KR20210130884A - Mask - Google Patents

Abstract

The present invention relates to a mask. Specifically, according to an embodiment of the present invention, a mask for filtering air flowing therein includes: a face cover which is provided to be worn on the face of a user; a respiratory assistance device which can be coupled to the face cover part; at least one sensor part which is provided on at least one of the face cover part and the respiratory assistance device; and a calculation part which calculates at least one of the filter usage time and the remaining life time of the filter based on the data measured from the at least one sensor part.

Description

mask {MASK}

The present invention is an invention for a mask.

Recently, as various problems of air pollution have occurred due to industrialization, they are included in various harmful substances in the air. These harmful substances may include various kinds of soot, fine dust, which has recently become a serious social issue, as well as allergy-causing pollen and various bacterial substances.

On the other hand, when harmful substances penetrate into the respiratory tract of the human body, various respiratory diseases may be caused and serious problems may be caused. In particular, it is necessary to wear a mask when the air quality is poor, such as a yellow dust phenomenon, and users who are likely to be exposed to a polluted air environment for a long time in a place with a lot of fine dust can wear a mask to prevent respiratory diseases.

In general, the mask is in close contact with the user's face, it is possible to prevent germs or dust in the air from entering the user's nose and mouth. In particular, the mask in which the filter is mounted on the mask may allow the user to inhale the air introduced through the filter. In a mask equipped with such a filter, the face joint is made of a non-breathable material, and when the user breathes in, external air passes through the filter and flows into the face joint to assist the user in breathing.

In a mask equipped with a conventional filter, if the filter is used for a long time, the performance of the filter for filtering contaminants, bacteria and fine dust deteriorates. As such, when the performance of the filter is deteriorated, it is not possible to effectively prevent the inflow of contaminants, bacteria, and fine dust into the respiratory tract, so there is a need to replace the filter in a timely manner. However, if the filter is frequently replaced even though the life of the filter is remaining, it is costly, and if the filter is replaced after the life of the filter is over, a mask that has lost its function is used. As such, when the user knows the filter replacement timing by informing the user of the filter lifespan, the filter can be replaced at an appropriate time. Therefore, there is a need for a device capable of informing the user of the filter lifespan.

Accordingly, the embodiments of the present invention were invented with the above background in mind, and an object of the present invention is to provide a mask capable of informing a user of a filter life or replacement time in a mask equipped with a filter.

According to an aspect of the present invention, there is provided a mask for filtering air flowing therein, comprising: a face cover provided to be worn on a user's face; Respiratory assistance device that can be coupled to the face cover; at least one sensor unit provided on at least one of the face cover unit and the respiratory assistance device; and a calculation unit for calculating at least one of a filter usage time and a remaining life time of the filter based on data measured from the at least one sensor unit, the mask may be provided.

According to embodiments of the present invention, there is an effect of notifying the user of the filter life or replacement time in the mask equipped with the filter.

1 is a perspective view of a mask according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view of the mask of FIG. 1 .
Figure 3 is an exploded perspective view of the respiratory assistance device of Figure 1;
Figure 4 is a rear perspective view of the respiratory assistance device of Figure 1;
5 is a view showing a state in which the breathing assistance device is coupled to the face cover of FIG. 1 .
6 is a cross-sectional view taken along line A-A' of FIG. 1 .
FIG. 7 is an enlarged view of part B of FIG. 2 .
FIG. 8 is a cross-sectional view taken along line C-C' of FIG. 4 .
9 is a bottom perspective view of the face cover of FIG. 1 .
FIG. 10 is a cross-sectional view taken along line D-D' of FIG. 9 .
11 is a view illustrating a state in which the opening/closing member is spaced apart from the bonding member in FIG. 9 .
12 is a diagram conceptually illustrating a relationship between a sensor unit, a display unit, a calculation unit, and a storage unit according to the first embodiment of the present invention.

Hereinafter, specific embodiments for implementing the spirit of the present invention will be described in detail with reference to the drawings.

In addition, in the description of the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, when it is said that a component is 'connected', 'supported', 'coupled', or 'fluid' to another component, it may be directly connected, supported, coupled, or moved to the other component, but other components in the middle It should be understood that elements may exist

The terminology used herein is only used to describe specific embodiments and is not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In addition, in this specification, the expression of the upper side, the lower side, the side, etc. is described with reference to the drawings in the drawings, and it is clarified in advance that if the direction of the object is changed, it may be expressed differently. For the same reason, some components are exaggerated, omitted, or schematically illustrated in the accompanying drawings, and the size of each component does not fully reflect the actual size.

Also, terms including an ordinal number such as 1st, 2nd, etc. may be used to describe various components, but the components are not limited by these terms. These terms are used only for the purpose of distinguishing one component from another.

The meaning of "comprising," as used herein, specifies a particular characteristic, region, integer, step, operation, element and/or component, and other specific characteristic, region, integer, step, operation, element, component, and/or group. It does not exclude the existence or addition of

Hereinafter, a detailed configuration of the mask 1 including the respiratory assistance device 100 according to an embodiment of the present invention will be described with reference to the drawings.

Hereinafter, referring to FIG. 1 , the mask 1 according to an embodiment of the present invention can be used in close contact with the user's face, and prevents pollutants, germs and dust in the air from entering the user's nose and mouth. can do. In addition, the mask 1 may assist a user wearing the mask 1 to breathe. Accordingly, the user can comfortably breathe (inhale) even while wearing the mask 1 . The mask 1 may include a breathing assistance device 100 , a face cover unit 200 , and a filter 300 .

2 and 3 , the breathing assistance device 100 may assist the user wearing the mask 1 to breathe. The respiratory assistance device 100 may provide a passage through which the air that has passed through the filter 300 flows to the face cover unit 200 , and the respiratory assistance device 100 receives the air that has passed through the filter 300 on the face. It may flow toward the cover part 200 . The respiratory assistance device 100 may have one side selectively coupled to the face cover unit 200 and the other side selectively coupled to the filter 300 . The respiratory assistance device 100 may include a body part 110 , a spacer 120 , and a fan unit 130 .

The body 110 may support the spacer 120 and the fan unit 130 . The body part 110 may be connected to the face cover part 200 and the filter 300 between the face cover part 200 and the filter 300 . In other words, one side of the body part 110 may be coupled to the face cover part 200 through a mask connector 111 to be described later, and the other side of the body part 110 is via a filter coupling part 124 to be described later. It may be combined with the filter 300 . In addition, the body part 110 may be disposed between the center of rotation of the blade 132 to be described later and the face cover part 200 .

Referring to FIG. 4 , a mask connector 111 for selectively coupling with the face cover part 200 may be provided on one side of the body part 110 , and the body part 110 may include a mask connector 111 . It may be selectively coupled to the face cover 200 through the. The mask connector 111 may be supported on one surface of the body 110 . Also, a connector groove 111a into which a port protrusion 231 of an intake port 230 to be described later may be inserted may be formed in the mask connector 111 . A port protrusion 231 may be inserted into the connector groove 111a , and the shape of the connector groove 111a may be formed to correspond to the shape of the port protrusion 231 . When the mask connector 111 and the intake port 230 are coupled, the fan unit 130 may exhaust air from the air passage 112 in a direction passing through the intake port 230 and the mask connector 111 . .

Hereinafter, with reference to FIGS. 5 and 6 , a process of coupling the body part 110 to the face cover part 200 in order to mount the breathing assistance device 100 to the face cover part 200 will be described in detail. . First, the body part 110 is positioned on the intake port 230 so that the port protrusion 231 is positioned at a position corresponding to the connector groove 111a. The intake port 230 is inserted in the inner direction (eg, the left side of FIG. 6 ) of the body part 110 so that the port protrusion 231 passes through the connector groove 111a. At this time, when the body part 110 is rotated by a predetermined angle in one direction (eg, clockwise in FIG. 5 ) with respect to the face cover part 200 , the port protrusion 231 is supported on the inside of the mask connector 111 . can be As such, when the port protrusion 231 is supported by the mask connector 111 , the respiratory assistance device 100 may be mounted on the face cover unit 200 . As such, when the mask connector 111 and the intake port 230 are coupled, the mask connector 111 may communicate with the intake port 230 . Also, the air introduced into the body 110 may flow into the face cover 200 through the mask connector 111 and the intake port 230 .

On the other hand, in order to remove the breathing assistance device 100 from the face cover part 200, the body part 110 is placed on the face cover part 200 so that the port protrusion 231 is placed at a position corresponding to the connector groove 111a. It is rotated by a predetermined angle in the other direction (eg, counterclockwise in FIG. 5 ). At this time, when the port protrusion 231 is placed at a position corresponding to the connector groove 111a, the port protrusion 231 passes through the connector groove 111a in the outward direction of the body 110 (eg, the right side of FIG. 6 ). ) to move the body part 110 to move. In addition, when the port protrusion 231 is separated from the mask connector 111 , the respiratory assistance device 100 may be detached from the face cover unit 200 .

As such, the body part 110 may be coupled to the face cover part 200 by coupling the mask connector 111 to the intake port 230 . Also, when the intake port 230 is coupled to the mask connector 111 , the mask connector 111 and the intake port 230 may be communicatively connected. Accordingly, the air introduced into the body 110 may flow to the inside of the face cover 200 through the mask connector 111 and the intake port 230 .

Meanwhile, an air passage 112 for the air passing through the filter 300 to flow into the body 110 may be formed inside the body 110 . The air passage 112 may be formed to pass through the body portion 110 , and may be formed to communicate with the mask connector 111 . In addition, the air passage 112 may communicate with an inlet 123 to be described later. Accordingly, the air passing through the filter 300 may flow into the air passage 112 through the inlet 123 . In addition, at least a portion of the fan unit 130 may be disposed inside the air passage 112 . As such, by disposing the fan unit 130 inside the air passage 112 , the air introduced into the air passage 112 may flow to the inside of the body 110 by the fan unit 130 . The air passage 112 may be opened to face the filter 300 or face the face of the user wearing the mask 1 . Also, the air passage 112 may have a circular cross-section.

Referring back to FIGS. 2 and 6 together with FIG. 7 , the spacer 120 may be supported on one side of the body 110 and may be configured to be fastened to the filter 300 . When the spacer 120 is fastened to the filter 300 , at least a portion of the spacer 120 is inserted into the filter 300 . In addition, the spacer 120 may be inserted into any one of the first filter layer 310 and the second filter layer 320 to separate the first filter layer 310 and the second filter layer 320 , which will be described later. For example, the spacer 120 may be inserted through the second filter layer 320 to support the first filter layer 310 , thereby providing a space between the first filter layer 310 and the second filter layer 320 .

In addition, the spacer 120 may maintain a space inside the filter 300 , which will be described later. For example, air passing through the filter 300 by the user's breathing (inhalation) and staying in the filter 300 for a predetermined time flows to the face cover 200 through the breathing assistance device 100 . If the mask 1 does not have the spacer 120 , the air inside the filter 300 is discharged to the breathing assistance device 100 so that the first filter layer 310 and the second filter layer 320 may be in close contact with each other. When the first filter layer 310 and the second filter layer 320 are in close contact with each other, the user's breathing may be disturbed. However, by inserting the spacer 120 into any one of the first filter layer 310 and the second filter layer 320 to space the first filter layer 310 and the second filter layer 320 apart, the first filter layer 310 and It is possible to prevent the second filter layer 320 from being in close contact. Accordingly, a predetermined space inside the filter 300 may be maintained without being destroyed by the spacer 120 , and the spacer 120 may be used by the user due to the adhesion between the first filter layer 310 and the second filter layer 320 . It can prevent obstruction of breathing.

In addition, the spacer 120 may be configured to be removable from the body portion 110 . The spacer 120 may include a support 121 , a connection part 122 , and a filter fastening part 124 .

Referring back to FIG. 6 , one or more supports 121 may be provided, and may support the first filter layer in order to prevent the first filter layer 310 and the second filter layer 320 from adhering to each other. At least a portion of the support 121 may be inserted into the filter 300 when the filter fastening part 124 is fastened to the filter 300 . In addition, when the one or more supports 121 are inserted through the second filter layer 320 , the first filter layer 310 and the second filter layer 320 may be separated by supporting the first filter layer 310 . For example, the one or more supports 121 may be formed to protrude from the filter fastening part 124 in a direction inserted into the filter 300 (eg, the left side of FIG. 6 ).

In addition, the one or more supports 121 may include a plurality of supports 121 , and when the plurality of supports 121 are provided, ends of the plurality of supports 121 may be connected to the connection part 122 . For example, one end of the support 121 may be connected to the filter coupling part 124 , and the other end of the support 121 may be connected to the connection part 122 . Also, the plurality of supports 121 may include a first support 121a and a second support 121b. The first support 121a and the second support 121b may be spaced apart from each other to provide a space for the fan unit 130 to be disposed. As such, the fan unit 130 may be interposed between the first support 121a and the second support 121b, and may be supported by the first support 121a and the second support 121b. In addition, a pair of each of the first supporter 121a and the second supporter 121b may be further provided. On the other hand, as shown in FIG. 7 , at least a portion of the plurality of supports 121 may be blocked by the fan unit 130, and at least another portion of the plurality of supports 121 may be opened and an inlet (to be described later) ( 123) may be formed.

The connection part 122 may prevent the first filter layer 310 and the second filter layer 320 from being in close contact by separating the first filter layer 310 and the second filter layer 320 from each other. In other words, when one or more supports 121 are inserted through the second filter layer 320 , the connection part 122 is spaced apart from the second filter layer 320 so that the first filter layer 310 and the second filter layer 320 are separated. adhesion can be prevented. For example, the connection part 100 may be in close contact with the first filter layer 310 when the spacer 120 is inserted through the second filter layer 320 . In addition, the connection part 122 may cover one surface of the fan unit 130 .

The connection part 122 may be supported by the support 121 so as to be spaced apart from the filter fastening part 124 by a predetermined distance. In addition, the connection part 122 may be supported by the support 121 to face the inner surface of the filter 100 . For example, the connection part 122 may be in contact with the inner surface of the filter 100 .

In addition, the connection part 122 may have a plate shape and may have a smooth surface. When the spacer 120 is inserted into the filter 300 and the filter 300 rotates with respect to the respiratory assistance device 100 for fastening the filter 300, the end of the support 121 and the filter 300 Friction between the inner surfaces can be reduced.

Meanwhile, referring to FIGS. 3 , 6 and 7 , an inlet 123 may be formed in the spacer 120 . The air that has passed through the filter 300 is introduced into the spacer 120 through the inlet 123 , and the air introduced into the spacer 120 can flow into the air passage 112 through the fan unit 130 . have. The inlet 123 may communicate with the inner side of the filter 300 , and may communicate with the air passage 112 . In addition, the air passing through the inlet 123 may flow toward the fan unit 130 disposed inside the air passage 112 through the filter fastening part 124 , and the body part by the fan unit 130 . (100) can flow inward. The inlet 123 may be formed between at least some of the plurality of supports 121 . In other words, the inlet 123 may be formed between at least a portion of the plurality of supports 121 that is not blocked by the fan unit 130 . On the other hand, air flowing through the filter 300 to the inlet 123 passes through the inlet 123 and the air passage 112 even when the fan unit 130 is not driven and flows into the body 110 . can do. In addition, a plurality of inlet 123 may be provided.

The inlet 123 may include a first inlet 123a and a second inlet 123b. As such, the first inlet 123a and the second inlet 123b are formed on both sides of the spacer 120 , so that the air passing through the filter 300 is transferred to both sides of the spacer 120 (eg, the upper side of FIG. 6 ). and the lower side) to the inside of the body part 100 . In addition, a part of the air that has passed through the filter 300 flows to the fan unit 130 through the first inlet 123a, and another part of the air that has passed through the filter 300 flows through the second inlet 123b. flow to the fan unit 130 . For example, the first inlet 123a and the second inlet 123b may be formed between at least some of the plurality of supports 121 , and may be formed symmetrically with respect to the center of the spacer 120 . .

Referring back to FIG. 6 , the filter fastening part 124 may couple the filter 300 and the breathing assistance device 100 to each other. The filter fastening part 124 may have a shape that can be inserted and coupled to the fixture 330 of the filter 300 . Accordingly, the filter coupling part 124 is coupled to the fixture 330 of the filter 300 , thereby coupling the spacer 120 and the filter 300 . One side of the filter coupling part 124 may be supported by the body part 110 , and the other side of the filter coupling part 124 may support a plurality of supports 121 . In addition, the filter fastening part 124 may be detached from the body part 110 . Accordingly, since the filter fastening part 124 is removed from the body part 110 , the spacer 120 may be selectively coupled to the body part 110 .

In this way, the user combines the body part 110 with the intake port 230 in a state in which the filter 300 is coupled to the filter coupling part 124 to assist the breathing apparatus 100, the face cover part 200 and the filter. (300) can be used integrally. However, the shape of the filter coupling part 124 may be the same as that of the intake port 230 . Accordingly, the user may directly couple the filter 300 to the face cover 200 , and it is also possible to integrally use the filter 300 and the face cover 200 without the breathing assistance device 100 .

Referring to FIG. 8 , the fan unit 130 may flow the air introduced into the inlet 123 through the filter 300 to the inside of the body part 100 . A part of the fan unit 130 may be disposed inside the air passage 112 , and the air introduced into the air passage 112 may flow into the body portion 100 . For example, the fan unit 130 may discharge air in a direction opposite to the face of the mask 1 user, and may receive air in a direction perpendicular to the direction in which the air is discharged. In other words, the flow direction of the air in the filter 300 and the flow direction of the air discharged by the fan unit 130 may be vertical. In addition, the fan unit 130 may be arranged such that a part thereof is placed in the air passage 112 .

Meanwhile, a part of the fan unit 130 may be inserted into the filter 300 , and may be disposed inside the filter 300 . Another part of the fan unit 130 may be disposed inside the filter 300 in a direction perpendicular to the direction in which the filter 300 extends (eg, the vertical direction in FIG. 6 ). The fan unit 130 may be supported by the body part 100 and the spacer 120 . Also, the fan unit 130 may be disposed inside the spacer 120 . The fan unit 130 may be surrounded by a plurality of supports 121 and a connection part 122 . At least a portion of the fan unit 130 is disposed inside the space surrounded by the plurality of supports 121 and the connection part 122 , thereby preventing interference between the fan unit 130 and the filter 300 . Accordingly, the fan unit 130 is disposed inside the filter 300 to allow the air that has passed through the inlet 123 from the filter 300 to flow into the body 110 without interference from the filter 300 . .

In addition, when the fan unit 130 is driven, when the fan unit 130 is not driven, the air at a higher flow rate than the flow rate of the air flowing into the body 110 through the air passage 112 is generated by the body unit. (110) can flow inward. As such, the fan unit 130 may assist the user's breathing by flowing a larger amount of air into the face cover 200 . The fan unit 130 may include a fan body 131 , a blade 132 , and a rotation shaft 133 .

The fan body 131 may support one or more of the blade 132 and the rotation shaft 133 . The fan body 131 may be disposed inside the spacer 120 and the air passage 112 , and may be supported by one or more of the plurality of supports 121 and the connection part 122 . Also, the fan unit 130 may be fixed to the spacer 120 by interposing the fan body 131 between the plurality of supports 121 of the spacer 120 . Also, a portion of the fan body 131 may be disposed between at least some of the plurality of supports 121 , and may block at least some of the plurality of supports 121 . In addition, the fan body 131 may guide the air so that the flow of air by the blade 132 is directed toward the inside of the mask 1 . In other words, air may be guided between the face cover unit 200 and the user's face by the fan body 131 .

The blade 132 is provided to rotate along a predetermined rotation path, and the air introduced into the spacer 120 through the inlet 123 may flow into the body 110 . The blade 132 rotates about a predetermined rotation shaft 133 extending in one direction, thereby allowing air to flow through the air passage 112 . In addition, the blade 132 may discharge air in a direction perpendicular to the direction in which the rotation shaft 133 extends. The fan unit 130 may be disposed such that the rotating shaft 133 is spaced apart from the face cover 200 by a predetermined distance. For example, the fan unit 130 may be arranged such that the rotation shaft 133 of the blade 132 is placed outside the air passage 112 , and in this case, the rotation center of the blade 132 is the filter 300 . can be placed within The blade 132 may be disposed inside the fan body 131 .

Meanwhile, one or more blades 132 may be provided. While the one or more blades 132 rotate, each blade 132 may rotate proximate to the air passage 112 in some of its rotational paths and away from the air passages 112 in other portions of its rotational path. As such, the one or more blades 132 may rotate some of the rotation paths toward the air passages 112 and some away from the air passages 112 , thereby allowing air to flow through the air passages 112 . . When a plurality of blades 132 are provided, some of the plurality of blades 132 may be covered by the connection part 122 . In this case, the connection part 122 may prevent the blade 132 from interfering with the inner surface of the filter 300 .

These blades 132 may be arranged to extend in parallel along the center of rotation. In other words, the blade 132 may be oriented in a direction parallel to the rotation shaft 133 . Also, the blade 132 may be bent and extended from the center of rotation to the outside of the rotation path. The blade 132 may have the same shape as the radius of curvature at one side of the center of rotation and the radius of curvature at the other side of the center of rotation. In other words, the blades 132 may be formed to be symmetrical with respect to an imaginary plane passing through the center of the plurality of blades 132 .

The rotation shaft 133 may support the blade 132 and may be an axis extending along the rotation center of the blade 132 . The rotation shaft 133 may extend along the axial direction. For example, the axial direction may be a direction in which the rotating shaft 133 extends in FIGS. 3 and 7 . The rotation shaft 133 is a direction perpendicular to the direction in which the air introduced into the spacer 120 through the inlet 123 flows into the air passage 112 on average (eg, the right direction in FIG. 6 ) ( For example, it may be formed to extend in the vertical direction of FIG. 6 ).

Referring back to FIG. 2 , the face cover unit 200 may be provided to be worn on the user's face, and may be in close contact with the user's face so as to cover the user's nose and mouth. The face cover unit 200 may be made of an impermeable material, and may have a shape corresponding to the user's face in order to more easily adhere to the user's face. In addition, a separate strap (not shown) may be provided on the face cover unit 200 to be coupled to the user's face. The face cover 200 may include a bonding member 210 , an air inlet 220 , and an intake port 230 .

The bonding member 210 may provide a portion to be worn on the user's face, and may be in close contact with the user's face to cover the user's nose and leaves. The bonding member 210 may prevent pollutants, germs and dust in the air from entering the user's respiratory tract.

The air inlet 220 may provide a passage through which air is introduced into the inside of the bonding member 210 from the outside of the bonding member 210 . The air inlet 220 may be provided on one side of the bonding member 210 . However, in the present specification, the air inlet 220 is shown to be formed on one side of the face cover 200 , but this is only an example and the air inlet 220 may be formed on both sides of the face cover 200 . And, it is also possible to be formed on the center line (C) of the face cover portion (200).

The intake port 230 may provide a portion to which the respiratory assistance device 100 is coupled to the face cover unit 200 . The intake port 230 may be formed to protrude from the air inlet 220 . Also, a port protrusion 231 may be formed in the intake port 230 . The port protrusion 231 may protrude from the intake port 230 and may have a shape corresponding to the shape of the connector groove 111a. In addition, the port protrusion 231 may be inserted into the mask connector 111 through the connector groove 111a, and when the body part 110 rotates at a predetermined angle with respect to the face cover part 200, the port protrusion ( 231 may be supported by the mask connector 111 . Accordingly, the port protrusion 231 is supported by the mask connector 111 , so that the respiratory assistance device 100 may be supported by the face cover unit 200 . Meanwhile, the intake port 230 may be configured to engage the fixture 330 of the filter 300 . Accordingly, the face cover 200 may be directly coupled to the filter 300 without the breathing assistance device 100 by engaging the intake port 230 with the fixture 330 .

Referring back to FIG. 6 , the filter 300 may filter contaminants, bacteria and dust from the air in the atmosphere. When the user breathes in, the filter 300 may filter the air flowing in from the outside and provide it to the breathing assistance device 100 . In addition, the filter 300 may be selectively coupled to the spacer 120 provided in the respiratory assistance device (100). The filter 300 may include a first filter layer 310 , a second filter layer 320 , and a fixture 330 .

A spacer 120 may be inserted into any one of the first filter layer 310 and the second filter layer 320 . For example, the first filter layer 310 may be in close contact with the connection part 122 , and one or more supports 121 may be inserted through the second filter layer 320 . The first filter layer 310 and the second filter layer 320 may be spaced apart from each other by the spacer 120 . In other words, the spacer 120 is inserted through the second filter layer 320 and disposed between the first filter layer 310 and the second filter layer 320 , so that the first filter layer 310 and the second filter layer 320 are separated. They may be spaced apart from each other without being in close contact with each other. Meanwhile, the edges of the first filter layer 310 and the second filter layer 320 may be connected, and the first filter layer 310 and the second filter layer 320 may be connected to form a predetermined space. The air that has passed through any one of the first filter layer 310 and the second filter layer 320 may stay inside this space for a predetermined time.

The fixture 330 may couple the filter 300 and the breathing assistance device 100 to each other. As the fixture 330 is engaged with the filter fastening part 124 of the breathing assistance device 100 , the filter 300 and the breathing assistance device 100 may be coupled. The fixture 330 may be supported on the second filter layer 320 . Also, the shape of the fixture 330 may be the same as that of the mask connector 111 of the body 110 . Accordingly, the fixture 330 may be coupled to the port protrusion 231 of the face cover unit 200 , and the filter 300 without the respiratory assistance device 100 may be directly coupled to the face cover unit 200 .

Referring back to FIG. 9 , the sensor unit 400 may measure data required to calculate one or more of the use time and the remaining life time of the filter 300 . In other words, the sensor unit 400 may measure data required to calculate at least one of the usage time and the remaining life time of the filter 300 by the operation unit 600 and transmit it to the operation unit 600 . One or more sensor units 400 may be provided, and may be provided on at least one of the inner and outer surfaces of the mask 1 . Here, the inside of the mask 1 may include not only the inside surface of the face cover 200 , but also the inside of the breathing assistance device 100 , the inside of the filter 300 , and the like. Accordingly, at least one sensor unit 400 may be provided in at least one of the breathing assistance device 100 , the face cover unit 200 , and the filter 300 .

The sensor unit 400 according to the present embodiment may include a first sensor 410 and a second sensor 420 to measure pressure, and the first sensor 410 and the second sensor 420 are It may be referred to as a first pressure sensor 410 and a second pressure sensor 420 . Hereinafter, the first sensor 410 will be described as a first pressure sensor 410 , and the second sensor 420 will be described as a second pressure sensor 420 .

The first pressure sensor 410 may measure a first pressure that is a pressure inside the mask 1 . For example, the first pressure may mean a pressure between the face cover part 200 and the user's face, a pressure inside the filter 300 or a pressure around the fan unit 130 . The first pressure sensor 410 may be provided inside the mask 1 , for example, inside the face cover 200 . Here, the inner side of the face cover unit 200 means one side that is in close contact with the user's face among both sides of the face cover unit 200 . The first pressure sensor 410 may continuously measure the pressure inside the mask 1 , and may transmit it to the operation unit 600 or the storage unit 700 . As another example, the first pressure sensor 410 may be provided inside the air passage 112 to measure the first pressure inside the air passage 112 . The first pressure sensor 410 may measure the pressure of air flowing from the air passage 112 to the inside of the face cover 200 by the fan unit 130 inside the air passage 112 .

The second pressure sensor 420 may measure a second pressure outside the mask 1 . For example, the second pressure may be a pressure outside the mask 1 . The second pressure sensor 420 may be provided outside the mask 1 , for example, outside the face cover unit 200 . Here, the outer side of the face cover unit 200 means one side of both sides of the face cover unit 200 that is not in close contact with the user's face. As another example, the second pressure sensor 420 may be provided on the body 110 to measure the second pressure outside the mask 1 . Here, the second pressure sensor 420 is inserted into the body 110 as well as the outer circumferential surface of the body 110 or disposed inside the body 110 to measure the second pressure outside the mask 1 . possible. The second pressure sensor 420 may continuously measure the pressure outside the mask 1 , and may transmit the measured second pressure to the operation unit 600 or the storage unit 700 .

The display unit 500 may receive and display at least one of the usage time and the remaining life time of the filter 300 calculated by the calculation unit 600 . The display unit 500 may receive one or more of the use time and the remaining life time of the filter 300 directly from the operation unit 600 , or may receive it from the storage unit 700 . Also, the display unit 500 may receive and display the accumulated use time of the filter 300 calculated from the operation unit 600 . The display unit 500 may be provided on one side of the face cover unit 200 .

Referring to FIG. 12 , the calculating unit 600 calculates one or more of the use time of the filter 300 , the accumulated use time of the filter 300 , and the remaining life time based on data measured from one or more sensor units 400 . can do. For example, the data measured from the sensor unit 400 is the filter 300 such as the pressure between the face cover unit 200 and the user's face measured by the sensor unit 400 and the pressure outside the face cover unit 200 . ) may be information for calculating the usage time.

The calculator 600 may calculate a pressure difference between the first pressure and the second pressure by comparing the first pressure measured by the first pressure sensor 410 and the second pressure measured by the second pressure sensor 420 . . Here, the pressure difference means the magnitude of the result obtained by subtracting the second pressure from the first pressure. However, in the present specification, the pressure difference has been described as meaning the difference between the first pressure and the second pressure, but this is only an example, and the second pressure is not measured through the second pressure sensor 420 but the storage unit 700 . may be a preset reference value. Accordingly, the calculator 600 may compare the first pressure measured from the first pressure sensor 410 with a preset reference value to calculate a pressure difference that is the difference between the first pressure and the reference value.

The calculation unit 600 compares the first pressure and the second pressure, and when the first pressure and the second pressure are the same, it may be determined that the wearing of the mask 1 is released from the user's face. In other words, if the pressure difference is 0, the calculator 600 determines that the user does not wear the mask 1 because the pressure inside and outside the mask 1 is the same, and the filter 300 is used by the user's breathing. judged as non-existent. In addition, when it is determined that the user releases the wearing of the mask 1 , the operation unit 600 may control the fan unit 130 to stop the operation of the fan unit 130 .

In addition, the calculator 600 compares the first pressure and the second pressure or a preset reference value and determines that the user breathes by wearing the mask 1 if the pressure difference is greater than or equal to a preset value. In other words, when the pressure difference is greater than or equal to a predetermined value, the operation unit 600 determines that the filter 300 is used by the user's breathing by changing the pressure inside and outside the mask 1 by breathing.

If it is determined that the filter 300 is used, the calculator 600 may calculate the time the filter 300 is used. The calculation unit 600 may start and stop time measurement when a certain predetermined condition is satisfied. For example, the calculating unit 600 may start time measurement when the calculated pressure difference is greater than or equal to a predetermined value, and may stop time measurement when the pressure difference is less than a predetermined value. In other words, the calculating unit 600 may calculate a time (use time of the filter 300 ) during which the pressure difference between the first pressure and the second pressure is maintained at a predetermined value or more. Also, the calculating unit 600 may display the calculated usage time of the filter 300 to the user through the display unit 500 .

Meanwhile, the usage time of the filter 300 calculated by the operation unit 600 may be stored in the storage unit 700 . Also, whenever it is determined that the filter 300 is used, the calculating unit 600 may calculate the usage time of the filter 300 and store it in the storage unit 700 . The calculator 600 may calculate the accumulated use time of the filter 300 through the stored use time of the filter 300 . In addition, the use time of the filter 300 stored in the storage unit 700 or the accumulated use time of the filter 300 may be used as data for calculating the life time of the filter 300 to be described later. On the other hand, the calculation unit 600 may be implemented by a calculation device including a microprocessor, a measuring device such as a sensor, a timer, and a memory, and the implementation method is obvious to those skilled in the art, so a further detailed description will be omitted.

When the first pressure (mask 1 internal pressure) is less than the second pressure (mask 1 external pressure), the operation unit 600 is configured to allow air to flow from the outside of the mask 1 to the mask 1 by the user's inhalation. It can be judged by the state of the intake air flowing into the interior. In addition, when the first pressure is greater than the second pressure, the calculator 600 may determine the exhalation state in which air is discharged from the inside of the mask 1 to the outside of the mask 1 by the user's exhalation. For example, if the user periodically repeats breathing while wearing the mask 1, the inspiratory state and the exhaled state may appear alternately.

When it is determined that the calculation unit 600 is converted from the inspiratory state to the exhaled state, it is determined that the user has breathed once. In this way, the calculating unit 600 may calculate the number of times the user's respiration by calculating the number of times converted from the inhaled state to the exhaled state. In addition, the number of respirations of the user calculated by the operation unit 600 may be stored in the storage unit 700 together with the user's use time of the filter 300 . This number of respirations may be used as data for calculating the remaining life time of the filter 300 .

Also, when it is determined that the filter 300 is used, the calculator 600 may calculate the remaining life time of the filter 300 based on data obtained from the sensor unit 400 . In other words, the calculator 600 may calculate the remaining life time of the filter 300 based on one or more of the use time of the filter 300 and the number of respirations of the user. Here, the remaining life time of the filter 300 may be calculated in consideration of not only the usage time of the filter 300 , but also the number of times the user breathes per hour on average and the number of times the user breathes through the filter 300 . For example, if the user's breathing becomes faster, such as exercising or having a conversation, the number of respirations per hour may be greater than the number of respirations per hour on average. At this time, even if the use time of the filter 300 is the same, since the number of times of breathing through the filter 300 increases, the life of the filter 300 is shortened faster. Accordingly, the calculating unit 600 may calculate the remaining life time of the filter 300 in consideration of the number of respirations during the time of using the filter 300 . Also, the calculator 600 may calculate the remaining lifetime of the filter 300 and display it on the display unit 500 .

The storage unit 700 may store the first pressure measured by the first pressure sensor 410 and the second pressure measured by the second pressure sensor 420 , and the first pressure and the second pressure are calculated by the calculator 600 . can be passed to However, this is only an example, and the second pressure may be a value previously stored in the storage unit 700 rather than being measured by the second pressure sensor 420 and stored in the storage unit 700 . Meanwhile, the storage unit 700 may store the usage time of the filter 300 calculated by the operation unit 600 whenever the filter 300 is used. Also, the storage unit 700 may store the number of respirations of the user calculated by the operation unit 600 . For example, the storage unit 700 may be a storage medium such as a memory.

Hereinafter, the operation and effect of the mask 1 having the above-described configuration will be described.

The user first inserts the filter 300 through the spacer 120 of the respiratory assistance device 100, and then connects the filter fastening part 124 and the fixture 330 to the breathing assistance device 100 by inserting the filter ( 300) can be installed. When the breathing assistance device 100 and the filter 300 are combined, the intake port 230 of the face cover 200 and the breathing assistance device ( 100) of the mask connector 111 may be coupled. At this time, the user inserts the port protrusion 231 of the intake port 230 into the connector groove 111a of the mask connector 111 , and then rotates the body part 110 at a predetermined angle with respect to the face cover part 200 . , the breathing assistance device 100 may be mounted on the face cover unit 200 . The user may wear the mask 1 when the face cover 200 and the breathing assistance device 100 are combined.

When the user wears the mask 1 and breathes, the air is filtered through the filter 300 and the performance of the filter 300 is deteriorated. At this time, by measuring the first pressure that is the pressure inside the mask 1 and the second pressure that is the pressure outside the mask 1 through the sensor unit 400, the time the filter 300 is used by the user's breathing, It is possible to calculate the number of breathing of the user. In addition, the remaining life time of the filter 300 may be calculated and informed to the user based on the calculated usage time of the filter 300 and the number of respirations of the user.

As such, the mask 1 according to the first embodiment of the present invention has the effect of providing the user with clean air that is filtered from fine dust, contaminants, and bacteria while the user breathes.

In addition, when the filter 300 capable of filtering air filters a lot of air, the performance of the filter 300 may be reduced, and the respiratory assistance device 100 according to the first embodiment of the present invention is By notifying the user of the lifespan of the filter 300 in consideration of the usage time of 300), the number of respirations of the user, etc., there is an effect of notifying the replacement time of the filter 300 .

Hereinafter, a second embodiment of the present invention will be described. In the description of the second embodiment, differences in comparison with the above-described embodiment will be mainly described, and the same description and reference numerals refer to the above-described embodiment.

According to the second embodiment of the present invention, the sensor unit 400 may include a first sensor 410 , and the first sensor 410 may be referred to as a flow rate sensor 410 . In this embodiment, the first sensor 410 is described as a flow sensor 410 . The flow rate sensor 410 may continuously measure the flow rate of air flowing into the mask 1 . For example, the flow rate sensor 410 may continuously measure the flow rate of air passing through the filter 300 . The flow sensor 410 may be disposed in any one of the inside of the filter 300 , a portion adjacent to the fan unit 130 , the air passage 112 , and the inside of the face cover 200 . In this way, the flow sensor 410 measures the flow rate of air flowing inside the face cover 200 through the filter 300 , and stores the flow rate value in the storage unit 700 or transfers it to the operation unit 600 . can

The calculating unit 600 may determine that the filter 300 is used when the air flow rate inside the filter 300 measured by the flow rate sensor 410 is equal to or greater than a predetermined value. When it is determined that the filter 300 is used, the calculation unit 600 may calculate at least one of a usage time of the filter 300 and a remaining life time of the filter 300 . In this case, the calculator 600 may determine that the user wears the mask 1 . In addition, when the flow rate measured by the flow rate sensor 410 is less than a predetermined value, the calculator 600 may determine that the wearing of the mask 1 is released from the user's face. The calculation unit 600 may measure the usage time of the filter 300 based on the time when the flow rate inside the mask 1 measured by the flow rate sensor 410 changes. In other words, the calculating unit 600 may calculate a time (use time of the filter 300 ) during which the flow rate measured by the flow rate sensor 410 is maintained above a predetermined value.

When the flow rate of air passing through the filter 300 increases, the calculator 600 may determine that the user is in an intake state. In addition, the calculation unit 600 may determine that breathing is greatly inhaled when the flow rate increases even in the same inspiratory state, and when the flow rate is slightly increased, it may be determined that the breathing is small. Also, the calculator 600 may calculate the number of respirations of the user based on the flow rate of air passing through the filter 300 .

In addition, the calculator 600 may calculate the remaining life time of the filter 300 based on one or more of the calculated user's respiration frequency, the flow rate of air, and the use time of the filter 300 . For example, the storage unit 700 may store the flow rate that passes through the filter 300 whenever the user breathes, and the operation unit 600 is stored in the storage unit 700 during the use time of the filter 300 . The flow rate of air passing through the filter 300 may be summed. This, the calculation unit 600 is based on the relationship between the flow rate of air summed during the use time of the filter 300 and the flow rate of air passing through the filter 300 per hour on average when breathing in general, the filter 300 is A rough estimate of the remaining lifetime can be calculated.

Hereinafter, a third embodiment of the present invention will be described. According to the third embodiment of the present invention, the sensor unit 400 may include a first sensor 410 , and the first sensor 410 may be referred to as a light detection sensor 410 . In this embodiment, the first sensor 410 is described as a light detection sensor 410 .

The light sensor 410 may sense the light irradiated into the face cover 200 , and the light sensor 410 may detect the light and transmit a signal to the operation unit 600 . The light sensor 410 may be provided inside the face cover unit 200 .

When light is not detected by the light detection sensor 410 , the operation unit 600 may determine that the mask 1 is worn on the user's face so that the light is not detected. Also, the calculator 600 may determine that the filter 300 is used when no light is detected by the light sensor 410 . Meanwhile, when light is sensed by the first sensor 410 , the calculator 600 may determine that the mask 1 has been removed from the user's face.

When it is determined that the filter 300 is used, the calculation unit 600 may calculate at least one of a usage time of the filter 300 and a remaining life time of the filter 300 . For example, the calculator 600 may calculate the usage time of the filter 300 by measuring a time from when light is not detected by the light detection sensor 410 to when light is sensed. Also, the calculator 600 may calculate the remaining life time of the filter 300 by subtracting the used time of the filter 300 from the total usable time of the filter 300 .

Hereinafter, a fourth embodiment of the present invention will be described. According to the fourth embodiment of the present invention, the sensor unit 400 may include a first sensor 410 , and the first sensor 410 may be referred to as a temperature sensor 410 . In this embodiment, the first sensor 410 is described as a temperature sensor 410 .

The temperature sensor 410 is provided inside the mask 1 and may be configured to continuously measure the temperature inside the mask 1 . For example, the temperature sensor 410 may measure the temperature between the face cover unit 200 and the user's face.

Meanwhile, the calculator 600 may receive the temperature inside the mask 1 from the temperature sensor 410 . When the measured temperature inside the mask 1 increases by a predetermined range, the calculation unit 600 may determine that the temperature inside the mask 1 increases by a predetermined range due to the user's breathing. At this time, the calculating unit 600 may determine that the filter 300 is used, and may determine that the mask 1 is worn on the user's face.

In addition, when the temperature inside the mask 1 is maintained for a predetermined time while increasing in a predetermined range, the operation unit 600 may determine that the filter 300 is continuously used. At this time, it may be determined that the user is wearing the mask 1 . In addition, when the temperature inside the mask 1 decreases by a predetermined range, the calculating unit 600 may determine that the mask 1 is removed from the user's face.

When it is determined that the filter 300 is used, the calculator 600 may calculate one or more of the use time and the remaining life time of the filter 300 . For example, the calculator 600 may calculate the usage time of the filter 300 by measuring a time from when the temperature inside the mask 1 rises to when it decreases. Also, the calculator 600 may calculate the remaining life time of the filter 300 by subtracting the used time of the filter 300 from the total usable time of the filter 300 .

Hereinafter, a fifth embodiment of the present invention will be described. According to the fifth embodiment of the present invention, the sensor unit 400 may include a first sensor 410 , and the first sensor 410 may be referred to as a humidity sensor 410 . In this embodiment, the first sensor 410 is described as a humidity sensor 410 .

The humidity sensor 410 is provided inside the mask 1 and may be configured to continuously measure the humidity inside the mask 1 . For example, the humidity sensor 410 may measure the humidity between the face cover unit 200 and the user's face.

The calculator 600 may receive the humidity inside the mask 1 measured through the humidity sensor 410 . When the measured humidity inside the mask 1 increases within a predetermined range, the calculation unit 600 may determine that the humidity inside the face cover 200 increases within a predetermined range due to the user's breathing. In this case, the calculator 600 may determine that the filter 300 is used by the user's breathing, and may determine that the mask 1 is worn on the user's face.

In addition, when the humidity inside the mask 1 is maintained for a predetermined time while increasing in a predetermined range, the operation unit 600 may determine that the filter 300 is continuously used. In addition, when the humidity inside the mask 1 decreases by a predetermined range, the calculating unit 600 may determine that the mask 1 is removed from the user's face.

When it is determined that the filter 300 is used, the calculator 600 may calculate one or more of the use time and the remaining life time of the filter 300 . For example, the calculator 600 may calculate the time the filter 300 is used by measuring the time from when the humidity inside the mask 1 rises to when it decreases. Also, the calculator 600 may calculate the remaining life time of the filter 300 by subtracting the used time of the filter 300 from the total usable time of the filter 300 .

Hereinafter, a sixth embodiment of the present invention will be described. The sensor unit 400 of the mask 1 according to the sixth embodiment of the present invention may include a first sensor 410 , and the first sensor 410 may be referred to as a gyro sensor. In this embodiment, the first sensor 410 is described as a gyro sensor 410 .

The gyro sensor 410 may measure the inclination of the mask 1 , and the gyro sensor 410 may measure the inclination of the mask 1 and transmit it to the calculator 600 . The gyro sensor 410 may be provided in the mask 1 .

The calculator 600 may determine that the filter 300 is used when the slope measured by the gyro sensor 410 is included in a preset predetermined range. In this case, the calculator 600 may determine that the mask 1 is worn on the user's face. Meanwhile, when the inclination measured by the gyro sensor 410 is not included in a predetermined range, the calculator 600 may determine that the mask 1 is worn off from the user's face.

When it is determined that the filter 300 is used, the calculator 600 may calculate one or more of the use time and the remaining life time of the filter 300 . For example, the calculator 600 may calculate the usage time of the filter 300 by measuring the time from the point in time when the inclination of the mask 1 is included in the predetermined range to the point in time not included in the predetermined range. have. Also, the calculator 600 may calculate the remaining life time of the filter 300 by subtracting the used time of the filter 300 from the total usable time of the filter 300 .

Meanwhile, in the present specification, the first to sixth embodiments have been described as different embodiments, but this is only an example, and one or more embodiments of the first to sixth embodiments are combined with each other to form the filter 300 . It is also possible to calculate one or more of the usage time and lifetime time of

As an example, the light sensor 410 and the first pressure sensor 410 may be combined to be provided in the mask 1 . The calculation unit 600 of the mask 1 provided with the light sensor 410 and the first pressure sensor 410 may calculate one or more of the use time and the remaining life time of the filter 300 . The calculation unit 600 may determine that the filter 300 is used by the user's breathing when the light is not detected by the light sensor 410 and the pressure measured by the first pressure sensor 410 changes. have. In addition, when light is detected by the light sensor 410 and the change in pressure is not detected by the first pressure sensor 410, the calculator 600 determines that the mask 1 is removed from the user's face. can

As such, the operation unit 600 may determine whether the user wears the mask 1 through the light detection sensor 410 and the first pressure sensor 410 and whether the filter 300 is used by the user's breathing. . In addition, the calculator 600 may calculate the usage time of the filter 300 by the user's breathing, the number of times the user breathes while wearing the mask 1, and the remaining life time of the filter 300 .

Meanwhile, as another example, the gyro sensor 410 and the first pressure sensor 410 may be combined and provided in the mask 1 . The calculating unit 600 of the mask 1 provided with the gyro sensor 410 and the first pressure sensor 410 may calculate one or more of a use time and a life time of the filter 300 . In this calculation unit 600, when the inclination measured by the gyro sensor 410 is included in a predetermined range and the pressure measured by the first pressure sensor 410 changes, the filter 300 is used by the user's breathing. can judge In addition, when the inclination is not included in the predetermined range and the pressure measured by the first pressure sensor 410 does not change, the calculator 600 may determine that the mask 1 is removed from the user's face.

As such, the operation unit 600 may determine whether the user wears the mask 1 and whether the filter 300 is used by the user's breathing through the gyro sensor 410 and the first pressure sensor 410 . In addition, the calculator 600 may calculate the usage time of the filter 300 by the user's breathing, the number of times the user breathes while wearing the mask 1, and the remaining life time of the filter 300 .

The following is a listing of embodiments of the present invention.

Item 1 is a mask for filtering air flowing therein, comprising: a face cover provided to be worn on a user's face; Respiratory assistance device that can be coupled to the face cover; at least one sensor unit provided on at least one of the face cover unit and the respiratory assistance device; and a calculator for calculating at least one of a filter usage time and a remaining life time of the filter based on the data measured from the at least one sensor unit.

Item 2 may include: a first pressure sensor provided on at least one of an inner surface of the mask and an outer surface of the mask, and configured to measure a first pressure inside the mask; a second pressure sensor for measuring a second pressure outside the mask; a flow sensor for measuring a flow rate of the air flowing into the mask; a light detection sensor for detecting light irradiated to the inside of the face cover; a temperature sensor for measuring a temperature inside the mask; a humidity sensor that measures the humidity inside the mask; and at least one of a gyro sensor that measures the inclination of the mask.

Item 3 is that the calculator may calculate a pressure difference that is a difference between the first pressure and the preset reference value by comparing the first pressure with a preset reference value, and if the pressure difference is greater than or equal to a preset value, the It is the mask that the filter determines to be used.

Item 4, wherein the calculating unit compares the first pressure with the second pressure to calculate a pressure difference that is a difference between the first pressure and the second pressure, and if the pressure difference is greater than or equal to a preset value, It is a mask, which determines that the filter is used.

Item 5 is a mask, wherein the calculation unit may calculate the use time of the filter, and the use time of the filter includes a time during which the pressure difference is maintained above the preset predetermined value.

Item 6 is, wherein the calculating unit is, when the first pressure is less than the second pressure, it is determined as an inspiration state, when the first pressure is greater than the second pressure, it is determined as an exhaled state, and the exhalation state in the intake state It is a mask, which calculates the number of times converted to and calculates the number of respirations of the user.

Item 7 is a mask, wherein the calculation unit calculates the remaining life time of the filter based on at least one of a use time of the filter and the number of respirations.

Item 8, the breathing assistance device, the body portion is formed with an air passage for the air to flow; and a fan unit, at least a portion of which is disposed inside the air passage, and is capable of flowing the air to the inside of the face cover part through the air passage.

Item 9, wherein the at least one sensor unit includes a first pressure sensor and a second pressure sensor capable of measuring a pressure, wherein the first pressure sensor is provided inside the air passage, The pressure is measured, and the second pressure sensor is a mask, which is provided in the body portion to measure a second pressure outside the mask.

Item 10 is a mask, wherein the calculation unit determines that the filter is used when the flow rate measured by the flow sensor is equal to or greater than a predetermined value.

Item 11 is a mask, wherein the calculation unit can calculate the use time of the filter, and the use time of the filter includes a time during which the flow rate measured by the flow sensor is maintained above the predetermined value. .

Item 12 is a mask, wherein the calculation unit calculates the remaining life time of the filter based on at least one of a flow rate of the air flowing into the mask measured by the flow sensor and a usage time of the filter. .

Item 13, the calculation unit,

It is a mask that determines that the filter is used when no light is detected by the light sensor.

Item 14 is a mask, wherein the calculating unit determines that the filter is used when the temperature measured by the temperature sensor increases in a predetermined range or when the measured temperature increases in the predetermined range for a predetermined time.

Item 15 is a mask, wherein the calculating unit determines that the filter is used when the humidity measured by the humidity sensor increases in a predetermined range or when the measured humidity increases in the predetermined range for a predetermined time.

Item 16 is a mask, wherein the calculation unit determines that the filter is used when the slope measured by the gyro sensor is included in a predetermined range.

Item 17 is a mask, wherein, when it is determined that the filter is used, the calculation unit calculates at least one of the use time and the remaining life time of the filter.

Item 18 is a mask, further comprising a display unit capable of receiving and displaying one or more of the use time and the remaining life time calculated by the calculation unit.

Although the embodiments of the present invention have been described as specific embodiments, these are merely examples, and the present invention is not limited thereto, and should be construed as having the widest scope according to the basic idea disclosed herein. A person skilled in the art may implement a pattern of a shape not indicated by combining/substituting the disclosed embodiments, but this also does not depart from the scope of the present invention. In addition, those skilled in the art can easily change or modify the disclosed embodiments based on the present specification, and it is clear that such changes or modifications also fall within the scope of the present invention.

1: Mask 100: Respiratory aid
110: body 111: mask connector
111a: connector groove 112: air passage
120: spacer 121: support
121a: first support 121b: second support
122: connection 123: inlet
123a: first inlet 123b: second inlet
124: filter fastening unit 130: fan unit
131: fan body 132: blade
133: rotation axis 200: face cover part
210: bonding member 211: through hole
220: air inlet 230: intake port
231: port projection 240: opening and closing member
241: stopper 300: filter
310: first filter layer 320: second filter layer
330: fixture 400: sensor unit
410: first sensor 420: second sensor
500: display unit 600: calculation unit
700: storage

Claims (18)

In the mask for filtering the air flowing inside,
a face cover provided to be worn on the user's face;
Respiratory assistance device that can be coupled to the face cover;
at least one sensor unit provided on at least one of the face cover unit and the respiratory assistance device; and
Comprising a calculation unit for calculating one or more of the use time and the remaining life time of the filter based on the data measured from the one or more sensor units,
Mask. The method of claim 1,
The at least one sensor unit is provided on at least one of an inner surface of the mask and an outer surface of the mask,
a first pressure sensor for measuring a first pressure inside the mask;
a second pressure sensor for measuring a second pressure outside the mask;
a flow sensor for measuring a flow rate of the air flowing into the mask;
a light detection sensor for detecting light irradiated to the inside of the face cover;
a temperature sensor for measuring a temperature inside the mask;
a humidity sensor that measures the humidity inside the mask; and
comprising at least one of a gyro sensor measuring the inclination of the mask,
Mask. 3. The method of claim 2,
The calculation unit,
By comparing the first pressure with a preset reference value, a pressure difference that is a difference between the first pressure and the preset reference value can be calculated, and when the pressure difference is greater than or equal to a preset value, it is determined that the filter is used,
Mask. 3. The method of claim 2,
The calculation unit,
Comparing the first pressure and the second pressure, a pressure difference that is a difference between the first pressure and the second pressure can be calculated, and when the pressure difference is greater than a predetermined value, it is determined that the filter is used ,
Mask. 5. The method according to any one of claims 3 and 4,
The calculation unit may calculate the usage time of the filter,
The use time of the filter includes a time during which the pressure difference is maintained above the predetermined value,
Mask. 6. The method of claim 5,
The calculation unit,
If the first pressure is less than the second pressure, it is determined as an inspiratory state, when the first pressure is greater than the second pressure, it is determined as an exhaled state, and by calculating the number of times the inspiratory state is converted to the exhaled state, Calculating the user's breathing rate,
Mask. 7. The method of claim 6,
The calculator calculates the remaining life time of the filter based on one or more of the use time of the filter and the number of respirations,
Mask. The method of claim 1,
The respiratory aid device,
a body portion having an air passage through which the air flows; and
At least a portion is disposed on the inside of the air passage, further comprising a fan unit capable of flowing the air to the inside of the face cover portion through the air passage,
Mask. 9. The method of claim 8,
The one or more sensor units include a first pressure sensor and a second pressure sensor capable of measuring a pressure,
The first pressure sensor is provided in the air passage to measure the first pressure in the air passage,
The second pressure sensor is provided in the body portion to measure a second pressure outside the mask,
Mask. 3. The method of claim 2,
The calculation unit,
If the flow rate measured by the flow sensor is greater than or equal to a predetermined value, it is determined that the filter is used,
Mask. 11. The method of claim 10,
The calculation unit may calculate the usage time of the filter,
The use time of the filter includes a time during which the flow rate measured by the flow sensor is maintained above the predetermined value,
Mask. 12. The method of claim 11,
The calculator calculates the remaining life time of the filter based on at least one of a flow rate of the air flowing into the mask measured by the flow sensor and a usage time of the filter,
Mask. 3. The method of claim 2,
The calculation unit,
Determining that the filter is used when no light is detected by the light sensor,
Mask. 3. The method of claim 2,
The calculation unit,
It is determined that the filter is used when the temperature measured by the temperature sensor increases in a predetermined range or when the measured temperature increases in the predetermined range for a predetermined time,
Mask. 3. The method of claim 2,
The calculation unit,
Determining that the filter is used when the humidity measured by the humidity sensor increases in a predetermined range or when the measured humidity increases in the predetermined range for a predetermined time,
Mask. 3. The method of claim 2,
The calculation unit,
It is determined that the filter is used when the slope measured by the gyro sensor is included in a predetermined range,
Mask. 17. The method according to any one of claims 3, 4, 10, 13 to 16,
The calculation unit,
If it is determined that the filter is used, calculating one or more of the use time and the remaining life time of the filter,
Mask. 18. The method of claim 17,
Further comprising a display unit capable of receiving and displaying at least one of the use time and the remaining life time calculated by the calculating unit,
Mask.

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