JP6942400B1 - Ventilation cap - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hat capable of sufficiently ensuring coolness. SOLUTION: The brim 3 and the crown 2, at least the slides 4 provided on the front and side sides, and the ventilation passage 5 formed in front of the crown 2 are provided, and the ventilation passage 5 has ventilation. A first opening 6 formed through the front and back surfaces of the brim 3 in front of the slide 4, a second opening 7 formed on the front side of the crown and from the base 2A of the crown 2 toward the top 2B, and a second opening. The covering member 8 that covers the first opening 6 and the second opening 7 from the front side, the mesh member 11 that covers the second opening 6 from the back side, and the exhaust formed between the covering member 8 and the crown 2 at the top 8B. It has a port 9 and has a configuration in which the air flowing in from the first opening 6 opened on the lower side of the brim 3 is discharged to the outside from the exhaust port 9 through the ventilation passage 5. [Selection diagram] Fig. 6

Description

The present invention relates to a hat provided with a ventilation path that takes in air from the lower end of the brim of a hat such as a cap, a hat, or a school cap and discharges it from the vicinity of the top end of the crown.

A hat is disclosed in which an intake port is provided on the upper side of the brim and on the front portion of the crown to draw wind into the inside of the hat body (for example, Patent Document 1). This hat is a hat composed of a brim and a crown, and vents are provided at each of the front part of the hat and the opposite positions thereof, and the vents provided at the opposite positions of the front part of the hat are cut and divided crowns. The cut portions are arranged so as to be offset in the vertical direction and overlapped with each other, and are formed by not connecting the cut portions to each other. In this hat, the size of the vents provided at the opposite positions of the front part of the hat can be freely adjusted.
In addition, hats that take in air from the inside of the slide on the front of the forehead and have an exhaust port on the top of the hat body are also on sale.

JP-A-2018-96005

Therefore, there were the following problems.
On the upper side of the brim, an air intake is provided in front of the crown, and in a hat that draws wind inside the hat body, an air intake is provided in a portion located on the forehead of the crown in parallel with the brim. This air intake can take only the air flowing from the front into the hat body, and it makes you feel cool when the air inflow speed is fast, but the effect is not so great when the air inflow speed is slow. I can't feel it. Furthermore, even if only the wind is passed through, it cannot cope with the radiant heat radiated from the outside of the hat body, and it cannot be said that the hat is cool.

On the other hand, in a hat that takes in air from the inside of the slide on the front of the forehead and has an exhaust port on the top of the crown, the air that hits the face flows into the inside of the hat body from the intake port provided on the inside of the slide. It is designed to flow to the exhaust port. However, there are innumerable hairs on the head inside the hat body, and the inflowing air becomes a turbulent state inside the hat body and cannot be smoothly discharged from the exhaust port. Therefore, the inside of the hat body is an environment in which fresh air is mixed with sweat and heat generated from the head, and the coolness is insufficient due to the radiant heat radiated to the hat body from the outside.

Therefore, an object of the present invention is to provide a hat that can sufficiently secure coolness.

The hat according to the present invention is provided with a brim, a crown, slips provided at least in front of and to the side of the lower end of the crown, and an air passage formed in front of the crown, and is breathable. The ventilation passage has a first opening formed through the front and back of the brim in front of the slip, a second opening formed on the front side of the crown and from the base to the top of the crown, and a first opening. It has a covering member that covers the portion and the second opening from the front side, a mesh member that covers the second opening from the back side, and an exhaust port formed between the covering member and the crown at the top, and is on the lower side of the brim. It is characterized in that the air flowing in from the first opening opened to the outside is discharged to the outside from the exhaust port through the ventilation path.

In the hat according to the present invention, a ventilation path is formed from the brim along the outer shape of the crown from the top of the crown to the rear, the height of the ventilation path gradually decreases toward the top of the crown, and the width of the covering member is the width of the brim. It gradually narrows from the top to the top of the crown, and in the covering member, all the contact portions with the brim and the crown other than the exhaust port are sewn.

The hat according to the present invention is characterized in that the slide has an uneven structure or the slide has a breathability.

The hat according to the present invention is characterized in that a plurality of intake ports are provided on a slide or a portion above the slide.

In the hat according to the present invention, a material having a high reflectance to radiant heat such as aluminum foil is attached to the inside of the brim, the crown and the covering member, and the reflective surface of the material having a high reflectance to radiant heat such as aluminum foil is attached. It is characterized in that it is mounted toward the incident light side.

The hat according to the present invention has a brim, a crown, a slide, and a ventilation path formed in front of the crown, and the ventilation path is formed so as to penetrate the front and back of the brim in front of the slide. The air flowing in from the first opening opened under the brim, which has an exhaust port formed between the crown and the crown at the top of the crown, is exhausted through the ventilation path. It is discharged from the mouth to the outside. Then, the air flowing in from the first opening flows into the ventilation path, rises inside the ventilation path, and moves along the rounded shape of the head. At this time, centrifugal force acts on the air, it flows at high speed inside the ventilation path, and it is not easily affected by hair, so the air is discharged from the exhaust port in a laminar flow state, and the wearer's head becomes a cool environment.

Further, in the hat according to the present invention, a material having a high reflectance to radiant heat such as aluminum foil is attached to the inside of the brim, the crown and the covering member, and the material having a high reflectance to radiant heat such as aluminum foil is reflected. The surface is attached toward the sunlight side. Therefore, it is possible to block most of the radiant heat, and the heat applied to the head is significantly reduced, which is effective as a measure against heat stroke.

It is a front view of the hat which concerns on embodiment of this invention. It is a perspective view of the hat which concerns on embodiment of this invention. It is a bottom view of the hat which concerns on embodiment of this invention. It is a side view of the hat which concerns on embodiment of this invention. It is sectional drawing (AA sectional view of FIG. 4) of the hat which concerns on embodiment of this invention. (A) to (d) show ventilation paths having different shapes. It is a figure for demonstrating the operation of the hat which concerns on embodiment of this invention.

Hereinafter, the best mode for carrying out the present invention will be described with reference to FIGS. 1 to 5.
Hats, which consist of crowns and brims, are used to block sunlight, create shade, and relieve the heat on the head and face. However, in recent years, the temperature has risen sharply, and the heat and stuffiness of the head have increased more than before, and the comfort of wearing a hat has been impaired.

The biggest factor in the heat of hats is the radiant heat from the sun. Even if we say radiant heat, there are regions of ultraviolet rays, visible rays, and infrared rays that are related to heat. Of these, the visible light that we can see does not have that much heat, and the infrared rays that we cannot see are the cause of the heat. Therefore, just because it looks like a sun doesn't mean it's cool.

The radiant heat from the sun generates heat when the cloth on the outside of the hat is irradiated, and the outside air temperature is also added to further raise the temperature of the cloth. This heat is radiated to the head as secondary radiant heat and generates heat again, so that humans feel the heat.
On the other hand, the radiant heat transmitted through the cloth is directly applied to the head as the primary radiant heat. We feel even more heat as both this primary and secondary radiant heat irradiate the head.
Therefore, in order to eliminate the heat inside the hat body, it is most important to prevent radiant heat from the outside.

As a measure against the heat inside the hat body, it is important to discharge the heat and sweat generated from the head, which is another heat source. In order to achieve this, it is necessary to ventilate the inside of the hat body, but if the hat body is provided with an intake port and an exhaust port, the inside of the hat body will be in a turbulent state with innumerable hair, and it will be hotter than expected. It does not solve the problem. The important thing is that the air inside the hat body is discharged in a laminar flow state.

As shown in FIGS. 1 to 3, the hat (venting cap) 1 according to the present invention is formed in front of the brim 3, the crown 2, the slide 4 provided at the lower end of the crown 2, and the crown 2. It is provided with a ventilation passage 5 and has ventilation. In the hat 1, the ventilation path 5 is formed from the first opening 6 formed through the front and back of the brim 3 in front of the slide 4 (X in the front-rear direction), and from the front side of the crown 2 and the base 2A of the crown 2. A second opening 7 formed toward the top 2B, a covering member 8 that covers the first opening 6 and the second opening 7 from the front side, a mesh member 11 that covers the second opening 7 from the back side, and a top. It has an exhaust port 9 formed between the covering member 8 and the crown 2 in the vicinity of 2B. The ventilation passage 5 is formed so as to project outward from the crown 2 (front of the front-rear direction X).
Then, in the hat 1, the air flowing in from the first opening 6 opened on the lower side (back side) of the brim 3 is discharged to the outside from the exhaust port 9 through the ventilation passage 5.
The slide 4 may be provided at least in front of and to the side of the lower end of the crown 2. Further, the mesh member 11 is fixed by being sewn to the crown 2 around the second opening 7, and covers the entire second opening 7.

The hat 1 is a cloth hat composed of a brim 3, a crown 2, and a ventilation path 5, and the sliding 4 is the same as a normal hat. The first opening 6 provided in the front direction of the head and the crown 2 facing the first opening 6 have the same length as the opening width of the brim 3 in the circumferential direction Z, and the hook portion 2C to the top 2B. Two openings 7 are provided, and the second opening from the tip of the first opening 6 of the brim 3 to the top 2B of the crown 2 is provided so as to cover the first opening 6 and the second opening 7 from the upper side (front side). A ventilation passage 5 extending slightly rearward from the portion 7 is provided.

The hat 1 according to the present invention is mainly composed of three members, a brim 3, a ventilation passage 5, and a crown 2. The most important member is the air passage 5, in which outside air flows in (sucked) from the lower side of the brim 3 and flows through the inside of the air passage 5 protruding to the outside of the crown 2 in a laminar flow state, and the top 2B of the crown 2 It is discharged from the discharge port 9 formed on the slightly rear side. By projecting the ventilation passage 5 to the outside of the crown 2, the structure is such that an exhaust duct is provided on the outside of the crown 2, and since innumerable hairs rarely affect the ventilation passage 5, the inhaled outside air is taken in. Can be smoothly discharged from the exhaust port 9 in a laminar flow state.

The hat 1 according to the present invention has two openings.
One is a surface where the brim 3 contacts the crown 2, and is a first opening 6 having a circumferential direction Z of 60 mm to 80 mm and a front-rear direction X of 8 mm to 15 mm in contact with the head of the brim 3. The first opening 6 is formed for the purpose of taking in air from the outside.
Further, the bottom portion of the crown 2 facing the first opening portion 6 is 60 mm to 80 mm wide, and the top portion 2B is a second opening portion 7 having an opening of about 50 mm. be. The second opening 7 is formed for the purpose of discharging heat and water vapor generated from the head.
Further, the dimensions of the first opening 6 and the second opening 7 may be determined according to the size of the hat and the type of the hat, and all of them are not limited to the above-mentioned dimensions.

In the hat 1 according to the present invention, the ventilation path 5 is provided from the tip of the brim 3 along the outer shape of the crown 2 to slightly behind the top 2B of the crown 2, and the height H of the ventilation path 5 is the base of the crown 2. It gradually decreases from 2A toward the top 2B (Fig. 4). Further, the width W of the covering member 8 is formed so as to gradually narrow from the brim 3 toward the top 2B of the crown 2 (FIG. 1). In the covering member 8, all the contact portions with the brim 3 and the crown 2 other than the portion forming the exhaust port 9 are sewn.

The ventilation path 5 has a shape protruding forward (X in the front-rear direction) from the crown 2, but when viewed from the side surface of the hat 1, the tip of the opening of the brim 3 is 8 mm to 15 mm, and the top 2B of the crown 2 is 3 mm. The height (width) of the air passage 5 protruding toward 5 mm and the top 2B is reduced. When the ventilation path 5 is viewed from the top end, the width W of the covering member 8 is 60 mm to 80 mm at the tip of the opening of the brim 3, but is 50 mm to 60 mm at the top 2B of the crown 2, and the covering member 8 Has a substantially trapezoidal shape.
That is, the cross-sectional area of the ventilation passage 5 gradually decreases from the first opening 6 which is the intake port toward the exhaust port 9. The smaller cross-sectional area is a structure in which the air flow velocity increases as the air flowing in from the first opening 6 approaches the exhaust port 9.
Further, as the flow velocity of the air increases, the pressure of the air passing through the ventilation passage 5 decreases, and the air is discharged from the discharge port 9 while taking in the high-temperature and high-pressure air having heat and water vapor generated from the head. ..

Further, the sliding 4 of the hat 1 according to the present invention may have an uneven structure or may have a breathability. Further, a plurality of intake ports (not shown) may be provided on the slide 4 or a portion above the slide 4 (immediately above the slide 4) so as to penetrate the front and back surfaces.

The intake port is provided on the side surface of the crown 2 and below the crown 2 as much as possible, which is a point to make the head side feel cool. That is, air flows in a laminar flow state inside the ventilation passage 5 at the top of the head, and the atmospheric pressure is also negative. Therefore, when air flows in from the lower end of the crown 2, the air tends to flow from the lower side of the side surface of the head toward the ventilation path 5 in a laminar flow state. As a result, a slight air flow is felt in the temporal region, and coolness is promoted. As an intake method on this side surface, it is preferable to use an uneven or fibrous easily ventilated (breathable) slide 4.
There is also a method of attaching a plurality of holes directly above the slide. In a general hat, a hole is provided from the center of the hat body to the vicinity of the top and used as heat exhaust inside the hat. However, in the hat 1 according to the present invention, this hole is used as an intake port. do.
In any case, the important thing is to inhale from the lower end of the hat 1 as much as possible.

In the hat 1 according to the present invention, a material (heat shield material) 10 having a high reflectance to radiant heat such as aluminum foil is attached to the inside of the brim 3, the crown 2 and the covering member 8, and the material (heat shield material) 10 is attached to the inside of the radiant heat such as aluminum foil. The reflective surface of the material 10 having a high reflectance is attached toward the sunlight side.

As mentioned earlier, the biggest factor that makes the head hot is the radiant heat from the sun.
In principle, a material 10 having a high reflectance to radiant heat such as aluminum foil is used on the entire surface of the inside of the hat 1, and all the reflecting surfaces are attached toward the sunlight side.
The material 10 having a high reflectance with respect to radiant heat includes various materials such as those using aluminum foil and those vapor-deposited on cloth, resin film, or the like. A material with a high reflectance of 10 with respect to radiant heat should have a high reflectance, but many hats 1 have a rounded shape, and if aluminum foil or the like is difficult to use, a heat shield material with aluminum vapor deposition can also be used. It is possible.
In this embodiment, aluminum is vapor-deposited on one side of the cloth in consideration of flexibility and breathability. Since the thickness of the material 10 having a high reflectance with respect to radiant heat is about 0.2 mm, even if it is used inside the hat body, the wearer of the hat 1 does not feel uncomfortable. As the material 10 having a high reflectance with respect to radiant heat, a material having a reflectance of about 75% to 93% is used.

As shown in FIG. 4, the brim 3 is made of a cloth 3A, a material 10 having a high reflectance to radiant heat, a plastic plate 3B, and a cloth 3A. The brim 3 uses a plastic plate 10 because of its strength. However, if the cloth 3A has rigidity, the plastic plate 3B is unnecessary.
The plastic plate 3B is less likely to transmit primary radiant heat and has a much smaller amount of heat than the hat body. In some cases, the material 10 having a high reflectance with respect to radiant heat is not used due to cost and the like.

The crown 2 is composed of a cloth and a material 10 having a high reflectance to radiant heat attached to the inside of the cloth. In order to make the inside look beautiful, a decorative cloth or net may be attached.

The ventilation passage 5 is fixed to the crown 2 from the first opening 6 of the brim 3 to the vicinity of the top 2B of the crown 2 by suturing or the like except for the exhaust port 9. Further, as shown in FIG. 4, the configuration is a cloth 8A, a material 10 having a high reflectance to radiant heat, a plastic plate 8B, and a cloth 8A. In this case as well, the plastic plate 8B may not be used when the strong cloth 8A is used or when the flexibility of the hat body is required. Further, in order to improve the air flow inside the hat body, it is possible not to provide the cloth under the plastic plate 10.

As shown in FIGS. 5A to 5D, the shape of the air passage 5 can be various, such as a U-shape, a triangular shape, or a circular shape. By changing the shape and size of the ventilation passage 5, the flow of air inside the ventilation passage 5 and the amount of air discharged from the exhaust port 9 change, so that the coolness inside the hat 1 also changes.

Next, the mechanism and effect of the hat 1 according to the present invention will be described in detail with reference to FIG.

The main configuration of the hat 1 of the present invention is a material 10 having a high reflectance to radiant heat such as a brim 3, a ventilation path 5, a crown 2, and aluminum foil.
Functionally, the first opening 6 that functions as an intake port provided in the brim 3, the exhaust port 9 formed near the top 2B of the crown 2, and the slide 4 and holes arranged at the lower end of the hat body. The intake port such as a clue is important.

The intake port (first opening 6) of the air flowing in due to the wind from the front surface or traveling is provided so as to open below the brim 3. The face is the most exposed to the wind when it blows or walks. The face has a large area and is easily exposed to air. Moreover, the air that hits the face easily rises and is easily taken into the inside of the hat body. The faster you walk, the greater the amount. That is, it can be said that the amount of air passing through the inside of the hat body is proportional to the wind speed or the walking speed.
As shown in FIG. 6, the air sucked from the intake port (first opening 6) flows into the ventilation passage 5 provided on the outside of the crown 2, but the air rises and becomes a rounded shape of the head. Move along. At this time, centrifugal force acts on the air, the air flows at high speed inside the ventilation passage 5, and is not easily affected by hair, so that the air is discharged from the exhaust port 9 in a laminar flow state.
Further, by covering the second opening 7 with the mesh member 11, it is possible to prevent hair from invading the ventilation path 5, maintain a state in which air easily flows inside the ventilation path 5, and also to maintain a state in which air easily flows from the head. Heat easily flows into the air passage 5. By fixing the mesh member 11 to the crown 2 on the peripheral edge of the second opening 6, the shape of the hemisphere of the crown 2 can be maintained. Since the shape of the crown 2 can be maintained, the hat 1 can be easily manufactured and can be easily worn by the wearer.
Further, in the hat 1 of the present invention, the closer to the exhaust port 9, the smaller the cross-sectional area, so that the flow velocity of the air in the ventilation passage 5 becomes faster. As a result, the head side of the ventilation path 5 becomes a negative pressure.

On the other hand, inside the crown 2, air expands due to heat and water vapor generated from the head, and the pressure also increases, so that the air flows into the ventilation passage 5 having a low atmospheric pressure.
As a result, the air inside the ventilation passage 5 further increases in speed and is discharged to the outside (outside) from the exhaust port 9. The slide 4 at the lower end of the side portion of the crown 2 is made of an uneven surface or a fiber type, or a hole is provided immediately above the slide 4 so that outdoor air can easily flow into the slide 4. There is.
As a result, the air flowing in from the lower end of the side portion of the crown 2 flows around the head toward the negative pressure air passage 5 in a laminar flow state, and the heat and water vapor generated from the head are discharged, so that a cool environment is created. can get.

It is said that the cap body has an air intake and an exhaust port, but it is said that it does not feel cool, but it is because the inside of the hat is in a turbulent state due to the influence of hair and the heat of the head is not discharged well. The hat 1 according to the present invention completely overcomes this problem.
Further, since the heat shield material is attached to all the members facing the sun such as the brim 3, the ventilation path 5, and the crown 2, radiant heat is blocked. Therefore, the hat 1 of the present invention can be said to be an epoch-making hat for measures against heat stroke, heat, etc., in which cool air flows under the super shade.

The features of the hat 1 according to the present invention can be summarized as follows.
First, since the material 10 having a high reflectance to radiant heat is contained in the entire surface, most of the radiant heat can be blocked, and the heat applied to the head can be significantly reduced, which is effective as a measure against heat stroke. ..
That is, by wearing the hat 1, it is possible to create a super shaded situation on the wearer's head.

Secondly, since the material 10 having a high reflectance to radiant heat is used, it can block ultraviolet rays and is gentle on the skin.

Thirdly, even when the wearer is stationary, the air near the face thermally expands and rises due to the influence of body temperature, and from the first opening 6 (intake port) of the brim 3 to the head through the ventilation passage 5. It flows. This means that there are no obstacles such as hair in the passage from the first opening 6 of the ventilation passage 5 to the exhaust port 9, and air is very easy to flow.

Fourth, as the walking speed of the wearer increases or the amount of air flowing from the front increases, the amount of air that hits the face increases, and this air vigorously passes through the ventilation passage 5 from the first opening 6 of the brim 3. Since it is exhausted from the discharge port 9 at the top, you can feel very cool.

Fifth, the cross-sectional area of the air passage 5 becomes smaller toward the top of the crown 2. That is, since the speed of the air flowing through the ventilation path 5 is increased, the comfort in the vicinity of the head is further improved.

Sixth, the faster the speed of the air passing through the ventilation passage 5, the higher the dynamic pressure inside the ventilation passage 5, and conversely, the lower the static pressure around it. As a result, the air on the side of the head also moves so as to be attracted to the head, so that the stuffiness of the entire head disappears and at the same time, a cool feeling is felt. For that purpose, a structure is preferable in which air easily flows into the inside of the hat body from an intake port such as a slide 4 or a hole at the lower part of the side surface of the crown 2.

Seventh, when the wearer moves, the head becomes hot, and the slip 4 in contact with the forehead makes it easy to sweat. Since air is flowing to the brim 3 side of the slide 4 in contact with the forehead, the slide 4 is also cooled and the forehead is less likely to sweat.

[Test 1]
He wore a hat on his head and stood in a windless room with a temperature of 22 ° C. In that state, I brought a burning incense stick near the exhaust port on the top of the hat.

[Result 1]
The smoke of the incense stick drifted backward from the exhaust port on the top of the hat.

[Discussion 1]
It can be seen that even in a calm state, air flows from the intake port (first opening) that opens below the brim, through the head, and from the exhaust port at the top. This is because the air near the face is heated by the body temperature to increase the buoyancy and rise, and the heat of the head further thermally expands to increase the flow velocity and is discharged from the exhaust port. In short, this hat is proof that it is very breathable.

[Test 2]
In front of the 800W far-infrared heater, put the heat shield material deposited on the cloth inside the hat body and the normal hat, about 30 cm from the heater so that the top end of the hat body is on the heater side. I put it in. The vapor-deposited heat shield material had its vapor-deposited surface facing the top side of the hat body. The surface temperature was measured by thermography. The room temperature at this time was 26 ° C.

[Result 2]
B) When the surface of the hat body is measured by thermography from the heater side, the temperature of the hat without the heat shield is 51.5 ° C, and the temperature of the hat with the heat shield inside is 55.4 ° C. The provided hat was 3.9 ° C higher.
B) At this time, the temperature inside is 53.1 ° C for the hat without the heat shield and 43.5 ° C for the hat without the heat shield. It was as low as 6 ° C.

[Discussion 2]
B) The surface temperature of the heater side of the hat body is that it is directly irradiated with radiant heat and heated, and once it passes through the hat body, it is reflected by the heat shield inside the hat body, and it is returned to the hat body and becomes heat. There are two things. That is, the temperature of the hat body that is directly irradiated from the heater and rises is 51.5 ° C. of the hat that is not provided with the heat shield. Further, the temperature was 55.4 ° C., which was transmitted through the hat body, reflected by the heat shield material, returned to the hat body, and became heat. That is, the fact that the temperature is 3.9 ° C higher means that the radiant heat is not applied to the head due to the influence of the reflection of the heat shield material.
B) The internal temperature of the hat is the temperature actually applied to the head. The fact that the temperature of a hat provided with a heat shield is 9.6 ° C lower is the heat shield effect itself, and means that the heat shield cools the head.

Although the present embodiment has been described above, other than this, the configuration described in the above embodiment can be selected or changed as appropriate without departing from the gist of the present invention. .. For example, in the present embodiment, in the hat 1, the height H of the air passage 5 is formed so as to gradually decrease toward the top 2B, but in the vicinity of the discharge port 9, the height is increased by increasing the height. The air that has passed through the ventilation path 5 can be smoothly discharged.

1 Hat (ventilation cap)
2 Crown 2A Base 2B Top 2C Hagi 3 Brim 3A Cloth 3B Plastic plate 4 Sliding 5 Vent 6 1st opening 7 2nd opening 8 Covering member 8A Cloth 8B Plastic plate 9 Outlet 10 Aluminum foil, etc. Against radiant heat Material with high reflectance 11 Mesh member H Height (height of ventilation path)
W width (width of covering member)
X Front-back direction Y Vertical direction Z Circumferential direction

Claims (5)

A breathable hat comprising a brim, a crown, slips provided at least in front of and to the side of the lower end of the crown, and a vent formed in front of the crown.
The ventilation passage includes a first opening formed through the front and back of the brim in front of the slip, and a second opening formed on the front side of the crown and from the base to the top of the crown. , A covering member that covers the first opening and the second opening from the front side, a mesh member that covers the second opening from the back side, and an exhaust formed between the covering member and the crown at the top. Have a mouth and
The vent is formed from the brim along the outer shape of the crown from the top of the crown to the rear.
The height of the air passage gradually decreases toward the top of the crown,
The width of the covering member gradually narrows from the brim toward the top of the crown.
The air flowing in from the first opening opened on the lower side of the brim is discharged to the outside from the exhaust port through the ventilation path.
A hat that features that. Prior Symbol covering member, the flange and the contact portion between the crown than the exhaust port are all sewn,
The hat according to claim 1. The slip has an uneven structure or the slip has breathability.
The hat according to claim 1 or 2, wherein the hat is characterized in that. A plurality of intake ports are provided on the slip or a portion directly above the slip.
The hat according to any one of claims 1 to 3, wherein the hat is characterized in that. Heat shielding material, the flange has been fitted et inside the crown and the covering member,
The hat according to any one of claims 1 to 4, wherein the hat is characterized in that.

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