount or more of a foreign material penetrating into the insulating layer is deposited may include

On the other hand, according to another aspect of the present invention, the body to be worn on the face to cover the respirator; a power supply provided in the body; a filter mounting part formed on the body, to which the conductive mask filter module described above is replaceably mounted, and to which the mounted conductive mask filter module is electrically connected to the power supply; an exhaust portion formed in the body, discharging the exhalation discharged from the respirator, and being closed during the inhalation; It may include; a control unit for controlling the power supplied to the conductive mask filter module mounted on the filter mounting unit.

The inhalation valve of the conductive mask filter module may be opened during inspiration and closed during expiration.

The exhaust unit may include an exhaust fan that is controlled by the controller and forcibly exhausts air in the body.

The exhaust unit may further include an exhalation valve that is opened when the air is discharged from the body so that air is not introduced through the exhaust fan during inhalation, and closed when the air flows in the reverse direction.

The filter mounting unit may include a fixing unit for fixing the mask filter module inserted into a mounting hole forming a space into which the mask filter module is inserted.

Controlled by the control unit, by detecting the occurrence of a short circuit in the conductive mesh layer of the mask filter module may further include an alarm unit for alarming the user.

The control unit may further include an alarm unit for notifying the user when it is detected that the amount of foreign matter deposited on the deposition sensor is greater than or equal to a certain amount.

a sealing part provided on a surface of the body in contact with the facial part, and formed of a soft material so as to be in close contact with the facial skin; It is provided in the sealing part, is arranged to be spaced apart to detect whether it comes into contact with the skin, and at least a pair of wearing sensors connected to the control unit; may further include.

The control unit may cut off the power supplied to the exhaust fan or the conductive mask filter module when the skin contact is not detected by the wearing sensor.

According to the conductive mask filter and conductive mask filter module of the present invention, and a mask having the same, the following effects are obtained.

First, since electric current is applied to the mask filter and charged foreign substances are collected, the filtration performance is not limited to the size of the mesh. This can be improved.

Second, the mask filter module is provided as a replaceable type, and filtration performance can be maintained even after washing and drying, so there is an effect of reducing waste while using a clean mask filter module every day.

Third, since a deposition sensor is provided in the mask filter, it is possible to estimate the amount of foreign substances accumulated in the mask filter, so that the mask filter can be replaced in a timely manner.

Fourth, power is supplied to the mask filter module or exhaust fan only when the mask is worn, and the power is automatically cut off when the mask is not worn, thereby reducing battery waste and increasing wearing time.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

The summary set forth above as well as the detailed description of the preferred embodiments of the present application set forth below may be better understood when read in conjunction with the accompanying drawings. For the purpose of illustrating the invention, there are shown in the drawings preferred embodiments. It should be understood, however, that the present application is not limited to the precise arrangements and instrumentalities shown.
1 is an exploded perspective view of a mask filter according to an embodiment of the present invention;
Fig. 2 is a cross-sectional view of the mask filter of Fig. 1;
Fig. 3 is a view showing a deposition sensor of the mask filter of Fig. 1;
Fig. 4 is a perspective view of the mask filter of Fig. 1;
5 is an exploded perspective view of a mask filter module according to an embodiment of the present invention;
Fig. 6 is a cross-sectional view of the mask filter module of Fig. 5;
Figure 7 is a cross-sectional view showing when the inhalation valve of Figure 5 is opened;
Figure 8 is a cross-sectional view showing when the inhalation valve of Figure 5 is closed;
9 is a perspective view showing a mask on which the conductive mask filter module of the present invention is mounted;
10 is a cross-sectional view illustrating a state in which the filter mounting part of the mask on which the conductive filter module of FIG. 9 is mounted and the conductive filter module are combined;
11 is a perspective view illustrating terminals of an inner peripheral surface of a filter mounting part of the mask on which the conductive filter module of FIG. 9 is mounted;
12 is a view showing an exhaust part of the mask to which the conductive filter module of FIG. 9 is mounted;
13 is a view showing a sealing part and a contact sensor of the inner surface of the mask on which the conductive filter module of FIG. 9 is mounted.

Hereinafter, preferred embodiments of the present invention in which the object of the present invention can be specifically realized will be described with reference to the accompanying drawings. In describing the present embodiment, the same names and the same reference numerals are used for the same components, and an additional description thereof will be omitted.

Hereinafter, an embodiment of the conductive mask filter 100 of the present invention will be described.

As shown in FIGS. 1 to 4 , the conductive mask filter 100 according to the present embodiment includes a first mesh 122 and a second mesh 124 , an insulating layer 130 , a frame 110 , and a deposition sensor. (150).

The first mesh 122 is a mesh network formed of a conductive material, and may form a mesh having a size through which air passes, and the anode of a power source may be connected thereto.

The second mesh 124 is connected to the negative electrode of the power source, is formed of a conductive material, and may form a mesh having a size through which air passes.

The first mesh 122 and the second mesh 124 may be disposed to face each other and to be spaced apart from each other.

That is, the first mesh 122 and the second mesh 124 are disposed to face each other and spaced apart from each other, and the conductive mesh layer 120 to which electricity of different polarities is applied may be formed.

The first mesh 122 or the second mesh 124 may be formed of an electrically conductive material such as copper or graphene material, or an electrically conductive material such as copper or graphene material may be coated on the surface of a fiber, etc. will be.

In this embodiment, the first mesh 122 and the second mesh 124 will be described as an example formed of a pure copper material having a purity of 99.9% or more. When the first mesh 122 and the second mesh 124 are formed of pure copper material, the proliferation of bacteria adhering to the surface is suppressed, and the collection efficiency of fine dust or ultrafine dust can be increased. However, the present invention is not necessarily limited thereto, and it may be formed of another conductive material or coated with a conductive material.

An insulating layer 130 that insulates the first mesh 122 and the second mesh 124 may be formed between the first mesh 122 and the second mesh 124 .

The insulating layer 130 may be formed of an insulating material that does not conduct electricity, such as a nonwoven fabric or a sponge, and transmits air.

1 and 2 , the first mesh 122 , the second mesh 124 , and the insulating layer 130 may be mounted on the frame 110 so that positions and intervals thereof may be fixed.

The frame 110 has an air permeation hole 112 through which air is communicated, and as described above, the first mesh 122 and the second mesh 124 and the insulating layer 130 have the air permeation hole. It is mounted within the 112 so that its position and spacing can be fixed.

In addition, the insulating layer 130 insulates the first mesh 122 and the second mesh 124 from each other and at the same time moves the foreign substances collected in the first mesh 122 toward the second mesh 124 . may block it.

That is, when a positive electrode is applied to the first mesh 122 and a negative electrode is applied to the second mesh 124 , foreign substances having a negative charge in the sucked air are collected in the first mesh 122 and positively charged in the sucked air. Foreign substances marked with may be collected in the second mesh 124 . At this time, since the insulating layer 130 insulates between the first mesh 122 and the second mesh 124 , a short circuit between the first mesh 122 and the second mesh 124 may not occur. . In addition, it is possible to block the foreign substances collected in the first mesh 122 from moving to the second mesh 124 riding on the sucked air.

In addition, a gas filter layer 142 may be provided in the air permeation hole 112 of the frame 110 to adsorb and remove harmful gases contained in the air that is sucked in.

In addition, the air permeation hole 112 of the frame 110 is provided with a moisture permeation prevention layer 144 so that moisture contained in the exhaled breath of the human body is absorbed by the first mesh 122 and the second mesh 124 and the insulating layer ( 130) to prevent the insulation between the first mesh 122 and the second mesh 124 from being destroyed.

The moisture penetration prevention layer 144 as described above may be disposed on a side facing the face of the conductive mask filter 100 .

In addition, the frame 110 has an anode terminal 127 provided so that the first mesh 122 and the anode of the power source are in electrical contact, and the second mesh 124 and the cathode of the power source are in electrical contact. A power terminal unit 126 including a negative terminal 128 may be provided. The positive terminal 127 and the negative terminal 128 may be provided to be spaced apart from each other so as not to be in electrical contact with each other.

On the other hand, some of the foreign substances passing through the first mesh 122 toward the second mesh 124 may penetrate and accumulate in the insulating layer 130 .

In this case, a deposition sensor 150 for detecting whether or not a predetermined amount or more of a foreign material penetrating into the insulating layer 130 is deposited may be further provided.

As shown in FIGS. 1 and 3 , the deposition sensor 150 as described above may include a deposition substrate 152 and a sensing electrode 154 .

The deposition substrate 152 may be positioned to be inserted into the insulating layer 130 and form a deposition space in which foreign substances penetrating into the insulating layer 130 are deposited.

The sensing electrodes 154 are spaced apart from each other so as to face each other on one surface of the deposition substrate 152, and may be disposed to be electrically connected to each other as foreign substances penetrating into the insulating layer 130 between the spaces are deposited. there is.

That is, when a foreign material is deposited between the pair of sensing electrodes 154 by a certain amount or more, the pair of sensing electrodes 154 are electrically connected. can do.

In addition, a pair of sensing terminal units 156 through which the pair of sensing electrodes 154 may transmit and receive signals to and from the external control unit 350 may be formed in the frame 110 .

Meanwhile, according to another embodiment of the present invention, the conductive mask filter module 200 in which the conductive mask filter 100 is modularized may be disclosed.

As shown in FIGS. 5 and 6 , the conductive mask filter module 200 may include a frame 110 , a conductive mesh layer 120 , an insulating layer 130 , and an inhalation valve 160 .

The frame 110 is substantially the same as the frame 110 of the above-described embodiment, and the pair of conductive mesh layers 120 includes the first mesh 122 and the second mesh 124 layer of the above-described embodiment. Since the insulating layer 130 is substantially the same as the insulating layer 130 of the above-described embodiment, a detailed description thereof will be omitted. In addition, the deposition sensor 150 may be provided to be buried between the insulating layer 130 .

The inhalation valve 160 may be provided in the air permeation hole 112 of the frame 110 so that air flows in only one direction. At this time, the inhalation valve 160 may be provided on the inner surface of the frame 110 toward the user's face, is opened only when the user inhales, and flows so that air is sucked in, the user in the reverse direction When is exhaled, the air permeation hole 112 is closed so that the exhaled exhalation does not flow toward the pair of conductive mesh layers 120 and the insulating layer 130 .

Exhaled breath by a person contains a large amount of moisture, and when this moisture accumulates on the insulating layer 130, the insulation between the pair of conductive mesh layers 120 may be destroyed, so the inhalation valve 160 When the user breathes in, the air is opened to inhale, and when the user exhales, the exhaled air does not flow toward the pair of conductive mesh layers 120 and the insulating layer 130, so that between the pair of conductive mesh layers 120 breakage of insulation can be prevented.

The inhalation valve 160 as described above, as shown in FIGS. 7 and 8, is provided in the frame 110 to open the air permeation port 112 when air flows in the inhalation direction, and exhale in the reverse direction. When flowing in the direction may include a valve 166 for closing the air permeation port (112).

More specifically, the inhalation valve 160 has an outer rim 162 coupled to the frame 110, and one or more spokes 164 and valve 166 extending from the outer rim 162 toward the center. may include

The valve 166 is provided on the rear side of the spokes 164 in the air flow direction based on when the air flows in the inhalation direction, and is fixed to the spokes 164, and the edge 162 side portion has a free end. By forming, when the air flows in one direction, it is elastically deformed and opened, and when the air flows in the reverse direction, it is supported by the spokes 164 or the rim 162 to close the air permeation port 112. It may be provided.

Such a conductive mask filter module 200 may be formed as a single individual and mounted on a mask 300 to be described later. In addition, since power is applied to the pair of conductive mesh layers 120 to adsorb and filter dust, the performance of the mask can be exhibited by re-applying power after washing and drying after use, so that it can be reused.

Meanwhile, according to another embodiment of the present invention, the mask 300 to which the above-described mask filter module is mounted may be disclosed.

As shown in FIG. 9 , the mask 300 on which the conductive mask filter module is mounted includes a body 310 , a power supply unit 320 , a filter mounting unit 330 , an exhaust unit 340 , and a control unit 350 . can do.

The main body 310 is worn on the user's face and may be provided to cover the respiratory tract such as the nose and mouth. In addition, the body 310 may be formed of a flexible material such as plastic or silicone so as to be in close contact with the user's face without air permeation. In addition, the main body 310 may be formed of a transparent material so that the wearer's mouth shape can be seen from the outside.

The main body 310 may be provided with a power supply 320 . The power supply unit 320 may be equipped with a replaceable battery or a rechargeable secondary battery.

The filter mounting part 330 may be opened so that the aforementioned conductive mask filter module 200 can be installed in a replaceable manner. In this case, when the conductive mask filter module 200 is mounted, the filter mounting unit 330 may be electrically connected to the power supply unit 320 to receive power and signals.

The conductive mask filter module 200 mounted on the filter mounting unit 330 may be electrically connected to the power supply unit 320 to supply power. To this end, as shown in FIG. 11 , on the inner circumferential surface of the filter mounting part 330 , the power terminal part 126 and the sensing terminal part 156 provided in the frame 110 of the conductive filter mask module are in electrical contact with the terminal part. 332 may be formed.

In addition, a fixing part 334 for fixing the mounted conductive mask filter module 200 may be provided on an inner circumferential surface of the filter mounting part 330 . As shown in FIG. 10 , the fixing part 334 may include a protrusion 336 protruding from an inner circumferential surface of the filter mounting part 330 . In addition, a groove 338 in which the protrusion is accommodated may be formed in the frame 110 of the conductive mask filter module 200 . Of course, a protrusion may be formed on the frame 110 of the conductive mask filter module 200 , and a groove may be formed on an inner circumferential surface of the filter mounting part 330 . Accordingly, the conductive mask filter module 200 may be detachably fixed to the filter mounting part 330 while the projection 336 is accommodated in the groove 338 by the elasticity of the projection or the frame 110 .

In this case, the conductive mask filter module 200 may be provided to be mounted on the filter mounting part 330 from the rear side facing the face of the main body 110 . Of course, the present invention is not limited thereto, and it is not limited to the mounting direction of the conductive mask filter module 200 , such as may be mounted from the front side facing the outside of the main body 110 .

The conductive mask filter module 200 may be mounted on the filter mounting part 330 to filter external air when the user breathes in and introduce the filter into the body 310 . As shown in FIG. 10 , the inhalation valve 160 provided in the conductive mask filter module 200 may be provided to open when the user breathes in and close when the user breathes out.

The exhaust unit 340 is formed in the main body 310 and may be provided to discharge the exhaled breath discharged through the user's nose or mouth, etc. to the outside of the main body 310 . At this time, the exhaust unit 340 may be closed during inhalation so that external air is introduced into the body 310 only through the conductive mask filter module 200 .

In addition, the control unit 350 may be provided to control the power supplied to the conductive mask filter module 200 mounted on the filter mounting unit 330 .

Meanwhile, as shown in FIG. 12 , the exhaust unit 340 is controlled by the control unit 350 , and an exhaust fan 342 that forcibly exhausts air in the main body 310 to the outside of the main body 310 . And it may include an exhalation valve (344).

The exhaust fan 342 may be mounted on the mask, and may be provided to forcibly exhaust the air in the main body 310 to the outside of the main body 310 while rotating under the control of the controller 350 . In addition, in order to prevent unfiltered air from flowing back into the body 310 through the exhaust fan 342 when breathing in, when air is discharged from the body 310 (ie, when exhaling), open And, when flowing in the reverse direction (ie, when breathing in) may be provided with an exhalation valve 344 that is closed.

Meanwhile, the main body 310 or the control unit 350 may further include an alarm unit 360 . The alarm unit 360 may be provided to inform whether and when to replace the mask filter module.

When moisture is excessively accumulated in the insulating layer 130 of the mask filter module, the insulation of the first mesh 122 and the second mesh 124 may be destroyed. In this way, when the insulation of the first mesh 122 and the second mesh 124 is broken and a short occurs, the conductive mesh layer 120 may lose the ability to collect dust.

Therefore, when a short circuit occurs in the first mesh 122 and the second mesh 124 , the alarm unit 360 detects this in the control unit 350 and prompts the user to replace the conductive mask filter module 200 . An alarm can be made by means of sound or lighting.

In addition, the alarm unit 360 counts the amount of time that power is supplied after the mask filter module is mounted, and when a preset time elapses, sounds or lights an alarm inducing replacement of the conductive mask filter module 200 The user may be alerted by such means.

In addition, a separate environmental sensor 370 is mounted on the outside of the mask body 310 to sound or light an alarm indicating that the life of the conductive mask filter module 200 has arrived in consideration of the exposure time in the environment. The user can be alerted.

In this case, the environmental sensor 370 may be a sensor that measures the concentration of dust or measures the concentration of harmful gas.

In addition, when the deposition sensor 150 is connected to the controller 350 and it is detected that the amount of dust deposited in the deposition sensor 150 is greater than or equal to a set amount, inducing replacement of the conductive mask filter module 200 The alarm may be notified to the user by means of sound or lighting.

On the other hand, as shown in FIG. 13 , a sealing part 380 formed of a soft member such as silicone may be provided on the surface of the mask body 310 in contact with the facial part to be in close contact with the skin of the face. In addition, at least a pair of wearing sensors 382 that are provided in the sealing part 380 , are spaced apart to detect whether they come in contact with the skin, and are connected to the controller 350 may be provided.

Therefore, when the user wears the mask, it can be detected that the wearing sensor 382 is in contact with the skin, and when the user takes off the mask, the wearing sensor 382 does not come into contact with the skin, so it is determined that the mask is removed can do.

On the other hand, the control unit 350 prevents power wasted by blocking the power supplied to the exhaust fan 342 or the conductive mask filter module 200 when the wearing sensor 382 does not detect the skin contact. can do.

In addition, the control unit 350 may include a switch 352 for manually turning on/off power supplied to the exhaust fan 342 and the conductive mask filter module 200 . Accordingly, it is possible to prevent wasted power by turning off the switch 352 during long-term storage.

As described above, the preferred embodiments according to the present invention have been described, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope of the present invention in addition to the above-described embodiments is understood by those of ordinary skill in the art. It is obvious to them. Therefore, the above-described embodiments are to be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description, but may be modified within the scope of the appended claims and their equivalents.

100: conductive mask filter 110: frame
112: air permeation hole 120: conductive mesh layer
122: first mesh 124: second mesh
126: power terminal 127: positive terminal
128: negative terminal 130: insulating layer
142: gas filter layer 144: moisture penetration prevention layer
150: deposition sensor 152: deposition substrate
154: sensing electrode 156: sensing terminal part
160: inhalation valve 162: rim
164: spoke 166: valve
200: conductive mask filter module 300: mask
310: body 320: power supply
330: filter mounting part 332: terminal part
334: fixing part 336: protrusion
338: groove 340: exhaust
342: exhaust fan 344: exhalation valve
350: control unit 352: switch
360: alarm unit 370: environmental sensor
380: sealing unit 382: wear sensor

Claims (25)

A first mesh of a conductive material connected to the anode of the power source and formed in a mesh shape through which air passes;
a second mesh of a conductive material to which the negative electrode of the power source is connected, the second mesh is disposed to face the first mesh and is spaced apart from the first mesh, and is formed in the form of a mesh through which air passes;
an insulating layer disposed between the first mesh and the second mesh, insulating the first mesh and the second mesh, and formed of a material through which air passes;
A conductive mask filter comprising a. According to claim 1,
a frame on which the first mesh, the second mesh, and the insulating layer are mounted, and spaced apart from the first mesh and the second mesh;
Conductive mask filter further comprising a. According to claim 1,
The insulating layer is a conductive mask filter provided to block the movement of foreign substances collected in the first mesh toward the second mesh. According to claim 1,
A conductive mask filter provided on the opposite side of the surface of the second mesh facing the first mesh, and further comprising a gas filter layer for removing harmful gases contained in the transmitted air. According to claim 1,
A conductive mask filter provided on the opposite side of the side facing the first mesh of the second mesh, and further comprising a moisture penetration prevention layer for preventing moisture penetration while allowing air to permeate. According to claim 1,
The first mesh or the second mesh is a conductive mask filter formed of a copper or graphene material. According to claim 1,
The first mesh or the second mesh is a conductive mask filter whose surface is a fiber coated with a conductive material. 3. The method of claim 2,
a positive terminal provided in the frame, the anode terminal of which the first mesh and the anode of the power source are in electrical contact;
a negative terminal provided on the frame to be spaced apart from the positive terminal and electrically contacting the second mesh and the positive electrode of the power supply;
A conductive mask filter comprising a. According to claim 1,
A conductive mask filter including a deposition sensor inserted into the insulating layer and configured to detect whether or not foreign substances penetrating into the insulating layer are deposited over a certain amount. 10. The method of claim 9,
The deposition sensor
a deposition substrate inserted into the insulating layer, on which foreign substances penetrating into the insulating layer are deposited;
a pair of sensing electrodes spaced apart from each other so as to face each other on one surface of the deposition substrate and electrically connected to each other as foreign substances penetrating into the insulating layer are deposited therebetween;
A conductive mask filter comprising a. a frame formed with an air permeation hole through which air is communicated;
At least one pair of conductive mesh layers are mounted to face each other in the air permeation hole of the frame, are formed in a mesh shape through which air passes, and are provided to connect the anode or the cathode of the power source;
an insulating layer provided between the conductive mesh layers of the frame, formed of a material through which air passes, and insulating between the conductive mesh layers;
an inhalation valve provided in the air permeation port and provided so that air flows in only one direction;
A conductive mask filter module comprising a. 12. The method of claim 11,
The conductive mesh layer is a conductive mask filter module whose surface is a fiber coated with a conductive material. 12. The method of claim 11,
The inhalation valve,
A conductive mask filter module including a valve provided in the frame that is opened when air flows in an inhalation direction, and closes the air permeation port when it flows in a reverse direction. 12. The method of claim 11,
The inhalation valve,
one or more spokes extending from an outer edge coupled to the frame toward the center of the frame;
It is provided on the rear side of the spokes in the air flow direction based on when the air flows in the inhalation direction, is fixed to the spokes, and the edge-side portion forms a free end, so that when air flows in one direction, it is elastically deformed and opened, A conductive mask filter module comprising a; a valve supported by the spokes or rims to close the air permeation port when air flows in the reverse direction. 12. The method of claim 11,
A conductive mask filter module including at least one pair of power terminals provided in the frame and provided to connect an anode or a cathode of a power source to the conductive mesh layer. 12. The method of claim 11,
It is inserted into the insulating layer and includes a deposition sensor that detects whether foreign substances that have penetrated into the insulating layer are deposited over a certain amount,
A conductive mask filter module including at least a pair of sensing terminals formed in the frame so that the deposition sensor is connected to an external control unit. a body worn on the face to cover the respiratory system;
a power supply provided in the body;
a filter mounting part formed on the main body, to which the conductive mask filter module of any one of claims 11 to 16 is replaceably mounted, the mounted conductive mask filter module being electrically connected to the power supply;
an exhaust portion formed in the body, discharging the exhalation discharged from the respirator, and being closed during the inhalation;
a control unit for controlling power supplied to the conductive mask filter module mounted on the filter mounting unit;
A mask on which a conductive mask filter module comprising a is mounted. 18. The method of claim 17,
The inhalation valve of the conductive mask filter module is a mask mounted with a conductive mask filter module that is opened during inspiration and closed during expiration. 18. The method of claim 17,
The exhaust part is controlled by the controller, and a conductive mask filter module including an exhaust fan for forcibly exhausting air in the body is mounted on the mask. 20. The method of claim 19,
The exhaust unit, the conductive mask filter module is mounted on a mask that is open when the air is discharged from the body so that air is not introduced through the exhaust fan during inhalation, and closes when the air flows in the reverse direction. 18. The method of claim 17,
The filter mounting unit,
a fixing part for fixing the mask filter module inserted into a mounting hole forming a space into which the mask filter module is inserted;
A mask on which a conductive mask filter module comprising a is mounted. 18. The method of claim 17,
A mask on which a conductive mask filter module is mounted, which is controlled by the control unit, and further includes an alarm unit configured to detect the occurrence of a short circuit in the conductive mesh layer of the mask filter module and alarm the user. 23. The method of claim 22,
When the control unit detects that the amount of foreign matter deposited on the deposition sensor provided in the mask filter module is greater than or equal to a certain amount, the mask is equipped with a conductive mask filter module further comprising an alarm unit for alarming the user. 20. The method of claim 19,
a sealing part provided on a surface of the body in contact with the facial part, and formed of a soft material so as to be in close contact with the facial skin;
at least one pair of wearing sensors provided in the sealing part, spaced apart to detect whether they come in contact with the skin, and connected to the control unit;
A mask on which a conductive mask filter module further comprising a is mounted. 25. The method of claim 24,
the control unit
A mask equipped with a conductive mask filter module that cuts off power supplied to the exhaust fan or conductive mask filter module when skin contact is not detected by the wear sensor.

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