KR200489143Y1 - Respiratory protection mask - Google Patents

Abstract

This design relates to a respiratory protection mask.
According to one aspect of the present invention, according to one aspect of the present invention, a sealing face element; A valve seat including an intake unit formed with an intake port and an exhalation unit formed with an exhalation port; An intake valve selectively shielding the intake port and an exhalation valve selectively shielding the exhalation port; And the intake unit includes: a support element disposed inside the intake port, the support element supporting the intake valve; And one or more support ribs having one end portion connected to the inner circumferential surface of the intake port and the other end portion connected to the support element and having a smaller terminal area toward the front of the intake port as viewed from the support element A respiratory protection mask may be provided.

Description

RESPIRATORY PROTECTION MASK

This design relates to a respiratory protection mask.

The respiratory mask is worn to prevent dust, dust, odor, and gas from entering the mouth and nose of the human body, and various forms are used depending on the purpose. Especially in the industrial field, the use of a respirator is required for health and safety reasons of workers.

The respiratory protection mask includes an intake unit in which air enters the inside of the respiratory protection mask when the wearer breathes in and a breath unit in which air escapes from the respiratory protection mask when the wearer breathes out, May include an intake valve and an exhalation valve that selectively block the flow of air.

Patent Document 1: Korean Patent Laid-Open No. 10-2006-0039128 (published on May 5, 2006) Patent Document 2: Korean Patent Laid-Open No. 10-2010-0075459 (Published on July 2, 2010)

The intake valve provided in such a respiratory protection mask may be a thin film-like film, and the intake unit may be provided with intake valve support means for supporting the intake valve so that the intake valve selectively shields the intake port. The intake valve support means may include a support portion disposed at a central portion of the intake port and supporting the intake valve, and one or more ribs extending in a direction transverse to the intake port to support the support portion. Here, one or more ribs may be formed in the form of a bar having a rectangular cross section, and may be provided in a form extending from the edge of the intake port to the center.

However, the above-described technique has the following problems.

One or more ribs across the intake port interfere with the flow of air through the intake port. There is a problem that the pressure of the air passing through the intake port drops.

Also, since one or more ribs are weak in strength, there is a problem that when the impact is applied or when a predetermined external force is applied, the rib is easily broken.

Further, there is a problem that the size of the respiratory protection mask is large, which makes it inconvenient to use.

Embodiments of the present invention have been proposed in order to solve the above-mentioned problems, and an object of the present invention is to provide a respiratory protection mask capable of reducing a pressure drop of air when a wearer breathes.

It is also intended to provide a respiratory protection mask capable of reducing the damage of the rib supporting the intake valve.

It is also intended to provide a respiratory protection mask that can be reduced in size.

According to one aspect of the present invention, a sealing face element; A valve seat including an intake unit formed with an intake port and an exhalation unit formed with an exhalation port; An intake valve selectively shielding the intake port and an exhalation valve selectively shielding the exhalation port; And the intake unit includes: a support element disposed inside the intake port, the support element supporting the intake valve; And one or more support ribs having one end portion connected to the inner circumferential surface of the intake port and the other end portion connected to the support element and having a smaller terminal area toward the front of the intake port as viewed from the support element A respiratory protection mask may be provided.

According to another aspect of the present invention, a sealing face element; A valve seat including an upper portion on which the intake valve is seated, and a lower portion inclined rearward with respect to the upper portion and on which the exhalation valve is seated; And a frame protruding from the lower portion to support the breathing valve and having a protruding length that increases toward the lower side.

Embodiments of the present invention can provide a respiratory protection mask that can reduce the air pressure drop when the wearer breathes.

Further, it is possible to provide a respiratory protection mask capable of reducing breakage of the rib supporting the intake valve.

In addition, a respiratory protection mask capable of reducing the size of the respiratory protection mask can be provided.

1 is a perspective view showing a respiratory protection mask according to an embodiment of the present invention.
Fig. 2 is a front view of the respiratory protection mask of Fig. 1; Fig.
Fig. 3 is a rear view of the respiratory protection mask of Fig. 1; Fig.
Fig. 4 is an exploded perspective view of the respiratory protection mask of Fig. 1; Fig.
Figure 5 is a rear perspective view of the sealing face element of Figure 4;
6 is a rear perspective view of the yoke of Fig.
7 is a rear perspective view of the valve seat of Fig.
8 is a side view of the valve seat of Fig.
Fig. 9 is a rear view of the intake valve support means of the intake unit of the valve seat of Fig. 4; Fig.
10 is a cross-sectional view cut into II of Fig.
11 is a cross-sectional view taken along line II-II in Fig.
Fig. 12 is a perspective view showing a state in which the sealing face element and the valve seat of Fig. 4 are combined. Fig.
13 is a perspective view showing a state in which the lower end portion of the yoke is engaged when the sealing face element and the valve seat of FIG. 12 are engaged.
Fig. 14 is a cross-sectional view showing a state in which the sealing face element of Fig. 13 and the engagement of the valve seat and yoke are completed.
FIG. 15 is a simulation result showing a change in air velocity passing through an intake port of a respiratory protection mask according to an embodiment of the present invention.
FIG. 16 is a simulation result showing a change in pressure of air passing through an intake port of a respiratory protection mask according to an embodiment of the present invention. FIG.

Hereinafter, specific embodiments for implementing the idea of the present invention will be described in detail with reference to the drawings. Here, it is noted that the drawings are not drawn at a constant rate for convenience of explanation.

FIG. 1 is a perspective view showing a respiratory protection mask according to an embodiment of the present invention, FIG. 2 is a front view of the respiratory protection mask of FIG. 1, and FIG. 3 is a rear view of the respiratory protection mask of FIG.

1 to 3, the respiratory protection mask 10 according to an embodiment of the present invention includes a sealing facepiece element 100 which is in close contact with the wearer's face, A valve seat 200 on which an inhalation valve 500 and an exhalation valve 600 are seated and a yoke covering the front surface of the sealing face element 100 and the valve seat 200. [ And a strap 400 connected to a loop 350 of the yoke 300 and fixing the respiratory protection mask 10 to the wearer's head.

In the description of the present embodiment, the direction in which the face of the wearer is positioned with respect to the respiratory protection mask 10 is referred to as the rearward direction (negative X-axis direction in FIG. 1) , And the direction in which the nose of the wearer is positioned is defined as upward (positive direction of the Z axis in FIG. 1) and downward (negative direction of the Z axis in FIG. 1).

The sealing facial element 100 may be formed to a size sufficient to cover the wearer's nose and mouth, and may be formed of a soft material so as to be in close contact with the wearer's face. For example, the sealing facial element 100 may be formed of a material such as rubber, silicon, or the like capable of being elastically deformed, deformed to a predetermined level by a strap 400 formed of an elastic material, and may be adhered to the face of the wearer. To this end, the rear face portion of the sealing face element 100 may have a curvature corresponding to the face shape of a person.

The valve seat 200 is coupled to the sealing face element 100 at the rear of the sealing face element 100 and supports the intake valve 500 and the exhalation valve 600. Specifically, the valve seat 200 includes an intake unit (FIGS. 4 and 220) through which the air passes when the intake valve 500 is engaged and the wearer breathes, and the breathing valve 600 is engaged and the wearer breathes And an expiration unit (FIG. 4, 230) through which the air passes when resting.

The intake unit 220 includes an intake port 201 through which the air passes and an intake valve 500 is disposed behind the intake port 201 and is disposed in front of the respiratory protection mask 10 through the intake port 201 . The intake unit 220 includes intake valve support means for supporting the intake valve 500. The intake valve support means is provided at the rear end of the support element 221 and a support element 221 fitted to the center hole (Figure 4, 510) of the intake valve 500 of the intake port 201, And one or more supporting ribs 223 connecting the supporting element 221 and the inner circumferential surface of the intake port 201 and supporting the intake valve 500. [ have. The intake valve 500 is disposed between the support ribs 223 and the engagement protrusions 222 in the forward and backward directions of the respiratory protection mask 10. When viewed from the front of the respiratory protection mask 10, May not be exposed to the outside. The specific structure and operation of the intake valve support means will be described later.

The intake valve 500 partially opens the intake port 201 when the wearer breathes and when the wearer does not breathe the air enters the seal face element 100 through the intake port 201 It is possible to shield the intake port 201.

A predetermined filtering cartridge ring device (not shown) capable of removing foreign matter, harmful substances, and the like contained in the air can be coupled to the front end of the intake unit 220. By the action of the filtering cartridge ring device, It is possible to prevent foreign matter, harmful substances, and the like from entering the wearer's respiratory tract.

The exhalation unit 230 includes an exhalation port (FIG. 4, 202) through which air flows and an exhalation valve 600 is disposed in front of the exhalation port 202 to selectively shield the exhalation port 202 . Specifically, the exhalation valve 600 partially opens the exhalation port 202 when the wearer breathes out, and the air flows through the exhalation port 202 to the inside of the sealing face element 100 when the wearer is not breathing It is possible to shield the exhalation port 202 so as not to enter. The exhalation valve 600 has an insertion protrusion 610 protruding rearward and can be fixed to the valve seat 200 by fitting the insertion protrusion 610 into the valve seat 200.

The intake valve 500 and the exhalation valve 600 may be a diaphragm formed of a soft material that is deformable by a pressure change of the air formed by the wearer's breath or exhalation. Silicon, or the like.

The yoke 300 may cover a part of the front surface of the sealing face element 100 and the valve seat 200 and may be formed in a shape capable of covering the exhalation valve 600. The back surface of the exhalation valve 600 and the yoke 300 are spaced apart from each other by a predetermined distance so that the air exhausted through the exhalation unit 230 can be discharged to the lower side of the respiratory protection mask 10 when the wearer breathes An air discharge space can be formed below the respiratory protection mask 10.

A loop 350 may be formed on both sides of the yoke 300 to connect the strap 400 to the strap 400 and the strap 400 may include a length adjusting member 410.

The wearer may apply sealing force to seal face element 100 so that seal face element 100 can mask the nose and mouth while strap 400 is connected to loop 350 and allow strap 400 to seal The length adjusting member 410 can be manipulated so as to be directed to the face element 100. Thereby, the sealing face element 100 is resiliently deformed and can be brought into closer contact with the face, and only by the action of the intake valve 500 and the exhalation valve 600 air is introduced into the interior of the sealing face element 100, Can be discharged from the inside of the sealing face element 100 to the outside.

Hereinafter, specific features of the above-described components of the respiratory protection mask 10 will be described in detail with reference to the drawings.

Fig. 4 is an exploded perspective view of the respiratory protection mask of Fig. 1, Fig. 5 is a rear perspective view of the sealing face element of Fig. 4, Fig. 6 is a rear perspective view of the yoke of Fig. Fig. 8 is a side view of the valve seat of Fig. 4; Fig.

4 to 8, the respiratory protection mask 10 is configured such that the valve seat 200 to which the intake valve 500 and the exhalation valve 600 are coupled is coupled to the sealing face element 100 and the sealing face element The yoke 300 may be coupled to the intake unit 220 and the exhalation unit 230 which are exposed forward through the exhaust ducts 100 and 100.

The intake valve 500 and the exhalation valve 600 are coupled to the valve seat 200 before the valve seat 200 is engaged with the sealing face element 100. In this embodiment, And the exhalation valve 600 are not limited thereto. For example, the intake valve 500 and the exhalation valve 600 may be coupled to the valve seat 200 after the valve seat 200 is engaged with the sealing face element.

The sealing face element 100 includes a sealing face element body 110 formed to cover the wearer's nose and mouth, a bending portion 120 forming the rear face of the sealing face element body 110 and closely contacting the wearer's face, A first surface 130 provided on the upper side of the sealing facial element body 110 and a second surface 140 provided below the sealing facial element body 110.

The seal facial element body 110 is formed with a rear open and a forward protruding form and the valve seat 200 is coupled with the seal facial element body 110 in the form of being received inside the seal facial element body 110 can do. At this time, the valve seat 200 is seated and fixed to the first surface 130 and the second surface 140.

A yoke seating part 112 can be formed on the front surface of the sealing facial element body 110 so that the yoke 300 can be seated in a state where the yoke 300 is fixed to the valve seat 200. The yoke mount part 112 may be formed to correspond to the rear surface shape of the yoke 300 and may be provided in the form of a step surface which is recessed at a predetermined depth from the front surface of the sealing surface element body 110.

The first surface 130 may be in close contact with the upper portion 211 of the valve seat 200 in which the intake unit 220 is formed and the second surface 140 may be in contact with the exhalation unit 230 of the valve seat 200 And may be in close contact with the formed lower portion 212. The second surface 140 may be provided in a rearwardly inclined form relative to the first surface 130 so that a portion of the exhalation unit 230 protrudes forward of the sealing facial element 100, The lower side of the air conditioner 300 may be coupled to the breathing unit 230.

The first surface 130 may be formed with a first hole 101 in which the intake unit 220 is inserted and the second surface 140 may be formed with a second hole 102 into which the exhalation unit 230 is inserted. . An intake unit 220 having an intake port 201 formed therein is inserted into the first hole 101. The first hole 101 forms a part of the intake passage. In addition, an exhalation unit 230 having an exhalation port 202 formed therein is inserted into the second hole 102, and the second hole 102 forms a part of the exhalation passage.

The circumferential portion of the first hole 101 may be fitted into the upper fitting portion 229 of the valve seat 200 to be described later and the circumferential portion of the second hole 102 may be fitted to the valve seat 200 And can be fitted in the lower engaging portion 237. Thus, both the upper side and the lower side of the sealing face element 100 can be firmly coupled to the valve seat 200 and fixed.

The yoke 300 includes a yoke body 310 covering a part of the front surface of the sealing face element 100 and the valve seat 200, a joint 320 formed on both sides of the yoke body 310, 310 and a loop 350 to which the strap 400 is connected.

The intake passage 301 may be formed at an upper portion of the yoke body 310 at a position corresponding to the first hole 101 and the intake unit 220. [

A yoke engaging portion 312 for fixing the upper portion of the yoke body 310 to the valve seat 200 may be formed around the intake passage 301 of the yoke body 310. The yoke engaging portion 312 may be provided along the circumference of the intake passage 301 and may be provided in the form of a protrusion projecting toward the center of the intake passage 301 and may be provided in the step 228 formed in the intake unit 220 The upper portion of the yoke body 310 can be fixed to the valve seat 200 by the engagement. The yoke 300 can be fixed to the yoke fixing groove 235 and the step 228 of the valve seat 200 by fixing the joint 320 and the yoke engaging portion 312 to each other, The valve seat 200 can be firmly fixed to the valve seat 200 and can not be easily separated from the valve seat 200 even if there is an external impact.

The yoke body 310 may have a shape in which both sides of the lower portion extend rearward and a center portion of the lower portion of the yoke body 310 may protrude forward. A portion of the lower portion of the yoke body 310 extending rearward and a portion projecting forward may form the exhalation passage 302 and the air discharged through the exhalation port 202 may pass through the exhalation passage 302 To the outside of the respiratory protection mask (10).

A joint 320 is formed on both sides of the yoke body 310 and the joint 320 can be formed in a cylindrical or hemispherical shape so that the yoke 300 can be rotated around the joint 320. In this embodiment, the joint 320 is formed to have a hemispherical shape. The joint 320 can be fitted into the yoke fixing groove 235 of the valve seat 200 during the assembly of the yoke 300 and the yoke 300 can be elastically deformed to a certain level have.

The valve seat 200 is provided with a seat body 210 including an upper portion 211 and a lower portion 212, an intake unit 220 provided in the upper portion 211 and a lower portion 212 provided in the lower portion 212 And an exhalation unit 230, as shown in FIG. That is, the valve seat 200 may include both the intake unit 220 and the exhalation unit 230, thereby simplifying the structure while reducing the overall number of components of the respiratory protection mask 10.

The upper portion 211 may be formed so that the intake unit 220 can communicate air in the forward and backward directions of the respiratory protection mask 10 in the wearing state of the respiratory protection mask 10. The front surface of the upper portion 211 may be in close contact with the back surface of the first surface 130 of the sealing facial element 100.

In addition, the lower portion 212 may be formed to have a shape inclined rearward at a predetermined angle with respect to the upper portion 211, whereby the size of the respiratory protection mask 10, particularly the vertical length, can be reduced. The front surface of the lower portion 212 may be in close contact with the back surface of the second surface 140 of the sealing face element 100.

In this embodiment, the air communication direction of the air intake unit 220 and the air unit 230 is described as an example in which the respiratory protection mask 10 is worn in the forward and backward directions, But it can also be understood as a concept including a direction inclined at a level substantially equivalent to the above.

The intake unit 220 can be formed in a cylindrical shape protruding from the upper portion 211 as a whole, and includes the intake port 201 and the intake valve support means as described above. The intake port 201 is an opening that penetrates the upper portion 211 in the anteroposterior direction, and provides a path through which the air passes when the wearer breathes.

The intake unit 220 includes an installation portion 226 formed at the free end side and to which a filtration cartridge and the like can be connected, an upper extension portion 227 disposed at the rear of the installation portion 226 and having a diameter enlarged in the radial direction, A step 228 formed at the end of the upper extension 227 and an upper engagement 229 provided between the upper extension 227 and the upper part of the upper part 211.

The upper extension 227 is formed to have a larger diameter than the diameter of the first hole 101. The first surface 130 is elastically deformed by the interference with the upper extension 227 when the valve seat 200 is coupled to the sealing face element 100 and then restored to its original state again, And can be fitted to the upper engagement portion 229.

The upper engagement portion 229 may have a size corresponding to the diameter of the first hole 101 and may be provided in the form of a groove provided between the upper side of the upper extension portion 227 and the upper side of the upper portion 211. When the first surface 130 is fitted to the upper engagement portion 229, the sealing face element 100 and the intake unit 220, that is, the valve seat 200, are pressed until a certain level of external force is applied to the sealing face element 100. [ The state of engagement with the upper portion 211 of the housing 201 can be maintained.

The step 228 is formed along the periphery of the upper extension 227 at the rear end of the upper extension 227 and the yoke fastening portion 312 formed at the back of the yoke 300 supports the upper extension 227 It may be elastically deformed and then be inserted into the step 228. Thereby, the yoke 300 can be fixed to the valve seat 200.

The intake valve 500 may be formed of a flexible material having a size capable of shielding the intake port 201 and has a center hole 510 to be coupled to the intake unit 220. The intake valve 500 can be coupled to and supported by the intake valve support means of the intake unit 220 from behind the valve seat 200. When the wearer is breathing, the pressure difference between the inside and outside of the respiratory protection mask 10 (The inside of the respiratory protection mask 10 is lowered) to open the intake port 201. When the wearer breathes out, the pressure difference between the inside and the outside of the respiratory protection mask 10 (Inner side of the intake port 10 is in close contact with the high-pressure intake valve support means to shield the intake port 201).

FIG. 9 is a rear view of the intake valve support means of the intake unit of the valve seat of FIG. 4, FIG. 10 is a cross-sectional view taken along line I-I of FIG. 9, and FIG. 11 is a cross-sectional view taken along line II-II of FIG.

9 to 11, the intake valve support means is provided inside the intake port 201 and may include the support element 221, the engagement protrusions 222, and the support ribs 223 as described above. have.

The support element 221 is inserted into the center hole 510 of the intake valve 500 and can be supported by the plurality of support ribs 223 and positioned at the center of the intake port 201. The supporting element 221 may be formed in a cylindrical shape whose center axis is parallel to the direction of communication of air, and may have a diameter corresponding to the size of the center hole 510.

The engaging protrusion 222 prevents the intake valve 500 inserted into the support element 221 from being released from the respiration process of the wearer and is provided in the radial direction of the intake port 201 from the rear end of the support element 221, The length has the form of protruding projections. A plurality of the locking protrusions 222 may be provided in the circumferential direction of the support element 221. In this embodiment, three locking protrusions 222 are provided at regular intervals. The intake valve 500 is moved backward to open the intake port 201 when the wearer breathes in, but is not released from the support element 221 due to interference with the engagement projection 222.

The support ribs 223 extend from the inner circumferential surface of the intake port 201 to support the support element 221 and limit the forward movement of the intake valve 500. A plurality of support ribs 223 may be provided. That is, the intake valve 500 is disposed behind the support ribs 223, and the front surface of the intake valve 500 is supported by the support ribs 223. In this embodiment, three support ribs 223 are shown spaced apart at regular intervals. However, the number and position of the support ribs 223 may be different.

The support ribs 223 are connected to the front of the support elements 221 relatively to the engagement protrusions 222. [ Thereby, the intake valve 500 can be moved between the engagement projection 222 and the support rib 223.

In addition, the support ribs 223 may have a wedge-shaped cross section that is pointed forward when viewed from the position of the support element 221. In other words, the support ribs 223 can have a smaller terminal area toward the front of the intake port 201. [ In this embodiment, the termination area means the cross-sectional area when cut into a plane perpendicular to the X-axis of Fig. With this configuration, when the air is introduced into the intake port 201, the pressure drop of the air by the support ribs 223 can be reduced, and the air velocity can be more uniformly distributed.

In the conventional case, the support rib provided in the intake port of the respiratory protection mask is provided in the form of a bar having a simple rectangular cross section without changing the terminal area, and the support rib acts as a resistor in the air flow, Drop and flow instability. However, according to the support rib 223 in this embodiment, the air introduced through the intake port 201 can be smoothly dispersed and moved along the support ribs 223, thereby reducing the function as a resistor, The phenomenon can be reduced.

Particularly, the front end portion of the support rib 223 can be rounded, and the end portion of the support rib 223 as a whole, as viewed from the position of the support element 221, As shown in FIG. In this case, the pressure drop amount of the air passing through the intake port 201 and the flow instability phenomenon can be further reduced.

Further, the support ribs 223 can be provided in such a form that the cross-sectional area increases as the distance from the support element 221 is larger as viewed from the support element 221. [ That is, when the intake port 201 is viewed from the front, the width of the support ribs 223 may become narrower toward the support elements 221.

The support ribs 223 can be more firmly fixed to the inner circumferential surface of the intake port 201 and can effectively support the intake valve 500 even with a small area.

On the other hand, the support ribs 223 may include grooves 224 opened rearward on the rear surface. The depth and width of the groove 224 can be formed to be deeper and wider as the distance from the support element 221 is increased so that the thickness of the injection molding surrounding the groove 224 can be kept constant. Further, the groove 224 may extend along the extension direction of the support rib 223.

By forming the groove 224, the supporting rib 223 can be structurally reinforced. When the wearer is breathing, the intake valve 500 is in close contact with the back surface of the support rib 223. If the groove 224 is formed, a part of the intake valve 500 is inserted into the groove 224 The intake valve 500 can be more surely brought into close contact with the support ribs 223 as the push-in phenomenon may occur.

The exhalation unit 230 includes a frame 231 that protrudes from the lower portion 212 and is formed so that the exhalation valve 600 is not separated by gravity and a vent port 202 formed in the frame 231 An insertion hole 233 into which the insertion protrusion 610 of the exhalation valve 600 can be inserted and a plurality of support ribs 232 formed on both sides of the frame 231 And a yoke fixing groove 235 into which the joint 320 of the yoke 300 is fitted.

The frame 231 may be formed so as to increase in length from the upper side to the lower side so that the front surface to which the breathing valve 600 is adhered is directed substantially vertically to the gravity direction or upward . That is, the exhalation valve 600 may be disposed long in the gravity direction, or the upper end 600a may be located further rearward than the lower end 600b. Specifically, the frame 231 may be provided in a state in which the front surface of the respiratory protection mask 10 is not tilted forward or backward, or may be inclined forward. Thus, the exhalation valve 600 can be brought into close contact with the front surface of the frame 231 in the absence of an external external force in the absence of respiration of the wearer. In the present embodiment, in explaining the inclined state of the breathing valve 600, the rearward inclination means that the upper end 600a of the breathing valve 600 is located in front of the lower end 600b, The upper end 600a of the exhalation valve 600 is located behind the lower end 600b.

Exhalation valve 600 is a place where the wearer's exhalation hits and moisture can be caught on the back surface of the breathing valve 600. The moisture of the breathing valve 600 increases the weight and the free end of the breathing valve 600 can be struck down. In this case, although the wearer does not exhale, there may be a problem that the breath port 202 is opened. Considering the environment in which the respiratory mask 10 is worn, this can cause serious safety problems for the wearer.

However, according to the present embodiment, the exhalation valve 600 can maintain a state in which the exhalation valve 600 is in close contact with the front surface of the frame 231 as long as the wearer does not exhale the breath, Can be prevented.

That is, the lower portion 212 of the valve seat 200 is formed to be inclined rearward from the upper portion 211, and the frame 231 is formed to protrude toward the lower side. So that the ventilation valve 600 can be stably operated. Thereby, the feeling of wearing of the respiratory protection mask 10 can be improved and the ease of use can be increased.

The exhalation valve 600 may be formed of a flexible material having a size capable of shielding the exhalation port 600. The exhalation valve 600 may include an insertion protrusion 610 may be provided.

When the wearer breathes, the inside of the respiratory protection mask 10 is in a lower pressure state than the outside, so that the exhalation valve 600, like the intake valve 500, has a force to be pulled toward the inside of the respiratory protection mask 10 But it is possible to shield the breathing port 202 while being in close contact with the front surface of the bar frame 231 supported by the support rib 232. When the wearer breathes out, the inside of the respiratory protection mask 10 becomes higher in pressure than the outside, so that the free end portion (lower end portion) of the breathing valve 600 is pushed around the insertion protrusion 610, The port 202 is opened so that air can be discharged to the outside of the respiratory protection mask 10.

The yoke fixing grooves 235 may be provided on both sides of the frame 231 and the height of the protrusions forming the grooves toward the front so that the joint 320 can be smoothly guided to the inside of the yoke fixing grooves 235 Can be lowered. The yoke fixing groove 235 has a shape corresponding to the shape of the joint 320 and can be formed such that the yoke 300 can rotate about the joint 320.

If the yoke fixing grooves 235 are provided on both sides of the frame 231 as in the present embodiment, the length of the valve seat 200 need not be increased to add a structure for fixing the valve seat 200 to the lower side , And the vertical length of the valve seat 200 can be further reduced.

A lower extension 236 and a lower coupling portion 237 having functions corresponding to the upper expansion portion 227 and the upper coupling portion 229 of the intake unit 220 are formed at the rear end of the frame 231 .

Specifically, the lower extension portion 236 is formed to have a larger diameter than the diameter of the second hole 102. The second surface 140 is resiliently deformed by interference with the lower extension 236 when the valve seat 200 is engaged with the sealing facial element 100 and then restored to its original state and the upper surface of the lower extension 236 And can be fitted to the lower engaging portion 237. [

The lower engaging portion 237 may have a size corresponding to the diameter of the second hole 102 and may be provided in the form of a groove provided between the front surfaces of the lower extension portion 236 and the lower portion 212. When the second surface 140 is fitted in the lower engaging portion 237, the sealing face element 100 and the exhalation unit 230, that is, the valve seat 200, are pressed until a certain level of external force is applied to the sealing face element 100. [ The state of engagement with the lower portion 212 of the base plate 210 can be maintained.

A method of assembling the respiratory protection mask 10 having the above-described structure will be described in detail as follows.

FIG. 12 is a perspective view showing the combined sealing face element and the valve seat of FIG. 4, FIG. 13 is a perspective view showing the combined bottom face of the yoke in a state where the sealing face element and the valve seat of FIG. Fig. 14 is a cross-sectional view showing a state in which the sealing face element of Fig. 13 and the engagement of the valve seat and yoke are completed.

The intake valve 500 is coupled to the intake unit 220 from the rear of the valve seat 200 and the exhalation valve 600 is connected to the exhalation unit 230 from the front of the valve seat 200. [ The valve seat 200 is coupled to the sealing face element 100. As shown in Fig.

At this time, the first surface 130 is resiliently deformed to be fitted to the upper joint portion 229, and the second surface 140 is elastically deformed and fitted to the lower joint portion 237. As a result, the rear surface of the sealing face element 100 and the front surface of the valve seat 200 can be in close contact with each other, and the mounting portion 226 and the upper extension 227 and the step 28 of the intake unit 220 The frame 231 and the yoke fixing groove 235 and the lower extension 236 of the exhalation unit 230 also pass through the second hole 102 to be exposed frontward .

When the engagement of the sealing face element 100 and the valve seat 200 is completed, the yoke 300 is coupled to the valve seat 200. Specifically, the joint 320 of the yoke 300 is fitted into the yoke fixing groove 235 first. Then, the yoke 300 is rotated upward so that the yoke portion 312 is elastically deformed and is caught by the step 228. Whereby the yoke 300 can be fixed to the valve seat 200.

At this time, the installation portion 226 of the intake unit 220 may be exposed forward through the intake passage 301, and may be coupled with the filter cartridge or the like in the future.

The strap 400 may be connected to the loop 350 of the yoke 300 at any stage during the assembly process described above.

As described above, the respiratory protection mask 10 according to the present embodiment can be easily assembled without using a fastening method which requires separate tools for joining, such as bolt, welding, and the like, thereby improving manufacturing productivity. Particularly, since the valve seat 200 is provided with the intake unit 210 and the exhalation unit 220 at the same time, in other words, since the intake unit 210 and the exhalation unit 220 are manufactured as a single component, The valve seat 200 and the sealing face element 100 can be easily assembled while reducing the total number of components constituting the ventilation mask 10, and the manufacturing productivity of the respiratory protection mask 10 can be improved.

Hereinafter, functions and effects of the respiratory protection mask 10 according to the present embodiment having the above-described configuration will be described.

When the assembly is completed through the above process, the wearer can wear the respiratory protection mask 10 using the strap 400.

The breathing protection mask 10 shields the nose and mouth of the wearer while wearing the breathing mask 10 and the air intake valve 500 and the breathing valve 600 are deformed according to the respiration of the wearer and the air is moved to the inside of the respiratory protection mask 10 Or may be evacuated from the inside of the respiratory mask 10.

Specifically, when the wearer breathes, the intake valve 500 is retracted or deformed to be fitted to the support element 221 to open the intake port 201, and the exhalation valve 600 is moved to the left side of the frame 231 And is in close contact with the front surface to shield the exhalation port 202. Whereby the air can be moved to the inside of the respiratory protection mask 10 through the intake port 201. When the wearer exhales, the intake valve 500 is inserted into the support element 221 and is supported by the support ribs 223 to shield the intake port 201, and the breathing valve 600 is supported by the frame 231, So that the exhalation port 202 is opened. Whereby the air can be discharged to the outside of the respiratory protection mask 10 through the exhalation port 202.

By this action, it is possible to prevent foreign matter, harmful substances, etc. from entering the respiratory apparatus of the wearer from the outside of the respiratory protection mask 10.

Particularly, in the present embodiment, since the support ribs 223 have a shape in which the end area becomes smaller toward the front of the intake port 201, the pressure drop of the air generated in the intake unit 220 The phenomenon that the flow becomes unstable can be reduced. This allows the wearer to breathe comfortably because he can inhale a sufficient amount of air even with less force.

Particularly, the front end portion of the support rib 223 is rounded and has a streamlined wedge shape as a whole, so that pressure drop of the air and flow instability phenomenon can be more effectively prevented.

Further, since the groove 224 is formed on the rear surface of the support rib 223, the support rib 223 can be structurally reinforced, deformation in the injection process can be prevented, and the intake valve 500 can be more reliably So that it can be held in close contact with the support ribs 223.

FIG. 15 is a simulation result showing a change in flow velocity of air passing through an intake port of a respiratory protection mask according to an embodiment of the present invention. FIG. 16 is a graph showing a result of simulation This is a simulation result showing the change in air pressure.

15 and 16, simulation results on the left side show simulation results of a respiratory protection mask to which a supporting rib having no change in the terminal area has been conventionally applied, and simulation results on the right side show that the terminal area becomes smaller The results of the simulation of the respiratory protection mask with the support ribs of the shape are shown.

Referring to FIGS. 15 and 16, it can be seen that the velocity gradient of the air flow passing through the intake unit 220 is more stably distributed in the present embodiment, and the amount of pressure drop is further reduced.

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

Item 1 is a sealing face element; A valve seat including an intake unit formed with an intake port and an exhalation unit formed with an exhalation port; An exhalation valve selectively shielding an exhalation port and an exhalation port for selectively shielding the intake port; And the intake unit includes: a support element disposed inside the intake port, the support element supporting the intake valve; And a respiratory protection mask including one or more support ribs connected at one end to the inner circumferential surface of the intake port and at the other end to the support element and having a smaller terminal area toward the front of the intake port as viewed from the support element .

Item 2 is the respiratory protection of item 1 with the support ribs pointed wedge-shaped forward of the intake port.

Item 3 is the respiratory protection of item 1 and item 2 in which the support ribs round the front end.

Item 4 is a respiratory protection mask of items 1 to 3, including a part where the support rib becomes larger in the amount of change in the terminal area as it goes toward the front of the intake port.

Item 5 is the respiratory protection of item 1 to item 4 in which the cross-sectional area increases as the support rib is away from the support element when viewed from the support element.

Item 6 is a respiratory protection mask of item 1 to item 5 in which a groove opened rearward is formed on the back surface of the support rib.

Item 7 is a respiratory protection mask of items 1 to 6, wherein the grooves extend along the extending direction of the support ribs.

Item 8 is a sealing face element; A valve seat including an upper portion on which the intake valve is seated and a lower portion inclined rearward with respect to the upper portion and on which the exhalation valve is seated; And a frame protruding from the lower portion to support the exhalation valve and having a protruding length increasing toward the lower side.

Item 9 is the respiratory protection mask of item 8 in which the front part of the frame to which the exhalation valve is attached is formed to be arranged so that the exhalation valve is elongated in the direction of gravity.

Item 10 is a respiratory protection mask of item 8 and item 9 in which the front part of the frame to which the exhalation valve is closely attached is arranged so that the upper end of the exhalation valve is positioned behind the lower end.

Item 11 further comprises a yoke covering a part of the front surface of the sealing face element, a joint is formed on the lower side of the yoke, and both sides of the frame are provided with yoke fixing grooves, It's a mask.

Item 12 is a respiratory protection mask of items 8 to 11, wherein the yoke is rotatably movable about a joint, and the yoke is first coupled to the joint and then rotated so that the upper side of the yoke is coupled to the valve seat.

Item 13 is characterized in that the valve seat is provided with an upper engagement portion which is a groove into which the sealing face element is fitted and an upper expansion portion which forms an upper engagement portion and on the back surface of the yoke is formed a yoke engagement portion which is fitted in a step formed at the end of the upper extension, The respiratory protection of items 8 to 12, where the catches are elastically deformed and caught in the step.

Item 14 is the respiratory protection of items 8 to 13, where the valve seat is joined behind the sealing face element.

While the present invention has been described with respect to specific embodiments of the respiratory protection mask according to the embodiments of the present invention, the present invention is not limited thereto, and the present invention is not limited thereto and should be construed as having the widest range according to the basic idea disclosed in this specification do. Those skilled in the art will be able to combine / modify the disclosed embodiments to effect a pattern of a shape that is not described, but this is also within the scope of the present invention. In addition, those skilled in the art can easily modify or modify the disclosed embodiments based on the present specification, and such changes and modifications are also within the scope of the present invention.

10: Breathing protection mask 100: Sealed face element
101: first hole 102: second hole
110: sealing face part element body 120: flexion part
130: first surface 140: second surface
200: valve seat 210: valve body
220: intake unit 221: support element
222: locking projection 223: supporting rib
224: groove 226: mounting part
227: upper extension 228:
229: Upper coupling portion 230: Exhalation unit
231: frame 232: support rib
233: insertion hole 235: yoke fixing groove
236: Lower extension part 237: Lower coupling part
300: yoke 301: intake passage
302: exhalation passage 310: yoke body
320: Joint 350: Loop
400: Strap

Claims (18)

A sealing facial element;
A valve seat including an intake unit formed with an intake port and an exhalation unit formed with an exhalation port; And
An intake valve selectively shielding the intake port and an exhalation valve selectively shielding the exhalation port,
The intake unit includes:
A support element disposed inside the intake port and supporting the intake valve; And
And the other end portion is connected to the support element. When viewed from the support element, the end surface area becomes smaller toward the front of the intake port, and when the inner surface of the intake port is moved toward the inner circumferential surface of the intake port And at least one supporting rib protruding in a wedge-like shape toward the front of the intake port. delete The method according to claim 1,
The support rib is rounded with a front end rounded. The method according to claim 1,
Wherein the support rib includes a portion where a change amount of a terminal area becomes larger toward the front of the intake port. The method according to claim 1,
Wherein the support rib has a cross-sectional area that increases as it is away from the support element when viewed from the support element. A sealing facial element;
A valve seat including an intake unit formed with an intake port and an exhalation unit formed with an exhalation port; And
An intake valve selectively shielding the intake port and an exhalation valve selectively shielding the exhalation port,
The intake unit includes:
A support element disposed inside the intake port and supporting the intake valve; And
At least one support rib connected at one end to the inner circumferential surface of the intake port and at the other end connected to the support element and having a smaller terminal area toward the front of the intake port when viewed from the support element,
And a rear opening is formed in the back surface of the support rib. The method according to claim 6,
Wherein the groove extends along the extending direction of the support rib. The method according to claim 6,
Wherein said support rib is pointed wedge-shaped forward of said intake port. The method according to claim 6,
The support rib is rounded with a front end rounded. The method according to claim 6,
Wherein the support rib includes a portion where a change amount of a terminal area becomes larger toward the front of the intake port. The method according to claim 6,
Wherein the support rib increases in cross-sectional area as viewed from the support element, away from the support element. The method according to claim 1,
The valve seat includes:
An upper portion on which the intake valve is seated and a lower portion inclined rearward with respect to the upper portion and on which the exhalation valve is seated,
And a frame protruding from the lower portion to support the breathing valve and having a protruding length increasing toward the lower side. 13. The method of claim 12,
Wherein a front portion of the frame to which the breathing valve is closely attached is formed so that the breathing valve is elongated in the direction of gravity. 13. The method of claim 12,
Wherein a front portion of the frame to which the breathing valve is closely attached is formed so that an upper end of the breathing valve is located behind the lower end. A sealing facial element;
A valve seat including an upper portion on which the intake valve is seated, and a lower portion inclined rearward with respect to the upper portion and on which the exhalation valve is seated;
A frame protruding from the lower portion to support the exhalation valve and to be protruded toward the lower side; And
And a yoke covering a part of the front surface of the sealing face element,
A joint is formed on the lower side of the yoke,
And yoke fixing grooves are formed on both sides of the frame to which the joint is coupled. 16. The method of claim 15,
Wherein the yoke is rotatably movable about the joint,
Wherein the yoke is first coupled to the joint and then rotated so that the upper side of the yoke is coupled to the valve seat. 16. The method of claim 15,
Wherein the valve seat is provided with an upper engagement portion which is a groove into which the sealing face element is fitted and an upper extension which forms the upper engagement portion,
A yoke engaging portion is formed on a back surface of the yoke so as to be fitted in a step formed at an end of the upper expanding portion,
And the yoke engaging portion is resiliently deformed and fitted to the step. 16. The method of claim 15,
Wherein the valve seat is engaged at the rear of the sealing face element.

Images