RESPIRATORY MASK

Abstract

Disclosed is a respiratory mask comprising a mask body and an articulated connection piece that can be connected to a respiratory tube. On the mask body, at least one exhalation gap is located in the vicinity of a connection that holds the articulated connection piece. Preferably, the exhalation gap terminates in an umbrella-shaped outflow channel that runs away from the patient. Preferably, at least two components of the respiratory mask are interconnected without play.

Claims

1. A respiratory mask, wherein the respiratory mask comprises flow openings which lead to exhalation gaps and are bounded by flow guide surfaces which cause a respiratory gas flow to converge and to be guided into the exhalation gaps, the respiratory gas flow moving along the flow guide surfaces from an inside of the respiratory mask to a surrounding environment, Wherein the exhalation gaps are separated from each other by spacing elements, and wherein the respiratory gas flow is deflected in an exhalation gap at least once on a flow guide surface.

2. The respiratory mask of claim 1, wherein the respiratory gas flow leaves an exhalation gap at an angle of 10-45° with respect to a plane which runs frontally to a face of a patient. The respiratory mask of claim 2, wherein the angle is 20-30°.

4. The respiratory mask of claim 2, wherein the angle is about 25°.

5. The respiratory mask of claim 1, wherein the respiratory gas flow is carried away in a substantially umbrella-shaped path.

6. The respiratory mask of claim 1, wherein the respiratory gas flow is guided into the exhalation gaps in a funnel-like fashion.

7. The respiratory mask of claim 1, wherein the flow guide surfaces in an upper region of the mask block the respiratory gas flow in a direction of a patient's eyes.

8. The respiratory mask of claim 1, wherein the respiratory gas flow is deflected only in an exhalation gap and/or an area of a transition of the mask body into the exhalation gap.

9. The respiratory mask of claim 1, wherein an exhalation gap is the narrowest point of the respiratory gas flow, which leaves the respiratory mask in a fan-shaped flow path along an outflow surface which extends the exhalation gap.

10. The respiratory mask of claim 1, wherein the exhalation gaps have an essentially rectangular cross-section and their longitudinal axes extend in a circumferential direction of an outflow surface.

11. The respiratory mask of claim 10, wherein the respiratory gas flow emerging from an exhalation gap is guided directly into an area of the outflow surface.

12. The respiratory mask of claim 1, wherein after leaving an exhalation gap, the respiratory gas flow is deflected on extended outflow surfaces and flows diffusely and quietly into the surrounding environment through an outflow channel defined by the outflow surfaces.

13. The respiratory mask of claim 1, wherein during passage through an exhalation gap along a flow guide surface the respiratory gas flow is deflected at an angle of 1-15° with respect to a vertical line which is at an angle of 90° with respect to a plane formed by parts of a mask body that bound the exhalation gap.

14. The respiratory mask of claim 13, wherein the respiratory gas flow is deflected at an angle of 2-7° with respect to the vertical line.

15. The respiratory mask of claim 13, wherein the respiratory gas flow is deflected at an angle of more than 2° with respect to the vertical line.

16. A respiratory mask, wherein the mask is an element of a complete ventilator and comprises a mask body and an articulated connector adapted to be connectable to a respiratory hose, wherein at least one exhalation gap is located in a vicinity of a transition between the articulated connector and a connection on the mask body that receives the articulated connector.

17. The respiratory mask of claim 16, wherein the at least one exhalation gap opens into an outflow channel bounded by outflow surfaces.

18. A respiratory mask, wherein the mask comprises a mask body and at least one outflow channel for respiratory gas in a vicinity of the mask body, wherein during its passage from an inside of the mask body through at least one exhalation gap to an outside environment along at least one flow guide surface, a respiratory gas flow is deflected at least once at an angle of more than 2° with respect to a vertical line which is at an angle of 90° with respect to a plane formed by parts of a mask body that bound the exhalation gap.

19. The respiratory mask of claim 18, wherein the angle of deflection is less than 7°.

20. The respiratory mask of claim 18, wherein the respiratory gas flow is guided in a funnel-like fashion from an inside of the mask body into the at least one exhalation gap.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] The invention is explained below with reference to the examples illustrated in the figures.

[0018] FIG. 1 shows a perspective view of a respiratory mask designed as a nasal mask.

[0019] FIG. 2 shows a view of the inside of the mask, as seen from the rear of FIG. 1.

[0020] FIG. 3 shows a view of the outside of the mask, as seen from the front of FIG. 1.

[0021] FIG. 4 shows a perspective view of the body of the mask in FIG. 1.

[0022] FIG. 5 shows a side view of the body of the mask.

[0023] FIG. 6 shows a cross section through the plane of symmetry of the body of the mask.

[0024] FIG. 7 shows a view of the retaining ring from the rear.

[0025] FIG. 8 shows a view of the retaining ring from the front.

[0026] FIG. 9 shows a perspective view of the retaining ring.

[0027] FIG. 10 shows a side view of the retaining ring.

[0028] FIG. 11 shows a cross-sectional view of the retaining ring from FIG. 10.

[0029] FIG. 12 shows a perspective view of the body of the mask.

[0030] FIG. 13 shows a partial view of an enlarged cross section through the body of the mask in the vicinity of the ball-and-socket joint.

[0031] FIG. 14 shows an enlarged view of the detail XIV in FIG. 13.

DETAILED DESCRIPTION OF THE INVENTION

[0032] FIG. 1 shows a respiratory mask that is designed as a nasal mask. The body 1 of the mask is made of a relatively strong material. The mask has a protruding edge 2, which rests against the face of a patient (not shown) and provides the necessary seal. An angled connector 3 connects the body 1 of the mask with a rotatably supported sleeve 4, which is used to attach a respiratory gas hose (not shown). To guarantee secure positioning of the respiratory mask on the patient's head, a forehead support 5 is used. The connector 3 and the mask body 1 are connected with each other by a ball-and-socket joint 18.

[0033] FIG. 2 shows the interior of the nasal mask from FIG. 1 in a direction of view from the inside towards a receptacle for the ball-and-socket joint 18, which is not shown in this drawing. Two pressure measurement connectors 9 are located in the upper area. Flow openings 7 lead to exhalation gaps 14 (not shown in this drawing). The flow openings 7 are bounded by flow guide structures 8, which are designed in such a way that they cause the respiratory gas flow to converge and to be guided into the exhalation gaps 14. The flow guide structures 8 are preferably designed in such a way that the respiratory gas flow is guided in funnel-like fashion into the exhalation gaps 14. The flow guide structures 8 in the upper region block the flow of respiratory gas in the direction of the patient's eyes. Inclined surfaces 6 are provided to facilitate the insertion of bayonet teeth 26 of a ball cage 24, which is not shown in this drawing.

[0034] FIG. 3 shows the view of the outside of the mask from FIG. 1, as seen from the front of the mask. An outflow surface 10 is formed as a ring. A retaining ring 31, which is not shown in this drawing, can be mounted and locked in place with the aid of ribs 11 and a catch 12.

[0035] FIG. 4 shows a perspective view of the body of the nasal mask. A centering ring 13 is provided for mounting the retaining ring. Exhalation gaps 14 are located on the sides of the centering ring 13 and open towards the outflow surface 10. The centering ring 13 has recesses 15 that act as a mechanical coding system to prevent incorrect mounting of the retaining ring.

[0036] FIG. 5 shows a side view of the body of the mask. The mask body 1, the centering ring 13, and the catch 12 are especially apparent in this view.

[0037] FIG. 6 shows a cross section through the body of the mask from FIG. 5. The respiratory gas flow 17 moves along the flow guide structure 8 and into the exhalation gap 14. The flow guide structure 8 is preferably designed in such a way that the respiratory gas flow is guided in funnel-like fashion into the exhalation gap 14. The exhalation gap is bounded by the flow guide surface 16. In the exhalation gap, the respiratory gas flow is deflected at least once on the flow guide surface 16. Deflection of the respiratory gas flow can take place only in the exhalation gap 14, only in the area of transition of the mask body 1 into the exhalation gap 14, or combined in both areas.

[0038] The respiratory gas flow moves from inside the respiratory mask to outside the mask along the flow guide surface 16. After leaving the exhalation gap 14, which is narrowest point, the respiratory gas flow leaves the respiratory mask in a fan-shaped flow path along the extended outflow surface 10. In this regard, the respiratory gas flow leaves the exhalation gap 14 at an angle alpha, which is preferably 10-45° to the vertical in FIG. 6. This vertical plane coincides with a plane that runs frontally to the face of a patient (not shown here).

[0039] FIG. 7 shows a top view of a retaining ring 31 from the rear. It has a width d of less than 7 mm, as indicated by a double arrow. Spacer ribs 25 allow the retaining ring 31 to be mounted on the mask body 1 in the vicinity of the outflow surface 10 without play and with pretension. In the assembled state, the exhalation gap 14 is bounded by outflow surfaces 28 on the retaining ring 31 and the outflow surface 10 on the body 1 of the mask. A tab 20 on the retaining ring 31 is the complement to the catch 12 on the body 1 of the mask, so that additional securing of the retaining ring 31 on the body 1 of the mask is ensured. A surface segment 19 that rests on the outflow surface 10 in the assembled state guarantees that no air can flow off in the direction of the patient's eyes. Slots 29 between the elements of the ball cage 24 allow easy assembly.

[0040] FIG. 8 shows a view of the retaining ring 31 from the front. The inner region of the retaining ring 31 is made of a hard material 23, and the outer region is made of a soft material 22. Nubs 21 improve the grip.

[0041] FIG. 9 shows the retaining ring 31 in a rear perspective view. This viewing direction reveals the receptacle 30 for the web of the centering ring 13.

[0042] FIG. 10 shows a side view of the retaining ring 31 and provides a view of the bayonet teeth 26.

[0043] FIG. 11 shows a cross-sectional view of the retaining ring 31 from FIG. 10.

[0044] The functions of the individual components illustrated in FIG. 9 to FIG. 11 will be explained again in detail later in connection with a description of the assembly and disassembly of the individual components for the specific purpose of further clarifying the mechanical significance and functionality of the individual components.

[0045] The perspective view in FIG. 12 again illustrates the mask body 1 after removal of the forehead support 5, which is not shown in FIG. 12. In the transition region between the outflow surface 10 and the centering ring 13, especially the location of the exhalation gap 14 is once again evident. The exhalation gaps 14 have essentially rectangular cross-sectional shapes, and their longitudinal axes extend in the circumferential direction of the outflow surface 10. The individual exhalation gaps 14 are separated from each other by spacing elements 32. The spacing elements 32 bring about a mechanical connection between the centering ring 13 and the other material of the body 1 of the mask.

[0046] The exhalation gaps 14 are preferably arranged in such a way that they extend in a region of the centering ring 13 that faces the outflow surface 10. In this way, the respiratory gas emerging from the exhalation gaps 14 is guided directly into the area of the outflow surface 10. After leaving the exhalation gaps 14, the respiratory gas flow is deflected on the wide and extended outflow surfaces 10, 28 and flows diffusely and quietly into the surrounding environment through the outflow channel defined by the outflow surfaces.

[0047] FIG. 13 shows an enlarged partial cross-sectional view in the area of transition between the ball-and-socket joint 18 and the retaining ring 31 held by the mask body 1. An arched course of the ball cage 24 is especially evident. The ball cage 24 extends concavely with a stronger curvature than a convexly shaped outer surface of the ball-and-socket joint 18. In this way, the ball-and-socket joint 18 is acted upon only along two guide lines, guide points 33, 34, or along linear segments of the ball cage 24. This makes it possible to compensate any production tolerances that may be present in the vicinity of the surfaces of the ball-and-socket joint 18 and/or the ball cage 24, since there is no surface guidance of the components on each other. Spring tensioning of the ball-and-socket joint 18 inside the ball cage 24 is preferably provided, so that secure support of the ball-and-socket joint 18 along the guide lines 33, 34 is guaranteed.

[0048] FIG. 14 shows an enlarged section of the passage of the respiratory gas flow through the exhalation gap 14 along the flow guide surface 16 to the surrounding environment see FIG. 6. The respiratory gas flow 17 enters the exhalation gap 14, for example, in funnel-like fashion. The exhalation gap is bounded by the flow guide surface 16. In the exhalation gap, the respiratory gas flow is deflected at least once on the flow guide surface 16. The respiratory gas flow is guided from the inside of the respiratory mask to the outside along the flow guide surface 16. During the passage of the respiratory gas flow through the exhalation gap 14 along the flow guide surface 16 to the surrounding environment, the respiratory gas flow is deflected at an angle beta (B), which is preferably arranged 1-15° to a vertical line 38. This vertical line stands essentially at an angle of 90° perpendicularly to the plane formed by the parts of the body of the mask that bound the exhalation gap. During the passage of the respiratory gas flow through the exhalation gap 14 along the flow guide surface 16 to the surrounding environment, it is especially preferred for the respiratory gas flow to be deflected at an angle beta (8) arranged 2-7° to a vertical line 38.

[0049] To provide further explanation of the function of the individual components, we shall now explain the assembly of the individual parts, starting from their unassembled state. This assembly can also be easily managed by the patient himself. In a first step, the mask body 1, which is made of the harder material, and the protruding edge 2 of the mask are fitted together. To this end, the protruding edge 2 of the mask has a U-shaped profile that is not evident in the drawings. This U-shaped profile is pushed onto an edge of the body 1 of the mask. In the area of the point of contact between the protruding edge of the mask and the body of the mask, there is at least one undercut and at least one projection complementary to the undercut. The undercut is preferably located in the area of the softer component. The interaction of the undercut and projection in the assembled state provides a secure connection.

[0050] In the next assembly step, for example, a shaft 35 of the forehead support 2 can be inserted in a mounting support 36 of the mask body 1 and secured by means of at least one fastening device 37. However, the assembly of the forehead support 5 can also be carried out at any other desired point of the assembly operation.

[0051] In another assembly step, the retaining ring 31 is pushed onto the connector 3, starting from the sleeve 4, and is positioned in the area of the ball-and-socket joint 18. As the retaining ring 31 is being pushed onto the connector 3, it has an orientation such that, after the placement operation has been completed, the bayonet teeth 26 point in the direction away from the sleeve 4, and the ball-and-socket joint 18 is partially enclosed by the ball cage 24 of the retaining ring 31.

[0052] In a final assembly step, the retaining ring 31 is positioned, together with the connector 3, in the vicinity of the centering ring 13 of the body 1 of the mask. Due to the asymmetrical arrangement of the ribs 11 along the periphery, as shown, for example, in FIG. 3, and the corresponding arrangement of the bayonet teeth 26, the bayonet teeth 26 can be inserted in the recesses 37 between the ribs 11 only in a single predetermined position. This creates a mechanical coding system.

[0053] After the bayonet teeth 26 have been inserted in the recesses 37 between the ribs 1 , the retaining ring 31 is twisted relative to the body 1 of the mask in such a way that the catch 12 is engaged. The catch 12 is preferably designed as a projection of the retaining ring 31 that engages a corresponding recess in the mask body 1. In principle, however, the device can also be constructed in the opposite way. Elastic engagement of the catch 12 is assisted if the retaining ring 31 is made of a relatively soft material, so that the likewise soft projection of the retaining ring 31 can be inserted in the recess of the mask body 1 and can also be twisted back out again.

[0054] After the retaining ring 31 has been twisted relative to the mask body 1, the assembly operation is complete. The final position of the retaining ring 31 is predetermined by a lateral stop of the bayonet teeth 26 on the ribs 11. In addition, the bayonet teeth 26 engage behind the ribs 11, so that the total unit is also able to withstand tensile loads.

[0055] The respiratory mask is disassembled in the reverse order of assembly described above.

[0056] As a result of the design of the retaining ring 31, it can be mounted on the mask body 1 without play and, if necessary, with pretensioning. Consequently, the width of the exhalation gap or gaps 14 now depends only on the tolerance of the height of the spacer ribs 25. The exhalation gap 14 is thus realized in a way that is extremely uniform and largely independent of tolerance. This in turn means that the discharge of the respiratory gas through the exhalation 14 is extremely constant and thus that the sound emissions produced by this discharge are likewise extremely constant.

[0057] The design of the retaining ring 31 allows the ball-and-socket joint 18 to be inserted in the elastic ball cage 24 of the retaining ring 31 and allows the ball cage 24 to enclose the ball-and-socket joint 18 at least partially. The ball-and-socket joint 18 is secured in the ball cage 24 by inserting the centering ring 13 in the receptacle 30 present in the retaining ring 31. As a result, the elastic elements of the ball cage 24 are bounded on one side by the ball-and-socket joint 18 and on the other side by the centering ring 13. In the assembled state, the ball-and-socket joint is secured in the area of the mask in this way. The mobility of the ball-and-socket joint, on the one hand, and the seal relative to the respiratory gas in the area between the ball-and-socket joint and the ball cage, on the other hand, are determined by the exact dimensioning and narrow tolerances.