DE102014017954A1 - Counterlung for a circuit respirator and respiratory protective device - Google Patents

Abstract

The present invention relates to a counterlung (1) for a breathing circuit protection device (100), comprising a container (2) with a dimensionally stable container body (3) and an opening (4) in the container body (3), wherein in the container body (3 ) an inlet opening (5) for the inlet of in the circuit of the respiratory protective device (100) CO2 -purified breathing air and an outlet opening (6) for the outlet of the inhaled breathing air back into the circulation of the respiratory protective device (100) is present, having a gas-tight Membrane (7) which covers the opening (4) of the container body (3) gas-tight, wherein the membrane (7) is designed so flexible that this in an inhalation state (E) in the interior of the container body (3) arched and in a Exhaled state (A) from the interior of the container body (3) bulged out, wherein in the inhaled state (E) breathing air has flowed through the outlet opening (6) from the interior of the container (2) and in the Exhalation state (A) CO2-purified breathing air has flowed through the inlet opening (5) into the interior of the container (2). Furthermore, the invention relates to a circulatory respirator (100) with at least one such Gegenlunge (1).

Description

The invention relates to a counterlung for a breathing circuit protection device and respiratory protective device.

Respiratory protection devices are devices that are used for respiratory protection, which means they provide protection against substances, particles or organisms that can enter the body via the respiratory tract. Self-contained breathing apparatus are devices that isolate the user of the device from the ambient atmosphere and supply it with breathable gas from a separate source. In particular, there are two types of portable self-contained breathing apparatus. On the one hand, there are container devices in which the breathing air is carried in compressed air bottles. Such devices are therefore also referred to as SCBA. On the other hand, there are circulatory respirators, also referred to as regeneration devices. In contrast to the container devices, circulatory respirators do not provide the complete air for inhalation, but they have a built-in oxygen source. These oxygen sources may be oxygen cylinders, liquid oxygen or chemically bound oxygen. So in a carbon dioxide filter exhaled carbon dioxide can be chemically bound and the oxygen consumed from the bottle to be supplemented.

STATE OF THE ART

To provide breathing air in stationary facilities, such. B. stationary respiratory or anesthetic equipment, as well as in mobile applications, such. As in respiratory protective devices, so-called counterlungs in the form of breathing bags are used. By injecting gas, a breathing bag is expandable until the breathing bag contains a construction-dictated maximum volume of gas. A state in which the breathing bag contains its design-related maximum gas volume is referred to below as the exhalation state. By releasing gas, the breath bag is shrinkable until the breath bag contains a minimum volume of gas, which in an idealized special case is zero liters. A state in which the breathing bag contains its construction-related minimum gas volume is referred to below as the inhalation state.

Gegenlungen or breathing bag have at least one access device and are preferably gas-tight. In breathing bags breathing air, i. d. R. at ambient pressure or slight overpressure, provided. Overpressure is particularly advantageous when using the breathing bag in a toxic environment, so that no foreign substances, in particular no toxins, can penetrate into the breathing bag from outside if the breathing bag is damaged.

Depending on their field of application, different demands are placed on counterlungs or breathing bags. Therefore, there are a variety of differently constructed breathing bag.

There are breathing bag are known, which are formed substantially flat and two flexible wall elements whose edge zones with each other, z. B. by gluing, welding, vulcanization or sewing, are connected. Such breathing bags are easy and relatively inexpensive to produce. A disadvantage of such breathing bags is that in the first state, ie in the state of maximum expansion, they have a substantially elliptical cross-section and thus often do not optimally utilize a receiving volume in the interior of a housing for receiving the breathing bag. This is especially true in cases where the housing does not have a dimension that is significantly smaller than the other two dimensions. The breathing bag is thus not suitable to optimally utilize the receiving volume. Moreover, such breathing bag have the disadvantage that in the second state, that is, when a recorded gas volume of the breathing bag has reached a minimum, the two wall elements, for. B. due to moisture, adhere to each other by adhesion forces. This leads to an increased resistance when filling the breathing bag and can lead to damage of the wall elements in extreme cases.

Furthermore, breathing bags are known which are essentially designed as bellows. Such breathing bags often have either a round or a rectangular cross-sectional area. In a special variant, the z. As in medical technology in stationary systems is widespread, such breathing bag have a foldable body made of an elastomer and a bottom (partially stationary) and a lid, the bottom and lid limit the body to two sides and are much stiffer than the body are formed , In the first state, the lid and the bottom have a maximum distance and in the second state a minimum distance from each other. Such breathing bags have the disadvantage that they have a relatively long seam or seal that is prone to damage. Breathing bags with a cylindrical base use a receiving volume of a housing with a rectangular base, the z. B. is used in respiratory protective equipment of the fire department, only partially. Furthermore, because of the elastomeric material, an elasticity of the main body is strongly temperature-dependent, so that the possible uses of these breathing bags are very limited. In particular for applications in which extreme ambient temperatures occur, such. As in fires, these breathing bags are therefore not suitable to provide without additional means for generating the overpressure. Thus, the elastomeric material properties change at extreme temperatures. When cold, elastomeric material becomes hard, while at high heat, elastomeric material softens. The change in the properties of the elastomeric material therefore adversely affects respiratory resistance for the user of a respirator with a bellows.

Another known embodiment of a breathing bag has a substantially tubular or cuboid breathing bag with a plurality of flexible walls. The breathing bag is arranged longitudinally between two pressure plates, wherein a pressure plate is clamped by means of a steel spring pair against the breathing bag and thus exerts a compressive force in the direction of the other pressure plate against the breathing bag. In the first state, the pressure plates have a maximum distance and in the second state a minimum distance from each other, whereby the breathing bag creases during the transition from the first state to the second state. Thus, in the second state, the walls of the breathing bag have an amorphous fold or an irregular fold.

Such breathing bags have a complicated shape and are expensive and expensive to produce. In particular, high human input is required for production. Furthermore, there is a high risk that leaks occur at seams. Such breathing bags also have the disadvantage that they require relatively expensive additional devices, such as spring arrangements, control arms or plate, and thus require a large amount of space. A receiving volume in the interior of a housing for receiving the breathing bag is thus not optimally utilized, since the space requirement of the additional devices in relation to the space required by the breathing bag is relatively large. This is particularly disadvantageous in mobile applications that require a housing with the lowest possible recording volume, such. B. in respiratory protective equipment of the fire department. Another disadvantage is that the breathing bag is relatively poorly protected on several outer sides against external influences and thus prone to damage due to external influences. Another disadvantage of such breathing bag that they are difficult to mount in a mobile respirator or removable from this due to the complicated shape.

In all the respiratory bags described above, the cleaning, disinfecting and drying is particularly difficult, in particular due to the twisted tubular shape or fold shape of the breathing bag inside a mobile respirator.

DISCLOSURE OF THE INVENTION

Based on this prior art, the invention has the object to provide a counter-lung for a breathing circuit protection device and a respirator with a counter-lung, which at least partially remedy the disadvantages described above. It is in particular the object of the present invention to provide a counter-lung for a breathing circuit protection device and thus a respiratory protective device, which are particularly easy to clean and at the same time robust and inexpensive to produce.

The above object is achieved by a counter-lung for a respiratory protective device with the features of claim 1 and by a respiratory protective device with the features of claim 10. Further features and details of the invention will become apparent from the dependent claims, the description and the drawings. In this case, features and details that are described in connection with the counter-lung according to the invention, of course, also in connection with the respiratory protective device according to the invention and in each case vice versa, so that with respect to the disclosure of the individual aspects of the invention always reciprocal reference is or may be.

According to a first aspect of the invention, the object is achieved by a counter lung for a breathing circuit protection device, comprising a container with a dimensionally stable container body and an opening in the container body, wherein in the container body an inlet opening to the inlet of the circulatory respirator CO ₂ -cleaned breathing air and an outlet opening to the outlet of the inhaled air back into the circulation of the respiratory protective device is present. The counterlung further comprises a gas-tight membrane which covers the opening of the container body gas-tight, wherein the membrane is formed so flexible that it is arched in an inhaled state into the interior of the container body and bulged out in an exhalation state from the interior of the container body, wherein In the exhalation CO ₂ -purified breathing air has flowed through the inlet opening into the interior of the container.

Such Gegenlunge is easy to clean and at the same time robust and inexpensive to produce. Due to the flexible membrane, the volume of the container of the counterlung is changeable. The membrane covers the opening of the container or the container body sealing. In an inhaled state, the membrane is arched into the interior of the container body and in an exhalation state, the membrane is arched out of the interior of the container body. The container is in particular formed in a hollow cylinder, one end face being closed and the opposite end face forming the opening. In another preferred development of the counterlung, the container may be cup-shaped. The simple, even coverage of the opening of the container body through the membrane a simple sealing line or sealing edge is obtained, act on the same everywhere sealing forces. This can reduce potential leaks. The counterlung or membrane does not require an arm or guide member to move the membrane between the inhaled and exhaled states. In the counterlung of this kind, a high volume can be achieved in the exhaled state, while at the same time a very compressed, small volume in the inhaled state can be achieved. The counterlung is simply constructed with few components.

The container body has an inlet opening and an outlet opening. The inlet opening and the outlet opening are provided in the wall, preferably in the lateral wall, of the container body. The inlet port is used for the intake of exhaled air, which has been previously cleaned of CO ₂ in the circulation of the respiratory protective device. To purify the exhaled air, preferably respiratory lime is used in the circulation of the respirator. The outlet opening in the container body is used to return the CO ₂ -purified breathing air back into the circulation of the respiratory protective device, in particular for re-inhalation by the user of the circuit respirator. In this case, the respiratory air contained in the container of the counterlung or the respiratory air which has flowed out of the container can additionally be enriched with oxygen.

The wall of the container body and the flexible membrane are gas-tight, so that breathing air can not escape through them. Furthermore, the membrane is arranged on the container body such that it covers the opening of the container body in a gastight manner.

Because the counter-lung has a dimensionally stable container body and only in the region of the opening of the container body has a flexible membrane, this can be easily cleaned. The membrane covers the opening, which only has contact with the container body with its edge. In the exhaled state, the membrane is curved outward, so that no contact of the membrane to the inner wall of the container body takes place except for the edge of the membrane. But even in the inhaled state, the membrane has no, at most only selectively with its center contact with the bottom of the container body. As a result, a bonding of a region of the membrane with another region of the membrane is completely excluded. Preferably, the membrane is clamped covering in the opening of the container body.

The counterlung can be easily cleaned due to its design. Just as easily it can be disinfected and dried. For this purpose, it is only necessary cleaning liquid, disinfectant or drying air through the inlet opening and / or the outlet opening in and out of the interior of the container. In this case, the cleaning, disinfecting and drying of the interior of the container can in particular be carried out easily in the expanded state of the counterlung, that is, when the counterlung is taken out of the circulation of the breathing apparatus.

The resulting in CO ₂ absorption in the cycle of the respiratory protective device water is distributed in such a Gegenlunge not uncontrolled in the container, but always runs due to its gravity in the direction of the lowest point of the container. This allows easy removal of water from the counterlung. Furthermore, it can be prevented that the air provided for inhalation is enriched with too much water. D. h., An unnecessarily high humidification of the air can be easily avoided by such Gegenlunge as a breathing bag in the form of a bellows or a flexible hose.

According to a preferred development of the invention may be provided in a counterlung that the membrane of synthetic rubber or synthetic polymer, in particular silicone, is formed. Particularly preferably, the membrane is formed of ethylene-propylene-diene rubber or has this for the most part. Such a membrane is on the one hand gas-tight, on the other hand, this can be easily cleaned. That is, a membrane formed of such materials can be easily cleaned without losing its properties through cleaning.

In an advantageous counterlung, it can be provided that the membrane is detachably fastened to the container body via latching and / or clamping elements, in particular in the region of the opening of the container body. Due to the simple solubility of the membrane of the container body, this can be particularly easily cleaned, disinfected and / or dried. That means for cleaning, Disinfecting and / or drying, the membrane can be easily detached from the container body, so that both the inside of the membrane, and the inner wall of the container body, which are in use in the respirator with moist breathing air in contact, are easily accessible. In particular, both the container body, as well as the membrane are suitable to be cleaned in a washing machine, so that a particularly simple and at the same time intensive cleaning, disinfecting and drying of the counterlung can be performed. Particularly advantageous is the possibility of the membrane on the outside of the container body. As a result, the attachment is facilitated.

In particular, a plurality of latching and / or clamping elements can be provided. These may be arranged, for example, on the container body and / or on the edge of the membrane. In particular, latching and / or clamping elements can be arranged on the outer wall of the container body. Ideally, the membrane and the latching and / or clamping elements are matched to one another in such a way that the edge of the membrane projects beyond the edge of the container body forming the opening and is sealingly fastened, in particular clamped, to the container body by means of the latching and / or clamping elements. The membrane can latching and / or clamping elements and on the container body can be arranged complementary counter-locking and / or clamping elements. Ideally, the locking and / or clamping elements tension the membrane over the opening of the container body.

The membrane is flexibly designed so that it depends on the breathing state of the user of a circulatory respirator, in which the counterlung is used, d. H. between inhalation and exhalation can be moved back and forth. In the inhalation state, the membrane is domed in the interior of the container body, bulging out of the interior of the container body in the exhalation state.

Particularly advantageous is a counterlung, in which the membrane is container-shaped, in particular bell-shaped or cup-shaped. Such a formed membrane is particularly suitable for the counterlung, since it can easily be moved back and forth between the inhalation state and the exhalation state. In other words, similar to a cap, such a membrane may be put on once "left" and once on "right", which corresponds to the exhalation state and the inhalation state or approximately the exhalation state and the inhalation state. The container-shaped, in particular bell-shaped or cup-shaped, design of the membrane ensures that the membrane in a transition from the exhaled state to the inhalation state or vice versa from a certain deformation automatically into the predetermined shape, d. H. the container shape, in particular the pot shape, jumps or rolls.

Further particularly preferred is a counterlung in which the membrane is thinner towards its center than at its edge. In particular, the membrane may advantageously be designed such that it has the smallest thickness in its center and, starting from the center towards the edge, becomes steadily thicker, in particular constantly steadily thicker. This makes it easier to make the transition from the inspiration state to the exhalation state and back.

According to a particularly advantageous development of the invention can be provided in a counterlung that the dimensionally stable container body having a first container body part and a second container body part, each container body part having an opening that the container body parts are fluid communicating with each other via a channel connected to each other that the gas-tight membrane Openings of the container body parts gas-tight covering or that two gas-tight membrane are provided, each membrane covering an opening gas-tight, that the inlet opening to the inlet of circulating respirator CO ₂ -purified breathing air in the first container body part and the outlet opening to the outlet of the recorded Breathing air is present back into the cycle of the respiratory protective device in the second container body part. The one membrane or the two membranes are advantageously made of synthetic rubber, in particular of ethylene-propylene-diene rubber, or synthetic polymer, in particular made of silicone. The membrane or both membranes are preferably releasably attached via latching and / or clamping elements on the container body, in particular in the region of the opening of the container body. When two diaphragms are provided, the first diaphragm is gas-tightly attached to the first reservoir body part and the second diaphragm is attached to the second reservoir body part. Such a trained counterlung is particularly advantageous because when used in a circuit of a breathing circuit breathing apparatus, the moisture in the exhaled breath settles mainly in the first container body part and collects there. This is because the inlet port to the inlet is arranged in the circulation of the respiratory protective device CO ₂ -purified breathing air in the first container body part. Since the outlet opening to the outlet of the inhaled breathing air is present back into the circuit of the circulatory respirator in the second container body part, the humidification of the inhaled air can be at least somewhat limited, since the humidity limited only by the channel, the first Container body part and the second container body part fluid communicates with each other, passes.

A further advantage of such a counterlung is that the membrane or the membrane parts can be made smaller than a large membrane in order to achieve the same container volume. As a result, the self-rolling behavior of the membrane, which occurs when the membrane turns from the inhaled state to the exhaled state and vice versa, can be intensified. Self-rolling behavior in the sense of the application means that the membrane, due to its thickness and material property, turns over into the respective end states of the membrane, ie. H. the inhalation state and the exhalation state, actively supported. In particular, there is no wrinkling of the membrane during the transition between the two breathing states.

Furthermore, in the case of a counterlung, it can advantageously be provided that the counterlung has at least one support bracket which spans the opening of the container body, in particular objecting to the opening, and that at least one spring element for exerting a spring force is seated on the membrane between the support bracket and the membrane , As a result, the inhalation process, i. H. the transition of the membrane from the exhalation state to the inhalation state, supported. The spring element, which may be in particular a spiral spring, such as a plate spring, a coil spring or a leaf spring, presses against the outside of the membrane. One side of the spring is supported on the support bracket, which is not yielding. The other side of the spring is supported on the outside of the membrane of the membrane. During the transition from the inhale state to the exhale state, the spring is biased against the direction of its spring force so that it can assist the reverse transition of the membrane due to its bias. Preferably, the spring element is at least on the support bracket positively and / or non-positively attached. The spring element can also be attached to the membrane, in particular detachably. For this purpose, for example, on the outside of the membrane, which faces the support bracket, a receptacle, in particular a pocket, a projection, etc., may be arranged. It can also be provided several support bracket. Ideally, the at least one support bracket extends across the center of a membrane. But it is also conceivable that a support bracket does not run over the center of a membrane. Decisive here are the design of the spring element and its arrangement on the support bracket. Ideally, the spring element is supported on the support bracket in such a way that the direction of the force passes through the center of the membrane. This allows a uniform everting of the membrane from the exhalation state to the inhalation state.

According to a further advantageous development of the invention may be provided in a counterlung that the opening of the container body or the openings of the container body parts is circular or oval is / are. According to the shape of the opening, the membrane may be formed. D. h., Is the opening of the container body or a container body part formed circular, and the membrane is advantageously formed circular. The same applies to an oval configuration of the opening. In particular, a circular configuration of the opening and of the membrane has the advantage that when the membrane is moved, it folds over or rolls over it in a defined manner.

According to a particularly advantageous further development of the invention, it may be provided in the case of a counterlung that it has a cooling device which is arranged at least in regions on the container body of the counterlung. As a result, heat can be withdrawn from the moist exhaled breathing air, so that the breathing air supplied to the user is cooler and thus more pleasant for the user. The cooling device is preferably in direct contact with the outer wall of the container body. Preferably, the cooling device covers the entire outer wall or at least large areas of the outer wall of the container body. This ensures effective cooling of the respiratory air within the container of the counterlung. As a cooling medium, the cooling device, for example, water, phase change material (PCM), or have similar coolant.

According to a second aspect of the invention, the object is achieved by a breathing apparatus comprising at least one counter-lung according to the first aspect of the invention, in particular that according to one of the preceding claims is formed. For the circuit respirator, the same advantages apply, in particular for the counterlung, as have already been explained in detail in a counterlung according to the first aspect of the invention. In particular, a circulatory respirator with such a counterlung can be cleaned particularly easily and inexpensively, disinfected and dried and thus quickly put back into the fully functional state. The counterlung may be located inside the circuit respirator, ie within a housing of the respiratory protective device. Alternatively, because of its robustness, the counterlung can also be arranged outside the circuit breathing apparatus. In such an embodiment of the breathing apparatus, the counter-lung is particularly accessible and can be due to your Design quickly and easily cleaned, disinfected and dried.

The circulatory respirator preferably also has a CO ₂ absorber for binding CO ₂ from the exhaled breath. The CO ₂ absorber preferably has a Atemkalkkanister. Furthermore, the circuit breathing apparatus preferably has an oxygen tank for O ₂ enrichment of the exhaled breath. Further, a hose system and a mouthpiece is provided, through which the breathing air is guided to and from the user. In the circuit of the breathing circuit breathing apparatus is followed by the mouthpiece of the CO ₂ absorber, then comes the counterlung, then the oxygen tank, before the circuit closes and returns to the mouthpiece.

PREFERRED EMBODIMENTS

Further, measures improving the invention will become apparent from the following description of some embodiments of the invention, which are illustrated in the figures. All of the claims, the description or the drawings resulting features and / or advantages, including structural details and spatial arrangements may be essential to the invention both for themselves, and in the various combinations. Each show schematically:

1 a sectional view through a counterlung for a respiratory protective device, wherein the counter lung is in the exhaled state,

2 a sectional view of the counterlung according to 1 wherein the counterlung is in the inhaled state,

3 a sectional view of the counterlung according to 1 wherein the counterlung additionally comprises a cooling device,

4 a sectional view of the counterlung according to 2 wherein the counterlung additionally comprises a cooling device, and

5 a frontal view of a circulatory respirator with a counterlung.

Elements with the same function and mode of action are in the 1 to 5 each provided with the same reference numerals.

In 1 is a schematic sectional view through a counterlung 1 for a circulatory respirator 100 shown, with the counterlung 1 in the exhaled state A is, in the CO ₂ -purified breathing air through the inlet opening 5 in the container body 3 in the interior of the container 2 has flowed. The container 2 indicates the container body 3 with an opening 4 on. A gas-tight membrane 7 covers the opening 4 of the container body 3 gastight, with the membrane 7 is designed so flexible that this in an inhaled state E in the interior of the container body 3 arched and bulged out in an exhalation state A from the interior of the container body §. In the inhaled state E, breathing air is through the outlet opening 6 from the inside of the container 2 flowed. About the inlet opening 5 and the outlet opening 6 can the counterlung 1 fluid communicating with the circuit leach of a respiratory protective device 100 get connected. Inhales a user of the respiratory protective device 100 out, the exhaled breath, after previous CO ₂ absorption, enters the counterlung 1 , where the membrane 7 from the inspiration state E to the exhalation state A. In other words, the interior of the container 2 or the container body 3 fills with humid CO ₂ -purged breathing air and the membrane bulges out from inside the container body 3 out.

The counterlung 1 according to the 1 and 2 has a special dimensionally stable container body 3 , This has a first container body part 3a and a second container body part 3b on that over a canal 18 fluid communicating with each other. The principle is the same as with just a single container body 3 , Here, each container body part 3a . 3b a separate opening 4 on. Each of the two openings 4 is with a membrane 7 gas-tight covered. In this counterlung 1 is the inlet opening 5 to the inlet of the circuit of the respiratory protective device 100 CO ₂ -purified breathing air in the first container body part 3a provided and the outlet opening 6 to the outlet of the inhaled air back into the circulation of the respiratory protective device 100 is located in the second container body part 3b , Exhaled air spreads over the canal 18 evenly in both container body parts 3a . 3b so that when exhaled A both membranes 7 bulge outwards and in inhalation E both membranes 7 arch inside.

As already stated, is in 2 schematically in a sectional view of the counterlung 1 according to 1 shown, with the counterlung 1 is now in the inhaled state E, in which the user has inhaled and thus the breathing air through the outlet opening 6 from the inside of the container 2 has flowed out. The negative pressure created during the inhalation process bulges the membrane 7 inside the container body 3 into it. In addition, the counterlung indicates 1 according to the 1 and 2 spring elements 10 and a support bracket 9 on. In each case a spring element 10 is between the support bracket 9 and one membrane each 7 arranged. In particular, the spring elements 10 on the support bracket 9 supported, particularly preferably attached. The support bracket 9 spans both openings 4 the container body parts 3a . 3b of the container body 3 and is objectionable to the openings 4 arranged. The spring elements 10 exert a spring force F on the diaphragm 7 out. At the transition of the membrane 7 from the inhaled state E to the exhaled state A, the spring elements 10 compressed against the direction of their spring force F. At the transition of the membrane 7 from the exhalation state A in the inhaled state E support the spring elements 10 due to its spring force F the movement of the diaphragm 7 into the interior of the container body parts 3a . 3b ,

The spring elements 10 be any kind of spring. In particular, they may be a spiral spring, such as a plate spring, a coil spring or a leaf spring. The support bracket 9 is dimensionally stable and preferably on the container 2 or the container body 3 attached so that he has a defined support for the spring elements 10 forms.

The membrane 7 are gas-tight. Furthermore, cover the membrane 7 the openings 4 the container body parts 3a . 3b gastight. These are the membranes 7 by means of locking and / or clamping elements 8th at the upper edge of the container body parts 3a . 3b , in particular detachable, attached. In the illustrated counterlung 1 are the membranes 7 bell-shaped or pot-shaped. This cup-shaped design of the membrane 7 facilitates the transition of the membrane 7 between the inhaled and exhaled states E, A. Moving from one state to another, the respective membrane rolls 7 partly independently back to their original shape, which is achieved when the membrane 7 have reached the inhalation state E or the exhalation state A.

The counterlung 1 according to the 1 and 2 is easy to clean and at the same time robust and inexpensive to produce. Due to the flexible membrane 7 is the volume of the container 2 the counterlung 1 easily changeable. The counterlung 1 is therefore easy to clean, especially to disinfect and to dry, because the membrane 7 from the container body 3 or the container body parts 3a . 3b can be easily solved. The release of the membrane 7 takes place by releasing the locking and / or clamping elements 8th , Are the membranes 7 from the container body 3 or the container body parts 3a . 3b solved, these can be cleaned separately from these. Advantageously, the membranes are 7 of synthetic rubber, in particular of ethylene-propylene-diene rubber, or of synthetic polymer, in particular of silicone. By using such materials, the membrane can 7 even be cleaned in a washing machine. At the same time are membranes 7 made of these materials very durable and permanently gas-tight.

In the 3 and 4 is the counterlung 1 according to the 1 and 2 shown again, in addition, a cooling device 11 for cooling the moist, warm air in the container 2 the counterlung 1 is provided. The cooling device 11 is over a mounting plate 19 is in contact with the outer wall of the container body 3 or the container body parts 3a . 3b , Through the cooling device 11 can effectively cool the breathing air inside the container 2 the counterlung 1 be enabled. As a cooling medium, the cooling device 11 For example, water, phase change material (PCM), or have similar coolant. The optional mounting plate 19 serves both to hold the counterlung 1 , as well as the cooling device 11 ,

5 schematically shows a respiratory protective device 100 which is a counterlung 1 having. The circulatory respirator 100 has a mouthpiece 15 on, through which a user breathing air from the respiratory protective device 100 inhale and release used breath. The path of breathing air through the respiratory protective device 100 is indicated by the arrows with the reference numerals 12 shown. That is, over the mouthpiece 15 and the entrance line 13 Exhaled breath enters the circulation circuit of the respirator 100 one. The exhaled breath is first passed through a CO ₂ absorber, which has soda lime, so that the exhaled breath is released as possible of CO ₂ . Subsequently, the CO ₂ -purified breathing air of the counterlung 1 fed. About the inlet opening of the container body part 3b the breathing air enters the container 2 , the counterlung 1 , Via the connection channel 18 the breathing air also enters the container body part 3a , The membrane 7 go into the exhalation A over. Much of the moisture of the breathing air remains in the first container body part 3b , As a result, the user better breathing air can be made available again for inhalation. Via the outlet opening in the container body part 3a the breathing air flows back into the circulation of the breathing apparatus 100 , Before inhaling the breathing air by the user of the respiratory protective device 100 can the breathing air with oxygen from the oxygen tank 17 be enriched. About the outlet line 14 The possibly enriched with oxygen breathing air is the mouthpiece 15 and thus supplied to the user.

A circulatory respirator 100 with such a counterlung 1 can be easily and inexpensively cleaned, disinfected and dried and thus quickly returned to the fully functional state. The counterlung 1 can be inside the circulatory respirator 100 or due to their robustness also outside the circulatory respirator 100 to be ordered. In such an embodiment of the breathing circuit protection device 100 is the counterlung 1 particularly accessible and can be quickly and easily cleaned, disinfected and dried due to its design.

LIST OF REFERENCE NUMBERS

1

counterlungs

2

container

3

container body

3a

first container body part

3b

second container body part

4

opening

5

inlet port

6

outlet

7

membrane

8th

Latching and / or clamping elements

9

support bracket

10

spring element

11

cooler

12

Flow direction respiratory air

13

Inlet line breathing air

14

Outlet line breathing air

15

mouthpiece

16

CO ₂ absorber

17

oxygen tank

18

channel

19

mounting plate

100

Closed-circuit breathing apparatus

A

Ausatemzustand

e

Einatemzustand

F

spring force

Claims (11)

Counterlung ( 1 ) for a circulatory respirator ( 100 ), comprising a container ( 2 ) with a dimensionally stable container body ( 3 ) and an opening ( 4 ) in the container body ( 3 ), wherein in the container body ( 3 ) an inlet opening ( 5 ) to the inlet of the circuit of the respiratory protective device ( 100 ) CO ₂ -purged breathing air and an outlet opening ( 6 ) to the outlet of the inhaled air back into the circulation of the respiratory protective device ( 100 ), comprising a gas-tight membrane ( 7 ), the opening ( 4 ) of the container body ( 3 ) covers gas-tight, wherein the membrane ( 7 ) is designed so flexible that it in an inhaled state (E) in the interior of the container body ( 3 ) and in an exhalation state (A) from the interior of the container body ( 3 ), wherein in the inhalation state (E) breathing air through the outlet opening ( 6 ) from inside the container ( 2 ) and in the exhalation state (A), CO ₂ -purified breathing air through the inlet opening (A) 5 ) in the interior of the container ( 2 ) has flowed. Counterlung ( 1 ) according to claim 1, characterized in that the membrane ( 7 ) is formed of synthetic rubber or synthetic polymer. Counterlung ( 1 ) according to claim 1 or 2, characterized in that the membrane ( 7 ) is formed of ethylene-propylene-diene rubber. Counterlung ( 1 ) according to one of the preceding claims, characterized in that the membrane ( 7 ) via latching and / or clamping elements ( 8th ) on the container body ( 3 ), in particular in the area of the opening ( 4 ) of the container body ( 3 ), is releasably attached. Counterlung ( 1 ) according to one of the preceding claims, characterized in that the membrane ( 7 ) container-shaped, in particular bell or cup-shaped, is formed. Counterlung ( 1 ) according to one of the preceding claims, characterized in that the membrane ( 7 ) is thinner toward its center than at its edge. Counterlung ( 1 ) according to one of the preceding claims, characterized in that the dimensionally stable container body ( 3 ) a first container body part ( 3a ) and a second container body part ( 3b ), each container body part ( 3a . 3b ) an opening ( 4 ), that the container body parts ( 3a . 3b ) over a channel ( 18 ) are connected in a fluid-communicating manner so that the gas-tight membrane ( 7 ) the openings ( 4 ) of the container body parts ( 3a . 3b ) gas-tight covering or that two gas-tight membrane ( 7 ) are provided, wherein in each case a membrane ( 7 ) an opening ( 4 ) gas-tight covering that the inlet opening ( 5 ) to the inlet of the circuit of the respiratory protective device ( 100 ) CO ₂ -purified breathing air in the first container body part ( 3a ) and the outlet opening ( 6 ) to the outlet of the inhaled air back into the circulation of the respiratory protective device ( 100 ) in the second container body part ( 3b ) is available. Counterlung ( 1 ) according to one of the preceding claims, characterized in that the counterlung ( 1 ) at least one support bracket ( 9 ) having the opening ( 4 ) of the container body ( 3 ), in particular concerning the opening ( 4 ), and that between the support bracket ( 9 ) and the membrane ( 7 ) at least one spring element ( 10 ) for exerting a spring force (F) on the membrane ( 7 ) sits. Counterlung ( 1 ) according to one of the preceding claims, characterized in that the opening ( 4 ) of the container body ( 3 ) or the openings ( 4 ) of the container body parts ( 3a . 3b ) is formed circular or oval is / are. Counterlung ( 1 ) according to one of the preceding claims, characterized in that it comprises a cooling device ( 11 ), which at least partially on the container body ( 3 ) is arranged. Circulatory respirator ( 100 ), comprising at least one counterlung ( 1 ) according to one of the preceding claims.

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