CN217187361U - Exhaust assembly, frame assembly, cushion assembly and patient interface device - Google Patents

Abstract

The utility model relates to an exhaust subassembly, frame subassembly, liner subassembly and patient interface device relates to the treatment of technical field breathing relevant disease for improve patient interface device and wear the comfort level. The patient interface device of the utility model, because the nose pad is adaptive to fit with the periphery of the nostril of the patient, only covers the nose of the patient, thereby the whole patient interface device is lighter, smaller and not prominent; the nasal pillow is fittingly attached to the periphery of the nostril of a patient to seal the nostril, so that the sensitive stressed part of the nose of the patient cannot be pressed; fix through bandeau and patient's head, can further improve its sealing stability, avoid sealed the destruction that receives external force.

Description

Exhaust assembly, frame assembly, cushion assembly and patient interface device

Technical Field

The present invention relates to the field of respiratory-related disorder therapy, and more particularly, to an exhaust assembly, a frame assembly, a cushion assembly, and a patient interface device.

Background

Respiratory related diseases are accompanied by a range of respiratory disorders, characterized by apneas, hypopneas and hyperpnoea. Examples of respiratory diseases include Obstructive Sleep Apnea (OSA), respiratory insufficiency, obesity, Chronic Obstructive Pulmonary Disease (COPD) and the like. Continuous Positive Airway Pressure (CPAP) therapy, Non-invasive ventilation (NIV) is commonly used to treat the above respiratory diseases. During treatment, a tube is not required to be inserted into the airway of a patient through a shell surgery, but a treatment device (such as a ventilator) is used to deliver continuous or variable pressure ventilation to the airway of the patient through a pipeline via a patient interface device (or called a mask) worn by the patient to assist the patient to perform part or all of the respiratory work to maintain a sufficient oxygen level in the body.

Existing patient interface devices (otherwise known as masks) are generally classified as full-face masks (as shown in fig. 29), nasal masks (as shown in fig. 30), or nasal pillow masks. The comfort level of full face mask is relatively poor, and relative nasal pillow face guard, it has small and exquisite light inadequately, can oppress the bridge of the nose, and the field of vision is not good, unfavorable to the patient who has claustrophobia and to the old patient of the rugged characteristics of face etc. sealed not good shortcoming. The nasal pillow of the nasal pillow mask can invade nostrils, and the air injection effect is generated when the nasal pillow is inflated, so that the nasal pillow has the defects of intolerance of pressure, and nostril acid swelling caused by long-time wearing. Nasal masks are therefore commonly used when the condition is not critical or when the mask is first worn for treatment in most patients with sleep apnea syndrome (OSA).

However, the conventional nasal mask cushion seals around the circumference of the nose of the patient and thus presses against the bridge of the nose of the patient, causing discomfort, and has poor stability of sealing with the nose of the patient, once damaged by external forces: if the patient turns over, the face wriggles with the mouth or the pipeline drags, the seal is easy to be damaged.

SUMMERY OF THE UTILITY MODEL

The utility model provides an exhaust subassembly, frame set spare, liner subassembly and patient interface device for solve above-mentioned technical problem.

According to a first aspect of the present invention, the present invention provides an exhaust assembly for placement on a patient interface device, comprising a main body, the main body comprising:

the air inlet pipe comprises a conical boss, wherein first exhaust holes are formed in the conical boss and are arrayed along the circumferential direction of the conical boss;

the conical boss comprises an inner wall, an outer wall and an inclined wall arranged between the inner wall and the outer wall, and the first exhaust hole is formed in the inclined wall;

the first vent vents gas from the patient interface device to an exterior of the patient interface device without changing a direction of gas flow.

In one embodiment, the inner hole diameter of the first exhaust hole is smaller or larger than the outer hole diameter of the first exhaust hole.

In one embodiment, the inner hole diameter of the first exhaust hole is larger than the outer hole diameter of the first exhaust hole, and the thickness of the inclined wall is 0.7mm to 2.0 mm.

In one embodiment, the inner hole diameter of the first exhaust hole is smaller than the outer hole diameter of the first exhaust hole, and the thickness of the inclined wall is 0.7mm to 1.5 mm.

In one embodiment, the first exhaust hole is oblong, rectangular or a structure formed by at least two straight lines which are relatively parallel and at least one arc line which directly connects the two straight lines.

In one embodiment, the first exhaust holes are arranged in a divergent manner, and the number of the first exhaust holes adjacent to each other is at most 2.

In one embodiment, the first exhaust hole is a circular hole.

In one embodiment, the first venting orifice is a tapered orifice.

According to the utility model discloses a second aspect, the utility model provides an exhaust assembly, be in including main part and setting first exhaust hole in the main part, first exhaust hole sets up and is being close to main part edge just is the type of dispersing and arranges, every the quantity of adjacent first exhaust hole around the first exhaust hole is at most 2.

In one embodiment, the body has an elliptical configuration.

In one embodiment, the body comprises a patient side and a patient-opposite side, the patient side being provided with a tapered boss, the first venting hole being provided on the tapered boss.

According to a third aspect of the present invention, the present invention provides a frame assembly for a patient interface device, comprising:

the air inlet pipeline is connected with one side of the frame main body, and the other side of the frame main body is connected with the liner assembly;

a pair of bone bridge arms including a first bone bridge arm and a second bone bridge arm oppositely disposed on the frame body; and

the connecting body is used for connecting the gasket assembly with the frame main body, the connecting body and the gasket assembly are sealed to form closed connection, a boss protruding from the inner side of the frame main body is arranged on the connecting body, a recess is formed between the boss and the inner wall of the frame main body and used for accommodating the gasket assembly, and the boss extends into the bottom of the gasket assembly;

the frame main body is provided with the exhaust assembly.

In one embodiment, the exhaust assembly is integrally molded with the frame body.

In one embodiment, the bone bridge arm is made of PP;

the bone bridge arm is integrally molded with the frame body.

According to a fourth aspect of the present invention, the utility model provides a frame set for patient interface device, include:

the frame comprises a frame main body, wherein one side of the frame main body is connected with an air inlet pipeline, the other side of the frame main body is connected with a gasket assembly, a third air outlet hole is formed in the gasket assembly, and a through hole corresponding to the third air outlet hole is formed in the frame main body;

a pair of bone bridge arms including a first bone bridge arm and a second bone bridge arm oppositely disposed on the frame body; and

the gasket assembly is connected with the frame main body through the connecting body, the connecting body and the gasket assembly are sealed to form closed connection, a boss protruding from the inner side of the frame main body is arranged on the connecting body, a recess is formed between the boss and the inner wall of the frame main body and used for accommodating the gasket assembly, and the boss extends into the bottom of the gasket assembly.

In one embodiment, the through holes are provided in pairs on the frame body and are symmetrically arranged with respect to a longitudinal center line of the frame body.

According to a fifth aspect of the present invention, the present invention provides a frame assembly for a patient interface device, comprising:

one side of the frame main body is connected with an air inlet pipeline, the other side of the frame main body is connected with a gasket assembly, and a second exhaust hole is formed in the air inlet pipeline;

a pair of bone bridge arms including a first bone bridge arm and a second bone bridge arm oppositely disposed on the frame body; and

the gasket assembly is connected with the frame main body through the connecting body, the connecting body and the gasket assembly are sealed to form closed connection, a boss protruding from the inner side of the frame main body is arranged on the connecting body, a recess is formed between the boss and the inner wall of the frame main body and used for accommodating the gasket assembly, and the boss extends into the bottom of the gasket assembly.

According to a sixth aspect of the present invention, there is provided a cushion assembly for a patient interface device, characterized in that the cushion assembly comprises a nasal cushion and an exhaust assembly as described above;

wherein the nasal cushion is configured such that when sealed against the base of a wearer's nose by pressurized gas, the nasal cushion is non-gripping against the patient's alar nose.

In one embodiment, the nasal cushion includes an upper side, a lower side opposite the upper side, and a circumferential side disposed between the upper side and the lower side, the circumferential side surrounding the upper side and the lower side to form a cavity; the upper side portion includes a face contact portion for contacting a face of a user;

the face contact part comprises a middle part and a first side part and a second side part which are positioned at two sides of the middle part, and the first side part and the second side part are connected with the circumferential side parts;

the intermediate portion includes a nasal opening in communication with the cavity and a peripheral seal surrounding the nasal opening, the nasal opening configured to surround an underside of a nostril of a user in response to the nasal cushion being donned by the user and to fittingly fit around the nostril of the user to seal with the peripheral seal.

According to a seventh aspect of the present invention, the utility model provides a patient interface device, include:

a cushion assembly including a nasal cushion for contacting a face of a patient, the nasal cushion being configured to fittingly conform about a nostril of the patient responsive to the patient interface device being donned by the patient, and the nasal cushion being configured such that it does not pass beyond a tip of the nose of the patient when sealed against a bottom of the nose of the wearer by pressurized gas;

the two sides of the frame component are respectively connected with the nasal cushion and the breather pipe in a sealing way; and

a headgear coupled to the frame, the headgear configured to be secured around a head of a patient in response to the patient interface device being donned by the patient.

In one embodiment, the liner assembly is a liner assembly as described above.

In one embodiment, an exhaust assembly as described above is also included.

In one embodiment, the frame assembly is a frame assembly as described above.

In one embodiment, the frame comprises a frame body and a conical boss arranged on the outer side of the frame body, the conical boss is provided with a connecting hole penetrating through the conical boss and the frame body, and two ends of the connecting hole are respectively connected with the nasal cushion and the breather pipe in a sealing manner.

In one embodiment, the frame includes a frame body and an elbow rotatably connected to the frame body, the elbow being sealingly connected to the vent tube.

In one embodiment, the frame is directly connected to an elbow connected to an air delivery conduit for connection to a pressure device,

the inner diameter of the air conveying pipeline is 15mm-22 mm.

In one embodiment, the frame is directly connected to a flexible hose connected to an air delivery conduit for connection to a pressure device; the inner diameter of the flexible hose is 12mm-15mm, and the inner diameter of the air conveying pipeline is 15mm-22 mm.

In one embodiment, the flexible hose is a tube having elasticity.

In one embodiment, the frame is provided with a connector, and the connector is rotatably connected with the flexible hose.

In one embodiment, the nasal cushion includes an upper side, a lower side opposite the upper side, and a circumferential side disposed between the upper side and the lower side, the circumferential side surrounding the upper side and the lower side to form a cavity; the cavity is communicated with the vent pipe.

In one embodiment, the frame is provided on its inside with a connecting body by means of which the nasal cushion is sealingly connected to the frame.

In one embodiment, the underside of the nasal cushion is provided with a base on which a bottom opening is provided;

the connector is configured as a boss projecting from an inner side of the frame, a recess is formed between the boss and an inner wall of the frame, the base of the nasal cushion is disposed in the recess, and the boss extends into the bottom opening.

In one embodiment, the patient interface device further includes first and second bone bridge arms disposed at respective ends of the frame, the first and second bone bridge arms extending over the ears along the cheeks of the wearer in response to the patient interface device being worn.

The headband includes a first side headband connected to the first bone beam arm, a second side headband connected to the second bone beam arm, and an upper headband and a rear headband disposed between the first side headband and the second side headband,

the upper headgear and the rear headgear are configured to be secured around a patient's hindbrain and a patient's crown, respectively, in response to the patient interface device being donned by the patient.

Compared with the prior art, the utility model has the advantages that the nasal cushion is adaptive to the periphery of the nostril of the patient and only covers the nose of the patient, so that the whole patient interface device is lighter, smaller and unobtrusive; the nasal pillow is fittingly attached to the periphery of the nostril of a patient to seal the nostril, so that the sensitive stressed part of the nose of the patient cannot be pressed; fix through bandeau and patient's head, can further improve its sealing stability, avoid sealed the destruction that receives external force.

Drawings

The present invention will be described in more detail hereinafter based on embodiments and with reference to the accompanying drawings.

FIG. 1 is a schematic perspective view (as viewed from the front side) of a nasal cushion according to example 1 of the present invention;

fig. 2 is a front view (as viewed from the front side) of the nasal cushion in embodiment 1 of the present invention;

fig. 3 is a top view (viewed from the upper side) of the nasal cushion according to example 1 of the present invention;

fig. 4 is a bottom view (as viewed from the lower side) of the nasal cushion in embodiment 1 of the present invention;

fig. 5 is a rear view (from the rear side) of the nasal cushion in embodiment 1 of the present invention;

fig. 6 is a schematic perspective view (as viewed from the left side) of the nasal cushion according to example 1 of the present invention;

FIG. 7 is a cross-sectional view at A-A of FIG. 3;

FIG. 8 is a cross-sectional view of FIG. 3 at B-B;

figure 9 is a cross-sectional view of a nasal cushion in example 2 of the present invention;

fig. 10 is a front view (as viewed from the front side) of the nasal cushion in example 3 and example 4 of the present invention;

fig. 11 is a schematic perspective view (from the left side) of the nasal cushion according to example 3 and example 4 of the present invention;

fig. 12 is a schematic perspective view (as viewed from the front side) of a nasal cushion according to example 5 of the present invention;

fig. 13 is a schematic perspective view (as viewed from the left side) of the nasal insert of example 5 of the present invention;

fig. 14 is a top view (as viewed from the upper side) of a nasal cushion in example 6 of the present invention;

fig. 15 is a front view (as viewed from the front side) of a nasal cushion in example 6 of the present invention;

fig. 16 is a schematic perspective view (as viewed from the front) of a nasal cushion according to example 6 of the present invention;

fig. 17 is a bottom view (as viewed from the lower side) of the nasal cushion in example 6 of the present invention;

fig. 18 is a bottom view (as viewed from the lower side) of the nasal cushion in example 7 of the present invention;

FIG. 19 is a schematic diagram of the basic structure of a human nose;

fig. 20a is a schematic perspective view of a patient interface device according to one embodiment of the present invention, wherein the patient interface device is worn by a patient, the first side headgear is closed, and the second side headgear is open;

FIG. 20b shows a perspective view of the frame and nasal cushion connection of FIG. 20 a;

FIG. 20c is a schematic illustration of the patient interface device of FIG. 20a as viewed from the right when worn by a patient;

FIG. 20d is a schematic illustration of the patient interface device of FIG. 20a when worn by a patient, with the nasal cushion unsealed;

FIG. 20e is a schematic diagram of the nasal cushion seal of FIG. 20a when the patient interface is donned by the patient, wherein the bold lines indicate that the peripheral seal expands and deforms in response to an increase in pressure within the cavity to conform closely about the patient's nares;

fig. 21 is a perspective view of the frame of the patient interface device shown in fig. 20 a;

fig. 22 is a front view of the frame of the patient interface device shown in fig. 20 a;

fig. 23 is a cross-sectional view of the frame of the patient interface device shown in fig. 20 a;

fig. 24a is a rear view of the frame of the patient interface device shown in fig. 20 a;

FIG. 24b is a cross-sectional view of the frame and nasal cushion connection shown in FIG. 20 a;

FIG. 24c is an enlarged view of FIG. 24b at I;

fig. 25 and 26 illustrate different arrangements of first venting holes in the frame of the patient interface device shown in fig. 20 a;

fig. 27a is a schematic perspective view of a patient interface device according to another embodiment of the present invention;

FIGS. 27b and 27c are schematic views of the headband shown in FIG. 27 a;

fig. 28 is a schematic perspective view of a patient interface device in accordance with yet another embodiment of the present invention;

fig. 29 and 30 show a wearing schematic of a prior art patient interface device.

Reference numerals:

100,200-nasal cushion;

110, 210-upper side; 111a, 211 a-face contact;

120, 220-lower side; 130, 230-front side; 140, 240-rear side; 150,250-cavity;

111,211-middle section; 112, 212-a first side; 113, 213-second side;

1111, 2111-nasal opening; 1112, 2112-surrounding seal;

121, 221-substrate; 122, 222-bottom opening; 123,223-sealing structure; 124-third vent hole;

131-a first groove means;

141-upper lip contact; 142-a support portion; 143-second groove means;

5-a patient interface device;

50-a frame; 501-a frame body; 502-a conical boss; 502 a-inner wall, 502 b-outer wall; 503-inclined wall; 52-connecting hole;

51-an exhaust section; 511-a first venting aperture;

53-first connection lug; 54-a second engaging lug; a 55-linker; 56-a recess;

60 a-a first trabecular arm; 60 b-a second trabecular arm; 61 a-a first stringing hole; 61 b-a second stringing hole; 62-a first bone beam arm connection; 63-a second bone beam arm connection;

70-a headband; 71 a-a first side headband; 71 b-a second side headband; 72-upper headband; 73-rear headband;

80-a breather pipe; 81-flexible hose; 82-a second connection end; 83-pipe connection head; 84-a first connection end;

90-bending a pipe; 91-second vent hole.

Detailed Description

The present invention will be further explained with reference to the accompanying drawings.

As shown in fig. 1-28, the present invention provides a patient interface device that includes a vent assembly (vent 51, described below), a cushion assembly (nasal cushions 100,200, described below), a frame assembly (frame 50, described below), a headgear assembly (headgear 70, described below), and a vent tube 80.

Wherein the frame 50 is sealingly connected on both sides to nasal cushions 100,200 and snorkel 80, respectively, through which snorkel 80 pressurized gas may be provided to a patient. Headgear 70 is coupled to frame 50, headgear 70 being configured to be secured about the patient's head in response to patient interface device 5 being donned by the patient. Exhaust 51 is provided on frame 50 or nasal cushions 100,200 for communicating the patient interface 5 side facing the patient with the ambient to exhaust the flow of exhaled air from the patient.

Each component will be described in detail below.

The nasal cushions 100,200 of the present invention will first be described in detail. Nasal cushions 100,200 are for contacting the face of a patient and are configured to fittingly conform around the nostrils of the patient in response to patient interface device 5 being donned by the patient. And the nasal cushion 100,200 is configured such that when sealed against the bottom of a wearer's nose by pressurized gas, the nasal cushion 100,200 has no clamping effect against both sides of the patient's nasal ala.

As described above, nasal cushions 100,200 are adapted to fit to frame 50 of patient interface 5 and to be placed on the face of a patient to provide pressurized gas to the patient for ventilation therapy, and nasal cushions 100,200 of the present invention are described in various embodiments below.

Example 1

As shown in fig. 4-11, the nasal cushion 100 of the present embodiment includes an upper side portion 110, a lower side portion 120 opposite the upper side portion 110, and a circumferential side portion disposed between the upper side portion 110 and the lower side portion 120, the circumferential side portion surrounding the upper side portion 110 and the lower side portion 120 to form a cavity 150, the cavity 150 forming an air bladder chamber when pressurized air is provided to a patient.

The upper side portion 110 includes a face contacting portion 111a for contacting the face of the patient. Specifically, the face contact portion 111a includes a middle portion 111 and first and second side portions 112 and 113 located on both sides of the middle portion 111, and the first and second side portions 112 and 113 are each connected to a circumferential side portion. It will be appreciated that the first and second side portions 112, 113 may be of the same or similar construction, or the first and second side portions 112, 113 may be symmetrically disposed about the middle portion 111 for ease of manufacture.

The middle portion 111 includes a nose opening 1111 in communication with the cavity 150 and a peripheral seal portion 1112 surrounding the nose opening 1111. Wherein the nasal opening 1111 is configured to surround the underside of the patient's nostril in response to the nasal cushion 100 being donned by the patient and to fittingly conform around the patient's nostril for sealing by the peripheral seal 1112.

Therefore the utility model discloses a nasal cushion 100 seals through the downside with patient's nostril and around the nostril, and it can reduce patient interface device's volume on the whole, makes it small and exquisite lightly and not prominent to also do not have the nasal pillow that inserts the patient, make its travelling comfort further improve.

Further, when pressurized gas is provided to the patient, the cavity 150 has a certain pressure inside (e.g., 4-25hpa), and thus the peripheral seal 1112 is able to expand and deform in response to an increase in pressure within the cavity 150, thereby conforming closely to the vicinity of the patient's nares. The nasal cushion 100 of the present invention thus conforms to the circumference of the patient's nares through the expansion of the peripheral seal 1112, thereby eliminating the need for individual patient nasal differences in design and manufacture. The ease of deformation of the membrane ensures that the peripheral seal 1112 fits snugly around the patient's nares, even though the individual patient's nose may vary, thereby improving the sealing and connection stability of the nasal cushion 100 in contact with the patient's face.

Alternatively, peripheral seal 1112 is recessed toward lower side portion 120, such that when peripheral seal 1112 is inflated by pressure within cavity 150, peripheral seal 1112 will lie in approximately the same plane as first and second side portions 112 and 113 (as shown in phantom in FIG. 7, where peripheral seal 1112 is inflated), thereby ensuring that face contacting portion 111a (intermediate portion 111) rests flat against the bottom of the patient's nose without wrapping around the patient's alar N2. Therefore, based on the utility model discloses a sealed stable connection is not realized through centre gripping patient's alar both sides to nasal cushion 100, but makes it closely laminate around patient's nostril N1 through the inflation deformation of sealing 1112 on every side, consequently the utility model discloses a do not need strict adaptation between nasal cushion 100 and patient's nasal part width (the distance between the alar of both sides, as shown in fig. 19) to the crowd that multiplicable nasal cushion 100 can adapt to improves its crowd suitability. In addition, the absence of the nasal cushion 100 gripping the patient's nose may also reduce its contact area with the patient's nose, thereby further increasing comfort.

Preferably, the distance L between the outside of the peripheral seal 1112 and the center of the nasal opening 1111 is no greater than the septum to nose tip height of the patient's nose (as shown in FIG. 19). That is, when the patient wears the nasal cushion 100, the outermost edge of the peripheral seal portion 1112 does not exceed the tip of the nose of the patient, and thus does not press the tip of the nose of the patient to cause discomfort, and also can be reduced in volume.

Further alternatively, the peripheral seal portion 1112 may not be recessed, but may be directly on the same plane as the first and second side portions 112 and 113, i.e., the face contacting portion 111a may be configured as a planar structure, which enables the expansion sealing function of the peripheral seal portion 1112 to be more pronounced.

In addition, the nose opening 1111 may be at least one hole, for example, 1 hole, 2 holes or a plurality of holes may be provided, and may be selectively provided according to the requirement.

The circumferential side portion includes a rear side portion 140, a front side portion 130 disposed opposite to the rear side portion 140, and left and right side portions between the rear side portion 140 and the front side portion 130. Wherein the rear side portion 140, the front side portion 130, the left side portion and the right side portion may be integrally constructed.

The rear lateral portion 140 is configured to face the lips of the patient in response to the nasal cushion 100 being donned by the patient, the rear lateral portion 140 including an upper lip contact portion 141 that contacts the upper lip of the patient and a support portion 142 that connects the upper lip contact portion 141 with the lower lateral portion 120.

The thickness d1 of the first side portion 112, the thickness d2 of the second side portion 113, the thickness d3 of the surrounding sealing portion 1112, the thickness d4 of the supporting portion 142, and the thickness d5 of the upper lip contact portion 141 satisfy the following defined formula:

d1 ═ d2, and d5 ═ d3 ≦ d1 ≦ d 4.

That is, the thickness of the first side portion 112 is the same as the thickness of the second side portion 113, and is greater than the thickness of the surrounding sealing portion 1112. For example, the thickness d1 of the first side portion 112 and the thickness d2 of the second side portion 113 may each be 0.6-1.5mm, and preferably may be 0.8-1.2 mm. The thickness d3 of the peripheral seal portion 1112 may be 0.3-0.8mm, and preferably may be 0.3-0.5mm, so in this embodiment the thickness of the peripheral seal portion 1112 is the smallest in the region of the membrane.

Because the first and second side portions 112, 113 contact the patient's face before the peripheral seal 1112 when the nasal cushion 100 is worn, the first and second side portions 112, 113 are important support points for the face when worn and are stressed more than the peripheral seal 1112; and the first side portion 112 and the second side portion 113 are positioned on both sides of the patient's nasal wings, so that the patient's force feeling at the corresponding positions of the first side portion 112 and the second side portion 113 is not obvious compared with the surrounding sealing portion 1112, and therefore, the thickness of the first side portion 112 and the second side portion 113 is set to be larger than that of the surrounding sealing portion 1112, so that the rigidity of the two is stronger than that of the surrounding sealing portion 1112, thereby effectively distributing the pressure of wearing the nasal cushion 100 on the face to increase the wearing comfort.

The support portion 142 may extend in the circumferential direction, and may form a part of the rear side portion 140, the left side portion, and the right side portion, for example. The support portion 142 needs to maintain the overall shape of the cavity 150 so that it retains its shape without collapsing when worn at low pressures and when the nasal cushion 100 is under pressure. The thickness d4 of the support 142 is thus the thickest, for example, 0.9-2.0mm, preferably 0.9-1.5mm, to ensure a certain rigidity.

The upper lip contact portion 141 corresponds to the area of the patient's face that is sensitive to the force, and therefore the thickness d5 can be the same as the thickness d3 of the peripheral seal portion 1112, and therefore the upper lip contact portion 141 is also a thin film area in this embodiment. So as to ensure that the oppression force of the upper lip of the patient is small enough when the patient wears the mask, and the wearing comfort can be improved.

The front side 130 and the back side 140 may or may not both have channel means provided thereon, or may have channel means provided thereon.

For example, in the present embodiment, the front side 130 is provided with a first groove means 131 recessed towards the rear side 140. The first channel means 131 is configured as a channel having two opposing inner walls with an acute included angle α 1 (which may be, for example, 20 ° to 70 °), and the thickness of the first channel means 131 may be 0.5 to 1.4 mm. Therefore, under the action of low pressure, when the pressure expansion of the surrounding sealing portion 1112 is not significant and cannot effectively fit the nose of the patient, the first channel mechanism 131 can provide a certain elastic support for the position near the nose of the patient, thereby increasing the sealing force. Meanwhile, by compressing the first groove mechanism 131 (even if the included angle α 1 thereof is reduced), it is possible to adapt compressibility to different nasolabial angles of different persons, so that it is possible to adapt to a more suitable wearing state.

The lower portion 120 includes a base 121, the base 121 having a bottom opening 122 disposed therein that communicates with the cavity, the bottom opening 122 having a sealing structure disposed therein for sealingly attaching the base 121 to the frame of the patient interface device.

The bottom opening 122 may be triangular, circular, or oval. The base 121 is sealingly and non-rotatably connected to the frame of the patient interface device by a sealing structure therein. The sealing structure may be a protrusion on the inner wall of the bottom opening 122 that seals by forming an interference fit with the frame.

Alternatively, the sealing structure may be a plastic part or a higher hardness silicone rubber, which is elastically deformed to achieve a sealing connection with the frame.

The nasal cushion 100 is preferably made of silicone rubber, but may also be made of foam, thermoplastic elastomer, resin, or textile materials.

Example 2

On the basis of the above embodiment 1, the present invention also provides a modified embodiment, i.e., embodiment 2, as shown in fig. 12. Differences from embodiment 1 described above will be mainly described below.

The present embodiment is different from embodiment 1 in that the thickness d1 of the first side portion 112 is the same as the thickness d2 of the second side portion 113, and is equal to the thickness d3 of the peripheral sealing portion 1112, i.e., d1 ═ d2 ═ d 3. The thicknesses of the three parts may be, for example, 0.3 to 0.8mm, so that the whole face contact part 111a may be formed as an air bag as a whole, thereby reducing the stress of the whole face contact part 111a and enhancing the wearing comfort. The nasal cushion 100 of the present embodiment is therefore able to more strongly conform to the facial features of some people with facial abnormalities.

In this embodiment, similar to embodiment 1, the thickness d4 of the supporting portion 142 can be still thicker, for example, d4 ≧ d 3. For example, d4 may be 0.9-2.0mm, preferably 0.9-1.5mm, to ensure a certain rigidity.

The same features and configuration of this embodiment as those of embodiment 1 will not be described again.

Example 3

On the basis of the above embodiment 1, the present invention also provides a modified embodiment, i.e., embodiment 3, as shown in fig. 13 and 14. Differences from embodiment 1 described above will be mainly described below.

This embodiment is different from embodiment 1 described above in that, in addition to the first groove means 131 recessed toward the rear side portion 140 being provided on the front side portion 130, the second groove means 143 recessed toward the front side portion 130 is provided on the support portion 142. The second channel means 143 may also be configured as a groove having two opposing inner walls with an acute included angle α 2 (which may be 20 ° to 70 °, for example), and the thickness of the second channel means 143 may be 0.5 to 1.4 mm. The groove provides some resilient support to the patient near the upper lip, increasing the sealing force, when the peripheral seal 1112 is not significantly expanded under pressure to effectively conform to the patient's nasal features; meanwhile, by compressing the first groove mechanism 131 (even if the included angle α 1 thereof is reduced) and the second groove mechanism 143 (even if the included angle α 2 thereof is reduced), the nose and lip angles of different people can be adapted in compressibility, so that the wearing state can be adjusted to be more suitable.

Example 4

On the basis of the above embodiment 2, the present invention also provides a modified embodiment, embodiment 4, as shown in fig. 13 and 14. Differences from embodiment 2 described above will be mainly described below.

This embodiment is different from embodiment 2 described above in that, in addition to the first groove means 131 recessed toward the rear side portion 140 being provided on the front side portion 130, the second groove means 143 recessed toward the front side portion 130 is provided on the support portion 142. The second channel means 143 may also be configured as a groove having two opposing inner walls with an acute included angle α 2 (which may be 20 ° to 70 °, for example), and the thickness of the second channel means 143 may be 0.5 to 1.4 mm. The groove provides some resilient support to the patient near the upper lip while the peripheral seal 1112 is not significantly expanded under pressure to effectively conform to the patient's nasal features, thereby increasing the sealing force; meanwhile, by compressing the first groove mechanism 131 (even if the included angle α 1 thereof is reduced) and the second groove mechanism 143 (even if the included angle α 2 thereof is reduced), the nose and lip angles of different people can be adapted in compressibility, so that the wearing state can be adjusted to be more suitable.

Example 5

On the basis of the above embodiments 1 and 2, the present invention also provides a modified embodiment, embodiment 5, as shown in fig. 15 and 16. Differences from the above-described embodiments 1 and 2 will be mainly described below.

The present embodiment differs from embodiments 1 and 2 described above in that the first channel mechanism 131 on the front side portion 130 is eliminated. I.e. in this embodiment neither the front side 130 nor the back side 140 is provided with a groove means, and optionally the thickness of the front side 130 may be 0.3 to 0.8mm, i.e. the thickness of the front side 130 is the same as the thickness of the surrounding seal 1112, and all is a thin film area.

Optionally, a portion of the front side 130 has a thickness that is the same as the thickness of the perimeter seal 1112, and may be, for example, 0.3 to 0.8 mm. And the thickness of another portion of the front side portion 130 is the same as that of the supporting portion 142, and may be, for example, 0.9 to 2.0mm, and preferably 0.9 to 1.5mm, to ensure a certain rigidity.

Example 6

As shown in fig. 17-20, the nasal cushion 200 of the present embodiment includes an upper side 210, a lower side 220 opposite the upper side 210, and a circumferential side disposed between the upper side 210 and the lower side 220, the circumferential side surrounding the upper side 210 and the lower side 220 to form a cavity, the cavity 250 forming a bladder chamber when pressurized gas is provided to a patient. Further, the upper side portion 210 includes a face contacting portion for contacting the face of the patient.

The face contact portion 211a includes a middle portion 211 and first and second side portions 212 and 213 located at both sides of the middle portion 211, and the first and second side portions 212 and 213 are connected to circumferential side portions. It will be appreciated that the first and second side portions 212, 213 may be of the same or similar construction, or the first and second side portions 212, 213 may be symmetrically disposed about the middle portion 211 for ease of manufacture.

Wherein the middle portion 211 includes a nasal opening 2111 in communication with the cavity 250 and a peripheral seal portion 2112 surrounding the nasal opening 2111, the nasal opening 2111 configured to surround the underside of a patient's nostril in response to the nasal cushion 200 being donned by the patient, and to fittingly fit around the patient's nostril for sealing by the peripheral seal portion 2112.

Consequently the utility model discloses a nasal cushion 200 seals through the downside with patient's nostril and around the nostril, and it can reduce patient interface device's volume on the whole, makes it small and exquisite lightly and not prominent to do not set up the nose pillow that inserts the patient, make its travelling comfort further improve.

Further, when pressurized gas is provided to the patient, the cavity 150 has a pressure inside (e.g., a pressure of 4-25hpa), and thus the peripheral seal 2112 is able to deform to conform around the patient's nares in response to an increase in pressure within the cavity 250. The nasal cushion 200 of the present invention thus conforms to the circumference of the patient's nares through the expansion of the peripheral seal 2112, thereby eliminating the need for individual patient nasal differences in design and manufacture. Thus, even if there are differences in the individual noses of the patient, the peripheral seal 2112 will be able to conform snugly around the patient's nares due to the flexible nature of the membrane, thereby improving the sealing and connection stability of the nasal cushion 200 in contact with the patient's face.

Optionally, the peripheral seal portion 2112 is recessed toward the inferior portion 220, so when the peripheral seal portion 2112 is inflated by pressure in the cavity 250, the peripheral seal portion 2112 will be in approximately the same plane as the first and second side portions 212, 213 (as shown in phantom, where the peripheral seal portion 2112 is inflated), thereby ensuring that the face-contacting portion 211a (intermediate portion 211) rests flat against the bottom of the patient's nose without wrapping around the patient's alar. Therefore, based on the utility model discloses a nasal cushion 200 does not realize sealed stable connection through centre gripping patient's alar both sides, but makes its and patient's nostril closely laminate on every side through the inflation deformation of sealing portion 2112 on every side, consequently the utility model discloses a do not need strict adaptation between nasal cushion 200 and patient's nasal part width (distance W between the alar of both sides) to the crowd that multiplicable nasal cushion 200 can adapt to improves its crowd suitability. In addition, the absence of the nasal cushion 200 gripping the patient's nose may also reduce its contact area with the patient's nose, thereby further increasing comfort.

Preferably, the distance L between the outside of the peripheral seal 2112 and the center of the nasal aperture 2111 is no greater than the septum-to-tip height of the patient's nose. That is, when the patient wears the nasal cushion 200, the outermost edge of the peripheral seal portion 2112 does not exceed the tip of the nose of the patient, and therefore does not press the tip of the nose of the patient to cause discomfort, and the volume thereof can be reduced.

Further alternatively, the peripheral seal portion 2112 may not be recessed, but may be directly on the same plane as the first side portion 212 and the second side portion 213, i.e., the face-contacting portion 211a may be configured as a planar structure, which makes the expansion sealing function of the peripheral seal portion 2112 more pronounced.

Further, the nose opening 2111 can be at least one hole, for example, 1 hole, 2 holes, or a plurality of holes can be provided, optionally as desired.

The circumferential side portion includes a rear side portion 240, a front side portion 230 disposed opposite to the rear side portion 240, and a left side portion 260 and a right side portion 270 between the rear side portion 240 and the front side portion 230. The important difference between this embodiment and the above-described embodiments 1-5 is that the peripheral seal portion 2112 in this embodiment extends forward to the front side portion 230 and rearward to the rear side portion 240, respectively, and the junctions between the peripheral seal portion 2112 and the front and rear side portions 230 and 240 are continuously curved surfaces, or the junctions thereof may be offset from each other.

Preferably, the peripheral seal portion 2112 extends forwardly to the front side portion 230, rearwardly to the rear side portion 240, respectively, and is formed integrally with the front side portion 230 and the rear side portion 240, i.e., a middle portion, so that the middle portion has a uniform thickness. I.e., the thickness d3 of the peripheral seal portion 2112 is the same as the thickness of the front and rear side portions 230, 240. For example, d3 may be 0.3 to 0.9mm, preferably 0.3-0.5mm, i.e. the middle portion is the membrane region (the region shown in dashed lines).

It is understood that the thickness d5 of the corresponding upper lip contact portion and the thickness d4 of the supporting portion on the rear side portion 240 are the same, and the same as the thickness d3 of the surrounding sealing portion 2112, i.e., d3 ═ d4 ═ d 5.

Further, the first side portion 212 extends to the left side portion 260, the second side portion 213 extends to the right side portion 270, and the connection positions between the first side portion 212 and the left side portion 260 and the connection positions between the second side portion 213 and the right side portion 270 are continuous curved surfaces, or the connection positions may be mutually displaced.

Preferably, the first side portion 212 extends to be integral with the left side portion 260 and the second side portion 213 extends to be integral with the right side portion 270, i.e., a peripheral portion having a uniform thickness. Therefore, the thickness d1 of the first side portion 212 is the same as the thickness of the left side portion 260 and the thickness d2 of the second side portion 213 is the same as the thickness of the right side portion 270, so that the whole formed body has a uniform thickness, which is greater than the thickness d3 of the surrounding seal portion 2112, i.e., d1 ≧ d 3. For example, d1 and d2 may each be 0.6 to 1.5mm, preferably 0.8 to 1.2 mm.

That is, in the present embodiment, the rigidity of the peripheral portions (the left side portion 260, the right side portion 270, the first side portion 212, and the second side portion 213) is greater than the rigidity of the intermediate portions (the peripheral seal portion 2112, the front side portion 230, and the rear side portion 240). This is because the peripheral portion is an important support point on the patient's face when the nasal cushion 200 is worn, and is more stressed than the middle portion corresponding to the patient's nose, and the peripheral portion is closer to the patient's cheek muscles, so the patient's stress is less felt, and thus the rigidity thereof is set to be greater than that of the middle portion, which can effectively distribute the pressure of the facial wear cushion, increasing the wearing comfort.

The lower side 220 includes a base 221, the base 221 having a bottom opening 222 disposed therein that communicates with the cavity, the bottom opening 222 having a sealing structure disposed therein for sealingly attaching the nasal cushion 200 to a frame of the patient interface.

The bottom opening 222 may be triangular, circular, or oval. The base 221 can be sealingly and non-rotatably connected with the frame of the patient interface device by a sealing structure therein. The sealing structure may be a protrusion on the inner wall of the bottom opening 222 that seals by forming an interference fit with the frame.

Alternatively, the sealing structure may be a plastic part or a higher hardness silicone rubber, which is elastically deformed to achieve a sealing connection with the frame.

The nasal cushion 200 is preferably made of silicone rubber, but may also be made of foam, thermoplastic elastomer, resin, or textile materials.

Example 7

On the basis of the above embodiments, the present invention also provides a modified embodiment, i.e., embodiment 7, as shown in fig. 18. The present embodiment is different from the previous embodiments in that the substrate 121,221 is provided with the exhaust part 51, i.e., the third exhaust part.

Wherein, the third exhaust part may be a third exhaust hole 124 disposed at both sides of the bottom opening 122. The setting mode and the size of third exhaust hole 124 can set up as required, the utility model discloses do not prescribe a limit to this.

It should be noted that, in the present embodiment, the air discharging portion 51 is provided on the nasal cushions 100, 200; in contrast, in the above embodiments 1 to 6, since the air release part 51 is not provided on the nasal cushions 100,200, the air release part 51 is provided on the frame 50, as described below.

The frame 50 and vent 51 of the present invention are described in detail below, and it will be understood that the frame 50 and vent 51 described below will be able to be combined with any of the nasal cushions 100,200 of embodiments 1-7 described above.

For example, referring to fig. 24a, a connector 55 may be provided on the inside of the frame 50, and the nasal cushions 100,200 may be sealingly connected to the frame 50 via the connector 55. The connector body 55 seals with the nasal cushions 100,200 to form a closed connection. The connecting body 55 may be made integral with the frame 50, for example by gluing, snapping or the like. In particular, the connecting body 55 is configured as a boss projecting from the inside of the frame 50, the boss forming a pocket 56 with the inner wall of the frame 50, the base 121,122 of the nasal cushion 100,200 being disposed in the pocket 56, the boss extending into the bottom opening 122, 222.

Further, referring to FIGS. 24b, 24c, 8 and 17, the outer wall of the connecting body 55 is provided with a sealing ring 551 which cooperates with the sealing structures 123,223 in the bottom openings 122,222 to sealingly connect the nasal cushions 100,200 to the frame 50.

It will be appreciated that the connecting body 55 may be configured as a structure that conforms to the shape of the bottom opening 122, 222.

In a preferred mode, as shown in fig. 21, the frame 50 includes a frame body 501 and a tapered boss 502 provided outside the frame body 501, and the tapered boss 502 is configured to be tapered in a direction away from the frame body 501, that is, an end of the tapered boss 502 away from the frame body 501 is smaller than an end close to the frame body 501, so that a side wall of the tapered boss 502 is formed as an inclined wall. Alternatively, the tapered boss 502 is constructed as a solid structure.

Further optionally, as shown in fig. 21, the tapered boss 502 includes an inner wall 502a, an outer wall 502b, and a sloped wall 502c disposed between the inner wall 502a and the outer wall 502 b. In this alternative embodiment, the thickness of the sloped wall 502c is 0.5mm to 2.0mm, preferably 0.9mm to 1.2 mm. It should be noted that the inclined wall 502c may have a uniform thickness or a non-uniform thickness. When the inclined wall 502c has a non-uniform thickness, the thickness of the inclined wall 502c means that the average thickness of the inclined wall 502c is 0.5mm to 2.0 mm. Preferably, the inclined wall 502c has an average thickness of 0.9mm to 1.2 mm.

Alternatively, it is understood that the distance between the inner wall 502a and the outer wall 502b is 0.5mm to 2.0mm, preferably 0.9mm to 1.2 mm. It is understood that when the inner wall 502a and the outer wall 502b are non-parallel structures, the distance between the inner wall 502a and the outer wall 502b refers to the average distance between the inner wall 502a and the outer wall 502 b.

Since the frame 50 is intended to be worn to the face of a patient, the frame 50 may include a patient side and a patient-opposing side, with the tapered boss 502 being disposed on the patient side.

Further, the conical boss 502 is provided with a through hole (connecting hole 52) penetrating through the conical boss 502 and the frame main 501, and the connecting hole 52 is respectively communicated with the nasal cushions 100 and 200 and the breather tube 80 in a sealing way. The coupling hole 52 may be provided at the center of the tapered boss 502 and symmetrically with respect to the longitudinal center line of the frame body 501.

Referring to the embodiment shown in fig. 21-23, the vent assembly is integrally molded with the frame 50, and thus it will be appreciated that the vent assembly includes a main body including the tapered boss 502 described above and a vent portion 51 disposed on the tapered boss 502. The exhaust part 51 includes a first exhaust part disposed on the inclined wall 502c of the tapered boss 502, and the first exhaust part includes a plurality of first exhaust holes 511 disposed along the circumferential direction of the connection hole 52. Since the first exhaust holes 511 are provided on the inclined wall of the tapered boss 502, the air flow discharged from the first exhaust holes 511 diverges in the radial direction (X direction) of the tapered boss 502 when viewed in the radial direction of the tapered boss 502; and when viewed from the axial direction (Y direction) of the tapered boss 502, the gas flow discharged from the first gas discharge holes 511 diverges in the axial direction of the tapered boss 502, so that the resultant direction of the gas flows discharged from the first gas discharge holes 511 is in the direction (Z direction) perpendicular to the axial direction of the tapered boss 502 and the radial direction of the tapered boss 502.

In some alternative embodiments, the inner hole diameter of the first venting hole 511 is smaller than its outer hole diameter; in these embodiments, the thickness of the sloped wall 502c is 0.7mm to 1.5 mm. As described above, the thickness of the sloped wall 502c may or may not be uniform. When the inclined wall 502c has a non-uniform thickness, the thickness of the inclined wall 502c means that the average thickness of the inclined wall 502c is 0.7mm to 1.5 mm.

In other alternative embodiments, the inner bore diameter of the first venting hole 511 is larger than its outer bore diameter; in these embodiments, the sloped wall 502c has a thickness of 0.7mm to 2.0 mm. As described above, the thickness of the sloped wall 502c may or may not be uniform. When the inclined wall 502c has a non-uniform thickness, the thickness of the inclined wall 502c means that the average thickness of the inclined wall 502c is 0.7mm to 2.0 mm.

Preferably, the first exhaust hole 511 may be configured as a tapered hole having an area gradually increasing in a direction from the inside to the outside of the tapered boss 502. The first exhaust hole 511 arranged in the mode is beneficial to better diffusion of airflow, the airflow can be quickly attenuated after flowing out of the first exhaust hole 511, the impact energy of the airflow is lower, and the patient bed partner cannot be disturbed; and mutual interference between the first exhaust holes 511 is not easily generated, so that noise can be further reduced in use.

Alternatively, the first exhaust hole 511 may also be configured as a tapered hole having an area gradually decreasing in a direction from the inside to the outside of the tapered boss 502.

Further, the first vent holes 511 are formed by die molding, specifically, by punch-through molding in the upper and lower directions, as viewed in the axial direction (Y direction) of the tapered boss 502. Compare among the prior art need be through multiple line position when the side direction trompil, perhaps through the mode that later stage laser beam drilling formed, the utility model discloses the mode technology formability that forms first exhaust hole 511 is better, the cost is lower, and can guarantee the quality in hole to the noise is lower when using.

The first venting holes 511 may also be elongated, oblong (as shown in fig. 21), circular, or oval. The radial cross section of the first exhaust hole 511 may also be configured as a special-shaped hole (e.g., a structure of at least two straight lines that are relatively parallel and at least one arc line that connects two straight lines).

The first exhaust holes 511 may be arranged in an array along a direction in which the diameter of the tapered boss 502 decreases, that is, the first exhaust holes 511 are arranged according to a certain rule in the direction. For example, the plurality of first exhaust holes 511 may be uniformly distributed on a concentric circle concentric with the connection hole 52, or the plurality of first exhaust holes 511 may be distributed on a certain ellipse. Or some of the plurality of first exhaust holes 511 are distributed on one ellipse and others are distributed on another ellipse concentric with the ellipse.

Referring to the embodiment shown in fig. 21, 24b and 26, the body of the exhaust assembly is of an oval configuration. Wherein, the first exhaust holes 511 are arranged near the edge of the conical boss 502 and in a divergent arrangement, and the number of the adjacent exhaust holes around each first exhaust hole 511 is at most 2. In other words, the first exhaust holes 511 are distributed in a single row in the geometric extension direction of the conical projection 502 (for example, the axial direction of the conical projection 502), so that the first exhaust holes 511 only have two adjacent exhaust holes at most.

Referring to the embodiment shown in fig. 25, the first discharge holes 511 may also be provided only at both sides of the connection hole 52, wherein the number of adjacent discharge holes around the first discharge hole 511 may be 3 or more.

It will be appreciated that when the elbow 90 is not provided on the frame 50 as described in the embodiments above, the patient interface device 5 as a whole can be made smaller and lighter, and drag from the large tubing to which the pressure device is connected can be overcome by the flexibility of the flexible hose 81. In these embodiments, the exhaust portion 51 is a first exhaust hole 511 provided on the frame body 501, or the exhaust portion 51 is a third exhaust hole 123 provided on the lower side of the nasal cushions 100, 200.

In each of the embodiments described below, the exhaust portion 51 (second exhaust hole 91) is provided in the elbow pipe 90 rotatably connected to the frame main body 501.

Specifically, as shown in fig. 27, the frame 50 includes a frame main body 501 and an elbow pipe 90 rotatably connected to the frame main body 501, a connection hole 52 penetrating through the frame main body 501 in the thickness direction is provided at the center of the frame main body 501, and the elbow pipe 90 is connected to the connection hole 52 and the vent pipe 80, respectively. By arranging the elbow 90, the ventilation pipe 80 and the frame main body 501 can rotate relatively, so that the ventilation pipe is convenient to adapt to various states of patients.

In one embodiment, the vent section 51 includes a second vent section disposed on a sidewall of the elbow 90. And the second exhaust portion may also be configured as a plurality of second exhaust holes 91, and specifically, a concave portion that is concave inward is provided on the side wall of the bent pipe 90, and the second exhaust holes 91 are collectively provided on the concave portion.

When the elbow 90 is provided on the frame 50, the elbow 90 can be pivotally connected to the second connection end 82, thereby making it more flexible to use. In these embodiments, the venting portion 51 is a second vent hole 91 provided on the elbow 90, or the venting portion 51 is a third vent hole 123 provided on the lower side of the nasal cushion 100, 200.

In a further alternative, as shown in fig. 21, the frame 50 includes a frame main body 501, a connection hole 52 is formed through the frame main body 501 at a central position in a thickness direction thereof, and the air pipe 80 is directly connected to the connection hole 52. In this embodiment, the venting portion 51 may be provided on the lower side portion 120,220 of the nasal cushion 100,200, as configured in the above-described embodiment 7; or the vent hole 51 is constructed as described in the other embodiments above.

The vent tube 80 is constructed as a flexible hose 81 which may have an internal diameter of 15-18mm, with a preferred internal diameter of 15 mm. Specifically, the flexible hose 81 includes a first connection end 84 connected to the connection hole 52. The flexible hose 81 further comprises a second connection end 82, which may be made of a rigid material (e.g. a thermoplastic such as PP, PC, etc.). The second connection 82 is rotatably connected to a pipe connection 83, which pipe connection 83 is connected to the pressure device via an air supply line. The air delivery conduit may have an internal diameter of 15mm to 22mm and a length of 1000mm to 2000 mm. The flexible hose 80 is advantageous in that, because it is more flexible than the air delivery conduit, drag forces generated by the air delivery conduit as the body moves can be overcome, thereby maintaining a stable seal of the mask system against the user's face.

Through the rotation between second link 82 and pipe connection head 83, can adapt to patient's different postures. The headband 90 of the present invention is described in detail below, and it will be appreciated that the headband 90 described below will be capable of being combined with each of the preferred or alternative frames 50 described above and any of the nasal cushions 100,200 described in embodiments 1-6 above.

Referring to fig. 20a, 20b, 20c, 20d and 20e, the frame 500 includes a frame main body 501 and first and second coupling lugs 53 and 54 provided at both ends of the frame main body 501. Wherein, the first connecting lug 53 is connected with a first bone bridge arm 60a, and the second connecting lug 54 is connected with a second bone bridge arm 60 b. When worn, the first engaging lug 53 extends from the left side of the frame body 501 to the headband 70 in the left-over direction along the patient's cheek, and the second engaging lug 54 extends from the right side of the frame body 501 to the headband 70 in the right-over direction along the patient's cheek.

It will be appreciated that the frame body 501 may be formed from the same material as the first and second bone beam arms 60a, 60b by a single unitary injection molding, i.e., one-piece molding. Alternatively, the frame body 501 and the first and second bone beam arms 60a and 60b may be connected by other means, such as by chemical bonding or mechanical means, using different materials.

Preferably, the frame body 501 is made of PC, and the first and second bone beam arms 60a and 60b are both made of PP. In addition, the frame body 501 may be made of other thermoplastic materials such as PP and ABS, and the first bone bridge arm 60a and the second bone bridge arm 60b may be made of other thermoplastic materials such as PC and ABS.

The first and second bone bridge arms 60a and 60b are more flexible than the frame body 501, and the thickness of the body portions of the first and second bone bridge arms 60a and 60b may be 0.6-1.8mm, preferably 0.9-1.1 mm. By this embodiment, the first and second bone arms 60a, 60b are more conformable to conform to different cheek regions of a patient, provide stable support, and cooperate with the headgear 70 to stably secure the nasal cushions 100,200 to the patient's face.

Headgear 70 includes a first side headgear 71a connected to first bone beam arm 60a, a second side headgear 71b connected to second bone beam arm 60b, and an upper headgear 72 and a rear headgear 73 disposed between first side headgear 71a and second side headgear 71b, upper headgear 72 and rear headgear 73 configured to be secured around a patient's hindbrain and a patient's crown, respectively, in response to patient interface device 5 being donned by the patient.

When worn, the first side head strap 71a extends from the first bone rail arm 60a in a direction above the patient's left ear and the second side head strap 71b extends from the second bone rail arm 60b in a direction rearward above the patient's right ear.

Specifically, the end portions of the first and second bone beam arms 60a and 60b are respectively provided with a first and second rope threading hole 61a and 61b, the end portions of the first and second side head straps 71a and 71b are respectively provided with a sticky buckle portion, and the first and second side head straps 71a and 71b are respectively attached to or buckled on the outer portions of the first and second side head straps 71a and 71b by being respectively passed through the first and second rope threading holes 61a and 61b to be turned and folded back, so that the first side head strap 71a is connected with the first bone beam arm 60a, and the second side head strap 71b is connected with the second bone beam arm 60 b. The pulling force of the first and second side straps 71a, 71b can be adjusted by adjusting the location of the snap or fit to accommodate different patient heads, e.g., the size of the patient's head can be selected to be closer to the first and second bone bridge arms 60a, 60b, and vice versa.

As shown in fig. 27a, 27b, 27c, and 20c, the extending directions of the first and second side head straps 71a and 71b are respectively aligned with the extending direction of the corresponding side of the rear head strap 73. Thus enabling a greater range of adjustability of headband 70. Specifically, a first end of the first side headband 71a is provided with a first adjustment structure 711, and a first end of the second side headband 71b is provided with a second adjustment structure 712; the first and second adjustment structures 711 and 712 are used to adjust the used length of the first and second side straps 71a and 71b, respectively, to adjust the tightening force of the user interface device.

Taking the first adjustment structure 711 and the second adjustment structure 712 as magic tapes, as shown in fig. 27b and 27c, the first adjustment structure 711 and the second adjustment structure 712 pass through the corresponding connecting holes 60 of the main body 100 and then are folded and attached to the outer side surfaces of the first side head band 71a and the second side head band 71b, so that the first side head band 71a forms a first reverse folding portion 713, and the second side head band 71b forms a second reverse folding portion 714. Since the adjustment of the first and second side head bands 71a and 71b plays a major role in wearing the user interface device, the length of the first and second side head bands 71a and 71b can be adjusted by the length of the both in use by being folded back, thereby adjusting the binding force of the user interface device.

As described above, since the extending directions of the first and second side headband 71a and 71b are substantially in line with the extending directions of both sides of the rear headband 73, respectively, the first and second side headband 71a and 71b have a larger adjustment range D1 than the conventional easy-to-use headband, i.e., the adjustment range of the first and second side headband 71a and 71b is D1+ D2 (as shown in fig. 27b and 20 c). In other words, the rear headband 73 also becomes the part of adjustment. Thus allowing the headband 70 to adjust much better than conventional Y-shaped headband.

Further, the value range of D1 is 70mm-150mm, preferably 85mm-120 mm. It will be appreciated that the adjustment range D1 is the distance from the first side headband 71a to where the upper headband 72 and the rear headband 73 are connected as described below, or the distance from the second side headband 71b to where the upper headband 72 and the rear headband 73 are connected as described below. In other words, the distance is measured in the extending direction of the first side headband 71a or the second side headband 71 b.

It will be appreciated that the first and second adjustment structures 711, 712 may also be other connection structures such as snaps, magnets, snaps, and clasps.

Wherein, the width W of the first side head belt 71a is 12mm-16 mm; the second headband 71b has a width W of 12mm-16 mm. The "width" is a dimension in a direction perpendicular to the extending direction of the first side headband 71a or the second side headband 71b, as shown in fig. 27 b. Too wide or too narrow a width may cause discomfort to the wearer, for example too narrow a width may cause local strangulation to the face and head of the user, while too wide a width may cover too much skin of the user. The first and second side head bands 71a and 71b within the above-described width range can improve the wearing comfort of the user while ensuring that the user interface device is tightly fixed to the face of the user.

Optionally, a third adjustment structure is provided on the rear head band 73 for adjusting the length of use thereof. The third adjustment structure may be similar to the first adjustment structure 711 and the second adjustment structure 712, such as a hook and loop fastener, a buckle, a magnet, a snap fastener, or other connecting structures, so as to further adjust the usable length of the headband 70.

The length of the rear head band 73 is 200mm-260mm, and the rear head band 73 within the length range can meet the head circumference size requirements of most people.

The headband 70 of the present invention further comprises an upper headband 72, wherein two ends of the upper headband 72 are respectively connected to two sides of a rear headband 73, as shown in fig. 27 b; the included angle alpha between the upper head band 72 and the rear head band 73 is 30-150 degrees; preferably 75-85 deg., so that the rear and upper headbands 73, 72 can be securely attached to the user's head.

In an alternative embodiment, shown in figures 27c and 20c, the upper headband 72 comprises a first end band 721 and a second end band 722, the first end band 721 extending from the intersection of the second end of the first side headband 71a and one of the sides of the rear headband 73 to the second end band 722, the second end band 722 extending from the intersection of the second end of the second side headband 71b and the other side of the rear headband 73 to the first end band 721; wherein the first end band 721 and the second end band 722 are connected by a fourth adjusting structure 723. Since the upper headband 72 may also serve as an auxiliary adjustment, a fourth adjustment structure 723 is provided to adjust its use length.

The fourth adjustment structure 723 includes a connection element disposed on one of the first end band 721 and the second end band 722 and a mating element disposed on the other of the first end band 721 and the second end band 722 in mating connection with the connection element.

For example, the connecting member and the mating member may be a hook and loop fastener, a buckle, a magnet, a snap, a buckle, or other connecting structures.

In one embodiment, the connecting element is a buckle 724 disposed on the first end strip 721, the mating element is a hook and loop fastener disposed on the second end strip 722, the hook and loop fastener passes through the buckle 724 and is folded back to be attached to the outer side of the second end strip 722, and the actual tightening force of the upper head strip 72 can be adjusted by the length of the folded back. The fourth adjustment structure 723, like the adjustment structure described above, allows the usable length of the upper headband 72 to be adjusted to accommodate users with different head sizes.

Further, in embodiments where a fourth adjustment structure 723 is provided, the upper headband 72 has a length of 190mm-310mm, preferably 230mm-270 mm. Wherein, the length of the upper headband 72 is: the hook and loop fastener on the second end band 722 is passed through the head band button 724 and is bonded to connect the first end band 721 and the second end band 722 after being folded back at its closest root, where the two ends of the upper head band 72 are extended by the length of the intersection of the rear head band 73 (or may be understood as the arc length between the two ends of the upper head band 72).

In another alternative embodiment, shown in figure 28, the upper headband 72 is provided without adjustment features to reduce cost.

Further, in this embodiment without an adjustment mechanism, the upper headband 72 has a length of 190mm to 310mm, preferably 230mm to 270 mm. It will be appreciated that in this embodiment, the length of the upper headband 72 is the extended length from the intersection of its two ends with the rear headband 73 (or may be understood as the arc length between the two ends of the upper headband 72).

Further, in the above-described preferred or alternative embodiment, the length of the first end band 721 and the length of the second end band 722 may be set to be unequal for ease of adjustment. As shown in fig. 27c, the length of the first end band 721 provided with the hook & loop fastener may be greater than the length of the second end band 722. In some preferred embodiments, the rear headband 73, the first side headband 71a, and the second side headband 71b are integrally cut from the same fabric and then spliced with the upper headband 72 at a splice line 701 as shown in figure 27 c.

In some alternative embodiments, the upper headband 72, the rear headband 73, the first side headband 71a, and the second side headband 71b are integrally cut from the same fabric.

In some alternative embodiments, the first and second side head straps 71a, 71b, the rear head strap 73, and the upper head strap 72 may also be formed by splicing three pieces of fabric.

In addition, the materials of the first and second side head bands 71a and 71b, the upper head band 72, and the rear head band 73 may be made of foam, silicon rubber, elastic fabric, or breathable fabric.

The headband 70 is a unitary structure in which the first and second side headband strips 71a and 71b and the upper and rear headband strips 72 and 73 are integrally formed, so that it can be constructed with a narrower width than the conventional four-point headband. For example, the width may be 8-16mm for better flexibility. In addition, the headband 70 does not pass under the ears of the patient when the headband 70 is worn, so that the headband 70 does not need to be taken off by the patient in the middle of wearing, the headband 70 is very convenient and easy to use, and the headband 70 can be conveniently worn and taken off only by adjusting the wearing tension of the headband 70 once without repeatedly adjusting the wearing tension of the headband every time of wearing or taking off.

While the invention has been described with reference to a preferred embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, the technical features mentioned in the embodiments can be combined in any way as long as there is no structural conflict. The present invention is not limited to the particular embodiments disclosed herein, but encompasses all technical solutions falling within the scope of the claims.

Claims (33)

1. An exhaust assembly disposed on a patient interface device, comprising a body, the body comprising:

the air inlet pipe comprises a conical boss, wherein first exhaust holes are formed in the conical boss and are arrayed along the circumferential direction of the conical boss;

the conical boss comprises an inner wall, an outer wall and an inclined wall arranged between the inner wall and the outer wall, and the first exhaust hole is formed in the inclined wall.

2. The exhaust assembly of claim 1, wherein the inner hole diameter of the first exhaust hole is smaller or larger than the outer hole diameter of the first exhaust hole.

3. The exhaust assembly according to claim 1, wherein an inner hole diameter of the first exhaust hole is larger than an outer hole diameter of the first exhaust hole, and the thickness of the inclined wall is 0.7mm to 2.0 mm.

4. An exhaust assembly according to claim 1, wherein the inner bore diameter of the first exhaust aperture is smaller than the outer bore diameter of the first exhaust aperture, and the inclined wall has a thickness of from 0.7mm to 1.5 mm.

5. An exhaust assembly according to claim 1 or 2, wherein the first exhaust aperture is oblong, rectangular or a configuration of at least two straight lines in parallel to at least one straight line connecting two arcs.

6. An exhaust assembly according to claim 1 or 2, wherein the first exhaust apertures are in a diverging arrangement, and the number of first exhaust apertures adjacent to each first exhaust aperture is at most 2.

7. The exhaust assembly of claim 1, wherein the first exhaust holes are circular holes.

8. The exhaust assembly of claim 1, wherein the first exhaust hole is a tapered hole.

9. The utility model provides an exhaust subassembly, its characterized in that is in including main part and setting first exhaust hole in the main part, first exhaust hole sets up and is being close to main part edge just is the type of dispersing and arranges, every the quantity of adjacent first exhaust hole around the first exhaust hole is 2 at most.

10. The exhaust assembly of claim 9, wherein the body has an oval configuration.

11. An exhaust assembly according to claim 8 or 9, wherein the body comprises a patient side and a patient-opposite side, the patient side being provided with a tapered boss, the first exhaust aperture being provided on the tapered boss.

12. A frame assembly for a patient interface device, comprising:

the air inlet pipeline is connected with the frame main body, and the other side of the air inlet pipeline is connected with the cushion assembly;

a pair of bone beam arms including a first bone beam arm and a second bone beam arm oppositely disposed on the frame body; and

the connecting body is used for connecting the gasket assembly with the frame main body, the connecting body and the gasket assembly are sealed to form closed connection, a boss protruding from the inner side of the frame main body is arranged on the connecting body, a recess is formed between the boss and the inner wall of the frame main body and used for accommodating the gasket assembly, and the boss extends into the bottom of the gasket assembly;

an exhaust assembly according to any one of claims 1 to 8 or according to any one of claims 9 to 11 is provided on the frame body.

13. The frame assembly of claim 12, wherein the vent assembly is integrally molded with the frame body.

14. The frame assembly according to any one of claims 12 to 13, wherein the bone beam arms are of PP material;

the bone bridge arm is integrally molded with the frame body.

15. A frame assembly for a patient interface device, comprising:

the frame comprises a frame main body, wherein one side of the frame main body is connected with an air inlet pipeline, the other side of the frame main body is connected with a gasket assembly, a third air outlet hole is formed in the gasket assembly, and a through hole corresponding to the third air outlet hole is formed in the frame main body;

a pair of bone bridge arms including a first bone bridge arm and a second bone bridge arm oppositely disposed on the frame body; and

the gasket assembly is connected with the frame main body through the connecting body, the connecting body and the gasket assembly are sealed to form closed connection, a boss protruding from the inner side of the frame main body is arranged on the connecting body, a recess is formed between the boss and the inner wall of the frame main body and used for accommodating the gasket assembly, and the boss extends into the bottom of the gasket assembly.

16. The frame assembly of claim 15, wherein the through holes are arranged in pairs on the frame body and are symmetrically arranged with respect to a longitudinal centerline of the frame body.

17. A frame assembly for a patient interface device, comprising:

one side of the frame main body is connected with an air inlet pipeline, the other side of the frame main body is connected with a gasket assembly, and a second exhaust hole is formed in the air inlet pipeline;

a pair of bone bridge arms including a first bone bridge arm and a second bone bridge arm oppositely disposed on the frame body; and

the gasket assembly is connected with the frame main body through the connecting body, the connecting body and the gasket assembly are sealed to form closed connection, a boss protruding from the inner side of the frame main body is arranged on the connecting body, a recess is formed between the boss and the inner wall of the frame main body and used for accommodating the gasket assembly, and the boss extends into the bottom of the gasket assembly.

18. A cushion assembly for a patient interface device, the cushion assembly comprising a nasal cushion and a vent assembly as set forth in any one of claims 1-8 or any one of claims 9-11;

wherein the nasal cushion is configured such that when sealed against the base of a wearer's nose by pressurized gas, the nasal cushion is non-gripping against the patient's alar nose.

19. The cushion assembly of claim 18, wherein the nasal cushion includes an upper side, a lower side opposite the upper side, and a circumferential side disposed between the upper side and the lower side, the circumferential side forming a cavity around the upper side and the lower side; the upper side portion includes a face contact portion for contacting a face of a user;

the face contact part comprises a middle part and a first side part and a second side part which are positioned at two sides of the middle part, and the first side part and the second side part are connected with the circumferential side parts;

the intermediate portion includes a nose opening in communication with the cavity and a peripheral seal surrounding the nose opening, the nose opening being configured to surround an underside of a user's nostril in response to the nasal cushion being donned by the user and to fittingly fit around the user's nostril for sealing by the peripheral seal.

20. A patient interface device, comprising:

a cushion assembly including a nasal cushion for contacting a face of a patient, the nasal cushion being configured to fittingly conform around a nostril of the patient responsive to the patient interface device being donned by the patient, and the nasal cushion being configured such that it does not pass beyond a tip of the nose of the patient when sealed against a bottom of the nose of the wearer by pressurized gas;

the two sides of the frame component are respectively connected with the nasal cushion and the breather pipe in a sealing way; and

a headgear coupled to the frame, the headgear configured to be secured around a head of a patient in response to the patient interface device being donned by the patient.

21. The patient interface device according to claim 20, wherein the cushion assembly is the cushion assembly according to claim 18 or 19.

22. The patient interface device according to claim 20, further comprising an exhaust assembly according to any one of claims 1-8 or any one of claims 9-11.

23. The patient interface device according to claim 20, wherein the frame assembly is according to any one of claims 12-14, 15-16, or 17.

24. The patient interface device according to claim 23, wherein the frame comprises a frame body and a tapered boss disposed outside the frame body, wherein the tapered boss is provided with a connecting hole penetrating through the tapered boss and the frame body, and both ends of the connecting hole are respectively connected to the nasal cushion and the ventilation tube in a sealing manner.

25. The patient interface device according to claim 24, wherein the frame comprises a frame body and an elbow rotatably connected to the frame body, the elbow being sealingly connected to the vent tube.

26. The patient interface device according to claim 24, wherein the frame is directly connected to an elbow connected to an air delivery conduit for connection to a pressure device,

the inner diameter of the air conveying pipeline is 15mm-22 mm.

27. The patient interface device according to claim 24, wherein the frame is directly connected to a flexible hose connected to an air delivery conduit for connection to a pressure device; the inner diameter of the flexible hose is 12mm-15mm, and the inner diameter of the air conveying pipeline is 15mm-22 mm.

28. The patient interface device according to claim 27, wherein the flexible hose is a tube having elastic properties.

29. The patient interface device according to claim 27, wherein the frame has a connector provided thereon, the connector being rotatably connected to the flexible hose.

30. The patient interface device according to claim 25, wherein the nasal cushion includes an upper side, a lower side opposite the upper side, and a circumferential side disposed between the upper side and the lower side, the circumferential side forming a cavity around the upper side and the lower side; the cavity is communicated with the vent pipe.

31. The patient interface device according to claim 30, wherein an interior side of the frame is provided with a connecting body by which the nasal cushion is sealingly connected to the frame.

32. The patient interface device according to claim 31, wherein an underside of the nasal cushion is provided with a base on which a bottom opening is provided;

the connector is configured as a boss projecting from an inner side of the frame, a recess is formed between the boss and an inner wall of the frame, the base of the nasal cushion is disposed in the recess, and the boss extends into the bottom opening.

33. The patient interface device according to any one of claims 20-32, further comprising first and second bone bridge arms disposed at respective ends of the frame, the first and second bone bridge arms extending over the ears along the cheeks of the wearer, respectively, in response to the patient interface device being donned;

the headband comprises a first side headband connected with the first bone beam arm, a second side headband connected with the second bone beam arm, and an upper headband and a rear headband arranged between the first side headband and the second side headband;

the upper headgear and the rear headgear are configured to be secured around a patient's hindbrain and a patient's crown, respectively, in response to the patient interface device being donned by the patient.

Images