DE202015100434U1 - oxygen mask - Google Patents

Abstract

Respiratory mask, with a breathing mask body (1), an inlet valve (3), an outlet valve (4) and a connection (6) for a gas line, by means of which an individual who wears the breathing mask, in the proper use of the breathing gas mask, a gas can be supplied characterized in that the inlet valve (3) is in fluid communication with a respiratory gas supply system (10) open to an ambient atmosphere of the respiratory mask (1), and that the gas line port (6) is in flow communication with the respiratory gas supply system (10).

Description

The present invention relates to a breathing mask according to the preamble of claim 1.

Various breathing gas analysis methods are known from the prior art in which a breathing mask is used to collect the exhaled air of a subject and to transfer it to an analysis device. For example, this describes WO 2007/000145 A2 a corresponding respiratory analysis method and a respiratory mask which can be used for this purpose. In the respiratory gas analysis method described in that international patent application, the carbon dioxide content in the exhaled air of a subject is determined, the ratio of ¹³ CO ₂ to ¹² CO _{2 being} calculated. During such a breathing gas analysis, the carbon dioxide concentration must not fall below the detection limit of the measuring instrument used or be exposed to strong fluctuations. In these cases, reliable statements would no longer be possible.

Basically, two scenarios are conceivable, which can lead to a fall below the detection limit or excessive fluctuations in the carbon dioxide concentration in the exhaled air of the subject. For one, the respiratory mask used could not sit correctly on the subject's face. Then it would seal in an insufficient manner, so that exhaled air can escape not only through an outlet valve of the breathing mask, but also on the exhaust valve into the environment. On the other hand, the patient can be supported by the addition of oxygen in his breathing. So according to the in the WO 2007/000145 A2 described a gas connection for an additional oxygen supply, through which a continuous oxygen supply is made possible directly into the interior of the breathing mask. As a result, an oxygen saturation of the patient can be achieved in many cases. Due to the permanent net flow of oxygen into the interior of the breathing mask, two scenarios turn up again. On the one hand, when the subject exhales, the oxygen supplied is mixed with the exhaled air and conducted together into the meter. On the other hand, even in the interval between two breaths oxygen is passed through the exhalation valve in the used for the Atemgasanalyseverfahren meter (the system is open in this direction). This leads to a change in the carbon dioxide concentration, which, on the one hand, can be below the detection limit of the measuring device and, on the other hand, results in strong fluctuations in the actual measuring signal.

Other respiratory masks known in the art can not adequately solve this problem.

That's how it describes US 2005/0085799 A1 a respiratory mask in which an oxygen supply in the breathing mask by a first valve and a Ausatemluftabfuhr from the breathing mask is accomplished by a second valve. The oxygen supply is connected to a closed breathing circuit. This results in the same, already described above problem: The oxygen concentration inside the breathing mask is relatively high, so that an oxygen saturation of the patient can be achieved. At the same time, however, oxygen may also be mixed with the exhaled air of the patient and reduce the carbon dioxide concentration in the exhaled air.

The WO 99/30760 A1 describes an inhalation device by means of which a drug in the form of an aerosol or a finely divided powder can be supplied to a patient. In this breathing mask, an inhalation valve is connected to a closed system, which serves to supply the drug. In addition, the teaching of that international patent application does not provide a solution for a controlled supply of oxygen.

The US 6,123,071 A describes a two-part mask with an oral and a nasal chamber. The oral cavity and the nasal chamber are connected by means of a hose. Furthermore, connecting pieces are provided to supply the breathing mask with pressurized air. That is, the breathing mask is again connected to a closed air or oxygen delivery system to achieve an increased oxygen concentration inside the breathing mask. As a result, however, the oxygen concentration in the exhaled air of a wearer of the breathing mask can also be increased again, which results in a reduction of the carbon dioxide concentration in the expiratory air of the wearer.

The US 2004/0211428 A1 also describes a respiratory breathing mask which, in turn, can be connected to a closed oxygen delivery system. This also results in the same problem with this breathing mask as in the previously discussed respiratory masks: The oxygen concentration inside the breathing mask is increased by the pressure-supplied oxygen, whereby an oxygen saturation of a patient wearing the breathing mask is guaranteed. However, oxygen also enters the exhaled air of the patient in this way. Thus, this breathing mask is not suitable for carrying out a carbon dioxide-specific analysis of the exhaled air of the patient.

It is an object of the present invention to provide a breathing mask which allows a wearer of the breathing mask to oxygenate without reducing the carbon dioxide concentration in the exhalation air of the wearer of the breathing mask.

This object is achieved by a breathing mask with the features of claim 1. Such a breathing mask comprises a breathing mask body, an inlet valve, an outlet valve and a connection for a gas line. By means of the gas line, an individual who wears the breathing mask can be supplied with a gas in the proper use of the breathing mask. This gas is preferably oxygen or oxygen-enriched air. In other words, the gas line that can be connected to the port is preferably an oxygen line or a line that carries oxygen-enriched air.

The respiratory mask claimed according to the invention is characterized in that the inlet valve is in fluid communication with a respiratory gas supply system which is open relative to an ambient atmosphere of the respiratory mask. Furthermore, the breathing mask is characterized in that the connection for the gas line is in flow communication with the breathing gas supply system. The breathing gas supply system is arranged on an outer side of the breathing mask. When the respirator is worn by an individual as intended, the outside of the respirator faces away from the individual while an inside of the respirator faces toward the face of the individual.

In contrast to the respiratory masks known from the prior art, an additional supply of oxygen therefore does not take place directly into the interior of the respiratory mask but into a respiratory gas supply system arranged outside the respiratory mask. The respiratory mask is designed and arranged so that an individual wearing the breathing mask breathes normally in the usual way, the inhaled air flowing through the inlet valve into the interior of the breathing mask and the exhaled air of the individual flowing through the outlet valve from the breathing mask. Now, when oxygen or oxygen-enriched air is supplied through the supplemental gas port on the respiratory gas delivery system, an individual wearing the respiratory mask inhales that oxygen or oxygen-enriched air. However, only so much oxygen or oxygen-enriched air is admitted into the respiratory mask as the individual pretends to do by inhaling. In other words, inside the respiratory mask, there is no unnecessary excess of oxygen that would go beyond the amount that the individual inhales.

Nevertheless, a constant flow of oxygen can be supplied to the breathing gas supply system via the connection for the gas line. Due to the open design of the breathing gas delivery system, excess oxygen simply flows into the atmosphere. The term "open" can also be referred to as "fluidically open". However, the inlet valve prevents excess oxygen from entering the interior of the breathing mask as long as the individual wearing the breathing mask does not actively inhale.

Since the novel arrangement of the connection for the gas line no continuous oxygen supply into the interior of the gas mask more, it is also because of avoiding mixing of oxygen supplied with exhaled air no longer to a reduction of carbon dioxide concentration in the exhaled air of the individual. Rather, the exhaled air of the individual can emerge from the breathing mask in an almost undiluted manner in the event of a common exhalation pulse through the outlet valve. This allows the exhaled air of the individual to be analyzed with high precision in a measuring device used for the analysis of expired exhaled gas.

The volume flow of the gas supplied via the connection for the gas line can consequently be set in any desired manner and has no influence on the carbon dioxide concentration in the exhaled air of the individual.

The individual is preferably a human or an animal, with mammals such as rodents or primates being preferred as animals.

In a variant, the breathing gas supply system is provided with a neck intended and adapted to be connected to a hose. The neck extends preferably on the outside of the breathing mask of the breathing mask body away. If the spout is not yet connected to a hose, it already forms a small-volume reservoir for a gas that is introduced into the breathing gas supply system via the connection for the gas line. The nozzle is therefore preferably arranged on an outer side of the inlet valve.

In a further variant, the breathing gas supply system comprises a tube having a first end and a second end. The first end is oriented towards the inlet valve, while the second end opens into the ambient atmosphere of the breathing mask. This orifice is not closed or regulated by a valve and / or an air flap and / or a pump, but designed to be open.

In one variant, the aforementioned tube is connected gas-tight to the nozzle. In this way it is possible to use the tube as part of the breathing gas delivery system. Furthermore, it is possible in this way to use the tube as a buffer volume for the breathing gas supply system.

The connection for the gas line is preferably formed on the neck. When a hose is connected to the nozzle, gas flowing through the gas line connector into the breathing gas supply system may continue to flow into the hose. As an individual wearing the breathing mask inhales, the gas flows from the hose back into the neck and through the inlet valve into the interior of the breathing mask. The inhaled air of the individual then consists of the gas that has accumulated in the hose. Depending on the amount of additionally supplied gas, the respiratory gas which has accumulated in the hose can be only the supplied gas or a mixture of the ambient air and the supplied gas.

If no hose is used, the inhalation air of the individual wearing the breathing mask consists either exclusively of ambient air (namely, if no additional gas is supplied through the connection for the gas line) or of a mixture of the ambient air and additionally via the Connection for the gas line supplied gas.

In one variant, the volume of the respiratory gas supply system is at least 5 ml, in particular at least 9 ml, in particular at least 10 ml, in particular at least 20 ml, in particular at least 50 ml and very particularly at least 100 ml. The volume of the respiratory gas supply system is - if it is 50 ml or is less - in particular formed by the aforementioned nozzle. In particular, when the volume of the breathing gas supply system is larger, it is formed by the nozzle and a buffer volume connected to the nozzle. The buffer volume can - as explained - for example, by a hose which is connected in a gastight manner with the nozzle, are provided.

In a further variant, the volume of the breathing gas supply volume is at most 600 ml, in particular at most 550 ml, in particular at most 500 ml, in particular at most 450 ml, in particular at most 400 ml, in particular at most 350 ml, in particular at most 300 ml, in particular at most 250 ml, in particular at most In this way, the buffer volume provided by the respiratory gas delivery system may correspond to the volume of a breath of the individual. That is, the respiratory gas delivery system can buffer such an amount of gas that an average individual breathing the respiratory mask inhales upon inhalation. When the volume inspiring the individual carrying the breathing mask is greater than the volume of the breathing gas delivery system, ambient air simply flows into the breathing gas delivery system due to the open structure of the breathing gas delivery system, such that the individual then also carries ambient air in addition to any gas supplied inhale. The open design of the breathing gas delivery system thus allows for greater dimensional tolerances of the buffer volume provided by the breathing gas delivery system.

In a further variant, the connection for the gas line has an opening with a center at a distance of at most 50 mm, in particular at most 40 mm, in particular at most 30 mm, in particular at most 20 mm and very particularly at most 10 mm from an outer surface the inlet valve is arranged. In other words, the connection for the gas line opens into the breathing gas supply system in the smallest possible distance to the outside of the inlet valve. As a result, even in the event that the buffer volume is low, a good supply of the individual carrying the respiratory mask can be ensured with the additional gas supplied via the connection. In addition, in this way dilution effects which could result in the buffer volume of the respiratory gas supply system can be avoided.

In a further variant, the inlet valve, the connection for the gas line and at least part of the breathing gas supply system are designed as a common structural unit. This common structural unit can be designed, for example, in the form of an inlet valve body, which comprises the inlet valve, the connection for the gas line and a connection for connecting a hose. Such an inlet valve body can be made particularly favorable and used in a particularly simple manner in a designated opening in the respirator body. This considerably facilitates the production of the breathing mask.

In a further variant, the common structural unit is used, when the respiratory mask is used as intended, in a flow-tight manner in the respiratory mask body. In this way it is achieved that the inhalation air of an individual who wears the breathing mask actually has to flow through the inlet valve, but can not flow past it.

In this way it is also ensured that no exhaled air from the interior of the breathing mask at the inlet valve over the breathing mask can flow. Furthermore, it is provided that the common structural unit can be removed from the respiratory mask body in a non-destructive manner before or after the intended use of the respiratory mask.

In a further variant, the connection for the gas line is arranged at an angle to an opening axis of the inlet valve. In this way, an overflow of the inlet valve can be achieved with the gas supplied through the terminal particularly advantageous. This greatly facilitates a supply of the individual carrying the respiratory mask with the additionally supplied gas. The angle may, for example, 15 ° to 100 °, in particular 30 ° to 95 °, in particular 45 ° to 92 °, in particular 60 ° to 90 °, in particular 75 ° to 88 °, in particular 85 ° to 95 ° (substantially rectangular) and especially 90 ° (at right angles).

There is also disclosed a breath analysis method for determining at least one constituent of the breath of an individual. The breathing analysis method is characterized in that a breathing mask is used according to the previous explanations, to transfer the exhaled air of the individual in a meter that is used for the analysis of respiratory gas. For this purpose, provision is made, in particular, to connect a hose in a gas-tight manner to the outlet valve of the breathing mask, so that the exhaled air of the individual can be transferred directly into the measuring device through the outlet valve and the hose. Such transfer of the exhaled air of an individual is already known per se and will therefore not be described in detail here. However, due to these intended uses of the breathing mask, the respiratory mask body is preferably configured such that a tube can be connected in a gastight manner with the outlet valve of the breathing mask.

Further properties and details of the presently claimed breathing mask will be described in more detail below with reference to an embodiment with corresponding figures. Show it:

1A an exploded view of an embodiment of a breathing mask;

1B a sectional view of the embodiment of the 1A ;

2A an exploded view of a known from the prior art respirator and

2 B a sectional view of the breathing mask the 2A ,

The 2A shows a breathing mask 1 with a breathing mask body 2 and an inlet valve 3 and an exhaust valve 4 in the breathing mask body 2 are used. The inlet valve 3 consists of an inlet valve body 3a having multiple openings through the air through the inlet valve 3 can flow through, as well as a first silicone disk 3b that closes these holes. The first silicone disk 3b is arranged such that air only from the outside to the inside of the breathing mask 1 can flow. In a similar way is the exhaust valve 4 designed. So it has an outlet valve body 4a on, which in turn is provided with holes through which air can flow. These holes come with a second silicone disk 4b covered. Here is the second silicone disc 4b arranged so that air only from the inside of the breathing mask 1 can flow to the outside, but not vice versa. This is the inlet valve 3 Consequently, only the supply of inhaled air into the interior of the breathing mask 1 while the exhaust valve 4 excluding the outflow of exhaled air from the interior of the breathing mask 1 serves.

The inlet valve 3 makes up together with a neck 5 and a connection for a gas line 6 an extended inlet valve body 7 , which is designed as a common unit. The connection 6 is with an oxygen nozzle 8th connected, the simple connection of an oxygen line to the connection 6 serves. Through the oxygen nozzle 8th and the connection 6 can oxygen in the neck 5 are fed and then through the inlet valve 3 into the interior of the breathing mask 1 flow when an individual wearing the breathing mask inhales.

At the neck 5 can a hose 9 be connected, the volume of the neck 5 increased. The extended intake valve body 7 , the oxygen pipe 8th and the hose 9 together form a breathing gas supply system 10 , Because the hose 9 at his the respiratory mask body 2 opposite end 11 can be configured open, through the oxygen nozzle 8th into the breathing gas supply system 10 introduced oxygen from the breathing gas supply system 10 into the environment of the breathing mask 1 escape, provided that the oxygen (optional along with other gases such as air) is not from an individual to the interior of the breathing mask 1 inhaled while inhaling.

The hose 9 does not necessarily have to be on the neck 5 be attached. If on the hose 9 is omitted forms an opening 12 of the neck 5 an open completion of the oxygen delivery system 10 ,

In the same way it is not absolutely necessary that the oxygen nozzle 8th is used. Rather, another nozzle can be used be to a gas line with the connection 6 connect to. A connection without a nozzle is also possible.

From the interior of the breathing mask 1 escaping exhaled air leaves the breathing mask body 2 through the outlet valve 4 and then flows through an outlet hose 13 , This outlet hose 13 can be connected directly to a meter where the expired air is to be analyzed. In this way, a simple transfer of the exhaled air in such a meter is possible.

So the breathing mask 1 can be held in a particularly simple manner on the face of an individual, is in the region of the connection of the outlet tube 13 on the breathing mask body 2 a retaining ring 14 provided on which a rubber band can be attached. By means of this rubber band, the respiratory mask is held securely over the mouth and nose of an individual, the respiratory mask body 2 while closing tightly with the facial surface of the individual, allowing inhalation exclusively through the inlet valve 3 and exhaling exclusively through the exhaust valve 4 becomes possible. When used as intended, the respiratory mask sits so firmly on the face of the individual in question that there is no air at the contact surface between the respiratory mask body 2 and can flow past the face of the individual.

The 1B shows a sectional view through the breathing mask 1 of the 1A , Identical elements are given the same reference numerals. In the presentation of the 1B is the interior 15 the breathing mask 1 clearly visible. It is also easy to see how the inlet valve 3 and the exhaust valve 4 in the breathing mask body 2 are placed. In this case, in particular, the different orientation of the inlet valve 3 and the exhaust valve 4 to see. So covered the first silicone disk 3b of the inlet valve 3 the inside of the inlet valve body 3a while the second silicone disk 4b the exhaust valve 4 the outside of the exhaust valve body 4a covered. In this way it is ensured that a gas through the inlet valve only into the interior 15 the breathing mask 1 can flow into the interior 15 the breathing mask 1 but not through the inlet valve 3 can leave. In the same way, this arrangement ensures that a gas is the interior 15 the breathing mask 1 only through the outlet valve 4 can leave while no gas through the exhaust valve 4 in the interior 15 the breathing mask 1 can flow in.

On one of the inside of the neck 5 facing side of the oxygen outlet 8th is also an opening 16 seen at a close distance to an outside of the inlet valve 3 in the neck 5 empties. This is done via the oxygen nozzle 8th supplied oxygen in close proximity to the inlet valve 3 into the breathing gas supply system 10 brought in.

The opening axis of the inlet valve 3 is represented by a double arrow marked with an X. The opening 16 of the connection 6 into the oxygen nozzle 8th is inserted, opens substantially at right angles to this opening axis X of the intake valve 3 ,

The breathing mask body 2 is made of silicone, while the extended intake valve body 7 and the exhaust valve body 4a made of polycarbonate. These materials allow easy insertion of the extended inlet valve body 7 and the exhaust valve body 4a in the breathing mask body 2 , wherein at the same time a good seal of the respiratory mask body 2 to the extended intake valve body 7 and the exhaust valve body 4a he follows.

By the arrangement of the oxygen outlet 8th on the outside of the inlet valve 3 For example, the volume flow set by an additional oxygen line does not play a significant role in the amount of oxygen passing through the inlet valve 3 through into the interior 15 the breathing mask 1 to be led. Rather, the oxygen is added to the interior 15 the breathing mask 1 is dosed by volume and is due to the breathing of the individual, which is the respiratory mask 1 bears, certainly. When the inlet valve 3 is closed (if the individual who wears the mask, so do not breathe), no oxygen flows into the interior 15 the breathing mask 1 ,

The 2A shows a breathing mask 101 as known in the art. In this breathing mask 101 are one from an inlet valve body 103a and a third silicone disk 103b existing inlet valve 103 and one of an exhaust valve body 104a and a fourth silicone disk 104b existing exhaust valve 104 in a breathing mask body 102 used. However, with this breathing mask 101 no respiratory gas supply system as in the breathing mask of 1A intended. True, in an interior of the breathing mask 101 In addition, oxygen can be dosed, but this is done via an oxygen port 108 directly into an interior of the breathing mask 101 empties.

Exhaled air may come from the breathing mask 101 again via a hose 113 be removed and transported directly to a meter. For a secure hold of the breathing mask 101 ensures a rubber band that attaches to a holder 114 be attached can. Because the oxygen nozzle 108 directly in the interior of the breathing mask 101 Even then, oxygen flows into the interior of the breathing mask 101 if an individual has the breathing mask 101 does not inhale, but exhales. Then, although the inlet valve 103 closed and the exhaust valve 104 opened, but the oxygen is on the oxygen nozzle 108 fed continuously. As a result, such supplied oxygen but directly through the exhaust valve 104 in the exhalation tube 113 and thus the carbon dioxide concentration in the exhaled air of the individual, the respiratory mask 101 carries, reduce. Also in the period between an inhalation of the individual, the breathing mask 101 carries and with an exhalation of the individual oxygen flows through the oxygen nozzle 108 into the interior of the breathing mask 101 and thus provides a reduction in carbon dioxide concentration in the exhaled air of the individual.

The 2 B shows a sectional view through the breathing mask 101 of the 2A , wherein like elements again with the same reference numerals as in the 2A are provided. In the presentation of the 2 B are the seat of the inlet valve 3 and the exhaust valve 4 in the breathing mask body 102 to recognize. Furthermore, it is easy to see in this illustration that the oxygen nozzle 108 directly into the interior 115 the breathing mask 101 empties. The resulting disadvantages in the handling of the breathing mask 101 have already been described in detail. These disadvantages occur in the in the 1A and 1B illustrated embodiment of a breathing mask not on.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely 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.

Cited patent literature

• WO 2007/000145 A2 [0002, 0003]
• US 2005/0085799 A1 [0005]
• WO 99/30760 Al [0006]
• US 6123071 A [0007]
• US 2004/0211428 A1 [0008]

Claims (10)

Respiratory mask, with a breathing mask body ( 1 ), an inlet valve ( 3 ), an outlet valve ( 4 ) and a connection ( 6 ) for a gas line, by means of which an individual who wears the breathing mask, in the proper use of the breathing gas mask, a gas can be supplied, characterized in that the inlet valve ( 3 ) in fluid communication with a relative to an ambient atmosphere of the breathing mask ( 1 ) open breathing gas supply system ( 10 ) and that the connection ( 6 ) for the gas line in flow communication with the breathing gas supply system ( 10 ) stands. Breathing mask according to claim 1, characterized in that the respiratory gas supply system ( 10 ) a nozzle ( 5 ) for connecting a hose ( 9 ) having. Breathing mask according to claim 1 or 2, characterized in that the respiratory gas supply system ( 10 ) a hose ( 9 ) having a first end and a second end ( 11 ), wherein the first end is oriented to the inlet valve and the second end ( 11 ) open into the ambient atmosphere of the breathing mask ( 1 ) opens. Respiratory mask according to claims 2 and 3, characterized in that the hose ( 9 ) gas-tight with the neck ( 5 ) connected is. Respiratory mask according to one of the preceding claims, characterized in that the volume of the breathing gas supply system ( 10 ) is at least 5 ml. Respiratory mask according to one of the preceding claims, characterized in that the volume of the breathing gas supply system ( 10 ) is at most 600 ml. Respiratory mask according to one of the preceding claims, characterized in that the connection ( 6 ) for the gas line an opening ( 16 ) with a center, wherein the center of the opening ( 16 ) at a distance of at most 50 mm from an outer surface of the inlet valve ( 3 ) is arranged. Respiratory mask according to one of the preceding claims, characterized in that the inlet valve ( 3 ), the connection ( 6 ) for the gas line and at least part of the breathing gas supply system ( 10 ) as a common building block ( 7 ) are executed. Respiratory mask according to claim 8, characterized in that the common structural unit ( 7 ) with proper use of the breathing mask ( 1 ) into the respiratory mask body ( 2 ) is used and before or after the intended use of the breathing mask ( 1 ) non-destructively from the respiratory mask body ( 2 ) can be removed. Respiratory mask according to one of the preceding claims, characterized in that the connection ( 6 ) for the gas line at an angle to an opening axis (X) of the inlet valve ( 3 ) runs.

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