SE516666C2 - Moisture heat exchanger for connecting to tracheal channel, contains bodies for distribuing oxygen over air inlet surfaces of moisture heat exchange bodies - Google Patents

Abstract

Oxygen distribution bodies (19-22) are used to distribute the incoming oxygen over a large part (preferably all) of the air inlet surface (17, 18) of the moisture heat exchange bodies (5, 6). The heat exchanger comprises moisture heat exchange bodies inside a casing (1-3) with parts (11-13) for connecting it to the tracheal channel. Each moisture heat exchange body has an inlet surface exposed to the air being inhaled. The casing is also provided with oxygen supply parts (14-16, 23) which have an inlet (23) for connecting to an oxygen line and also have an outlet communicating with each air inlet surface in the moisture heat exchange bodies.

Description

before the oxygen and is rapidly dried out. Even in this case, the consequence is that the mixture of air and oxygen supplied to the person is colder and drier than if oxygen had not been depleted. It is further known in the past to arrange with a special adapter the supply of oxygen to a moisture-heat exchanger which is not in itself provided with oxygen supply means. Such is described in a brochure sheet published by Gibeck in 1999 entitled "Trach-Vent (re- registered trademark) Starter Kit "and with printing identification number 7 010 710 - 9904. This known moisture-heat exchanger thus consists of a housing which houses two moisture-heat exchanger bodies but which is not provided with any oxygen supply means. The moisture-heat exchanger is in this basic design intended for use by a person who is not in need of oxygen enrichment of the inhaled air.

The brochure sheet also describes how an adapter can be connected to the humidity-heat exchanger housing when the person using the moisture-heat exchanger is in need of extra oxygen. The adapter is designed as a housing with a connection nipple for oxygen and provided with exhaust openings which when the adapter is mounted on the housing of the moisture heat exchanger will be located upstream of each moisture heat exchanger body seen in the inhalation direction. The exhaust openings are directed so that the oxygen will flow parallel to the inlet surface of each moisture-heat exchanger body. Thereby a spreading effect is achieved which means that a relatively large part of the respective moisture-heat exchanger body is used for heating and humidifying the oxygen gas. The disadvantages described above therefore do not occur to the same degree with this moisture-heat exchanger with associated adapter. The latter, however, has the disadvantage that an additional accessory must be used when oxygen is to be supplied to the inhaled air. This entails an extra cost and that it becomes more cumbersome to handle.

Disclosure of the Invention Against this background, the object of the present invention is to provide a moisture-heat exchanger with oxygen supply and which obviates the problems described above which adhere to conventional such moisture-heat exchangers.

This object has been achieved according to the invention in that a moisture-heat exchanger of the type specified in the preamble of claim 1 has the special features stated in the characterizing part of the claim. Thanks to the oxygen spreading means, oxygen will be distributed over all or at least most of the moisture-heat nano »10 15 20 25 30 516 666 3 exchanger body surface and together with the inhaled air effectively utilize moisture and heat stored in the body. This is because the dispersion prevents the moisture-heat exchanger body from being subjected to local drying, as is the case with conventional moisture-heat exchangers where the oxygen passes through the moisture-heat exchanger body when inhaled. Furthermore, the invented moisture-heat exchanger eliminates the need to provide a special to achieve a good distribution of the oxygen flow through the moisture-heat exchanger body.

According to a preferred embodiment of the invention, the outlet of the oxygen supply means is provided with at least one outlet opening which imparts to the oxygen a flow direction which forms an angle with a normal to the inlet surface of the moisture-heat exchanger body. This is a practical and simple way of ensuring that the oxygen will be exposed over a large part of the inlet surface as it flows over it. The outlet opening so arranged thereby constitutes the said oxygen spreading means.

It is then preferred that the direction of flow is substantially parallel to said inlet surface. This optimizes the said effect. By "substantially parallel" I is also included that the flow direction at certain parts of the inlet surface is not completely parallel to it, for example because the inlet surface is not flat. It is particularly advantageous in this case to design the outlet so that the oxygen spreading means consists of a plurality of such outlet openings. Thereby, the oxygen gas will coat the inlet surface from several different directions and thereby further increase the possibility of utilizing as large a part of the moisture-heat exchanger body as possible. This therefore constitutes another preferred embodiment of the invention.

According to a further preferred embodiment of the invented moisture-heat exchanger, the oxygen supply means comprises a distribution chamber associated with each moisture-heat exchanger body which communicates with the inlet and with each outlet opening. By arranging such a distribution chamber, it is achieved in a simple manner that the supplied oxygen gas can be passed on via the outlet in such a way that such a large part of the inlet surface is reached. This arrangement is particularly advantageous when the outlet comprises several different outlet openings, since the distribution chamber then effectively ensures that oxygen gas will be blown out through each of these.

According to a further preferred embodiment of the invention, the same is applied to such a type of moisture-heat exchanger which comprises two moisture-heat exchanger bodies. In this case, the inlet of the oxygen supply is connected to one of the moisture-heat exchangers' distribution chamber of the exchanger body. This is connected through duct means to the distribution chamber of the second moisture-heat exchanger body.

According to a further preferred embodiment of the invention, the housing of the moisture-heat exchanger is partly double-walled with a space between the walls. The gap is used as a distribution chamber and as channel means connecting these to each other. This embodiment provides a simple way of distributing the air to the inlet surface of each moisture-heat exchanger body.

According to another preferred embodiment of the invention, the housing is molded in plastic in a single piece. This achieves a very cost-effective manufacture of the same, where the assembly of the components in particular is facilitated.

According to a further preferred embodiment of the invention, the housing comprises a cylinder portion and two end portions, which are connected to the cylinder portion by means of a joint. Thus, the housing can be made in a single piece without making it difficult to assemble the components of the moisture-heat exchanger. When assembling, the end sections are initially folded up so that the ends of the cylinder section are completely open. Then a moisture-heat exchanger body can be inserted into each end without obstruction. When this has been done, the end portions are folded down over the ends of the cylinder portion by means of the joints so that the moisture-heat exchanger bodies are kept in place.

The above and other advantageous embodiments of the invented moisture-heat exchanger are stated in the claims dependent on claim 1.

The invention is explained in more detail by the following detailed description of preferred embodiments thereof and with reference to the accompanying drawings, the described embodiments being intended only as illustrative examples.

Brief description of the drawing Figure 1 is a perspective view of a diametrical section through a moisture-heat exchanger according to the invention. Figure 2 is a side view of the housing of the moisture-heat exchanger in Figure 1 before it has been assembled.

Figure 3 is an end view from the right of the house in Figure 2.

Figure 4 is a perspective view of the house in Figure 2.

Figure 5 is a diametrical section through an alternative embodiment of a moisture-heat exchanger according to the invention. Description of exemplary embodiments The perspective view of a moisture-heat exchanger according to the invention shown in Figure 1 is a diametrical section and thus represents half the moisture-heat exchanger.

The figure is slightly stylized to clarify the essentials of the function. The moisture-heat exchanger is symmetrical around the cut. It consists of a substantially cylindrical housing with a cylinder portion 1, a first end portion 2 and a second end portion 3. The housing forms a continuous circular cylindrical bore 4, in which a first 5 and a second 6 moisture-heat exchanger body are arranged. These are located close to each end of the house and at a distance from each other so that a space is formed between them in the center area of the house.

The lower part of the house has double walls 9, 10 arranged at a distance from each other. The double-walled part of the housing has a circumferential extent of about 120 ° of the circular-cylindrical bore. Between the walls, a space is formed that extends in the entire axial direction of the house. The outer wall 9 has an opening 11 and the inner wall an opening 12, which openings are perpendicular to the cylinder axis of the housing, are of the same diameter and located opposite each other. These openings 11, 12 are connected to each other by a circular wall 13. Through the circular wall, the space is partially blocked in the central part of the housing. However, the circumferential extent of the openings 11, 12 is smaller than the circumferential extent of the double-walled part of the housing so that the space is open on each side as the circular wall. The gap forms a first distribution chamber 14 and a second distribution chamber 15 adjacent each moisture-heat exchanger body. The part of the space which is located between them on both sides outside the circular wall 13, constitutes channel means 16, which connects the two distribution chambers 14, 15 to each other.

Each moisture-heat exchanger body 5, 6 has an outwardly facing inlet surface 17,18, which is substantially openly exposed to the environment. In the left end portion, four openings 19, 20 are provided in the inner wall 10 of the double-walled area. The openings 19, 20 are located immediately outside the adjacent moisture-heat exchanger body 5. Through these openings the distribution chamber 14 communicates with the space immediately in front of the inlet surface 17 of the moisture-heat exchanger body 5. Correspondingly, the right distribution chamber 15 communicates pine »10 15 20 25 516 666 6 via four openings 21, 22 with the space immediately in front of the inlet surface of the second moisture-heat exchanger body 6.

The left distribution chamber 14 is provided with a connecting pipe 23 for connection to an oxygen line. The connecting pipe 23, the distribution chambers 14, 15, and the duct means 16 constitute oxygen supply means where the connecting pipe 23 is inlet and the openings 19, 20, 21, 22 are outlets.

In use, the opening 11 is connected to a tracheal cannula connected to a person's respiratory tract. As the person exhales, exhaled air is forced up through the openings 11, 12, deflected and flows through each moisture-heat exchanger body 5, 6 out through its respective inlet surface 17, 18 to the surroundings. The exhaled air contains moisture and heat. Some of the moisture and heat are absorbed by the respective moisture-heat exchanger body 5, 6. When the person then inhales, inlet air is sucked in through the inlet surface 17, 18 of the respective moisture-heat exchanger body and out through the openings 11, 12 to the person's respirators. In this case, the inhaled air will absorb moisture and heat stored in the moisture-heat exchanger bodies since the previous exhalation.

The oxygen supply means are arranged so that oxygen is mixed into the inhaled air. In this case, oxygen is supplied continuously through the inlet 23 into the distribution chamber 14, which is thus filled with oxygen. The oxygen gas flows out through the openings 19, 20 in the inner path 10. These openings are radially directed and will cause the oxygen to flow close to the inlet surface 17 of the moisture-heat exchanger body 5. Each opening will generate a V-shaped oxygen jet which sweeps along the inlet surface 17 and forms a kind of oxygen curtain next to it. The oxygen will then be mixed with the air that is sucked in from the surroundings.

The air that has passed the moisture-heat exchanger body will thus be moistened, heated and oxygen-enriched when inhaled. The openings 19, 20 function as oxygen spreading means so that the oxygen is spread over practically the entire inlet surface 17 of the moisture-heat exchanger body. Thanks to the fact that the entire moisture-heat exchanger body is thus utilized for oxygen-enriched air, a very good oxygenation of the air is achieved.

A portion of the oxygen gas flowing into the distribution chamber 14 flows further through the duct member 16 to the second distribution chamber 15 at the right end of the figure. From there, the oxygen gas is passed on through the openings 21, 22 in a corresponding manner as described above. Arrows A, B, C and D mark the oxygen flow through the left moisture heat exchanger body and arrows A, E, F, G, H and L mark the oxygen flow through the right moisture heat exchanger body. In the embodiment shown, the moisture-heat exchanger is provided with an opening 24, located opposite the connection opening 11, 12. In the opening 24 a valve 25 is arranged. Through this, the supply of treatment fluid to the person can be administered and / or used for sucking a patient's respiratory organ.

Each moisture-heat exchanger body 5, 6 consists of folded paper which is rolled up into a cylinder and arranged concentrically with the housing. The pleated paper forms a large number of axial channels for the passage of the air and oxygen mixture.

Of course, other types of moisture-heat exchanger bodies can also be used, such as e.g. foam plastic.

Figures 2 and 3 show in more detail how the housing of the moisture-heat exchanger is constructed. Each end portion 2, 3 is attached to the cylinder portion 1 by means of a hinge joint 26, 27. The end portions 2, 3 and the cylinder portion 1 are made in one and the same piece and molded in plastic. Each joint consists of a short plastic tongue 26, 27 which is foldably forbidden with the respective end portion and with the cylinder portion. In the condition shown in Figures 2 and 3, the two moisture-heat exchanger bodies 5, 6 are mounted axially through the respective end opening of the cylinder portion 1 of the housing. A distance in from each end opening the housing has two stop rods 28, 29 which define how far - specific moisture-heat exchanger body can be inserted. The distance between the stop rods 28, 29 and the adjacent end opening corresponds approximately to the axial length of the respective moisture-heat exchanger body 5, 6 so that its inlet surface 17, 18 is located just inside the outer end of the cylinder portion 1.

After the moisture-heat exchanger bodies 5, 6 have been inserted, the end portions 2, 3 are folded down 180 ° by folding 90 ° around first each tongue 26, 27 connection with the cylinder portion 1 and then 90 ° around the connection of each tongue 26, 27 with respective end portion 2 3. In this case, the respective plastic tongue 26, 27 will be received by a recess 30, 31 on the outside of the end portion 1. Around each end opening, the cylinder portion 1 of the housing is provided with a circular flange 32, 33 which is enclosed by a corresponding flange 34, 35 of the respective end portion 2, 3. Each end portion 2, 3 is further provided with a hollow snap pin 36, 37 arranged to be snapped into a recess 38 l at the respective end of the cylinder portion 1 of the housing in order to keep the end portions 2, 3 in place. The connection for the inlet 23 is arranged in the middle of the snap pin 36 of the left end portion 2 in Figure 2. Each end portion 2, 3 has an opening 39 which occupies the greater part of the end portion so that the inlet surface 17, 18 of the inner moisture-heat exchanger body 2, 3 is freely exposed to ambient air. A diametrically arranged stop rod 40 prevents the moisture-heat exchanger body from coming loose indefinitely. In each end portion 2, 3 has an axially directed annular part 41 which abuts with its end surface against a corresponding end surface of the cylinder portion 1 of the housing. 21, 22. The annular part 41 thus forms a part of the inner wall 10.

Figure 3 further shows how the circular wall 13 connecting the openings 11, 12 to each other occupies a part of the space between the walls 9, 10 but leaves a free area on each side which constitutes the previously described channel member 16.

Figure 4 is a perspective view of the moisture-heat exchanger housing to illustrate its structure more clearly. A more detailed description of what the figure shows should, however, be superfluous as this appears from the descriptions of Figures 1-3, which is why reference is made here to these. Figure 5 schematically illustrates an alternative embodiment of the invented moisture-heat exchanger. In this embodiment, the moisture-heat exchanger body 15 is in the form of a hollow cylinder with inlet 17 for inhaled air on the outer surface of the cylinder.

The moisture-heat exchanger body in this example is preferably made of foam plastic. It is surrounded by a housing with two end portions 2, 3 and a cylindrical portion 1. The greater part of the cylinder portion is open to expose the inlet 17 of the moisture-heat exchanger body to ambient air. In the right end 3 of the figure, an opening 12 for connection to a tracheal cannula is arranged. The left end wall 2 is covering, but may be provided with a valve-like opening of a similar type as in the example in Figure 1, detail 24, 25.

The right end portion is double-walled and forms a cavity which constitutes a distribution chamber 14 for oxygen supplied through an inlet pipe 23. The distribution chamber is provided with a number of circumferentially distributed, axially directed outlet openings 21, 22, through which the oxygen gas can flow out.

Upon inhalation, the flow path of the air is as marked by the arrows B, D, E and the flow path of the oxygen as marked by the arrows A, C, D, E. In the embodiment where the air inlet upon inhalation is the outer surface of a cylindrical moisture-heat exchanger body, the openings through which the oxygen gas is distributed to the air inlet can alternatively be tangentially directed. i lip ..

Claims (11)

rinna 10 15 20 25 30 516 666 10 PATENTKRAV Regenerative moisture-heat exchanger provided with connecting means (11, 12, 13) for connection to a tracheal cannula, which moisture-heat exchanger comprises a housing (1, 2, 3) and at least one moisture-heat exchanger body (5, 6) arranged in the housing with an inlet surface (17, 18) through which air flows in during inhalation, which housing (1, 2, 3) is provided with oxygen supply means (23, 14, 15, 16) with inlet (23) for connection to an oxygen line and which oxygen supply means is connected to outlets (19, 20, 21, 22, 21a, 22a) communicating with each inlet moisture heat exchanger body (5, 6) inlet surface (17, 18), characterized by being integrated with the housing (1, 2, 3) arranged oxygen spreading means (19, 20, 21, 22, 21a, 22a) arranged to disperse from the oxygen supply means (23, 14, 15, 16) flowing oxygen over most of each moisture-heat exchanger body (5, 6) inlet surface (17, 18), preferably over substantially the entire inlet surface (17, 18) of the entire moisture-heat exchanger body (5, 6). Moisture-heat exchanger according to claim 1, characterized in that said outlet (19, 20, 21, 22, 21a, 22a) comprises at least one outlet opening (19, 20, 21, 22, 21a, 22a) so arranged that through the outlet opening ( 19, 20, 21, 22, 21a, 22a) flowing oxygen gas has a flow direction which forms an angle with a normal to the inlet surface (17, 18) of the moisture-heat exchanger body (5, 6), which outlet opening (19, 20, 21, 22, 21a, 22a) constitute said oxygen spreading means (19, 20, 21, 22, 21a, 22a). Moisture-heat exchanger according to claim 2, characterized in that said flow direction is substantially parallel to the inlet surface (17, 18) of the moisture-heat exchanger body (5, 6). Moisture-heat exchanger according to claim 3, characterized in that the outlet (19, 20, 21, 22, 21a, 22a) comprises a plurality of outlet openings> (19, 20, 21, 22, 21a, 22a), each outlet opening so arranged that through the same flowing oxygen gas has a flow direction which is substantially parallel to the inlet surface (17, 18) of the moisture-heat exchanger body (5, 6). Moisture heat exchanger according to one of Claims 1 to 4, characterized in that the oxygen supply means (23, 14, 15, 16) comprises a body (5, 5) for each moisture-heat exchanger body (5, 5). 6) assigned distribution chamber (14, 15) which communicates with the inlet (23) and with the at least one outlet opening (19, 20, 21, 22, 21a, 22a). Humidity-heat exchanger according to claim 5, characterized in that it comprises a first (5) and a second (6) moisture-heat exchanger body, the inlet (23) communicating directly with the distribution of the first moisture-heat exchanger body (5). chamber (14) and wherein channel means (16) connect the distribution chamber (14) of the first moisture-heat exchanger body (5) to the distribution chamber (15) of the second moisture-heat exchanger body (6). Humidity-heat exchanger according to claim 6, characterized in that a part of the housing (1, 2, 3) has double walls with a space between them, the space forming said distribution chambers (14, 15) and duct means (16) . Moisture-heat exchanger according to claim 6 or 7, characterized in that the housing (1, 2, 3) is substantially cylindrical, each moisture-heat exchanger body (5, 6) is substantially cylindrical and parallel to the housing, the inlet surfaces ( 17, 18) are perpendicular to the cylinder direction and away from each other, the moisture-heat exchanger bodies (5, 6) are arranged at a distance from each other and in that the connecting means (11, 12, 13) are arranged between the moisture-heat exchanger bodies (5, 6) . Moisture-heat exchanger according to one of Claims 1 to 8, characterized in that the housing (1, 2, 3) is molded in plastic in a single piece. Moisture-heat exchanger according to claim 9, characterized in that the housing comprises a cylinder portion (1) and two end portions (2, 3), each end portion (2, 3) being connected to the cylinder portion by means of a joint (26, 27) . Moisture-heat exchanger according to one of Claims 1 to 10, characterized in that each moisture-heat exchanger body (5, 6) comprises folded paper.