GR1010417B - Smart inhalation mask for medical gas cylinders - Google Patents

Abstract

The invention relates to a smart inhalation mask practicable for medical gas cylinders (1), which mask has the ability to calculate the amount of gas at any time, using the Internet of Things. It consists of the main body of the mask (4) which encloses a fitting system (5) and a smart monitoring system (6) inside it; it is easily attached to a portable disposable medical gas cylinder (3) and works with two operating modes (inhalation mode and measurement mode). The measurement and processing data are transferred, in real time and via a wireless network (23), from the intelligent monitoring system to the imaging system (34).

Description

Smart inhalation mask for medical gas cylinders

Description

The present invention relates to the development and manufacture of a smart inhalation mask for medical bottles. More specifically, the present invention refers to the development and manufacture of a smart mask for inhalation use, providing - at any time - the possibility of calculating the amount of gas, using the internet of things.

It is an object of the present invention to solve the disadvantages of the prior art in providing a respirator mask for disposable medical gas cylinders which releases oxygen. The disadvantage of the already existing inhalation masks is that they are - until now - only used as simple mouthpieces. This means that there is no information during inhalation regarding excess gas in the cylinder, as for example excess medical oxygen. A disposable portable medical oxygen cylinder, without other propellant gases, preservatives or fragrances, is an aid and a source of energy for people with physical or mental fatigue or with a hectic pace of life and stress. It is also a help to people who face asthma problems, to smokers, to the elderly or even to those who come from allergic shock, etc. It is recommended for use before or after any intense sports activity, as it increases the content of oxygen in the blood.

Smart masks are known in the art and are described both in the inventions US20 17002823 1 , WO20 17069756А 1 , US20 180256926, US5764203A and in the applications from the company Baiid Auto Technologies, which has released such masks in the market with Internet of Things capability and level of protection against Covid-19 by monitoring oxygen levels. However, these inventions relate to smart masks for calculating the amount of pollutant absorption, smart respiratory face masks for recording positive and negative pressure (and therefore any leaks), smart masks suitable for monitoring the quality of the air the user breathes or smart respiratory masks with display unit respectively. This implies that there is no prior art smart inhalation mask that - using the internet of things - will record, accurately calculate and display the amount of gas in a medical gas cylinder, such as oxygen for example.

The present invention proposes the development of a smart inhaler mask by constructing an assembly system inside it of suitably adapted components that attach the integration of a smart monitoring system and allow integration into the medical bottle. This innovation can be adapted to various types of inhalation masks, such as USD610250S, US7255106B2, US6158428A and other types of inhalation masks for portable medical disposable bottles already on the market. The superiority of the design of the smart inhalation mask of the present invention lies in the fact that it incorporates a smart monitoring system inside it, which automatically calculates the amount of gas in the medical bottle. In contrast to other systems, such as manometers and flowmeters, which are attached to the outside of the bottle and simply record the bottle pressure. The fact that the intelligent monitoring system can be located inside the mask, on the one hand, makes it easy to adapt and portable, as it has a low weight, on the other hand, it allows the direct visualization of the recording and processing data via a wireless network in a mobile phone in real time, on a computer and on any display and interface device, through an easy-to-use specialized web application. In this way, it will be able to transfer the data both to the attending physician and to the medical gas cylinder company, if the user so wishes, in order to ensure the timely supply of the medical cylinders. The smart inhaler mask for medical bottles has two working modes: the inhalation working mode and the measuring working mode. The user can choose which of the two operating modes he wants, adjusting the gas flow with simple movements.

The drawings accompanying the invention briefly illustrate the following:

Drawing 1 is a diagram showing a way of making a smart inhalation mask for medical gas cylinders (1), which is composed of the smart inhalation mask (2) and the medical gas cylinder (3).

Figure 2 graphically depicts the assembly of the smart inhalation mask (2), which consists of the main body of the mask (4), an assembly system (5) and a smart monitoring system (6).

Figure 3 shows the main body of the mask (4), which consists of the mouthpiece (7), the gas separation surface (8), the neck of the mask (9) having an outflow pressure projection (11) and two holes, the fitting hole (12) and the hole (13), and the attachment interface of the mask to the gas cylinder (10)

Figure 4 graphically illustrates the assembly system (5), which consists of an expansion piston (15) connected to a T-type nozzle (14) via a sealing ring (16).

Figure 5 graphically illustrates the intelligent monitoring system (6), which consists of a very low-power microcontroller (18) powered by a battery (19) and actuated by a button (20) via a pressure piston (24) and located interfaced with a unit of a pressure and temperature sensor (17), controlled by firmware (21) and equipped with a storage memory (22) and a wireless network (23).

Figure 6 is a detailed illustration of the neck (9), which includes the elements of the assembly system (5) in connection with the bottle discharge nozzle (25) and with elements of the intelligent monitoring system (6) and the element of the neck consisting of a gas outlet duct (26) in contact with the gas separation surface (8).

Figure 7A is an isometric sectional view of the smart inhaler mask (2) in the inhalation mode. Figure 7B is a cross-sectional isometric view of the smart inhaler mask (2) in the measurement mode. Figure 7C illustrates the isometric view of the T-type nozzle (14). Figure 7D illustrates the isometric view of the expansion piston (15). Figure 7E shows an isometric section of the smart inhaler mask for medical gas cylinders (1) which is wirelessly interfaced to a computing and imaging system (34).

The invention is described in detail below, by way of a non-limiting example and with reference to the accompanying drawings, which show one embodiment of the subject matter of the present invention.

The present non-limiting example of the invention proposes the development and manufacture of a smart inhaler mask for medical gas cylinders (1) as shown in drawing 1, which consists of the smart inhaler mask (2) and the medical gas cylinder (3). The smart inhalation mask (2) in drawing 2 consists of a mask (4) made of thermoplastic materials such as polylactic acid, using 3D printing technology such as Melt Filament Deposition. The mask (2) depending on the application can also be manufactured with other prosthetic manufacturing technologies such as stereolithography, selective laser fusion and selective laser melting. The mask is printed with a high neck (9), so as to attach the assembly system (5) and the smart tracking system (6) inside it, and provide comfort in the grip and use.

In drawing 3 the 3D printed mask (4) shows the parts of which it consists such as the mouthpiece (7), the gas separation surface (8) that separates the gas passage from the neck part (9) to the mouthpiece (7) ). The separation surface (8) is designed perpendicular to the gas flow, and the holes (27) it has have a specific diameter and pattern to allow a specific and controlled amount of gas to escape per unit time. The mouthpiece (7) has been constructed in such a way as to provide comfort to the user, and to touch his face smoothly, parallel to his body and not raised or tilted. Its design allows the outflow and removal of excess oxygen and carbon dioxide from the side faces after each exhalation, without the user necessarily needing to remove the mouthpiece from their face. The neck of the mask (9) has an appropriately designed attachment interface with the respective cross-section of the gas cylinder (10) so that it optimally snaps into it. The neck also has an outlet pressure protrusion (11), which is the point the user presses to release the gas from the bottle (3). The projection (11) has a shaping curve and utilizes the elasticity of the material for its operation, as it returns to its original position after being pressed. Also, a hole (12) is designed in the neck so that the expansion piston (15) of the coupling system (5) can exit and a coupling hole (13) from which a pressure piston (24) exits which with the pressing it activates the button (20) of the microcontroller (18) to start the measurement.

Figure 4 shows the components of the assembly system (5), which are an expansion piston (15) which can move inside a T-type nozzle (14) and is assembled by means of a sealing ring (16). The dimensions for the sealing ring (15) were chosen to precisely abut the special configuration of the expansion piston (15), and to adequately seal its connection to the T-nozzle (14). The T-type piston and nozzle can be easily and precisely manufactured with additive manufacturing technologies such as selective laser fusion and selective laser melting. The piston could be replaced by a screw, which by threading the T-nozzle (14) would have the possibility of assembly.

The expansion piston (15) is cylindrical in cross-section as shown in Figure 7D, with its recessed configuration (33) designed to precisely fit the large sealing ring (16), while having a constant cross-section longitudinally to fit inside of the T-type nozzle (14). The expansion piston (15) is of sufficient length that when pushed inward, it blocks the flow of oxygen from the outlet of the cylinder (32) to the mouthpiece (7) and allows flow only to the pressure sensor (17), setting the device in the measuring mode, while correspondingly in the inhaling mode it allows the flow of oxygen from the bottle discharge nozzle (25) to the mouthpiece (7) through the inlet (29), when the expansion piston (15) is not pushed inward. The mounting location of the large sealing ring (16) is curved to avoid wear, while for the connection of the recessed configuration there is a chamfer instead of a sharp change in cross-section, which allows smooth movement of the expansion piston (15). The diameter tolerance of the large cross-section is such that the expansion piston (15) moves easily into the T-nozzle (14).

Figure 5 graphically illustrates the intelligent monitoring system (6), which consists of a very low-power microcontroller (18) powered by a battery (19) and activated by a button (20) and interfaced with a sensor unit pressure and temperature (17), is controlled by firmware (21) and has a storage memory (22) and a wireless network (23).

Figure 6 is a detailed illustration of the neck (9) of the smart inhalation mask (2), which includes the components of the assembly system (5) in connection with the outlet nozzle of the bottle (25) and with components of the smart monitoring system ( 6) and the neck element consisting of a gas outlet duct (26) in contact with the gas separation surface (8). The T-type nozzle (14) is designed with three outlets and one inlet as shown in drawing 7C, of which the inlet (29) is located at its bottom, with a diameter such that it fits precisely into the integral discharge nozzle of the gas cylinder (25) as shown in scheme 7E. The outlet (31) is a socket for the expansion piston (15), with a diameter such that the expansion piston (15) is attached internally, and with a tolerance to move inside the T-type nozzle (14), without allowing gas losses. The outlet (32) is the one that leads to the gas outlet duct (26) which ends at the separation surface (8). The transfer of the gas from the T-type nozzle to the holes (28) of the separation surface (8) is possible by the gas outlet pipe (26), which is connected to its outlet (32) and ends in one of the holes, while the remaining holes are constructed to vent gas losses resulting from the base flow. The gas outlet duct (26) forms an integral part of the neck of the mask (9) connecting the gas separation surface (8) and the upper part of the T-nozzle (14).

The outlet (30) located opposite the socket of the expansion piston (15), leads to the pressure sensor (17) of the intelligent monitoring system (6), which can be used to monitor pressure changes in a gas. The diameter of the outlet (30) is sized to fit the pressure sensor (17).

Finally, at the outlet (32) of the T-nozzle (14) a curved configuration has been designed to accurately position the gas outlet duct (26) so that when the outlet pressure projection (11) pushes the T-nozzle (14) down to allow the gas to flow from the outlet (32) to the outlet duct (26) without loss, as shown in drawing 7E.

When the user wishes to inhale, he holds the bottle (3) with one hand and places the mouthpiece (7) on his face using the other hand to press the pressure protrusion (11), i.e. the special curved configuration on the side of the neck (9) of the inhaler with his thumb. When the pressure projection (11) is pressed down, the gas exits the container due to the negative pressure difference. Initially, the gas passes through the built-in discharge nozzle of the bottle (25), is guided to the T-type nozzle (14) and exits through its upper outlet (32), which is connected to the duct (26) of the mask (2), which ends at the separation surface (8), a surface with 8 holes of 2 mm diameter at the top of the smart mask (2), as shown in the section of the smart mask (2) in drawing 7A. The gas path is completely sealed, with the help of sealing rings (16) and (27).

When the user wishes to see the contents of the oxygen cylinder, he presses the expansion piston (15) with his finger to close the gas outlet (26). The expansion piston (15), enclosed within the outlet (31) of the T-nozzle, when pushed inward closes the upper outlet (32) of the T-nozzle (14) leading to the intake ports (28) located on the surface separation (8), as shown in drawing 7B. In this way the gas is confined between the inlet (29) of the T-type nozzle, and the outlet (30) which ends up in a unit of a pressure and temperature sensor (17) of the intelligent monitoring system (6). The very low power microcontroller (18) receives pressure and temperature readings from the module (17) and processes the gas content into a percentage with the help of firmware (21).

The ambient pressure and temperature readings taken by the sensor unit (17) when the expansion piston (15) is free as well as the gas pressure and temperature readings taken when the expansion piston (15) is pressed by the user are stored in the memory (22) and through the wireless network (23) it has, the data is transferred to a calculation and display system (34).

The calculation and display system (34) can be calibrated using a full cylinder of medical gas (3). The user will be able to choose to delete the existing calibration so that with the application of a new full cylinder the new maximum pressure will be re-recorded.

Assuming 100% fullness at the maximum measured pressure and 0% at the last ambient pressure measurement, using a matching table method for every 1% difference, the percentage of the current cylinder fullness through measurement can be displayed on the calculation and display system (34) of this current pressure. By applying temperature compensation to the parallel temperature readings taken from the sensor unit (17) the pressure readings have excellent accuracy which results in the also excellent accuracy of the percent full calculation despite the temperature conditions of taking the pressure readings.

Claims (3)

Smart inhalation mask for medical gas cylinders CLAIMS 1. Smart inhalation mask for medical gas cylinders (1) consisting of a smart inhalation mask (2) with a mouthpiece (7) carrying a gas outlet pipe (26) and holes (28), in which mask a fitting system (5) is incorporated. characterized in that it contains an expansion piston (15) in connection with a T-type nozzle (14), whose inlet (29) allows the passage of the quantity of gas from a medical gas cylinder (3) on the one hand, pressing the pressure projection (11), on the one hand measuring this quantity at its output (30), attaching it to an intelligent monitoring system (6), which contains a unit of a pressure and temperature sensor (17) and firmware (21). 2. Smart inhaler mask for medical gas cylinders (1) according to claim 1, characterized in that it uses a smart monitoring system (6) inside the smart inhaler mask (2), which consists of a very low power microcontroller ( 18) powered by a battery (19) and activated by a button (20) via a pressure piston (24) and interfaced with a unit of a pressure and temperature sensor (17), controlled by firmware (21) and having a memory storage (22) and wireless network (23). 3. Smart inhalation mask for medical gas cylinders (1), according to claim 1, characterized in that it has two operating states: a) the inhalation mode in which the user inhales holding the bottle (3) with one hand and places the mouthpiece (7) on his face using the other hand to press the pressure protrusion (1 1) with the thumb down so that the gas exits the container due to the negative pressure difference driven through the T-type nozzle (14), b) and the measurement mode in which the user presses the expansion piston with his finger ( 15) so as to block the gas outlet duct (26) leading to the inhalation holes (28) restricting the gas between the inlet (29) of the T-nozzle (14) and the outlet (30) which leads to a unit of a pressure sensor and temperature (17) of the intelligent monitoring system (6) which processes the gas content in percentage with the help of firmware (21).