FR3110436A1 - Breathing assistance device - Google Patents

Abstract

Title: Breathing assistance device. The main object of the present invention is a device for assisting breathing (1) of a patient, comprising at least one housing (2) in which extends at least one inspiration circuit (16), a 'gas inlet (18) and an exhalation circuit (20), the inspiration circuit (16) comprising an air inlet (44), a device for circulating (28) air in the inspiration circuit (16), a device for mixing (48) the air coming from the circulation device (28) with the gas coming from the gas supply line (18), a control valve ( 30) for the circulation of the air / gas mixture within the inspiration circuit (16) of the air and a nozzle (22) intended to be connected to a patient, characterized in that the inspiration circuit (16) comprises a device (50) for accumulating at least the gas arranged aeraulically between the circulation device (28) and the mixing member (48). Figure 1.

Description

Breathing assistance device

The present invention falls within the field of patient breathing assistance devices, and in particular breathing assistance devices for intubated patients.

Patients in respiratory distress require respiratory assistance to ensure oxygenation of their tissues. The breathing assistance devices currently used conventionally comprise at least one conduit dedicated to patient inspiration on which is installed at least one air circulation device. This device for circulating air is adapted to generate a flow of air which is treated, for example by adding oxygen, before being directed towards the respiratory system of the patient, and thus ensuring the respiration of the latter . Such respiratory assistance devices also include an exhalation line through which the air exhaled by the patient circulates and is then expelled.

To allow the patient to inhale and exhale, valves allowing or blocking the flow of air through the line dedicated to the patient's inspiration or expiration are installed. Thus, a valve blocks the circulation of air in the pipe dedicated to exhalation when air enriched in dioxygen circulates towards the patient to spread more particularly in the respiratory system of the patient. Once a sufficient quantity of enriched air is brought to the patient, a valve blocks the air circulation in the line dedicated to the inspiration of the patient and the valve blocking the circulation in the line dedicated to the expiration is positioned to allow the expiration of the air contained by the patient's respiratory system through the pipe dedicated to expiration.

When the valve blocks the circulation of air in the line dedicated to inspiration, oxygen continues to spread upstream of the valve in the line dedicated to inspiration. Unable to flow to the patient because of the position of the valve, the oxygen spreads upstream of the pipe dedicated to inspiration and in particular towards the air circulation device. The presence of oxygen-enriched air in contact with the air circulation device can lead to oxidation of the components of the ventilation device and then cause their deterioration, potentially generating breakdowns.

The present invention falls within this context by proposing an air accumulation device positioned between a source of oxygen supply and the ventilation device, this accumulation device making it possible to contain the oxygen during the period when the valve of the duct dedicated to inspiration blocks the circulation of air through said duct.

The main object of the present invention is thus a device for assisting the breathing of a patient, comprising at least one casing in which extends at least one inspiration circuit, a gas inlet pipe and a expiration, the inspiration circuit comprising an air inlet, a device for circulating the air in the inspiration circuit, a member for mixing the air coming from the circulation device with the gas coming from the gas inlet pipe, a valve for controlling the circulation of the air/gas mixture within the air inspiration circuit and an end piece intended to be connected to a patient, characterized in that the circuit inspiration comprises a device for accumulating at least the gas arranged aeraulically between the circulating device and the mixing member.

The circulation device allows air to be expelled through the inspiration circuit to a patient connected to the assisted breathing device. The gas supply line is connected to the inspiration circuit at the level of the mixing device to enrich the air with gas, such as oxygen, circulating in the inspiration circuit before being expelled towards the patient . The air exhaled by the patient is then expelled through the exhalation circuit.

The inspiration circuit control valve allows the flow of the air/gas mixture towards the patient when the latter must inspire air and blocks the supply of the air/gas mixture when the patient must exhale.

The flow of gas through the gas inlet line into the inspiration circuit continues even when the control valve blocks the flow of the air/gas mixture to the patient. The gas then rises upstream of the inspiration circuit to the accumulation device where the gas accumulates for a maximum duration of expiration. This duration corresponds to the maximum time during which the control valve blocks the flow of air downstream of the inspiration circuit.

According to an optional characteristic of the invention, the air accumulation device comprises two chambers delimited by a partition, the two chambers communicating with each other via at least one orifice provided through the partition.

The accumulation device comprises an internal space, the partition dividing this internal space to form the two chambers. One of the two chambers communicates aeraulically with the upstream of the inspiration circuit while the other chamber communicates aeraulically with the downstream of the inspiration circuit, the orifice provided on the partition ensuring the connection between the downstream and upstream of the inspiration circuit.

According to another optional characteristic of the invention, the partition comprises a lower edge and an upper edge along a vertical axis, the orifice being provided closer to the upper edge than to the lower edge of the partition.

The gas accumulating in the gas supply line is usually oxygen and is heavier than the air flowing through the inspiration circuit. When it accumulates in the accumulation device, this gas accumulates more particularly at the lower edge of the partition and then fills the volume of one of the chambers. When this volume is filled, the gas fills the other chamber by flowing through the orifice.

The positioning of the orifice close to the upper edge allows the gas to fill the volume of one chamber before filling the volume of the other chamber when necessary, thus guaranteeing storage of oxygen in the lower part of the chamber , before going to the other room.

According to another optional feature of the invention, a first chamber is in aeraulic communication with the circulation device via an inlet of the accumulation device and a second chamber is in aeraulic communication with the mixing member through a discharge orifice of the accumulation device.

Thus, the gas first fills the second chamber before filling the first chamber, if necessary.

According to another optional characteristic of the invention, a volume defined by the first chamber and the second chamber is between 750 cm ³ and 1250 cm ³ .

The gas supply line continues to supply gas to the inspiration circuit even when the control valve blocks airflow in the inspiration circuit. The volumes of the first chamber and of the second chamber are determined to be able to contain all the gas coming from the gas inlet pipe mixing with the air in the inspiration circuit during the maximum time of expiration, c ie the maximum time during which the control valve blocks the circulation of air in the inspiration circuit. This guarantees that, regardless of the duration of the exhalation phase, the oxygen remains in the accumulation device, without reaching the air circulation device.

This volume takes into account the pressure of the gas when it arrives in the mixing device as well as its variation in volume due to a change in pressure between the moment when it circulates through the gas inlet pipe and the moment when it is stored in the accumulation device.

According to another optional characteristic of the invention, the mixing member comprises a first end piece directly in communication with the discharge orifice of the accumulation device, a second end piece directly in communication with the control valve and at least one third end piece directly in communication with the gas inlet pipe, the gas inlet pipe being devoid of a device for controlling the flow of gas in the pipe.

According to another optional characteristic of the invention, the gas inlet pipe comprises a device for measuring the flow of gas flowing through the gas inlet pipe.

The mixing device allows the gas supply pipe to be connected to the inspiration circuit so that the gas circulating in the gas supply pipe mixes with the air circulating in the inspiration circuit.

According to another optional characteristic of the invention, the breathing assistance device comprises an acoustic attenuation member arranged aeraulically downstream of the circulation device on the inspiration circuit.

The acoustic attenuation device makes it possible to partially reduce the acoustic waves produced by the circulation device.

According to another optional characteristic of the invention, the acoustic attenuation member is arranged aeraulically between the circulation device and the accumulation device.

According to another optional characteristic of the invention, the acoustic attenuation member forms a common unit with the accumulation device.

It is understood by common unit that the accumulation device is secured to the acoustic attenuation member before the assembly of the breathing assistance device.

According to another optional characteristic of the invention, the acoustic attenuation member takes the form of a cylinder, the accumulation device being formed radially around the acoustic attenuation member.

In other words, the accumulation device forms a cylinder in the center of which is positioned the acoustic attenuation member. It is thus understood that the air first circulates in the acoustic attenuation member before circulating in the accumulation device.

According to another optional characteristic of the invention, a volume of one of the two chambers forms a half-volume of the accumulation device, the other chamber forming the other half-volume of the accumulation device.

It is understood that the partition of the accumulation device is positioned in the internal space so that the internal space is distributed equitably between each of the chambers, that is to say that 50% of the volume of the internal space is formed by the first chamber and that the remaining 50% is formed by the second chamber.

According to another optional characteristic of the invention, the accumulation device comprises a duct connecting aeraulicically the acoustic attenuation member to the downstream of the inspiration circuit, the duct being formed in a spiral around the organ of acoustic attenuation.

In this alternative embodiment, the conduit of the accumulation device is configured to be able to store all of the gas emitted by the gas inlet conduit during the maximum expiration time.

According to another optional characteristic of the invention, a volume defined by the duct of the storage device is between 750 cm ³ and 1250 cm ³ .

According to another optional characteristic of the invention, the duct of the accumulation device has a section of rectangular shape.

The invention also relates to a method of circulating air through a breathing assistance device according to any of the preceding characteristics, the circulation device forcing the circulation of air from the inlet of air to the nozzle intended to be connected to a patient respectively through the circulation device, the accumulation device, the mixing member and the control valve, the control valve being able to take a circulation position allowing the circulation of air between the air inlet and the nozzle intended to be connected to a patient or a blocking position preventing the circulation of air between the mixing member and the nozzle intended to be connected to a patient, during which the pressurized gas flowing in the gas supply line to the mixing device accumulates in the accumulation device when the control valve is in the blocking position.

The variation of the position of the control valve makes it possible to reproduce the natural inspiration and expiration of the patient by authorizing or blocking the circulation of the air/gas mixture towards the patient.

Other characteristics, details and advantages of the invention will emerge more clearly on reading the description which follows on the one hand, and several examples of embodiment given by way of indication and not limitation with reference to the appended schematic drawings on the other. part, on which:

is a representation in perspective of a breathing assistance device according to the invention;

is a representation in perspective of an accumulation device of the respiratory assistance device according to a first embodiment of the invention;

is a representation in perspective of an acoustic attenuation member and of an accumulation device of the respiratory assistance device according to a second embodiment of the invention.

is a vertical section of the acoustic attenuation member and of the accumulation device of the respiratory assistance device according to a third embodiment.

The features, variants and different embodiments of the invention may be associated with each other, in various combinations, insofar as they are not incompatible or exclusive with respect to each other. In particular, variants of the invention may be imagined comprising only a selection of characteristics described below in isolation from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage and/or to differentiate the invention. compared to the prior art.

In the following description, the denominations “longitudinal”, “transverse” and “vertical” refer to the orientation of a breathing assistance device according to the invention. A longitudinal direction corresponds to a main direction of extension of a housing of the respiratory assistance device, this longitudinal direction being parallel to a longitudinal axis L of a reference L, V, T illustrated in the figures. A transverse direction corresponds to a direction parallel to a transverse axis along which a control valve mainly extends, this transverse direction being parallel to a transverse axis T of the reference L, V, T and this transverse axis T being perpendicular to the longitudinal axis L. Finally, a vertical direction corresponds to a direction parallel to a vertical axis V of the reference L, V, T, this vertical axis V being perpendicular to the longitudinal axis L and the transverse axis T.

In addition, the terms “upstream” and “downstream” used in the rest of the description refer directly to the direction of the circulation of air or gas within a circuit considered. More specifically, the term “upstream” of an object in the description will refer to the start of air circulation in the circuit considered, i.e. before the object in question. Conversely, the term "downstream" of an object in the description will refer to following the circulation of the air in the circuit considered, i.e. after the object in question.

As shown on the , a breathing assistance device 1 comprises at least one housing 2 taking the overall shape of a rectangular parallelepiped with six faces. The casing 2 comprises two longitudinal walls 6 extending in a plane in which are inscribed a longitudinal axis L, forming the main extension axis of the casing 2, and a vertical axis V perpendicular to the longitudinal axis L. two longitudinal walls 6 extend along the longitudinal axis L between two side walls 8a, 8b which for their part extend parallel to the vertical axis V and to a transverse axis T perpendicular to the longitudinal L and vertical axes V The two longitudinal walls 6 and the two side walls 8a, 8b extend along the vertical axis V between an upper wall 10 and a lower wall 12, these lower 12 and upper 10 walls extending in planes in which the longitudinal L and transverse T axes are inscribed.

The box 2 comprises at least one display device 14 positioned at one of the two side walls 8a, 8b. To facilitate understanding of the invention, it is defined that the side wall on which the display device 14 is positioned is positioned at the front of the housing 2 along the longitudinal axis L, the other side wall thus being at the rear of the case 2. A front side wall 8a and a rear side wall 8b are thus defined. of the indication "front" or "rear" in the following description.

The display device 14 is here a screen on which at least information related to the breathing assistance device 1 is displayed. The display device 14 can also be a tactile communication interface, or touch screen, with which a practitioner can interact directly by tactile contact with the respiratory assistance device 1.

The casing 2 houses an inspiration circuit 16, a gas inlet pipe 18 and an exhalation circuit 20 extending in the internal volume 4 of the casing 2. The inspiration 16 and expiration 20 circuits, as well as the gas inlet pipe 18, are particularly visible on the because one of the longitudinal walls 6 of the casing 2 has not been shown in this figure, making visible certain components of the respiratory assistance device 1 extending into the internal volume 4 of the casing 2.

The inspiration 16 and expiration 20 circuits here each comprise a connection end piece 22 to a tube connecting the inspiration 16 or expiration 20 circuit to a patient. This connection end piece 22 extends through the front side wall 8a, to place the tube connected to the patient in air communication with the inspiration 16 or expiration 20 circuit.

The gas inlet pipe 18 also includes a connection member 24 extending through the front side wall 8a, opening out inside the breathing assistance device 1. This connection member 24 makes it possible to connect the gas inlet pipe 18 of the breathing assistance device 1 to a gas distribution system, external to the breathing assistance device 1. The gas inlet pipe 18 comprises a pipe 26 connecting this connection device 24 to the inspiration circuit 16.

The inspiration circuit 16 is configured to distribute a flow of air to the patient, thus simulating the natural inspiration of a human being, the gas inlet pipe 18 enriching the air supplied to the patient with a gas, such as oxygen for example. The exhalation circuit 20 makes it possible to manage the expulsion of air from the patient like the natural exhalation of a human being. The inspiration 16 and expiration 20 circuits of the respiratory assistance device 1 thus operate in cooperation with each other to produce artificial respiration close to the natural respiration of a human being.

In the breathing assistance device 1, the gas inlet pipe 18 has no gas flow control device in said pipe. The gas thus enters the respiratory assistance device 1 at the pressure of the hospital network and this supply of gas is not interrupted when the respiratory assistance device 1 is placed in the exhalation position.

For this, the inspiration circuit 16 comprises at least one device 28 for circulating air through the inspiration circuit 16 to the patient, and an inspiration control valve 30 authorizing or blocking the circulation. air into inspiration circuit 16. Similarly, exhalation circuit 20 includes an exhalation control valve 32 allowing or blocking the flow of air through exhalation circuit 20, each control valves 30, 32 extending here mainly along the transverse axis T. Each control valve 30, 32 can thus assume a circulation position and a blocking position. When a control valve 30, 32 is in a circulation position, it allows the free circulation of air in the circuit on which the control valve concerned is installed. Conversely, when a control valve 30, 32 is in a blocking position, it prevents the circulation of air in the circuit on which the control valve concerned is installed. Thus, the alternating change of positions of the inspiration 30 and expiration 32 control valves makes it possible to control the patient's inspiration and expiration.

The inspiration control valve 30 is placed in a circulation position when the patient is to inhale, the expiration control valve 32 then being placed in a blocking position, so that the air sent to the patient does not circulate in the exhalation circuit 20. Conversely and when the patient has to exhale, the inspiration control valve 30 is placed in a blocking position, preventing a supply of air to the patient, and the exhalation control valve 32 is placed in a circulation position allowing the patient to expel the air contained in his respiratory system.

We will now describe in more detail the inspiration circuit 16 according to a first embodiment, with reference to the .

The inspiration circuit 16 includes at least one air inlet 44 and the device 28 for circulating air in the inspiration circuit 16, forcing air to circulate through the inspiration circuit 16 from the air inlet 44. Also and according to the example illustrated here, the inspiration circuit 16 comprises an acoustic attenuation member 46, an air mixing member 48, the air being mixed with a gas from the gas inlet pipe 18, the inspiration control valve 30 of the air/gas mixture of the inspiration circuit 16 and the connection endpiece 22 intended to be connected to a patient. According to the invention, the inspiration circuit 16 comprises an accumulation device 50 for at least the gas, such an accumulation device 50 being arranged aeraulically between the circulating device 28 and the mixing member 48 .

The air inlet 44 of the inspiration circuit 16 is here provided at the level of one of the longitudinal walls 6 of the casing 2. The air inlet 44 consists of a mouth of the inspiration circuit 16 open on the exterior of the respiratory assistance device 1 at the level of one of the longitudinal walls 6 of the casing 2. However, an air inlet 44 of the inspiration circuit 16 provided on another wall of the casing 2, such as for example the upper wall 10 or the other longitudinal wall 6 of the casing 2 would not depart from the scope of the invention. Advantageously, an air-filtering device is arranged at the level of the air inlet 44 of the inspiration circuit 16 to filter the particles in suspension in the air drawn into the inspiration circuit 16.

The inspiration circuit 16 comprises a first tube 52 extending mainly here along the transverse axis T between the air inlet 44 of the inspiration circuit 16 and the circulation device 28.

The circulation device 28 comprises a ventilation device housed in a volute 60 and an electric motor 62 capable of driving the ventilation device in rotation about an axis of rotation, the latter being substantially parallel to the longitudinal axis L The volute 60 is shown here on the by a cylinder whose two discoid faces each extend in a plane perpendicular to the axis of rotation. Additionally, electric motor 62 is also shown as a cylinder extending longitudinally between rear side wall 8b and volute 60.

The first tube 52 opens directly into the volute 60 of the circulation device 28 at the level of one of the discoid faces of the volute 60, so that the air circulating in the first tube 52 circulates as far as the volute 60.

The ventilation device consists of a propeller configured to draw air from outside the respiratory assistance device 1 through the first tube 52 to expel it downstream of the inspiration circuit 16.

Downstream of the circulation device 28, the inspiration circuit 16 comprises a second tube 64 extending from the volute 60 of the circulation device 28 towards at least the lower wall 12 of the housing 2.

More particularly and according to the example illustrated here on the , the second tube 64 extends vertically from the circulating device 28 to the acoustic attenuation member 46. The latter generally takes the form of a cylinder whose two discoid faces are substantially perpendicular to the vertical axis V. The acoustic attenuation member 46 consists of a hollow cylinder in which the air expelled by the circulating device 28 circulates downstream of the inspiration circuit 16. The member Acoustic attenuation 46 also includes a layer of sound absorbing material radially surrounding the hollow cylinder and configured to absorb at least a portion of the acoustic waves produced by circulating device 28.

According to the invention, the breathing assistance device 1 comprises the accumulation device 50 intended to form a volume in which the injected gas can accumulate during one of the respiratory phases. According to the example shown here, the acoustic attenuation member 46 and the storage device 50 are associated with each other. However, the invention is not limited to this association, the accumulation device 50 being able to be dissociated from the acoustic attenuation member 46. In addition, the breathing assistance device 1 can comprise the device for accumulation 50 without comprising any acoustic attenuation member.

The acoustic attenuation member 46 is aeraulically and directly connected to the air accumulation device 50, here taking the form of a cylinder vertically extending the acoustic attenuation member 46 towards the lower wall 12. A further description detail of the air accumulation device 50 will be made following the general description of the inspiration circuit 16.

The inspiration circuit 16 comprises a third tube 66 connecting the accumulation device 50 to the mixing device 48. The latter comprises a body 80 taking the overall shape of a "Y" which has at each of its ends a tip such that a first tip 74 is directly in communication with the third tube 66, a second tip 76 is directly in communication with the inspiration control valve 30 and at least a third tip 78 is directly in communication with the conduit gas inlet 18.

As a reminder, in the breathing assistance device, the gas inlet pipe 18 has no device for controlling the flow of gas in said pipe. The gas thus enters the respiratory assistance device 1 at the pressure of the hospital network and this gas supply is not interrupted when the respiratory assistance device is placed in the exhalation position.

According to another alternative or cumulative embodiment of the invention, the gas inlet pipe 18 comprises at least one member for measuring the flow rate of the gas flowing through the gas inlet pipe 18. This measuring member allows the practitioner to be informed about the flow rate of the gas flowing to the patient, the practitioner adjusting this flow rate according to the information received.

The air expelled by the circulation device 28 thus circulates through the body 80 from the first end piece 74 towards the second end piece 76. Gas is mixed with the air circulating in the body 80, this gas coming from the pipe gas inlet 18 flowing from the third endpiece 78 to the body 80. The gas may preferably be oxygen so that the air circulating in the body 80 is enriched with oxygen.

The oxygen-enriched air then flows to a fourth tube 84 on which the inspiration control valve 30 is arranged. The inspiration control valve 30 comprises at least one control member configured to assume a circulation position authorizing a circulation of oxygen-enriched air in the inspiration circuit 16 and a blocking position preventing such circulation in the inspiration circuit 16.

When the control member is in a circulation position, the oxygen-enriched air circulates from the mixing member 48 to the connection end piece 22 of the inspiration circuit 16, thus delivering this oxygen-enriched air to the patient. Conversely, when the control member of the inspiration control valve 30 is in a blocking position, the control member prevents the circulation of oxygen-enriched air through the fourth tube 84, the enriched air in oxygen and more particularly dioxygen is then stored at the level of the accumulation device 50.

We will now describe more precisely the air accumulation device 50 according to this first embodiment with reference to the .

The accumulation device 50 according to the example illustrated in the generally takes the form of a cylinder extending along the vertical axis V.

The accumulation device 50 includes an upper discoid wall 90, a lower discoid wall 92 and a cylindrical wall 94 extending between the upper discoid wall 90 and the lower discoid wall 92. The upper and lower discoid walls 90, 92 take a disc-shaped and here extend mainly in a plane in which the longitudinal L and transverse T axes are inscribed, the cylindrical wall 94 extending for its part from the periphery of each of the upper and lower discoid walls 90, 92 to to the other discoid wall 90, 92 along the vertical axis V. The cylindrical wall 94 and the upper and lower discoid walls 90, 92 participate in delimiting an internal space 96 of the accumulation device 50.

The air accumulation device 50 comprises an advantageously rectangular and planar partition 98 extending in a plane in which at least the vertical axis V and the transverse axis T are inscribed in the internal space 96 of the air accumulation device. accumulation 50. The partition 98 thus comprises four edges, of which two vertical edges 100 are in contact with the internal face of the cylindrical wall 94, an upper edge 102 being in contact with the upper discoid wall 90 and a lower edge 104 covering being in contact with the lower discoid wall 92.

The partition 98 separates the internal space 96 into a first chamber 106 and a second chamber 108 of the accumulation device 50, each of the chambers 106, 108 communicating with each other through an exchange orifice 110 provided at the through the partition 98. In other words, each chamber 106, 108 is a sub-portion of the internal space 96 delimited by at least a portion of the lower and upper discoid walls 90, 92 and cylindrical 94 as well as by the bulkhead 98.

The upper discoid wall 90 includes an inlet orifice 112 formed at the level of the first chamber 106 so that the latter is in aeraulic communication with the air circulation device.

Similarly, the lower discoid wall 92 comprises an evacuation orifice 118 formed at the level of the second chamber 108 so that the latter is in aeraulic communication with the mixing member. Advantageously, the lower discoid wall 92 of the accumulation device 50 also comprises an aeraulic connection endpiece 120 which projects at the level of the evacuation orifice 118 towards the outside of the accumulation device 50, this aeraulic connection endpiece 120 being configured to cooperate with the third tube and/or the mixing member.

As specified above, the first chamber 106 and the second chamber 108 of the air accumulation device 50 communicate aeraulically with each other through the exchange orifice 110. Thus, the air expelled by the circulation device circulates respectively through the first chamber 106 of the accumulation device 50, then passes through the exchange orifice 110 to then circulate through the second chamber 108 towards the mixing device.

Advantageously and according to the example illustrated here on the , the exchange orifice 110 of the partition 98 is more particularly arranged closer to the upper edge 102 than to the lower edge 104 of the partition 98. The exchange orifice 110 is also closer to the upper discoid wall 90 than of the lower discoid wall 92.

The sum of the volumes defined by the first chamber 106 and the second chamber 108 is between 750 cm ³ and 1250 cm ³ . In addition, the volume of the second chamber 108 here corresponds to the half-volume of the internal space 96 of the storage device 50, the volume of the first chamber 106 then corresponding to the other half-volume of the internal space 96 of the accumulation device 50.

The volume of the first chamber 106 and of the second chamber 108 are configured to be able to accommodate a quantity of gas emitted by the gas inlet pipe into the mixing member when the control member of the control valve inspiration is in a blocking position and during a maximum time of expiration. The latter corresponds to the maximum time during which the inspiration control valve is in a blocking position, the expiration control valve then being in a circulation position. Indeed, when the control member of the inspiration control valve is in a blocking position, gas, and more particularly oxygen, continues to arrive in the mixing member from the gas inlet pipe . The oxygen-enriched air then accumulates at the level of the mixing device and then goes up the inspiration circuit towards the accumulation device 50. The oxygen-enriched air then accumulates in the second chamber 108. The oxygen being heavier than air, it first accumulates at the level of the lower discoid wall 92 and gradually fills the second chamber 108. Once the oxygen has filled the volume of the second chamber 108, the dioxygen flows to the first chamber 106 through the exchange orifice 110 and then begins to fill the volume of the first chamber 106. The volumes of the first chamber 106 and the second chamber 108 make it possible to contain all of the dioxygen supply through the gas supply line during the maximum exhalation time.

Once the control member of the inspiration control valve resumes a circulation position and the expiration control valve resumes a blocking position, the air enriched by the dioxygen accumulated in the first chamber 106 and in the second chamber 108 is then expelled towards the connection endpiece of the inspiration circuit and thus towards the patient.

A second embodiment of the invention will now be described with reference to the . In the description of the second embodiment which follows, certain references of the respiratory assistance device of the first embodiment are reused to refer to the same components.

As shown on the , the air accumulation device 50 here forms a common unit with the acoustic attenuation member 46. In other words, the acoustic attenuation member 46 and the air accumulation device 50 are integral with each other and are designed to be mounted simultaneously in the respiratory assistance device.

For this, the acoustic attenuation member 46 takes the form of a cylinder, the accumulation device 50 being formed radially around the acoustic attenuation member 46. Thus, the first and second chambers 106, 108 are arranged around the acoustic attenuation member 46, the latter being partially in contact on the one hand with the first chamber 106 of the storage device 50 and on the other hand with the second chamber 108 of the storage device 50 More precisely, the acoustic attenuation member 46 is positioned at the center of the accumulation device 50 so that the distance measured between an external face 122 of the acoustic attenuation member 46 and an internal face 124 of the wall cylindrical 94 of the accumulation device 50 is constant all around an axis of revolution R passing through the center of the acoustic attenuation member 46, the axis of revolution R being substantially parallel to the vertical axis V.

The upper discoid wall 90 of the accumulation device 50 covers on the one hand the two chambers 106, 108 and on the other hand one of the discoid faces of the acoustic attenuation member 46, the discoid faces of the member acoustic attenuator 46 extending in a plane parallel to the planes in which the upper and lower discoid walls 90, 92 extend. In another embodiment, the upper discoid wall 90 of the storage device 50 is the one of the discoid faces of the acoustic attenuation member 46.

The inlet orifice 112 of the upper discoid wall 90 is aligned with a hollow cylinder 126 of the acoustic attenuation member 46 along the axis of revolution R, the latter passing through the center of the hollow cylinder 126. Thus, the second tube of the inspiration circuit passes through and/or opens at the level of the inlet orifice 112 of the upper discoid wall 90 to guide the air propelled by the circulation device through the hollow cylinder 126 of the acoustic attenuation member 46.

The hollow cylinder 126 has a discharge end 128 opening out at the level of the lower discoid wall 92 of the accumulation device 50 without however being in contact with said wall. Indeed, a lower portion 130 of the partition 98 extends between one of the discoid faces of the acoustic attenuation member 46 and the internal face of the lower discoid wall 92, that is to say the face of the lower discoid wall 92 oriented towards the internal space 96 of the accumulation device 50. Thus, a space is formed between the acoustic attenuation member 46 and the accumulation device 50.

The partition 98 is almost flat and extends in the internal space 96 by presenting a contact edge 132 with the acoustic attenuation member 46. More particularly, the partition 98 extends here in a plane in which inscribe the vertical axis V and the axis of revolution R. In addition, the partition 98 has a rounded gap 134 at the discharge end 128 of the hollow cylinder 126, this rounded gap 134 forming an outline of the evacuation end 128 of the hollow cylinder 126. This rounded gap 134 allows the hollow cylinder 126 to emerge at the level of the first chamber 106 of the accumulation device 50 while ensuring a seal between the two chambers 106, 108 of the accumulation 50 at the level of the lower edge 104 of the partition 98.

In this second embodiment, the exchange orifice 110 is also made close to the upper edge 102 of the partition 98 and is therefore located in an upper part of the storage device 50 along the vertical axis V. In addition, the lower discoid wall 92 comprises the evacuation orifice 118 as well as the aeraulic connection piece 120 aeraulically connecting the second chamber 108 to the third tube and/or to the mixing member of the inspiration circuit.

We will now describe more precisely the circulation of air through the inspiration circuit when the control member of the inspiration control valve is in a circulation position, then the accumulation of gas in the second chamber 108, then in the first chamber 106 of the accumulation device 50 when the control member of the inspiration control valve is in a blocking position.

According to the second embodiment, the device for circulating the air of the inspiration circuit forces the circulation of air from the air inlet to the connection end piece intended to be connected to a patient, respectively through the circulation device, the acoustic attenuation device 46, the accumulation device 50, the mixing device and the control valve. The control member of the control valve can adopt a circulation position authorizing the circulation of air between the air inlet and the connector intended to be connected to a patient or a blocking position preventing the circulation of the air between the mixing member and the tip intended to be connected to a patient.

When the inspiration control valve is in a circulation position, the air expelled by the circulation device flows vertically from the inlet port 112 of the upper discoid wall 90 towards the exhaust end 128 of the hollow cylinder 126 to circulate in the first chamber 106. The air then passes into the second chamber 108 through the exchange orifice 110 to circulate downstream of the inspiration circuit through the evacuation orifice 118 and the air connection end piece 120 of the lower discoid wall 92.

When the inspiration control valve is in a blocking position, the air flowing from the circulation device into the inspiration circuit downstream of the mixing device is blocked at the level of the inspiration control valve. 'inspiration. The gas circulating from the gas inlet pipe, such as oxygen, can no longer circulate in the inspiration circuit downstream of the mixing device. The gas accumulates in the mixing device, then rises upstream of the inspiration circuit towards the accumulation device 50. The gas then accumulates in the second chamber 108 during the maximum expiration time. Since the gas is generally oxygen, which is heavier than air, the gas first accumulates at the level of the lower discoid wall 92 of the accumulation device 50 and then fills, during the maximum exhalation time, the second chamber 108 then the first chamber 106. At the end of the maximum expiration time, the inspiration control valve returns to a circulation position. The dioxygen and the air accumulated in the first chamber 106 and in the second chamber 108 are then expelled towards the patient through the evacuation orifice 118 and the aeraulic connection endpiece 120 downstream of the accumulation device 50 of the inspiration circuit.

A third embodiment of the invention will now be described with reference to FIGS. 4 and 5. In the description of the third embodiment which follows, certain references of the respiratory assistance device of the first and second embodiments are reused to refer to the same components.

As shown on the , the accumulation device 50 comprises an accumulation conduit 136 air-connecting the acoustic attenuation member 46 downstream of the inspiration circuit. More specifically, the accumulation duct 136 connects the discharge end 128 of the hollow cylinder 126 of the acoustic attenuation member 46 to the discharge orifice of the accumulation device 50.

The accumulation duct 136 is arranged in a spiral around the acoustic attenuation member 46 in the internal space 96. The accumulation duct 136 here has a rectangular section, however, an accumulation duct 136 having another section shape, such as a circular or triangular section, would not depart from the scope of the invention. According to the direction of air circulation, the accumulation duct 136 extends from the lower discoid wall 92 towards the upper discoid wall 90 along the vertical axis V. In addition, the spiral formed here by the duct accumulation 136 is wound around the axis of revolution R.

The accumulation duct 136 comprises a first section 138 extending substantially perpendicular to the axis of revolution R from the discharge end 128 of the hollow cylinder 126 towards the cylindrical wall 94 of the accumulation device 50. The duct accumulation 136 then comprises a plurality of superimposed sections 140 forming the spiral wound around the axis of revolution R. Each section of a superimposed section 140 extends substantially perpendicular to the axis of rotation R between the cylindrical wall 94 and the contact edge 132 of the accumulation device 50.

The volume formed by the accumulation duct 136 is between 750 cm ³ and 1250 cm ³ . The volume of the accumulation conduit 136 is configured to be able to accommodate a quantity of gas emitted by the gas inlet conduit into the mixing member when the control member of the inspiration control valve is in a position blocking and for a maximum expiration time.

We will now describe more precisely the circulation of air through the inspiration circuit when the control member of the inspiration control valve is in a circulation position, then the accumulation of gas in the duct. accumulation 136 of the accumulation device 50 when the control member of the inspiration control valve is in a blocking position.

According to the third embodiment, the device for circulating the air of the inspiration circuit forces the circulation of air from the air inlet to the connection end piece intended to be connected to a patient, respectively through the circulation device, the acoustic attenuation device 46, the accumulation device 50, the mixing device and the control valve. The control member of the control valve can adopt a circulation position authorizing the circulation of air between the air inlet and the connector intended to be connected to a patient or a blocking position preventing the circulation of the air between the mixing member and the tip intended to be connected to a patient.

When the inspiration control valve is in a circulation position, the air expelled by the circulation device flows vertically from the inlet port 112 of the upper discoid wall 90 towards the exhaust end 128 of the hollow cylinder 126 to circulate in the first section 138 of the accumulation duct 136. The air then circulates through the plurality of superimposed sections 140 of the accumulation duct 136 to then circulate downstream of the inspiration circuit via the evacuation orifice and the aeraulic connection end piece.

When the inspiration control valve is in a blocking position, the air flowing from the circulation device into the inspiration circuit downstream of the mixing device is blocked at the level of the inspiration control valve. 'inspiration. The gas circulating from the gas inlet pipe, such as oxygen, can no longer circulate in the inspiration circuit downstream of the mixing device. The gas accumulates in the mixing device, then rises upstream of the inspiration circuit towards the accumulation device 50. The gas then accumulates in the accumulation conduit 136 during the maximum expiration time. The gas generally being dioxygen, which is heavier than air, the gas first accumulates at the level of the first section 138 of the accumulation duct 136 then fills, during the maximum expiration time, the plurality of superimposed sections 140 of the accumulation duct 136. At the end of the maximum expiration time, the inspiration control valve resumes a circulation position. The oxygen and the air accumulated in the accumulation duct 136 are then expelled towards the patient through the evacuation orifice and the aeraulic connection end piece downstream of the accumulation device 50 of the inspiration circuit. The invention cannot however be limited to the means and configurations described and illustrated here, and it also extends to any equivalent means or configuration described and illustrated here, and it also extends to any equivalent means or configuration and to any combination technique operating such means. In particular, the orientation of each of the components of the inspiration circuits may be different from that described in the description above.

Claims (12)

Device for assisting the respiration (1) of a patient, comprising at least one casing (2) in which extends at least one inspiration circuit (16), a gas inlet pipe (18) and an exhalation circuit (20), the inspiration circuit (16) comprising an air inlet (44), a device (28) for circulating air in the inspiration circuit (16), a member (48) for mixing the air coming from the circulation device (28) with the gas coming from the gas inlet pipe (18), a control valve (30) for the circulation of the air mixture /gas within the air inspiration circuit (16) and a connector (22) intended to be connected to a patient, characterized in that the inspiration circuit (16) comprises an accumulation device (50 ) at least the gas arranged aeraulically between the circulating device (28) and the mixing member (48). A breathing assistance device (1) according to claim 1, wherein the air accumulation device (50) comprises two chambers (106, 108) delimited by a partition (98), the two chambers (106, 108) communicating with each other via at least one orifice (110) formed through the partition (98). Breathing assistance device (1) according to Claim 2, in which the partition (98) comprises a lower edge (104) and an upper edge (102) along a vertical axis, the orifice (110) being provided more closer to the upper edge (102) than to the lower edge (104) of the partition (98). A breathing assistance device (1) according to any of claims 2 or 3, wherein a first chamber (106) is in airflow communication with the circulation device (28) via a inlet orifice (112) of the accumulation device (50) and a second chamber (108) is in aeraulic communication with the mixing member (48) by means of an outlet orifice (118) of the device accumulation (50). A breathing assistance device (1) according to claim 4, wherein a volume defined by the first chamber (106) and the second chamber (108) is between 750 cm ³ and 1250 cm ³ . A breathing assistance device (1) according to any preceding claim in combination with claim 4, wherein the mixing member (48) comprises a first tip (74) directly in communication with the orifice of discharge (118) of the accumulation device (50), a second nozzle (76) directly in communication with the control valve (30) and at least a third nozzle (78) directly in communication with the inlet pipe of gas (18), the gas inlet pipe (18) being devoid of a device for controlling the flow of gas in the pipe. Breathing assistance device (1) according to any one of the preceding claims, comprising an acoustic attenuation member (46) aeraulically arranged downstream of the circulation device (28) on the inspiration circuit (16 ). Breathing assistance device (1) according to Claim 7, in which the acoustic attenuation member (46) is disposed aeraulically between the circulation device (28) and the accumulation device (50). A breathing aid device (1) according to any one of claims 7 or 8, wherein the acoustic attenuator (46) forms a common unit with the storage device (50). Breathing assistance device (1) according to claim 9, in which the acoustic attenuation member (46) takes the form of a cylinder, the accumulation device (50) being formed radially around the acoustic attenuation device (46). A breathing aid device (1) according to claim 10 in combination with claim 2, wherein a volume of one of the two chambers (106, 108) forms half a volume of the storage device (50) , the other chamber (106, 108) forming the other half-volume of the storage device (50). Breathing assistance device (1) according to claim 10, in which the accumulation device (50) comprises a duct (136) aeraulically connecting the acoustic attenuation member (46) downstream of the circuit of inspiration (16), the duct (136) being arranged in a spiral around the acoustic attenuation member (46).