FR3118585A1 - Dual Oxygen Inlet Medical Ventilator and Common Oxygen Pressure Sensor - Google Patents

Abstract

Title of the invention Medical ventilator with two oxygen inlets and common oxygen pressure sensor The invention relates to a medical ventilator (50) comprising an O2 supply circuit (1) with circuit sections (12, 13) comprising an HP oxygen inlet (2) for receiving high pressure (HP) gas and a LP oxygen inlet (3) for receiving low pressure (LP) gas fluidly connecting to each other another (14) to form a common oxygen supply line (15). A pressure sensor (16) performs gas pressure measurements within one of these circuit sections (12, 13) or the common line (15). Part of the common line (15) and circuit sections (12, 13) is arranged in a block (10) arranged in the medical ventilator (50). The block (10) further comprises an internal chamber (11) in fluid communication with the common line (15), or one of the circuit sections (12, 13), and in which the pressure sensor (16 ) so as to measure the gas pressure in the part of the common line (15) or of the circuit sections (12, 13) passing through the block (10). Figure of the abstract: Fig. 4

Description

Dual Oxygen Inlet Medical Ventilator and Common Oxygen Pressure Sensor

The invention relates to a medical ventilator comprising two oxygen inlets for O ₂ HP and LP supplying circuit sections which are fluidly connected to each other to form a common oxygen supply line arranged in a block, called an "oxygen block", arranged in the medical ventilator, the block further comprising an internal chamber in fluid communication with the common line and in which a pressure sensor is fitted to measure the pressure of the gas.

As part of their respiratory therapy, some patients need to be ventilated with oxygen-enriched air, i.e. air containing an oxygen content greater than 21% vol. This is particularly the case for certain patients with respiratory pathologies, such as Covid-19 for example.

To do this, medical ventilators, that is to say respiratory assistance devices, often include, in addition to their internal air supply circuit, an internal O ₂ supply circuit making it possible to bring additional oxygen in order to be able to carry out an enrichment of the air in O ₂ and thus to obtain the desired air/oxygen mixture.

Since oxygen can come from different sources, and therefore be at different pressures from one source to another, it is necessary for the O ₂ supply circuit of the medical ventilator to include different O ₂ inlets dedicated to the different oxygen sources, typically two oxygen inlets, one of which is "high pressure" and the other is "low pressure", as illustrated in .

A pressure sensor located on a common line in fluid communication with the "high pressure" and "low pressure" inlets is used to measure the pressure of the circulating oxygen, as shown in And .

However, this type of arrangement according to the prior art poses several problems, in particular of integration into medical ventilators.

First, the choice of the pressure sensor is a first integration constraint. Indeed, the sensor is a component to be soldered on an electronic card and it is therefore the electronic card which supports the sensor that must be successfully arranged in the fan so that the pressure measurement can be made. This is not always easy due to constraints of size and fixing of the card in the fan.

In addition, the card must generally be attached directly to the common line. This creates layout and maintenance constraints because the sensor must be easily replaced without the risk of damaging the electronic card that carries it when the sensor has to be changed. This is not always possible or easy due to the small internal size of some medical ventilators.

Finally, since the gas pressure arriving via the HP inlet can reach 10 bar, the contact surface between the card carrying the pressure sensor and the common O ₂ supply line must be able to withstand this pressure. This currently makes it necessary to use robust sensors, and therefore of large dimensions, which again generate constraints in particular in terms of size and installation in small or cramped spaces.

The problem is therefore to allow integration of the O ₂ pressure sensor monitoring the oxygen circuit of a medical ventilator with two O ₂ inputs, ie an HP input and a LP input, not posing all or part of the aforementioned constraints, that is to say an easy and efficient integration of the sensor, in particular in medical ventilators with constraints of available space.

The solution of the invention then relates to a medical ventilator comprising:

a) an O ₂ supply circuit comprising:

• a first circuit section comprising a first oxygen inlet configured to receive gas at high pressure (HP), that is to say an "HP inlet",
• a second circuit section comprising a second oxygen inlet configured to receive gas at low pressure (LP), that is to say a "LP inlet",

the first and second circuit sections being fluidly connected to each other to form a common oxygen supply line, and

b) a pressure sensor arranged to perform gas pressure measurements within one of said first circuit section, second circuit section or common oxygen supply line,

characterized in that:

• at least part of the common oxygen supply line, of the first circuit section and of the second circuit section is arranged in a block arranged in the medical ventilator, called “oxygen block”,
• the block further comprises an internal chamber in fluid communication with at least a common line part, of the first circuit section or of the second circuit section arranged in the block and
• the pressure sensor is arranged in said internal chamber so as to measure the pressure of the gas in the part of the common line, of the first circuit section or of the second circuit section passing through the block.

According to the embodiment considered, the medical ventilator of the invention may comprise one or more of the following characteristics:

• the block is or comprises a compact mass, for example made of polymer, metal or metal alloy, preferably formed from a single piece or unique piece, that is to say made in one piece, in which the different sections, chambers, etc., for example by machining, by drilling, by molding or any other technique.
• the block is extractable, i.e. it can be dismantled and extracted from the fan.
• the extractable block is fixed in the fan by screwing.
• the block is formed of polymer, in particular thermoplastic, for example of POM-C plastic.

alternatively, the block is formed of metal or a metal alloy.

• the block is formed from a single piece that is machined, injected, stamped or obtained by another manufacturing process.
• the block is fixed in an extractable manner in the casing of the fan.
• the block has a prismatic shape or any other suitable shape.
• the pressure sensor arranged to perform gas pressure measurements within the first circuit section conveying the O ₂ HP.
• alternatively, the pressure sensor arranged to perform gas pressure measurements within the second circuit section conveying the O ₂ BP.
• alternatively, the pressure sensor arranged to perform gas pressure measurements within the common oxygen supply line, preferably downstream of gas non-return means.
• preferentially, the pressure sensor arranged to perform gas pressure measurements within the second circuit section, preferably downstream of gas non-return means.
• the second circuit section comprises gas non-return means arranged between the second oxygen inlet and the fluidic connection site to the common line.
• the internal chamber is in fluid communication with the second circuit section between said gas non-return means and the common line, ie the downstream part of the second section, that is to say between said gas non-return means of said second circuit section bringing the O ₂ BP and the connection site where the first and second circuit sections are fluidly connected to each other and to the common line.
• the internal chamber is in fluid communication with at least a common line part, of the first circuit section or of the second circuit section via a junction channel, preferably with the downstream part of the second circuit section.
• the internal chamber is in fluid communication with at least a part of the second circuit section arranged in the block, that is to say the O ₂ BP supply section, preferably with the downstream part of said second section.
• the internal chamber is in fluid communication, via the junction channel, with at least part of the second circuit section arranged in the block.
• the pressure sensor includes a sensor body and a pressure tap.
• the sensor body is located in the internal chamber of the block.
• the pressure tap is located in the junction channel.
• the junction channel is laid in the block.
• the pressure sensor is arranged on an electronic card.
• the electronic card is secured to the block, preferably fixed outside the internal chamber.
• the electronic card is fixed to the outer peripheral wall of the block, preferably it is fixed by screwing or the like.
• fluid sealing means are arranged between the pressure sensor and the block so as to ensure fluid sealing between said pressure sensor and said block, preferably between the junction channel and the internal chamber.
• the inner chamber is at atmospheric pressure (i.e. 1 atm).
• the internal chamber leads to the outside of the block via an opening.
• the internal chamber comprises an opening emerging outside the block and the electronic card covers said opening, i.e. the electronic card forms a cover closing said opening.
• additional fluidic sealing means are arranged between the electronic card and the block.
• the first and/or second circuit sections comprise gas non-return means, preferably one or more non-return valves, so as to prevent in particular the HP oxygen rising towards the LP inlet.
• the first and/or second circuit sections comprise filtration means, preferably one or more filters, for example of the HEPA type, to stop the impurities or pollutants likely to be present in the first and/or second circuit section(s) circuit and/or in the oxygen flow(s), in particular microorganisms (bacteria, pollens, viruses, etc.), dust and other particles, etc.
• the HP inlet includes an HP oxygen inlet port.
• the LP inlet includes a LP oxygen inlet port.
• the common line includes a solenoid valve and a flow sensor to regulate the flow of oxygen in the common line.
• the solenoid valve and the flow sensor are arranged on the common line downstream of the block.
• the first and/or second circuit sections and/or the common line comprises passages or conduits for gas or the like.
• fluidic connection means, arranged on the ventilator at the level of the HP and LP oxygen inlets, allow the fluidic connection of HP and LP oxygen sources, respectively, to said fan so as to supply said HP and LP oxygen inlets with HP and LP oxygen from said HP and LP oxygen sources.
• the fluid connection means comprise fluid connections or connectors or the like.
• the fluid connection means are traversed by upstream parts of said first and second circuit sections.
• the fluid connection means comprise fluid connections or connectors or the like carrying the first and second oxygen inlets, i.e. the HP and LP oxygen inlets.
• it comprises a micro-blower configured to supply air or an air/oxygen mixture, the oxygen coming from the O ₂ supply circuit.
• the O ₂ supply circuit supplies the micro-blower with oxygen, the air/oxygen mixture being produced upstream or in the micro-blower.
• alternatively, the O ₂ supply circuit is connected downstream of the outlet of the micro-blower to produce the air/oxygen mixture downstream of the micro-blower.
• the micro-blower comprises a volute comprising an internal compartment with an impeller, said impeller being driven in rotation by an electric motor.
• the electric motor is enclosed in a casing.
• the volute surmounts the motor housing.
• it comprises control means configured to control the micro-blower.
• the control means comprise at least one electronic card with microprocessor(s), in particular with a microcontroller.
• the flow and/or pressure sensors are electrically connected to the control means to provide them with the flow and/or pressure measurements that they operate.
• the common circuit solenoid valve is controlled by the control means.

The invention also relates to an installation for supplying an air/oxygen mixture to a patient comprising:

• a medical ventilator according to one of the preceding claims and
• a high pressure oxygen source fluidly connected to the first oxygen inlet configured to receive high pressure gas (i.e. > 2 bar), and/or
• a low pressure oxygen source fluidly connected to the second oxygen inlet configured to receive low pressure gas (i.e. < 1.5 bar).

Depending on the embodiment considered, the installation of the invention may include one or more of the following characteristics:

• the BP oxygen source is an oxygen concentrator.
• the HP oxygen source is a gas pipeline, including a hospital network, or a pressurized gas container, such as a gas cylinder.

The invention will now be better understood thanks to the following detailed description, given by way of illustration but not limitation, with reference to the appended figures, including:

diagrams an O ₂ supply circuit with two oxygen inlets of a medical ventilator according to the prior art.

schematizes the regulation part of the O ₂ supply circuit of .

is a schematic external side view of one embodiment of an oxygen pressure sensor oxygen block fitted to a medical ventilator according to the present invention.

is a cross-sectional schematic view of the oxygen block of the .

is a schematic sectional view of a first embodiment of the seal between the pressure sensor and the oxygen block of the .

is a schematic sectional view of a second embodiment of the seal between the pressure sensor and the oxygen block of the .

a schematic sectional view of a third embodiment of the seal between the pressure sensor and the oxygen block of the .

schematizes a medical ventilator according to the invention integrating the oxygen block with oxygen pressure sensor of the And .

is a cross-sectional diagram of the oxygen block fitted to the ventilator of according to the invention.

is another cross-sectional diagram of the oxygen block fitted to the ventilator of according to the invention.

diagrams an O ₂ supply circuit 1 with two oxygen inlets 2, 3 of a medical ventilator 50 according to the prior art. This O2 supply circuit 1 conventionally comprises two oxygen inlets 2, 3, namely:

- a first inlet 2 called "high pressure" or "HP inlet" intended to receive oxygen under pressure or O ₂ "HP" coming from a source of oxygen under pressure (not shown) coming to be connected to it fluidically , typically gas cylinders or an oxygen pipe, such as a network of pipes arranged in a hospital building or the like. Typically, the pressure of oxygen "HP" can be between approximately 2.8 and 6 bars

- a second inlet 3 called "low pressure" or "BP inlet" intended to receive oxygen at low pressure or O ₂ "BP" coming from a low pressure oxygen source (not shown) coming to be connected thereto fluidically, such as an oxygen concentrator producing oxygen by separation of ambient air by means of a molecular sieve, for example zeolite beads. Typically, the oxygen pressure "BP" does not exceed approximately 1.5 bar in the absence of flow and decreases in the presence of flow, typically it becomes less than 1.5 bar, and even generally less than 1 bar, for example the order of 500 mbar, with flow. In all cases, the pressure of O ₂ BP is lower than that of O ₂ HP.

These HP and LP inlets 2, 3 supply circuit sections 12, 13 which have just been fluidically connected to each other (at 14) to form a common line 15, ie a single line, for supplying oxygen thus forming the internal O ₂ supply circuit 1 of the fan 50.

It is usual to arrange on the common oxygen supply line 15, a pressure sensor 16 which makes it possible to know the oxygen pressure in the common line and also to monitor the source of O ₂ given that the pressure measurement provides information on the state of the O ₂ source. Thus, when the source is an O ₂ HP network, in the event of a pressure problem that is too high (ie > 10 bar for example) or on the contrary, too low (< 2.8 bar for example), pressure monitoring makes it possible to highlight this problem and alert the user, or even adapt the fan regulations accordingly. The pressure sensor 16 is generally arranged on an electronic card.

The circuit sections 12, 13 further each comprise:

• filtration means 17, typically a filter, for example a HEPA filter, making it possible to stop any pollutants or impurities (e.g. dust, microorganisms, particles, etc.) that may be present in the gas so as to prevent them from contaminating or dirty the pneumatic path located downstream, and
• non-return means 18 of the non-return valve type making it possible to prevent gas rising towards the two inlets 2, 3, in particular the passage of HP gas towards the LP inlet.

schematizes the regulation part of the O ₂ supply circuit 1 of , that is to say elements arranged on the common line 15 making it possible to operate a regulation of the fraction of oxygen in the air or FiO ₂ , therefore of the O ₂ concentration of the oxygen-enriched air produced in the fan 50.

As can be seen, downstream of the O ₂ pressure sensor 16, there is usually, arranged on the common line 15, a solenoid valve or EV 19 and a flow sensor 20 which make it possible to regulate the flow of O ₂ in order to to obtain the desired FiO ₂ , for example an FiO ₂ set by a doctor on the ventilator 50. An additional filter ₂₁ can also be found there. depending on the command sent to the EV 19 by the fan control means 50 and the O ₂ pressure measured upstream of the EV 19 by the sensor 16. The O ₂ flow thus obtained can then be used in the control logics of the fan 50 so as to have a more precise and more stable regulation vis-à-vis the O ₂ pressure changes likely to occur.

This type of arrangement according to the prior art poses several problems related to the pressure sensor 16 and its integration in the fan 50, in particular due to the fact that it is carried by an electronic card.

is a schematic external side view of an embodiment of the block 10, also called "oxygen block", with an oxygen pressure sensor 16 equipping a medical ventilator 50 according to the present invention, such as that illustrated in , while is a schematic sectional view of this block 10. This block 10 10 is absent from conventional fans of And .

This block 10 is here a compact mass, for example of polymer, preferably formed in one piece, in which the various sections, chambers, etc. are arranged, for example by machining, by drilling, by molding or any other technique, as explained below. To allow the operation of the fan 50, the block comprises or may comprise operating components or elements such as the gas inlets/inlets and the gas discharge/outlet without leakage, one or more non-return valves, one or more solenoid valves, filtration and measurement instrumentation..., as detailed below.

As can be seen, in the embodiment according to the invention, in particular on the And , a part of the common oxygen supply line 15, as well as the first and second circuit sections 12, 13 are arranged in a block 10 arranged in the medical ventilator 50, such as a thermoplastic part, for example polyacetaltel , such as POM-C. The block 10 is advantageously removable, that is to say it is detachably fixed in the fan 50, for example by means of screws 58 (cf. or the like.

In other words, part of the common oxygen supply line 15 and the first and second circuit sections 12, 13, that is to say the O ₂ HP 12 and LP 13 sections, respectively, form gas passages arranged in block 10.

Furthermore, the common oxygen supply line 15 also comprises, as in the , a flow sensor 20 arranged downstream of block 10.

As illustrated in , And , an internal chamber 11, ie a compartment, is arranged in the volume of the block 10 and is in fluid communication with, in the proposed embodiment, the part of the second section 13 arranged in the block 10, that is to say say the oxygen supply section BP, here via a junction channel 8 connecting the internal chamber 11 to the second section 13. The junction channel 8 is therefore subjected to the same gas pressure as the second section 13, downstream of the gas non-return means 18 (cf. ), considering the direction of oxygen flow, typically a non-return valve.

The pressure sensor 16 is arranged in the internal chamber 11 so as to be able to measure the pressure of the gas coming from the second section 13 of oxygen supply BP arranged in the block 10. To this end, the pressure sensor 16 comprises a sensor body 6A and a pressure tap 6B of which the sensor body 6A is located in the internal chamber 11 and the pressure tap 6B is located in the junction channel 8 communicating with the second section 13 of oxygen supply BP , downstream of non-return means 18 arranged like those shown in . The junction channel 8 is at the same pressure as that prevailing in the second section 13 for supplying oxygen BP.

It should however be emphasized that the downstream part 13B of the second section 13 of the oxygen supply BP, which is located downstream of the non-return means 18, is at the same pressure as the downstream part 12B of the first section 12, in downstream of the non-return means 18, such as another non-return valve, arranged downstream of the first oxygen inlet 2, as illustrated in And , and that the upstream part 15A of the common line 15 in the regions located after the connection site 14 of the downstream parts 12B, 13B of the first and second sections 12, 13 and of the common line 15 within the block 10. Therefore , the junction channel 8 can be connected to it indifferently to measure the oxygen pressure therein.

Furthermore, the upstream part 12A of the first HP oxygen supply section 12 and the upstream part 13A of the second LP oxygen supply section 13 comprise fluid connection means 28A, 28B to one of the oxygen sources HP and BP, respectively. Said fluidic connection means 28A, 28B are fittings, fluidic connectors or the like. For example, the fluidic connection means 28A carrying the HP 2 inlet orifice can comprise a connector with a movable internal valve, while the fluidic connection means 28B carrying the LP 3 inlet orifice can comprise a connector of the type "olive", as illustrated in And .

The internal chamber 11 of block 10 is itself at atmospheric pressure. The same applies to the part of the sensor 16 forming the sensor body 6A. Fluid sealing means 5, such as O-rings or the like, are arranged between the pressure sensor 16 and the block 10 so as to ensure fluid sealing between the pressure sensor 16 and the block 10, and therefore also between the channel junction 8 and the internal chamber 11, which ensures that the internal chamber 11 remains at atmospheric pressure.

To schematize several possible arrangements of fluidic sealing means 5 between pressure sensor 16 and block 10, namely:

• Axial seal (or in cover) with O-ring in groove 22 arranged at the entrance of the junction channel 8, on the side of the internal chamber 11, on [Fig. 5],
• Radial seal with seal located in an annular groove 23 arranged in the junction channel 8 on [Fig. 6], and
• Mixed seal with seal 5 in a conical groove 24 at the entrance to the junction channel 8, on [Fig. 7].

Moreover, as illustrated in And , the internal chamber 11 opens outside the block 10 via an opening 4, that is to say that it is open towards the outside of the block 10, via the opening 4.

As can be seen, the electronic card 9 is arranged so as to come to cover the opening 4, like a lid, being fixed via fixing screws or the like 25 to the outer peripheral wall 26 of the block 10, that is i.e. on its outer surface. This is advantageous because it allows easy disassembly and access to the sensor 16 and it also simplifies the mounting of the electronic card 9 in the fan 50.

In other words, the pressure sensor 16 is integrated into the internal chamber 11 of the block 10 and is in contact with the flow of O ₂ "under pressure" via the junction channel 8 in order to measure the oxygen pressure in the line common 15 passing through the block 10, while the electronic card carrying the sensor is screwed or similar directly to the block.

It is possible to provide additional sealing means 27, such as a seal or the like, between the electronic card 9 and the outer surface of the outer peripheral wall 26 of the block 10, as illustrated in And .

The electronic card 9 further comprises a bore, that is to say an orifice 7, putting the chamber 11 in fluid communication with the ambient atmosphere so as to balance the pressures and to have an internal chamber 11 at atmospheric pressure.

schematizes a medical ventilator 50 according to the invention integrating the block 10 within a shell or peripheral carcass 55.

Generally, such a ventilator 50 comprises a micro-blower 51, also called a turbine or compressor, for delivering a gas (arrow 57), such as air or oxygen-enriched air to a patient, means of control 52, such as an electronic card with a microprocessor, in particular to control the micro-blower 51 and the solenoid valve 19, to which the pressure 16 and flow rate 20 sensors, etc., are connected. Air enters the fan 50 via an air inlet 56 feeding an internal air passage bringing the air to the micro-blower 51.

The micro-blower 51 comprises a volute comprising an internal compartment including an impeller which is driven in rotation by an electric motor arranged in a casing. The volute tops the motor housing. The motor of the micro-blower 51 is controlled by the control means 52 to accelerate its rotations and thus deliver respiratory gas during the patient's inspiratory phases and, conversely, to slow down, i.e. decelerate/braking, during the phases patient expiratory.

The ventilator 50 also includes other elements of the oxygen circuit 1, such as those mentioned in connection with And , such as gas non-return means 18, preferably one or more non-return valves, and also filtration means 17, such as a filter, for example of the HEPA type, arranged on the first and second circuit sections 12, 13 bringing the HP and LP oxygen, as well as the solenoid valve 19 and the flow sensor 20 arranged on the common line 15, downstream of the block 10.

Power supply means, such as a connection to the mains or an internal battery, preferably rechargeable, supply the components of the fan requiring electrical energy to operate, in particular the electronic cards, the sensors, etc.

The gas outlet 54 of the medical ventilator 50 is connected to the patient via a patient circuit (not shown) with one or two branches, i.e. one or more gas lines, preferably flexible hoses, and an interface breathing apparatus, such as a respiratory mask, a tracheal intubation tube or the like.

In general, the fact of arranging the electronic card 9 and the pressure sensor 16 on the oxygen unit 10 according to the invention allows them to be easily integrated into the ventilator 50 and without negatively impacting the general bulk and allows elsewhere maintenance and assembly/disassembly of these elements, in particular of the sensor 16.

Claims (10)

Medical ventilator (50) comprising:

• an O ₂ supply circuit (1) comprising:

• a first circuit section (12) comprising a first oxygen inlet (2) configured to receive high pressure gas (HP),
• a second circuit section (13) comprising a second oxygen inlet (3) configured to receive gas at low pressure (LP),

the first and second circuit sections (12, 13) being fluidly connected to one another (14) to form a common oxygen supply line (15), and

• a pressure sensor (16) arranged to carry out gas pressure measurements within one of said first circuit section (12), second circuit section (13) or common oxygen supply line (15) ,

characterized in that:

• at least a part of the common line (15) for supplying oxygen, of the first circuit section (12) and of the second circuit section (13) is arranged in a block (10) arranged in the medical ventilator (50 ),
• the block (10) further comprises an internal chamber (11) in fluid communication with at least a common line part (15), of the first circuit section (12) or of the second circuit section (13) arranged in the block (10) and
• the pressure sensor (16) is arranged in said internal chamber (11) so as to measure the pressure of the gas in the part of the common line (15), of the first circuit section (12) or of the second circuit section ( 13) crossing the block (10).

Fan according to Claim 1, characterized in that the second circuit section (13) further comprises gas non-return means (18), the internal chamber (11) being in fluid communication with the second circuit section (13 ) between said non-return gas means (18) and the common line (15). Fan according to one of the preceding claims, characterized in that the internal chamber (11) is in fluid communication with at least a common line part (15), of the first circuit section (12) or of the second circuit section ( 13) via a junction channel (8). Fan according to one of the preceding claims, characterized in that the internal chamber (11) is in fluid communication with at least part of the second circuit section (13) arranged in the block (10), preferably via the junction (8). Fan according to one of Claims 3 or 4, characterized in that the pressure sensor (16) comprises a sensor body (6A) and a pressure tap (6B), the sensor body (6A) being located in the internal chamber (11) and the pressure tap (6B) being located in the junction channel (8). Fan according to one of the preceding claims, characterized in that the pressure sensor (16) is arranged on an electronic card (9), said electronic card (9) being secured to the block (10), preferably fixed (25) outside the inner chamber (11). Fan according to one of the preceding claims, characterized in that fluidic sealing means (5) are arranged between the pressure sensor (16) and the block (10) so as to ensure fluidic sealing between the said pressure sensor ( 16) and said block (10), preferably between the junction channel (8) and the internal chamber (11). Fan according to one of the preceding claims, characterized in that the internal chamber (11) opens outside the block (10) via an opening (4) and/or the internal chamber (11) is at atmospheric pressure. Fan according to one of the preceding claims, characterized in that the internal chamber (11) comprises an opening (4) emerging outside the block (10) and the electronic card (9) covers the said opening (4), preferably additional fluidic sealing means (27) are arranged between the electronic card (9) and the block (10). Installation for supplying an air/oxygen mixture to a patient comprising:

• a medical ventilator according to one of the preceding claims and
• a high pressure oxygen source fluidly connected to the first oxygen inlet (2) configured to receive high pressure gas (ie > 2 bar), and/or
• a low pressure oxygen source fluidly connected to the second oxygen inlet (2) configured to receive low pressure gas (ie <1.5 bar).