DE202019106349U1 - Full face mask - Google Patents

Abstract

A full face mask intended to be worn on a user's face, comprising: a mask body having a lens portion and a soft portion joined together, the soft portion fitting the user's face and the mask body forming an interior; a breathing tube arranged on the mask body and connected to the interior; an unfolded insulation support section arranged in the interior such that the interior defines an upper space and a lower space, the lower space being connected to the breathing tube; andat least one inlet valve disposed on the deployed insulation support section, a channel defined at the junction of the lens section and the soft section, and the channel having a guide plate to prevent the circulation of gas flowing from a lower end of the channel to the breathing tube .

Description

Field of invention

The present invention provides a full face mask for underwater activities. In particular, the present invention provides a full face mask for snorkeling that can improve safety.

Description of the Prior Art

Breathing devices used for underwater activities have all long used a design in which a mask is separated from the breathing tube, the mask covering the eyes and nose with an airtight design. The breathing tube is clamped through the mouth, forcing the user to inhale / exhale air through it. In other words, such a breathing device for underwater activities will have at least two parts, i.e. a "mask" and a "breathing tube", which may be difficult to transport. In addition, the fixed relationship between the two parts should be taken into account, so that the creation of the parts is also time-consuming. For use, it is also necessary to change the habit of breathing through the mouth and nose into forced breathing through the mouth, which could only be achieved through training. In particular, if water accidentally gets into the mask or into the breathing tube, the nose or mouth must be exhaled to expel the water, or the breathing tube must be removed to drain the water and then clamped through the mouth again. These actions are quite complicated for users and it is not easy for users to get used to these actions. For beginners or people who are afraid of water, these actions are more difficult, which increases the likelihood of inhaling water, compromises safety and significantly reduces the fun of leisure activities.

In order to solve the above problems, a design has been developed in recent years according to which the mask and the breathing tube are combined into a single device. The principle of the design is that when worn, the mask simultaneously covers the user's eyes, nose and mouth, so that the eyes, nose and mouth are completely isolated from the outside environment. The breathing tube is located directly on the mask body and extends upwards. Since the components are simplified and easy to transport and the nose and mouth are all in the same space in the mask, the user can breathe naturally through the nose or mouth, which comes close to the breathing habit in daily life.

On the other hand, the inhaled and exhaled gases are all exchanged with the outside air through the breathing tube at the top of the mask, and the water entering the mask is easily discharged through the user's mouth / nose. As a result, the user need not consider whether to dispense the water through the mouth or the nasal cavity, so that the psychological pressure during use is greatly reduced. For beginners or users who are afraid of water, the level of acceptance is significantly improved. As an improvement in theoretical safety is expected, such a design is widely welcomed by the masses of people who participate in snorkeling.

This type of full face mask, which covers the eyes, nose and mouth of the user at the same time, has a good design concept. However, since the mouth and nose are in the same room, carbon dioxide can easily accumulate and cause dizziness and fainting, or the user can hyperventilate due to anxiety caused by water accumulation in the mask or the like if the channel for the inhaled / exhaled gas is not continuous, the ability to block the water flow is not good, and the water outlet design is not stable. This is worse than the risks of designing with separate parts. The reason for this is that if the user does not feel able to breathe air through the breathing tube due to the excessive accumulation of carbon dioxide in the mask, or if a large amount of water penetrates into the mask below the water surface, the user does not go through it alone can breathe the breathing tube and loosen the mask to dispense the water, as when using the mask with the separate design. If the user encounters the above circumstances while wearing the full face mask, the user may be at risk of drowning regardless of whether the user continues to wear the mask or removes it entirely, which is quite dangerous. The following two messages about user drowning illustrate the hidden dangers of designing full face masks: 1. (https://snorkelstore.net/snorkeling-safety-new-potential-hazards-full-face-snorkel-masks); and "Recent snorkel deaths prompts investigation into full-faced snorkel masks" (http://www.ktvu.com/news/recent-snorkeldeaths-prompts-investigation-into-full-faced-snorkel-masks).

The design flaws that cause the risks mentioned above are very subtle. Only very experienced designers can repeat tests know a little bit about it. Ordinary consumers will not be able to spot these design flaws when buying the masks until it is too late when the danger arises in use. The design flaws of such masks are described in detail below:

First, as in 1 is shown, the conventional full face mask 100 with an isolation section 110 in an interior of it and two air ducts 116 provided, which are arranged in a ring on the left and on the right side of the full face mask. The isolation section 110 is used to create an upper room 112 (also known as the eye area) and a lower room 114 (also known as the nose and mouth) while defining the two air ducts 116 for gas communication between the breathing tube (not shown) and the lower room 114 be used.

According to this design, it is officially stated that the gas circulation path is as follows: a) The fresh air inhaled from the upper breathing tube flows through the upper room 112 and then flows through one-way valves 120 in the isolation section on the two sides of the isolation section in the lower room 114 for an oral and nasal inhalation process; b) The exhaust gas exhaled from the mouth and nose is exhaled from the lower section of the full face mask 100 to side one-way valves 140 and the breathing tube 100 at the top over the two on the left and on the right side of the full face mask 100 air channels arranged in a ring 116 dissipated and then released to the outside.

It is also used in conjunction with the traditional full face mask 100 found that when water enters the mask and settles in the lower room 114 the mask accumulates, the user only needs to exhale deeply, whereupon the pressure in the mask can be increased to remove the accumulated water from a one-way valve 130 at under the lower room 114 output arranged mouth section.

This seemingly reasonable theoretical design actually has major shortcomings. In particular, the insulation sections 110 of conventional full face masks 100 all a reflex design in terms of a simple manufacturing process, a wide adaptation to face shapes and comfort. However, this design cannot be fully adapted to the cheeks and nose of the user or cover these areas. That is, when such a full face mask is worn, there will be many gaps between the isolation section 110 and the cheeks and nose of the user. Due to the presence of these gaps, the inhaled / exhaled gas does not flow according to the originally intended path (ie the clean air comes from the upper room 112 and through the one-way valves 120 of the isolation section 110 in the lower room 114 a). The exhaled exhaust gas flows through the air channels 116 to the breathing tube and the side one-way valves 140 up to be spent. In fact, the clean air is much more likely to flow through the gaps directly into the lower room 114 and is inhaled through the nose and mouth, and accordingly it is also more likely that the exhaust gas exhaled from the mouth and nose from the gaps to the upper space 112 flows back and is discharged from the breathing tube.

Such an air flow makes the one-way valves 120 of the insulation section on both sides of the insulation section 110 are arranged, actually inoperable because of opening the one-way valves 120 a certain air flow is required in the insulation section. If the clean air through the above gaps in the lower room 114 sufficient flow is of course not provided to the one-way valves 120 of the isolation section to open what the one-way valves 120 of the insulation section unusable and ineffective. Similarly, the exhaust gas is in the lower room 114 of course choose a shorter route and go straight through the gaps nearby to the upper room 112 flow, whereupon it is issued instead of the air ducts 116 to choose with a longer path. This is a natural phenomenon of fluid flow. Therefore, the design of the air ducts also appears to be superfluous and does not achieve the expected effects.

The actual gas circulation path through the conventional full face mask mentioned above 100 constructed is very different from the expected theory. That is, theoretically, it is expected that the pure air inhaled by the user and the exhaust gas exhaled by the user will follow certain paths. Because of the gaps between the insulation section 110 and the clean air enters the face through the gaps. As a result, the one-way valve 120 of the isolation section on the isolation section 110 cannot be opened or not fully opened. The amount of clean air that gets into the nose and mouth is, of course, insufficient. The user has the natural feeling that the inhalation is not going smoothly. In addition, in the case where the air intake is insufficient, the exhaled exhaust gas is largely discharged through the spaces. If water accumulates in the mask, the user will want the deep water accumulated Exhale from the one-way valve 130 Output at the mouth section under the mask, but the water dispensing effect is greatly reduced due to air leaks. Therefore, there is a likely risk of breathing water or hyperventilation due to anxiety, as the water cannot be dispensed in time. The result of inadequate air supply and inability to deliver water is, in fact, a serious threat to physical integrity.

In addition, the type of full-face masks that use the one-piece design for the eyes, nose and mouth to reduce the knowledge of breathing techniques required for underwater use has led to widespread use among different age groups. However, this has caused many fatal accidents in recent years. From 2019, the European Union (EU) has made mandatory mandatory safety supervision that CE products must be CE certified in accordance with the requirements of the new Regulation (EU) 2016/425 before the products can be sold in the EU , the Standard EN 136: 1998 is an EU standard for performance, test modes and labeling of full face masks. It is particularly important that in the test mode of EN 136: 1998 the full face mask is tested at 50 RMV (tidal volume ratio) and under the conditions that the drain valve on the mask is open or closed and the test result of the mask must meet the condition, that the carbon dioxide content of the inhaled air (dead space) must not exceed 1% on average. That is, when the full face mask is used in water, when the user inhales, enough clean air must be supplied so that a larger amount of oxygen can fully penetrate the mask, and when the user exhales, dirty air can really and effectively get to the outside the mask so that no carbon dioxide remains in the mask. This is the only way the mask can pass the test standard to ensure that the user can breathe safely in the dead space without being in danger under water.

However, as mentioned above, conventional full-face masks have a number of life-threatening technical designs (ie the actual gas circulation path is obviously different from what is theoretically expected, so that the intake of clean air and the emission of carbon dioxide are not standard), so that it is almost impossible for these masks to meet the test standard EN 136: 1998. These life-threatening designs lead to potential dangers, and consumers have no way of identifying technical defects based on the appearance of the masks. It is therefore particularly important to obtain certification according to the Standard EN 136: 1998 to introduce for the product.

Therefore, providing a full face mask that meets various safety standards has become an urgent need in the art, and this is also a particular focus of the present invention.

Content of the invention

It is an object of the present invention to provide a full face mask that meets various safety standards.

In order to achieve the above object, a full-face mask according to the preferred embodiment of the present invention has a mask body, a breathing tube, an unfolded insulation carrier section and at least one inlet valve. The mask body conforms to a user's face over a soft portion to form an interior. The breathing tube is arranged on the mask body and connected to the interior such that the user can breathe in / exhale air through the breathing tube. The unfolded insulation support section is arranged in the interior, so that the interior defines an upper space and a lower space, and the lower space is connected to the breathing tube. The at least one inlet valve is arranged on the unfolded insulation carrier section.

In order to achieve the above object, a full-face mask according to a further preferred embodiment of the present invention has a mask body, a breathing tube, an unfolded insulation carrier section and at least one inlet valve. The mask body has a lens portion and a soft portion which are connected to each other. The soft section conforms to a user's face and forms an interior. The breathing tube is arranged on the mask body and connected to the interior. The unfolded insulation support section is arranged in the interior such that the interior defines an upper space and a lower space. The lower room is connected to the breathing tube. The at least one inlet valve is arranged on the unfolded insulation carrier section. A channel is defined at the junction of the lens section and the soft section. The channel has a guide plate for preventing the circulation of gas flowing from a lower end of the channel to the breathing tube.

In one embodiment, the full-face mask according to the invention also has a first insulation plate, which is in the lower space is arranged that the lower space defines a proximal space and a distal space. The proximal space is near the user's nose.

In one embodiment, the first insulation plate of the full-face mask according to the invention also has a one-way valve for dispensing exhaust gas exhaled by the user.

In one embodiment, the lens section of the full-face mask according to the invention also has a deflection opening which is connected to the distal space.

In one embodiment, the soft section of the full-face mask according to the invention furthermore has a stop piece which covers the deflection opening.

The following sections describe the detailed technology and preferred embodiments of the present invention in conjunction with the accompanying drawings to illustrate those skilled in the art the features of the claimed invention.

Figure list

• 1 shows a perspective view of a conventional full face mask;
• 2nd shows a schematic perspective view of a full face mask according to the invention;
• 3rd shows a schematic front view of an unfolded insulation carrier section of the full face mask according to the invention;
• 4A to 4D show schematic cross-sectional views of the unfolded insulation support portion of FIG 3rd along the lines BB , CC , DD and EE as a result;
• 5 shows a schematic cross-sectional view of the full face mask along the line AA ;
• 6 shows a schematic exploded view of the full face mask of FIG 5 with a frame and an outer cover;
• 7 shows a schematic view of a lens portion of the full face mask of FIG 5 ;
• 8th shows a schematic view of the full face mask of FIG 5 in which the lens portion is connected to a soft portion;
• 9 shows a schematic exploded view of the full face mask according to the invention;
• 10th shows a schematic combined view of the full face mask of FIG 9 ;
• 11 shows a schematic view showing the flow path of the air flow in the channel of the full face mask according to the invention when the user exhales; and
• 12th FIG. 14 is a schematic view showing the inhalation, exhalation and discharge directions of the full face mask of FIG 5 .

Description of the embodiments

As in 2nd is shown is a full face mask 200 1, which is illustrated in one embodiment of the present invention, is configured to be worn on a user's face and has a mask body 210 , a breathing tube 220 , an unfolded insulation support section 230 and at least one inlet valve 241 on.

The mask body 210 has a soft section 214 and a lens section 216 that are connected to each other. The mask body 210 fits over the soft section 214 (or referred to as an "apron section") that is on the perimeter of the lens section 216 is formed on the face of a user, and the mask body 210 forms an interior 212 . The breathing tube 220 is over the mask body 210 arranged and with the interior 212 connected so that the user can inhale / exhale air through the breathing tube. The unfolded insulation support section 230 is in the interior 212 arranged so that the interior 212 an upper room 232 and a lower room 234 Are defined. A front 2301 of the unfolded insulation support section 230 can (indirectly or directly) on the inside of the lens section 216 be attached. The backside 2302 of the unfolded insulation support section 230 is directed backwards and the face of the user (which faces forward and the lens section 216 is facing).

The backside 2302 of the unfolded insulation support section 230 can be in direct contact with the user's face and fit the user's cheek and cover the user's nose area (roughly from the bridge of the nose to the cheeks on either side of the mouth).

Since there are many gaps between the insulation section 110 that in the conventional full face mask 100 is used, and the cheek and nose of the user are there, air easily flows through the gaps directly into the lower space 114 when the user inhales, so the one-way valve 120 of the isolation section itself almost in a closed state for a long time. In this embodiment, as in 3rd is shown, the unfolded insulation support section 230 fully fit on the user's cheek and cover the user's nose area so that there is no space between the deployed insulation support section 230 and the user's cheeks and nose. An upper room 232 (also known as the eye area) and a lower area 234 (also known as the nose and mouth) are actually separate and defined. In detail, as in the 4A to 4D is shown, the unfolded insulation support section 230 preferably be arranged such that it has an inward curvature in the vicinity of the bridge of the nose. The inward curvature may extend a maximum of 1 cm inward (towards the lower room 234 ) ( 4A) to fit snugly around the bridge of the nose. The unfolded insulation support section 230 that extends down from the bridge of the nose does not bulge inwards ( 4B) . The unfolded insulation support section 230 has an outward curvature at the portion near the cheeks on both sides of the mouth. The outward curvature extends at most 1 cm outwards (towards the upper room 232 ) ( 4C and 4D ) to ensure good support so that the mask is less likely to collapse. In this way, when the user inhales, the at least one inlet valve 241 that on the unfolded insulation support section 230 is easily forced to open because the pressure in the nose and mouth is actually reduced without air leakage, and the exhaust gas exhaled through the nose and mouth will not flow back through the gaps and get inside 212 accumulate.

As in 5 which is a partial and schematic cross-sectional view of the full face mask 200 according to an embodiment of the present invention along the line AA shows, that is at least one inlet valve 241 on the unfolded insulation support section 230 arranged, for example, the at least one inlet valve 241 on the unfolded insulation support section 230 be arranged symmetrically on the left and right side of the nose area of the user.

According to 6 can the lower room 234 the full face mask 200 furthermore have at least one one-way valve, for example an upper outlet valve 252 and a lower drain valve 254 can be. The upper exhaust valve 252 and the lower drain valve 254 can each be inclined at different angles so that when water accumulates, the accumulated water can optionally be dispensed through the most suitable valve according to the angle of rotation of the user's head. If there is only a small amount of accumulated water, the accumulated water can easily come from the lower drain valve 254 be released to the outside before the water reaches the level of the upper outlet valve 252 accumulates. At this time, the upper exhaust valve is 252 specifically responsible for the emission of the exhaust gas exhaled by the user, so that the efficiency of the emission of water and gas is further improved. Using the mask is smoother and easier, with no risk of water being inhaled, and the safety and fun of snorkeling can be improved naturally.

The full face mask 200 can also have a first insulation plate 260 with a peripheral portion 261 have that in the lower room 234 is arranged. The peripheral section 261 can be directly or indirectly on the inside of the lens section 216 be attached so that the lower room 234 a proximal space 235 near the user's nose and a distal space 236 defined that is away from the user's nose.

The mask body 210 can also be a framework 218 and an outer cover 219 have, the frame 218 around the lens section 216 and the soft section 214 can be attached around the lens portion 216 continue to protect. The outer cover 219 is on the lens section 216 or on the frame 218 releasably attached and preferably shields the area of the lens section 216 with the upper exhaust valve 252 and the lower drain valve 254 off to the upper exhaust valve 252 and the lower drain valve 254 to protect. If the upper exhaust valve 252 and the lower drain valve 254 Structures that cannot be easily damaged are the outer cover 219 may not be necessary. The first insulation plate 260 can be made of a soft material or a hard material and can also be a one-way valve 256 for dispensing exhaust gas exhaled by the user.

As in 7 is shown, the lens section 216 the full face mask 200 this embodiment also a deflection opening 211 have, which is below a guide plate 217 located from the inside of the lens section 216 extends. If water W in the upper room 232 the full face mask 200 penetrates, the water flows W along the inside of the lens section 216 or the guide plate 217 to the deflection opening 211 and flows to the lower drain valve 254 of the lower room 234 and is then issued to the outside.

As in 8th is shown, the soft section 214 a stop piece 2141 exhibit. If the soft section 214 with the lens section 216 is connected, the stop piece 2141 the deflection opening 211 cover and can be configured to prevent the water W along the deflection opening 211 to the upper room 232 flows back. That is, the stop piece 2141 can serve as a one-way valve to allow the water W unidirectional to the lower room 234 flows. As in the 9 and 10th is shown, the soft section 214 and the lens section 216 after they are connected, a channel 213 within the perimeter of the full face mask 200 form. The channel 213 has a guide plate 213a on. The guide plate 213a can be a section of the lens section 216 or a section of the soft section 214 and is at the junction of the channel 213 and the breathing tube 220 provided for a direct circulation of from a lower end of the channel 13 to the breathing tube 220 flowing gas 213 to block. If, as in 11 the exhaust gas exhaled by the user is shown C. from the lower room 234 in the lower end of the channel 213 enters and then to the top of the channel 213 and the breathing tube 220 flows, the guide plate 213a prevent the direct circulation of the exhaled gas (the air in the left channel flows directly to the right channel or vice versa), which would otherwise lead to the exhaust gas C. (Carbon dioxide) in the full face mask 200 accumulates. In this case, the exhaust gas C. are not fully dispensed and the user is at risk because they cannot breathe enough clean air. By arranging the guide plate 213a the air from the left channel and the right channel is blocked and then flows more evenly and directly to the breathing tube 220 and then becomes the outside of the full face mask 200 spent.

• Wenn der Benutzer einatmet, kann die Luft R vom Einlassventil 241 des entfalteten Isolationsträgerabschnitts 230 in den unteren Raum 234 strömen und somit mit weniger Kraftaufwand in die Nase und den Mund eintreten, so dass die Luft(Sauerstoff)menge, die der Benutzer einatmet, ausreichend ist. Wenn der Benutzer ausatmet, wird das Einlassventil 241 zwangsweise geschlossen, strömt ein Teil des Abgases C vom Kanal 213 zum Atemschlauch 220, um ausgegeben zu werden, während ein Teil des Abgases C vom proximalen Raum 235 durch das Einwegeventil 256 der ersten Isolationsplatte 260 zum distalen Raum 236 strömt und dann durch das obere Auslassventil 252 oder das untere Ablassventil 254 nach außen strömt. Wenn das Wasser W versehentlich in die Vollgesichtsmaske 200 fließt, kann das in den Innenraum 212 eindringende Wasser W aufgrund der Anordnung der ersten Isolationsplatte 260 im distalen Raum 236 zwischen dem Linsenabschnitt 216 und der ersten Isolationsplatte 260 isoliert und zwischen der Linse 218 und der ersten Isolationsplatte 260 gesammelt werden und wird nicht in den proximalen Raum 235 eintreten, um mit der Nase und dem Mund des Benutzers in Kontakt zu kommen, wodurch Panik und Angstzustände des Benutzers vermieden werden. Wenn der Benutzer ausatmet, nimmt der Druck im distalen Raum 236 zu, um das angesammelte Wasser vom oberen Auslassventil 252 oder vom unteren Ablassventil 254 auszugeben. Alternativ kann, wenn der Benutzer von der Wasseroberfläche auftaucht, aufgrund des Gewichts des angesammelten Wassers die Wirkung der Schwerkraft das Wasser direkt aus dem oberen Auslassventil 252 oder dem unteren Ablassventil 254 herausbringen (in Abhängigkeit von der Menge des angesammelten Wassers oder der Richtung des Kopfes), ohne dass der Benutzer ausatmen muss. Ein solches Design kann die Probleme des Stands der Technik erheblich verbessern, gemäß denen es für den Benutzer schwierig ist, ausreichend reine Luft einzuatmen (der Kohlendioxidgehalt zu hoch ist) und der Benutzer sich Sorgen macht, wenn er mit dem angesammelten Wasser in Kontakt kommt, und es ist während des Einatmens und des Ausatmens anwendbar.

According to 12th becomes the airflow path of the full face mask 200 described in this embodiment as follows:

• When the user inhales, the air can R from the inlet valve 241 of the unfolded insulation support section 230 in the lower room 234 flow and thus enter the nose and mouth with less effort, so that the amount of air (oxygen) that the user inhales is sufficient. When the user exhales, the intake valve 241 part of the exhaust gas flows when closed C. from the canal 213 to the breathing tube 220 to be output while a part of the exhaust gas C. from the proximal space 235 through the one-way valve 256 the first insulation plate 260 to the distal space 236 flows and then through the upper exhaust valve 252 or the lower drain valve 254 flows outwards. If the water W accidentally into the full face mask 200 flows into the interior 212 penetrating water W due to the arrangement of the first insulation plate 260 in the distal space 236 between the lens section 216 and the first insulation plate 260 isolated and between the lens 218 and the first insulation plate 260 are collected and will not be in the proximal space 235 Enter to come into contact with the user's nose and mouth, thereby avoiding panic and anxiety. When the user exhales, the pressure in the distal space increases 236 to the accumulated water from the upper outlet valve 252 or from the lower drain valve 254 to spend. Alternatively, when the user emerges from the surface of the water, due to the weight of the water accumulated, the effect of gravity can direct the water out of the upper outlet valve 252 or the lower drain valve 254 bring out (depending on the amount of water accumulated or the direction of the head) without the user having to exhale. Such a design can greatly improve the problems of the prior art, according to which it is difficult for the user to breathe in enough clean air (the carbon dioxide content is too high) and the user is worried when he comes into contact with the accumulated water, and it is applicable during inhalation and exhalation.

As described above, the unfolded insulation support portion of the full face mask according to the present invention completely fits and covers the cheeks and the nose of the user, and a guide plate is arranged in the channel so that the user can easily breathe in pure air and can exhaust gas more effectively from the breathing tube and / or the one-way valve and is less likely to flow back and accumulate, thereby meeting various safety standards. At the same time, a stopper or an isolation plate can also be provided to isolate the water that accidentally flows into the full face mask from the nose and mouth of the user, thereby preventing the user from coming into contact with the water and thereby becoming anxious and panics, and safety in use is increased.

The above description relates to the detailed technical content and features thereof according to the invention. Those skilled in the art will be able to make a variety of modifications and modifications based on the foregoing description and proposals of the invention Make replacements without departing from their characteristics. Although such modifications and substitutions have not been fully illustrated in the foregoing description, they are still substantially covered by the appended claims.

Reference symbol list

100

Full face mask

110

Isolation section

112

upper room

114

lower room

116

Air duct

120

One-way valve of the isolation section

130

One-way valve of the mouth section

140

side one-way valve

200

Full face mask

210

Mask body

211

Deflection opening

212

inner space

213a

Guide plate

214

soft section

2141

Stop piece

216

Lens section

217

Guide plate

218

frame

219

outer cover

220

Breathing tube

230

unfolded insulation support section

2301

front

2302

back

232

upper room

234

lower room

235

proximal space

236

distal space

241

Inlet valve

242

Valve lock

256

One-way valve

252

upper exhaust valve

254

lower drain valve

260

first insulation plate

261

Circumferential section

A

angle

R

air

C.

Exhaust gas

W

water

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Non-patent literature cited

• Standard EN 136: 1998 [0013, 0014]

Claims (6)

Full face mask designed to be worn on a user's face, with: a mask body having a lens portion and a soft portion connected to each other, the soft portion fitting on the face of the user and the mask body forming an interior; a breathing tube which is arranged on the mask body and connected to the interior; an unfolded insulation support section which is arranged in the interior such that the interior defines an upper space and a lower space, the lower space being connected to the breathing tube; and at least one inlet valve, which is arranged on the unfolded insulation support section, wherein a channel is defined at the junction of the lens portion and the soft portion, and the channel has a guide plate to prevent the circulation of gas flowing from a lower end of the channel to the breathing tube. Full face mask after Claim 1 , wherein a channel is defined at the junction of the lens portion and the soft portion, and the channel has a guide plate to prevent the circulation of gas flowing from a lower end of the channel to the breathing tube. Full face mask after Claim 1 , further comprising a first isolation plate located in the lower space so that the lower space defines a proximal space and a distal space, the proximal space being near a user's nose. Full face mask after Claim 3 wherein the first isolation plate further includes a one-way valve for dispensing exhaust gas exhaled by the user. Full face mask after Claim 1 , wherein the lens section further has a deflection opening which is connected to the distal space. Full face mask after Claim 1 , wherein the soft section further comprises a stop piece that covers the deflection opening.

Images