WO2022097292A1 - Electronically coolable mask - Google Patents

Abstract

[Problem] In recent years, it has been increasingly preferred to wear a mask regularly for avoiding health damage due to the global spread of coronaviruses. However, in areas where the average temperatures are higher or situations where the temperatures are higher, e.g., a summer season, when a mask is worn, there is a problem that the release of heat generated associated with breathing becomes impossible and a health problem such as a heat disorder and heatstroke may occur. [Solution] In these current-day situations, the present invention provides a mask which is used in the cooling of a breathing-associated gas with an electronic cooling element or the like and which utilizes an electronic cooling part or the like that has a comb-shaped structure. The mask enables the cooling of a breathing-associated gas with higher efficiency for the purpose of preventing the increase in a body temperature during the breathing in a high-temperature environment, and thereby the cooling of the breathing-associated gas can be achieved with efficiency for preventing the occurrence of health problems.

Description

Electronic cooling mask

The present invention relates to the technical field of daily protection products, especially to masks.

Widely applied in daily life, masks block the nose and mouth, prevent pollen, fine particles, dust, viruses, germs and other air pollutants, and serve as a protective function for maintaining good health.

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Survey on September 10, 2020

According to Non-Patent Document 1, a product has been developed in which the cooling surface of a Pelche element is brought into direct contact with the neck to survive the intense heat with Kyushu Electric Power from an external power source. In addition, suitable prior patent documents could not be searched in Japan.

Due to the recent spread of coronavirus, it is necessary to wear a mask even in the hot summer months, but the hot air in breathing stays in the mask, and the gas in the mask becomes a temperature and high humidity equivalent to or higher than the body temperature. Therefore, there is a problem that heat cannot be discharged for the purpose of adjusting the body temperature and temperature by breathing, and there is a concern about health hazards such as heat stroke and heat stroke.

The concern about health hazards cannot be dispelled by not stably inhaling gas below body temperature outdoors in midsummer. Therefore, as a conceivable method for solving this problem, heat exchange between the inside and the outside is performed with a mask provided with a Pelche element, as in the site information referred to in the non-patent literature in the above-mentioned prior literature. It can be considered to be configured to have a cooling surface of the Pelche element inside.

However, when the inventor actually created it, even if the cooling surface of the Pelche element was turned inward, the temperature dropped sufficiently in breathing. In particular, the temperature of the gas generated during respiration is inevitably equivalent to the body temperature, and the result is that the problem of not being able to sufficiently suppress the temperature rise of the body due to the transpiration effect associated with the exhaled exhaust is further found.

In such a situation, in order to improve the waste heat efficiency associated with respiration, including the evaporation effect in the waste heat required by the body temperature associated with respiratory exhaust, it is necessary to widen the contact area of the exhaled gas in the cooling unit. By further providing a comb-shaped heat exchange part that can expand the contact surface with the air during breathing on the cooling surface of the Pelche element, the part where the gas during breathing stays inside the oral cavity and the mask can be prevented. In addition to the provision, a comb-shaped additional cooling section was provided between the cooling surface and the oral cavity to efficiently solve the problem.

In addition, since the moisture of the exhaled air condenses on the comb-shaped cooling part of the case as the exhaled air cools, the condensed water is discharged to the outside by a drain hose or the like, and the discharged water is led out to the heat-generating waste heat surface of the case. By evaporating the moisture that has condensed inside on the waste heat surface, the heat dissipation efficiency is improved by utilizing the evaporation waste heat effect that accompanies the vaporization of the condensed moisture, and achieving higher performance waste heat or improvement of cooling efficiency. You may be able to do it.

By providing a comb-shaped heat exchange component having a height of about 0.3 cm to 5 cm on the cooling surface of the Pelche element instead of simple surface cooling like the neck cooler in Non-Patent Document 1 described above, exhalation and intake air are taken. It was confirmed that the temperature of the air conditioner can be lowered below the outside air temperature and the exhaled air temperature.

Appearance with the mask on Outside the mask Inside the mask (a) without filter (b) with filter Example of schematic perspective view of the structure when viewed from the side of the mask Example of schematic perspective view of structure with drain when viewed from the side of the mask

First, it will be described from the appearance side based on FIG. Although the mask shown in this photo is made of urethane and has some thickness, there is a problem that it is not strong enough to fix the cooling parts to the mask. To solve this problem, the mask is used as a spacer or frame. By equipping the mask with parts made of resin or the like, the strength is such that the cooling unit can be held. The mask is not limited to the urethane mask, and the mask may be made of fibers having a certain strength made of an appropriate mesh material. Further, the electronic cooling unit may be appropriately provided with an electric fan so as to improve the cooling efficiency.

As for the appearance, as shown in FIG. 1, the cooling element is configured to operate by USB power supply or the like from the outside, and the mask-integrated cooling unit can be provided by the electronic cooling element. This power supply may be a solar cell or the like, and the cooling unit is provided with an electronic heat exchange unit such as a Pelche element, which makes it possible to have a simple structure. Further, instead of air cooling as shown in the image, a larger heat exchange unit such as liquid cooling may be provided, but a Pelche element, which is lightweight in terms of weight, is preferable.

The cooling unit configured in this way has a structure in which a volume sufficient to temporarily retain gas in breathing exists in the gap between the cooling unit and the face, and the structure of the face portion and the cooling unit is When observed from the side surface, the structure of the gap between the face line 4000 and the comb-shaped cooling unit 3001 is assumed in FIG. A filter unit 3002 used for the mask is configured between the oral cavity / nasal cavity portion associated with the face line 4000 of the mask and the comb-shaped heat exchange cooling unit 3001. It is preferable to consider that the performance of the mask itself can be arbitrarily designed due to the difference in the material of the filter portion.

The comb-shaped cooling unit configured as described above can sufficiently secure the volume in which the respiratory gas stays. For this reason, it is possible to secure a sufficient volume for heat exchange associated with cooling in a short time of the breathing timing of one breath, and it is possible to sufficiently cool the intake air in the physical heat exchange associated with breathing. It is possible to construct a mask with a filter that can prevent the waste heat efficiency associated with respiration from deteriorating by using the mask regularly, which drastically reduces the risk of inhaling the gas that remains as it rises.

FIG. 2 shows the appearance of the present invention. The mask consists of a mask that is stronger than a mask made of ordinary rubber strings, and if necessary, a fixture 1002 (electronic cooler) made of resin or the like to support the electronic cooler 1001 that is heavy as it is. The electronic cooling mask 1000 is configured by fixing the mask with a cooler), and the fixture 1002 may not be provided if the mask material has sufficient strength.

FIG. 3A shows how the comb-shaped heat exchange cooling unit 3001 is configured inside the mask of the present invention. Further, in (b), a filter, which is the main function of the mask, is configured and fixed on the comb-shaped heat exchange portion. Further, the circular portions provided on the left and right when viewed from the center of FIGS. 3 (a) and 3 (b) are provided with a valve-shaped structure when exhaling (exhausting), thereby exhaling (exhausting). ) May be considered to be configured so that it can be easily discharged. Further, the performance of the mask may be considered to change depending on the performance of the filter shown in (b).

Further, since it is fully possible that dew condensation occurs in the cooling portion of the present invention, silver or copper is used as a countermeasure against the growth of mold and germs caused by the drain hose for draining to the outside and the increase in humidity due to dew condensation. By using appropriate antibacterial and bactericidal materials such as ion coats such as, it is configured to reduce the risk of infection associated with breathing used in the present invention, and deodorization by electrical plasma or ions. It may be configured to further have a function such as sterilization.

It is more effective that the comb-shaped heat exchange metal part for expanding the gas contact area of the cooling part has a high thermal conductivity, and the heat exchange part due to undulations of about 3 mm is used for expanding the contact area. It is possible to design a wide area such as a heat exchange part with undulations of about 5 cm, and it is preferable that the device is thermodynamically devised to further improve the heat exchange efficiency, and the inventor is about 3 mm to 15 mm. We are conducting experiments using the heat exchange parts of comb-shaped, fin-shaped, spiny-shaped, columnar and their forest-shaped with the height of. Further, by stacking a plurality of electronic cooling elements, such as stacking two layers, it is possible to configure the structure so that sufficient cooling can be realized more efficiently for the user. Further, although the cooling portion shown in FIG. 3A is made of a metal bonded to the cooling element in a state of high thermal conductivity, the cooling portion is formed wider than the area of the metal portion and is appropriately comb-shaped or the like. Depending on the structure of, the design may be made such as expanding the thermal contact area.

Further, the moisture generated by the above-mentioned dew condensation is discharged from the inside to the outside of the mask by the drain hose, and the dew condensation discharged by the drain hose or the like is discharged to the heat dissipation part of the heat exchange part composed of the electronic parts provided on the outside. The overall cooling performance of the mask of the present invention may be improved by improving the heat dissipation efficiency on the outside by evaporating the water on the heat radiating portion by inflowing the water accompanying the above.

Further, the inside of the heat exchange component is provided with the drain hose 5001 in which the structure of the heat exchange part of the cooling part and the waste heat part configured to sandwich the semiconductor cooling element 1004 is directed from the inside to the outside as shown in FIG. It is also possible to configure the waste heat efficiency to be further improved by absorbing heat as vaporization heat accompanying the evaporation of the dew condensation moisture by flowing the moisture condensed on the cooling surface to the mask outer evaporation waste heat unit 5002.

In order to lower the temperature of the gas inside the mask, which is a factor that inhibits waste heat associated with breathing, a comb-shaped cooling part with a wider contact area is provided to enable sufficient cooling, and it is possible to cool the oral cavity and nasal cavity in summer. By avoiding the rise in body temperature due to the mask used for the part, it is possible to take care not to cause health problems such as heat radiation disease and heat stroke, and depending on the performance of the filter material, a surgical mask level electric electronic cooling mask is realized. , Even under a virus environment such as corona, it can be expected to make people's activities and dignified environment more comfortable.

1000 Mask outside with cooler 1001 Electronic cooler with electric fan (electronic cooler part)
1002 Cooler fixture 1003 Electronic cooler power cable 1004 Semiconductor cooling element 3000 Inside mask with cooler 3001 Inside mask with cooler Comb-shaped heat exchange part (comb-shaped heat exchange part inside cooler)
3002 Dustproof filter for mask 4000 Face line 5001 Drain hose part 5002 Mask outer evaporation Waste heat part

Claims (4)

1. In the technical field of daily protection products,
   A mask used for the nasal cavity and oral cavity used for respiratory safety to maintain health.
   Equipped with heat exchange parts that exchange heat between the inside of the mask and the outside of the mask,
   In the cooling unit provided inside the heat exchange component,
   Exhaled breathing stays in the mask and
   Due to the exhalation that remains warm in the mask
   By raising the temperature of the gas that accompanies continuous breathing,
   To avoid harming your health
   The cooling portion provided inside the mask is provided with heat exchange parts in a comb-shaped or columnar shape.
   Mask used for nasal cavity and oral cavity
2. The device according to claim 1, further comprising a cooling unit that has been subjected to an antibacterial treatment.
   Mask used for nasal cavity and oral cavity
3. The apparatus according to claim 1, characterized in that it is made of a mask material that has been subjected to an antibacterial treatment.
   Mask used for nasal cavity and oral cavity
4. The apparatus according to claim 1 is provided with a component for allowing the moisture condensed inside to flow out to the evaporation portion formed of the waste heat portion outside the mask by using the moisture condensed in the comb-shaped cooling portion inside the mask. It is characterized in that the cooling efficiency of this mask is improved by the evaporation effect in the outer waste heat portion by the moisture.
   Mask used for nasal cavity and oral cavity

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