KR102682693B1 - disposable mask - Google Patents

Abstract

The present invention provides a disposable mask that can give a clean impression by suppressing deformation at both edges of the mask body. In the disposable mask 10, below the transverse center line Q that divides the dimension of the mask body 20 in the vertical direction Y into two, it extends in the width direction A low-rigidity region 14 having a predetermined width and lower stiffness than other parts is located.

Description

disposable mask

This disclosure relates to disposable masks.

Patent Document 1 discloses a mask main body formed of a sheet of fibrous non-woven fabric, a pair of earring parts extending in a ring shape from both edges of the mask main body, and a plurality of pleated parts ( A disposable mask with pleats is disclosed.

Patent Document 1: Japanese Patent Publication No. 2008-55035 (P2008-55035)

In the disposable mask disclosed in Patent Document 1, a cut is formed in the center portion of the edge portions on both sides of the mask body in the vertical direction. Normally, when the earring part is worn on the ear, a force that seeks to deform the mask main body in the upward and downward direction from the fixed end of the earring part acts on the mask main body, but even if the force applied to the central part acts, it is dispersed and absorbed by the incision. This can suppress deformation.

However, since the incision is located in the center of the mask body, the separation distance from the fixed end of the earring part to the incision is relatively large, and the force cannot be transmitted from the fixed end of the earring part to the incision and distributed or absorbed, so it cannot be distributed or absorbed between the fixed end and the incision. There is a risk that deformation may occur. In particular, in the earring part, when worn, the ear is located above the lower fixed end, so the force that pulls the free part of the earring part diagonally upward increases, so there is an area in the center to cushion this force. Even if installed, the edges on both sides are deformed before the force is transmitted. In addition, both edges and the bottom edge of the mask body are extended in a straight line, and although they can disperse and absorb the force intended to deform the mask body when cutting, when viewed from the front, they protrude from the face in the width direction. Because they have the same shape, they cannot give a neat impression that makes the wearer's face appear smaller.

The present invention is an improvement on the conventional disposable mask, and its object is to provide a disposable mask that can suppress deformation of the mask body, exhibit a curved shape that follows the shape of the face, and give a clean impression.

In order to solve the above problems, the present invention relates to a disposable mask that has a vertical direction and a width direction and includes a mask body and a pair of ear hook portions.

In the disposable mask according to the present invention, below the transverse center line that divides the vertical dimension of the mask main body into two, it extends in the width direction and has a predetermined width in the vertical direction, and is smaller than other portions. A low-stiffness region with low stiffness is located.

A high-rigidity area is located adjacent to the upper and lower sides of the low-stiffness area, and the high-stiffness area has a higher rigidity than the low-stiffness area and is located below the transverse center line. Therefore, the low-stiffness area and the upper and lower sides thereof are located below the low-stiffness area. Since the bending guide means by the high-rigidity area located adjacent to the direction is located below the transverse center line, the force is reliably applied in the low-rigidity area before deformation occurs due to the force directed upward from the fixing part of the earring portion. It can be dispersed and absorbed.

The mask body has a wrinkle portion made of overlapping portions of sheets folded and stacked, the wrinkle portion extends throughout the width direction of the mask body, the high-rigidity region is formed by the wrinkle portion, and the low-rigidity region Since it is formed from a non-overlapping portion located between the wrinkles, a high-stiffness region and a low-stiffness region can be formed not only at both edges of the mask body but also throughout the width direction. In addition, since the low-rigidity region and the high-rigidity region can be formed by bending the base sheet into a pleat shape, the configuration is simple and the manufacturing cost is low compared to forming means such as arranging a separate member or partially changing the mass of the sheet. can be suppressed.

The mass per unit area of the sheet in the high-rigidity region is higher than the mass per unit area of the sheet in the low-rigidity region. In this case, by manufacturing the mass of the portion forming the low-rigidity region in the sheet base material to be smaller than that of other portions, the low-rigidity region can be formed even without folding and overlapping into a pleated shape.

It has the low-stiffness region, a first high-stiffness region located above the low-stiffness region, and a second high-stiffness region located below the low-stiffness region, and the correlation between their stiffnesses is the second high-stiffness region. High-stiffness region ≥ the first high-stiffness region > the low-stiffness region. In this case, the force directed upward from the fixing part of the earring part can be sufficiently received in the second high-rigidity area and then absorbed and dispersed in the low-rigidity area. Additionally, because the first and second high-rigidity regions have different rigidities, the low-rigidity region located between them can be made easier to bend.

Since the vertical dimension of the high-rigidity region is 6 to 12 mm and the vertical dimension of the low-rigidity region is 1 to 7 mm, the low-rigidity region can function as a bending guide portion at both edges of the mask body. there is.

Since bending inducing means are located on both sides of the low-rigidity region, the force applied to both edges of the mask body in the low-rigidity region can be absorbed and distributed to enable more reliable bending.

On both sides of the mask body, a seal area formed of a plurality of joints and extending in the vertical direction is disposed, and the bending guide means is formed in a non-seal area where the joints are not disposed, so low rigidity The rigidity in this area is further lowered, allowing for reliable bending.

According to the disposable mask according to one or more embodiments of the present invention, when worn, the force intended to deform the mask main body can be distributed and absorbed in the low rigidity region, so that the edges on both sides of the mask main body are deformed and the facial mask body is deformed. It is possible to prevent separation from Additionally, the entire mask body follows the face line, giving a clean impression when viewed from the front.

The drawings show specific embodiments of the invention and include essential features of the invention as well as optional and preferred embodiments.
1 is a plan view from the front of a disposable mask according to the present invention.
FIG. 2 is a perspective cross-sectional view taken along line II-II in FIG. 1 and looking at one side of the mask from the outside.
Figure 3 is a side view of the cut surface of Figure 2.
Figure 4 is a side view of the mask in a worn state.
Figure 5 is a partially enlarged view of Figure 4.
FIG. 6 is a cross-sectional view taken along line VI-VI shown in FIG. 5.
Fig. 7 is a plan view from the front of the mask in an example of the modification.
FIG. 8 is a cross-sectional view similar to FIG. 6 of a mask in an example of a modification.
Figure 9 is a front view of the mask in a worn state.
Figure 10 is a histogram of the preliminary evaluation of the small face effect.
Figure 11 is a graph of this evaluation of the small face effect.

The following embodiments relate to the disposable mask shown in FIGS. 1 to 11 and include not only essential components of the invention but also optional and preferred components.

1 and 2, the mask 10 shown as an example of the disposable mask of the present invention has a vertical direction (Y) and a width direction (X), and has a skin facing surface and a non-skin facing surface facing it. , a transverse center line (Q) dividing the dimension in the vertical direction (Y) into two, a mask body 20, and a pair of ring-shaped earring parts extending from both edges 20c and 20d of the mask body 20 ( 30).

The mask body 20 is formed of a base sheet 21 made of fibrous nonwoven fabric, and has an upper edge 20a extending linearly in the width direction (X) and slightly convexly bent downward to extend in the width direction (X). It has an extended lower edge (20b) and both side edges (20c, 20d) extending in the vertical direction (Y) between the upper and lower edges (20a, 20b). The lower edge 20b has a central portion 19a extending linearly in the width direction (X) and curved side curved portions 19b and 19c located on both sides of the central portion 19a. The mask body 20 is between the upper and lower ends where the upper and lower fixing parts 34A and 34B that fix both ends 31A and 31B of the pair of earring parts 30 are located, and the upper and lower ends in the vertical direction Y. It further has a mouth cover portion (middle portion) 24 located in and facing the wearer's mouth. Additionally, the mask body 20 has a curved corner portion 27 where the upper and lower edges 20a and 20b and both side edges 20c and 20d intersect. Since the corner portion 27 is curved rather than sharp, even if the wearer's face touches the corner portion 27, it does not cause irritation.

The mask body 20 has both edge portions 18 located outside the upper and lower fixing portions 34A and 34B of the ear hook portion 30 in the width direction (X), and lower than the lower end of the fixing portion 34B. It has an extended contact portion (23). When worn, the contact portion 23 is located opposite the wearer's chin and has an external shape that protrudes downward from the mouth covering portion 24.

The dimension (long dimension of both edges 20c, 20d) (W1) of the mask body 20 (mask 10) in the vertical direction (Y) is 60 to 100 mm, and the dimension in the width direction (X) (upper and lower edges) The long dimension (L1) of (20a, 20b) is 140 to 180 mm. If the dimension W1 of the mask body 20 in the vertical direction (Y) is 60 mm or less, it cannot sufficiently cover the standard-sized chin of an adult wearer. On the other hand, if the dimension W1 is larger than 100 mm, , the lower end of the mask body 20 extends downward from the chin, which may give the impression that the mask 10 is vertically longer than it actually is when viewed from the front.

The base sheet 21 forming the mask body 20 is composed of an inner layer sheet 25 located on the skin-facing side and an outer layer sheet 26 located on the non-skin facing side. The inner layer sheet 25 and the outer layer sheet 26 are joined to each other by an outer peripheral seal region 40 extending intermittently along the outer peripheral edge of the mask body 20. The outer peripheral seal area 40 is formed of a plurality of joint portions 41 arranged at a predetermined distance apart in the extending direction. The outer seal area 40 includes an upper seal area 42 consisting of two lines extending intermittently in the width direction (X) along the upper edge 20a of the mask body 20, and a lower edge 20b. Accordingly, it has a lower seal area 43 that extends intermittently in the width direction (X) and a side seal area 44 that extends intermittently in the vertical direction (Y) along both edges 20c and 20d.

The inner layer sheet 25 and the outer layer sheet 26 are, for example, a breathable fibrous nonwoven fabric sheet with a mass of 10 to 40 g/m ² containing heat-sealable fibers, such as meltblown fibrous nonwoven fabric, spunbond fibrous nonwoven fabric, and SMS. In addition to various known fibrous non-woven fabrics such as fibrous non-woven fabric and air-through fiber non-woven fabric, it can be formed from sheet materials with good feel and breathability such as woven fabric, gauze, and cotton cloth. Although not shown, an intermediate sheet containing a filter function for fine particles or a fragrance or antibacterial agent may be interposed between the inner and outer layer sheets 25 and 26. The earring portion 30 is preferably elastically stretchable and is formed of a known material such as non-woven fabric, woven fabric, plastic film, or rubber string.

The outer peripheral seal area 40 is a weld seal line for welding the inner layer sheet 25 and the outer layer sheet 26 to each other at the plurality of intermittently arranged joints 41, and both sheets 25 and 26 are outer peripheral seals. They are joined only in area 40 and are not joined to each other in other parts. Therefore, compared to the case where the entire inner surfaces of both sheets 25 and 26 are bonded to each other, the entire mask 10 has excellent flexibility and breathability.

Referring to FIG. 2, the joint portion 41 of the outer peripheral seal region 40 is approximately rectangular and divided into a pair of short sides and a pair of long sides, and the upper seal region 42 and the lower seal region 43 are , the joint portion 41 is arranged so that the long side extends in the width direction (X), forming two seal lines extending in the vertical direction (Y). Additionally, the separation distance between the seal lines of the upper seal area 42 in the vertical direction (Y) is larger than the separation distance between the seal lines of the lower seal area 43 in the vertical direction (Y). The side seal area 44 is a plurality of outer joint portions 41A intermittently arranged to form one line extending in the vertical direction (Y) along both edges 20c and 20d, as well as the outer joint portion 41A of the earring portion 30. It has a plurality of inner joint portions 41B located above the fixing portion 34B.

Referring to FIG. 2, an elastic piece (nose pit) 60 extending in the width direction (X) is disposed between the seal lines of the upper seal area 42. The elastic piece 60 is interposed between the inner layer sheet 25 and the outer layer sheet 26, and is specifically inserted into a cylindrical space formed between the two seal lines forming the upper seal region 42. It is fixed. On the outer side of both ends of the elastic piece 60 in the width direction, a joint portion 41 is disposed to regulate the movement of the elastic piece 60 in the width direction (X).

The upper and lower edge portions of the inner layer sheet 25 extend outward in the vertical direction (Y) than the lower edge portions of the outer layer sheet 26, and the upper and lower extension portions 25a and 25b extend inward in the vertical direction (Y). It is bent into a curved shape and is fixed to the non-opposing surface side of the outer layer sheet 26 by the upper seal area 42 and the lower seal area 43. Additionally, the lower edge 20b of the mask body 20 has a shape gently curved downward due to the lower extension portion 25b being bent in a curved shape. The curved lower edge 20b and the curved corner portion 27 of the mask body 20 are engaged, so that the mask 10 has an overall rounded appearance.

The earring portion 30 has upper and lower ends 31A and 31B located at the upper and lower ends of the mask body 20, and a free portion 32 extending in a ring shape between the upper and lower ends 31A and 31B. The upper end 31A is fixed to the upper end of the mask body 20 by the upper fixing part 34A, and the lower end 31B is fixed to the lower end of the mask main body 20 by the fixing part 34B. The upper and lower fixing portions 34A and 34B have a mesh-shaped embossed pattern and are rectangular in shape larger than the upper and lower ends 31A and 31B, and the upper and lower ends 31A and 31B are fused or adhered to the mask body 20. Since the upper and lower fixing portions 34A and 34B are larger than the outer shapes of the upper and lower ends 31A and 31B, the upper and lower ends 31A and 31B have the necessary peeling strength with respect to the mask body 20, and the upper and lower ends 31A and 31B are maintained during wearing. ), even if a force to peel it is applied, it is not easily peeled off. Both ends 31A, 31B of the ear hook portion 30 are fixed to the non-skin facing surface of the mask main body 20 by upper and lower fixing portions 34A, 34B. Since both ends 31A, 31B of the ear loop portion 30 are fixed to the non-skin facing surface of the mask body 20, in the wearing state, both ends 31A, 31B of the ear loop portion 30 are attached to the mask. By bringing the main body 20 closer to the face, the adhesion of the mask main body 20 can be improved.

In some of the upper and lower fixing portions 34A and 34B, joint portions 41 forming upper and lower seal regions 42 and 43 are arranged in an overlapping manner. In these polymerized areas, not only the welded parts of the sheet are concentrated and the bond strength is increased, but also the rigidity is relatively high and there is a risk of strong irritation if it touches the skin, but the corners where the upper and lower seal areas 42 and 43 are located Since (27) is rounded, there is no risk of strong irritation even if it touches the skin.

The mouth cover portion 24 of the mask body 20 has a plurality of pleated portions 28 extending in the width direction (X) formed by bending the base sheet 21 into a pleat shape. The pleated portion 28 includes, in order from the upper side, first to third pleated portions 28A to 28C that are convex upward on the non-skin facing surface side of the mask main body 20, and a third pleated portion 28C. It has a fourth wrinkle portion 28D that is convex downward on the lower side. The base sheet 21 has a cross section bent into an Ω shape in the third pleat portion 28C and the fourth pleat portion 28D. By performing such pleating processing, the mouth cover portion 24 has high rigidity regions (overlapping portions) 13A, 13B in which the base sheet 21 is folded and stacked in multiple layers, and a third pleated portion. A low-rigidity region (non-overlapping region) located between (28C) and the fourth wrinkle portion 28D and having a lower rigidity than the high-rigidity regions 13A and 13B having a single-layer structure in which the base sheet 21 is not folded and overlapped ( 14). Here, “the rigidity of the high-rigidity regions 13A, 13B is higher than that of the low-rigidity region 14” means that, at least in terms of bending rigidity in the vertical direction (Y), the high-rigidity regions 13A, 13B have lower rigidity. It means higher than area (14).

In the present invention, the high-rigidity regions 13A and 13B and the low-rigidity region 14 are formed by the overlapping and non-overlapping portions of the base sheet 21, but the base sheet 21 is not bent and partially bent. These two regions 13A, 13B, and 14 may be formed by manufacturing the sheet so that the mass per unit area (unit weight) of the sheet is smaller than that of other parts. Additionally, both regions 13A, 13B, and 14 may be formed by providing rigidity imparting means such as a separate sheet member or adhesive only in the high rigidity regions 13A and 13B. In addition, the mode of folding and stacking the base sheet 21 is not limited to the example shown, and for example, the pleated portion 28 may be entirely directed upward or downward, and the portion forming the later bending guide means 15 may be formed. Instead of this Ω type, it may be folded and stacked to have various known cross-sectional shapes.

In the mouth cover portion 24, the base sheet 21 is bent into a pleat shape, so that parts other than the low-stiffness area 14 include a high-rigidity area 13A formed by folding and overlapping the base sheet 21. 13B) is located. In addition, in the mouth cover portion 24, below the transverse center line Q, the base sheet 21 is bent in a Ω-shaped cross section, forming a low-rigidity region 14 and a low-rigidity region 14. ) has a bending inducing means 15 composed of a first high-rigidity region 13A located adjacent to the upper side of the lower rigidity region 13B and a second high-rigidity region 13B located adjacent to the lower side of the low-rigidity region 14. In addition, during the manufacturing process, a small single layer portion (about 0.1 to 0.5 mm) formed between the wrinkles 28A to 28B regardless of the applicant's intention does not become the low-stiffness region 14.

Referring to FIG. 3, the dimensions in the vertical direction (Y) of each high-rigidity region 13A and 13B are almost the same, for example, the dimension in the vertical direction (Y) of the first high-rigidity region 13A (second high-rigidity region 13A). The dimension W3 of the rigid region 13B in the vertical direction (Y) is also the same) is 6 to 12 mm. Meanwhile, the dimension W4 of the low-rigidity region 14 in the vertical direction (Y) is 1 to 7 mm. When the dimension W4 of the low-rigidity region 14 in the vertical direction (Y) is less than 1 mm, the low-rigidity region 14 cannot function as a starting point for inducing bending, and the high-rigidity region 13A, 13B There is a risk of deformation occurring in some parts. On the other hand, when the dimension W4 in the vertical direction (Y) of the low-rigidity region 14 exceeds 7 mm, it becomes relatively too large and is further bent multiple times within the low-rigidity region 14, resulting in a distorted shape. There are concerns.

Referring again to FIG. 2, the distance between the lower end of the eyepiece 22 (same as the border M) and the center portion 19a in the vertical direction (Y) (in the vertical direction (Y) of the eyepiece portion 23) The maximum dimension (W2)) is 8 to 14 mm. Because the contact portion 23 has this maximum dimension W2, it can cover the entire chin of the wearer. In addition, the vertical separation dimension between the upper seal area 42 and the upper edge 20a forming the outer peripheral seal area 40, and the width direction (X) between the side seal area 44 and both edges 20c and 20d The separation dimension is 2 to 7 mm, the separation dimension R1 in the vertical direction (Y) between the lower seal area 43 and the central region 19a is 1 to 5 mm, and the outer circumference of the mask body 20 is. Among the outer seal areas 40 located at the edge portion, the lower seal area 43 is located closest to the outer edge of the mask body 20. By having the outer peripheral seal area 40 in this arrangement, it is possible to effectively prevent the lower edge extending downward from the lower seal area 43 from floating up when worn.

Referring to FIGS. 4 and 5, when the mask 10 is worn, a force F3 is directed to both sides from the central portion where the elastic band 60 is disposed at the upper end of the mask body 20, and the ear loop portion 30 A force F5 is generated that pulls the free portion 32 rearwardly or diagonally downward, thereby causing a downward force F1 to act on the upper fixing portion 34A. Meanwhile, at the lower end of the mask body 20, a force F4 is applied from the center of the contact portion 23 to both sides, and a force F6 is applied to the free portion 32 of the ear loop portion 30 to pull it obliquely upward. By doing so, a force F2 directed upward acts on the fixing portion 34B.

Between the upper and lower fixing portions 34A and 34B of the edge portions 18 on both sides of the mask body 20, forces F1 and F2 directed in opposite directions act on each other, causing the edge portions 18 on both sides to deform and rise from the face. There is a risk of separation. When the rigidity of both edge portions 18 is relatively low, it is possible to distribute and absorb the force intended to deform it, but when the rigidity of the entire mask body 20 is relatively high, it does not fit the face and may cause injury. There are concerns.

In the mask 10 according to the present embodiment, a plurality of pleated portions 28 are located on the entire mouth cover portion 24 at both edge portions 18 of the mask body 20, forming a high-rigidity region 13A, By forming 13B), it has the necessary rigidity, and by partially providing the low-rigidity region 14, the force intended to deform the edge portions 18 on both sides can be distributed and absorbed.

Referring to FIG. 6, in the low-rigidity region 14, the force F2 directed upward from the fixing portion 34B of the earring portion 30 is absorbed and dispersed, so that the low-rigidity region 14 is formed in the mask body 20. ) is folded and overlapped in the anteroposterior direction on the inner side, forming a tuck shape. In this way, in the low-rigidity region 14, by absorbing and dispersing the force F2 directed upward, the edge portions 18 on both sides are deformed to protrude from the face, forming a gap into which pollen or dust in the air enters. can be suppressed. In addition, in the low-rigidity region 14, the mask body 20 is bent convexly outward from the upper edge 20a to the lower edge 20b by being bent in a chin shape so as to overlap in the front-back direction. It has a parabolic outline that follows the wearer's face line.

In addition, for example, if the high-stiffness region is disposed only on the upper side of the low-stiffness region and the high-stiffness region is not disposed on the lower side, there is no part that becomes the starting point of bending that receives the upward force, and in the low-stiffness region, Bending cannot be induced. In the mask 10 of this embodiment, the first high-rigidity region 13A adjacent to the upper side of the low-rigidity region 14 and the second high-rigidity region 13B adjacent to the lower side are arranged, Bending is induced starting from the two boundaries (stiffness change points) 16 and 17 of the low-stiffness region 14 and the first and second high-stiffness regions 13A and 13B, and the low-stiffness region 14 is It is bent into a chin shape.

Referring to FIG. 4, when the earring portion 30 is hung on the ear 80, the force F6 that pulls diagonally upward becomes greater than the force F5 that pulls diagonally downward, and the upper side of the edge portions 18 on both sides becomes larger. The force F2 directed toward becomes greater than the force F1 directed downward. In order to suppress deformation of the edge portions 18 on both sides, it is desirable to arrange the bending guide means 15 near the fixing portion 34B on which the force F2 directed upward is applied, and is located at or near the transverse center line Q. On the upper side, the edge portions 18 on both sides are deformed before absorbing and dispersing the upward force F2. In the mask 10, the bending inducing means 15 composed of the first and second high-rigidity regions 13A and 13B and the low-rigidity region 14 is located below the transverse center line Q, that is, By being located near the top 34B, the force F2 directed upward can be absorbed and dispersed in the low-rigidity region 14 as soon as possible, thereby suppressing deformation of the edge portions 18 on both sides.

Specifically, when the dimension of the mask body 20 in the vertical direction (Y) is about 60 to 100 mm, the distance in the vertical direction (Y) from the transverse center line Q to the low-rigidity region 14 is The dimension R3 is preferably about 2.0 to 8.0 mm. As the separation dimension R3 is within this range, the force F2 directed upward from the fixing portion 34B of the earring portion 30 is absorbed and dispersed in the low-rigidity region 14, and is used as a starting point in the wearing state. It can be bent.

In the second high-rigidity region 13B of the bending guide means 15, an outer joint portion 41A forming the emboss line of the side seal region 44 and a plurality of outer joint portions 41A located outside the width direction (X). A wide joint 45 consisting of an inner joint 41B is located. At both edge portions 18 of the mask body 20, a wide joint portion 45 is located in the second high-rigidity region 13B, thereby (per unit area) the joint portion of the second high-rigidity region 13B ( The total area of 41A, 41B) is larger than that of the first high-rigidity region 13A, and the second high-rigidity region 13B can be said to have higher rigidity than the first high-rigidity region 13A. Therefore, the correlation between the stiffness values of the first and second high-stiffness regions 13A, 13B and the low-stiffness region 14 at both edge portions 18 is: second high-stiffness region 13B ≥ first high-stiffness Area 13A > becomes low-stiffness area 14.

Due to the difference in stiffness between the first high-stiffness region 13A and the second high-stiffness region 13B, Since the ease of bending is different, it becomes easier to induce bending in the bending inducing means 15. In addition, by positioning the wide joint 45 in the second high-stiffness region 13B, the force F2 directed upward can be widely received and absorbed in the low-stiffness region 14, so that it is more powerful than that at the boundary 16. It becomes easier to bend.

<Variation example>

7 and 8, in the mask 10 of this modification, the joint portion 41A is not disposed in the low-rigidity region 14, and a non-sealed region (bending assist means) 51 is formed. It is done. In order to absorb and disperse the force intended to deform both edge portions 18 in the low-rigidity region 14, it is desirable that the rigidity of the low-rigidity region 14 be as low as possible, and a side seal region ( It is preferable that the outer joint portion 41A of 44) is not disposed. In the present embodiment, in the non-overlapping portion, the non-sealed region 51 where the joint portion 41 is not disposed is located, so that the rigidity of the low-rigidity region 14 has a predetermined relatively low rigidity and is more secure. By absorbing and dispersing the upward force F2, bending becomes easier. That is, the non-seal area 51 is intended to assist the function of the low-rigidity area 14 as a bending guide. In order to achieve this effect, it is preferable that the dimension of the non-seal area 51 in the vertical direction (Y) is larger than the separation dimension (pitch) between the plurality of outer joint portions 41A of the side seal area 44. When the dimension of the non-sealed area 51 in the vertical direction (Y) is equal to or smaller than that between the outer joints 41A, it is not the non-sealed area 51 but the outer joints in the side seal area 44. This is because there is a risk that the upward force F2 may be absorbed and distributed in the spaced portion between 41A and cause bending, and the entire mask body 20 may not be able to be curved into a predetermined shape.

Referring to FIG. 9, when the mask 10 according to the present embodiment is worn, there are no portions on both edge portions 18 of the mask body 20 that are spaced apart from the face and protrude from the face line. Additionally, since the edges 20c and 20d on both sides of the mask body 20 draw a gentle parabolic shape that is convex inward in the low-rigidity region 14, it can follow the face line and fit the face. Additionally, since the contact portion 23 has a round shape consisting of a central portion 19a and side curved portions 19b and 19c that follow the outline line of the chin, it fits the chin and does not make the chin look wider than it actually is.

In the case of a typical disposable mask that is generally rectangular, the sharp corners at the bottom form an outline that deviates significantly from the face line, which may give the impression that the face is larger than it actually is. On the other hand, if the part that contacts the wearer's chin is formed to have an extremely narrow width, there is a risk that the tip of the chin is partially exposed, giving the impression that the size of the mask being worn does not fit the size of the face.

Referring again to FIG. 2, in the mask 10 according to the present embodiment, in the contact portion 23 of the mask 10, the width direction ( The angle θ1 of the first line K1 extending to ) and the second line K2 connecting the intersection point P2 of P1, the lower edge of the free portion 32, and the inner edge of the fixed portion 34B is 10 to 40. degrees, preferably 15 to 35 degrees. If the bridge angle θ1 is less than 10 degrees, the contact portion 23 may have an appearance that protrudes horizontally from the chin line, giving the impression that the face is horizontally long. On the other hand, if the bridge angle θ1 exceeds 40 degrees, There is a risk that the contact portion 23 becomes too sharp, giving the impression that the wearer's face is longer vertically than it actually is compared to before wearing the mask 10. Since the bridge angle θ1 of the mask 10 is within the range of 10 to 40 degrees, the edges 20c and 20d on both sides form a gentle parabolic shape with a concave bend in the low-stiffness region 14, and the eyepiece portion is suitable. Because it has a rounded shape, the range from under the cheek to the tip of the chin gives a neater impression than the actual face line, and can create a small face effect that makes the face look smaller than it actually is.

<Evaluation method for small face effect>

<Pre-evaluation method>

First, as preliminary preparation, the materials used for evaluation include 540 photographic images of a Japanese woman's face (taken from above the shoulder), a 24-inch liquid crystal display, and a head mannequin (with the standard size of a Japanese woman in her 20s). Facial model, Bio Skin Doll F-300S, Burax) were prepared. Next, the pre-evaluators (a total of 36 men and women over the age of 18) were seated on a chair 60 cm away from the screen of the liquid crystal display placed on top of the desk. On the screen of the liquid crystal display, an image was displayed in a predetermined size (JPEG image of 354 × 472 pixels, 9.8 cm long × 13.07 cm wide), and a head mannequin was placed across the liquid crystal display. The pre-evaluator observed the head mannequin and the photographic image A displayed on the screen of the liquid crystal display in contrast, and ranked the face size of the image when the head mannequin's face size was set at 50 points from 1 to 100 (the larger the number, the larger the face). It was evaluated in the range of and used as a preliminary evaluation value. The preliminary evaluator operated the mouse of the PC main body connected to the liquid crystal display with one hand and displayed the preliminary evaluation value by moving the cursor to a number deemed appropriate on the visual analog scale. In addition, the order of evaluation of the images by each evaluator and the number of evaluations were conducted randomly.

The preliminary evaluation values by each preliminary evaluator were aggregated for each photographic image, and the average value was calculated. Additionally, the number of evaluators varies for each photographic image, and on average, 18 people evaluated one photographic image. Figure 10 shows a histogram created based on preliminary evaluation values (the vertical axis is frequency, the horizontal axis is the rank of visible face size), and the average value of the distribution was 51.3, the standard deviation was 7.7, the minimum value was 32.5, and the maximum value was 77.6. In ascending order from the minimum value of this distribution, there are 22 photo images (small faces), in order from the average value there are 22 photo images (average-sized faces), and in descending order from the maximum value there are 22 photo images (large faces), for a total of 66 photo images (photo images). Image A) was used as the image used in the main evaluation below.

<This evaluation method>

A photo image A prepared in advance and a photo image B were prepared by wearing the mask 10 on the face of photo image A using image editing software. The present evaluators (a total of 11 men and women over the age of 18, who are different from the prior evaluators), under the same conditions as the pre-evaluation method, evaluated one photo each of 66 photographic images (33 each of photographic images A and B), outwardly. Visible face size was assessed. During the main evaluation, adjustments were made so that each main evaluator did not evaluate both photographic image A and photographic image B by the same person. Photographic images A and B evaluated by each evaluator were selected at random. The main evaluation values obtained through this main evaluation are aggregated for each of the six conditions of whether or not the mask 10 is worn (photo image A, photo image B) × original face size (small face, average face size, large face), and the average value is obtained. and its standard error was calculated.

<Results of this evaluation>

Referring to FIG. 11, in the case of “small face without mask 10”, the average of the real evaluation value when not wearing (the real evaluation value of photographic image A) is 40.5, while the average of the real evaluation value when not wearing the mask 10 is 40.5. The average of the main evaluation values in one state (main evaluation values of photographic image B) was 33.5. Additionally, in the case of “a face of average size without a mask,” the average of the evaluation values when not wearing the mask was 53.3, while the average of the evaluation values when wearing the mask 10 was 44.8, “without a mask.” Even in the "large face" state, the average of the evaluation values when not wearing the mask is 70.6, while the average of the evaluation values when wearing the mask 10 is 63.1, and in both cases, the average of the evaluation values when wearing the mask 10 is 70.6. Regardless of the size of the face without it, the visible size of the face felt smaller when wearing the mask (10).

In addition, a two-factor analysis of variance regarding the six conditions mentioned above was performed on the evaluation values obtained through this evaluation, and the main effect of whether or not the mask 10 was worn was found (F(1, 10)=10.40, p=0.09). , there was a main effect of the original face size (F(2, 20)=91.55, p=0.01), and statistically significant results were obtained. There was no alternation between whether or not the mask 10 was worn and the original face size. Therefore, regardless of the original face size, statistical results could be obtained in which the face wearing the mask 10 appears smaller (appears as a small face) than the face not wearing the mask 10.

As for the member constituting the mask 10, unless otherwise specified, other than the materials described in this specification, known materials commonly used in this type of field can be used without limitation. In addition, terms such as “first” and “second” used in this specification are used simply to distinguish the same elements, positions, etc.

10: Disposable mask
13A: first high rigidity area
13B: Second high rigidity region
14: low rigidity area
15: Bending guidance means
20: Mask body
21: Base sheet
28A∼18D: wrinkles
41: junction
Q: Transverse centerline
W3: Dimension in the vertical direction of the high-rigidity area
W4: Dimension in the vertical direction of the low-rigidity area
X: Width direction
Y: Up and down direction

Claims (6)

A disposable mask that has a vertical direction and a width direction and includes a mask body and a pair of earring parts,
Below the transverse center line dividing the vertical dimension of the mask body into two,
A low-rigidity region extending in the width direction and having a predetermined width in the vertical direction is located, and has lower rigidity than other parts,
A high-stiffness area is located adjacent to the low-stiffness area above and below the low-stiffness area, and the high-stiffness area has higher stiffness than the low-stiffness area and is located below the transverse center line,
The mass per unit area of the sheet in the high-rigidity region is higher than the mass per unit area of the sheet in the low-rigidity region,
The mask, characterized in that the low-stiffness region does not exist above the transverse center line. The method of claim 1, wherein the mask body has a wrinkle portion made of overlapping portions of sheets folded and stacked, the wrinkle portion extends across the entire width direction of the mask body, and the high-rigidity region is formed by the wrinkle portion, A mask wherein the low-stiffness region is formed of non-overlapping portions located between the wrinkles. The method of claim 1 or 2, comprising the low-stiffness region, a first high-stiffness region located above the low-stiffness region, and a second high-stiffness region located below the low-stiffness region, A mask in which the correlation of stiffness is the second high-stiffness area ≥ the first high-stiffness area > the low-stiffness area. The mask according to claim 1 or 2, wherein the high-rigidity region has a vertical dimension of 6 to 12 mm, and the low-rigidity region has a vertical dimension of 1 to 7 mm. The mask according to claim 1 or 2, wherein bending inducing means are located on both sides of the low-rigidity region. The method of claim 5, wherein a seal area formed of a plurality of joints and extending in the vertical direction is disposed on both sides of the mask body, and the bending guide means is formed in a non-seal area where the joints are not disposed. A mask that works.