IT202000007876A1 - System for qualifying and testing tissue samples - Google Patents

Description

DESCRIPTION of the Industrial Invention entitled:? System to qualify and test fabric samples?

DESCRIPTION

The present invention relates to a system for qualifying and testing tissue samples.

The system includes means for generating a flow of nebulized liquid, configured to spray a certain quantity of liquid. of drops of liquid on the tissue sample and means of detecting the quantity? of liquid absorbed by the tissue sample.

? also present a unit? control configured to control the operation of the generation means and / or the detection means.

In particular, the present invention relates to the realization of an instrument for qualifying and testing fabrics to be used in the production of masks for personal protection.

Personal protective masks are generally used to protect the respiratory tract, in particular nose and mouth, of a user, from any droplets suspended in the environment, which could be a probable source of contamination.

To allow proper protection,? It is necessary that the fabric used does not allow the passage of these droplets, that is, it allows the droplets to be filtered, preventing the user from coming into contact with these droplets.

Furthermore, in order to prevent sick users from contaminating the environment around them, the masks must protect both at the exit and at the entrance, i.e. the fabric must guarantee a correct filtering action towards the user from and to the outside.

It is therefore evident that a correct procedure aimed at qualifying and classifying the tissue samples with which the masks are made, in order to evaluate their filtering power, is absolutely necessary. to avoid the proliferation of infections and diseases in a widespread manner.

At the moment a fabric water repellency analysis is carried out, evaluating how much a fabric does not absorb a liquid that is dropped on that fabric.

Furthermore, other methods and systems known to the state of the art provide for evaluating the absorption of the tissue, that is, in the event that a tissue is penetrated by a certain amount of water. of liquid, how much liquid is retained by the meshes of the fabric and how much is released.

The examinations that are carried out by the systems and methods known to the state of the art, however, do not provide for simulating the various possible conditions under which? subjected the fabric of a mask.

In fact, the simple dispensing of a liquid on the fabric of the mask does not truthfully simulate the impact that the droplets, in suspension or generated by the user wearing the mask, have on the fabric.

Is there therefore a need? not satisfied by the systems and methods known in the state of the art of realizing a system for qualifying and testing tissue samples that solves the above-mentioned disadvantages.

The present invention achieves the above purposes by providing a system as described above, in which the generation means comprise a liquid reservoir connected to a unit? dispensing, which includes means for regulating the quantity? dispensing liquid, dispensing time adjustment means and dispensing pressure adjustment means.

The presence of the unit? dispensing allows to obtain a system that allows to subject the tissue sample to the same conditions in which it will be found? once used as a face mask, in order to reproduce the emission of water droplets having the same characteristics as the user's breath, coughing or sneezing.

How will it turn out? evident from the illustration of some executive examples, the various adjustments can be made through the unit? control, configured to change the operating parameters of the various components of the unit? of dispensing.

The regulation of the delivery time, of the quantity? and pressure, allow you to change the size of the droplets and the speed? impact of the droplets with the fabric sample.

The various adjustment means are in fact configured to obtain droplet sizes lower than 10 micrometers, speed? of impact on the tissue between zero and about 50 m / s, in order to simulate a user's breath to sneezing.

Starting from the general concept described of the unit? dispensing devices and adjustment means, the system object of the present invention provides for various executive variants aimed not only at improving the components described, but also at presenting additional characteristics.

In fact, for the realization of templates, at least two fundamental requirements must be taken into account.

The first ? the one described, that is the capacity? droplet absorption and filter function.

The masks must be positioned on the user's mouth, so they must necessarily have a high degree of breathability.

The concept of breathability? ? as opposed to the filtering function, as, generally, the filtering action limits the breathability? of fabrics.

The fabrics for the masks must provide both a high degree of droplet absorption and a high breathability.

The evaluation of a fabric can not? therefore regardless of the absorption analysis in combination with the breathability analysis.

For this reason, according to a preferred embodiment, the system object of the present invention provides means for detecting the transpiration of the fabric sample.

The means for detecting perspiration can be constituted by any component known in the state of the art, however? it is preferable to use an evaluation of the pressure difference acting on the two faces of the fabric sample.

To get such an assessment? It is necessary to use a closed environment, in which to arrange the tissue sample.

In fact, according to a possible embodiment, an insertion chamber for said tissue sample is provided, positioned on a plane configured to divide the insertion chamber into two parts, of which a delivery part and a detection part.

Does the disbursement part communicate with the said unit? of dispensing.

In combination with this configuration, the transpiration detection means can comprise a device for regulating the pressure inside the insertion chamber and at least a first pressure sensor communicating with the dispensing part and at least a second pressure sensor communicating with the detection part.

The system object of the present invention? therefore able to evaluate the respirability? o degree of comfort of the mask.

How will it turn out? pi? evident from the illustration of an executive example, this configuration allows to evaluate whether a fabric not only absorbs the droplets satisfactorily, but also if it allows a user to breathe adequately with the mask on.

It is also evident that the means for detecting perspiration can be used to evaluate the transpiration not only of a tissue sample, but also of the filters present in the masks.

This aspect gives the system object of the present invention the possibility? to qualify and test fabrics for the creation of masks, but also masks already? realized.

According to an embodiment, means of detecting the quantity? of liquid include a balance.

Advantageously, the unit? dispensing unit comprises an injection cylinder, which has a piston moved by an activation motor, inside an internal chamber in communication with opening / closing means of a dispensing valve.

The cylinder also comprises at least one pressure sensor for the liquid present in the internal chamber.

How will it turn out? evident from the illustration of some executive examples, the peculiar realization of the unit? dispensing allows you to control, for each dispensing, the volume of the dispensed liquid (thanks to the measurement of the piston stroke), dispensing time (activation of the electric motor to perform the piston stroke) and dispensing pressure (pressure sensor).

Also, it will come illustrated a dispensing valve with variable geometry, so that, in combination with the unit? delivery, size the droplets in the desired way, according to the needs? operational.

Given the advantages described above relating to the system for qualifying and testing tissue samples, the present invention also relates to a method for qualifying and testing tissue samples, which involves the following steps: a) dispensing a stream of nebulized liquid on said fabric sample,

b) detection of the quantity? of liquid absorbed by said tissue sample.

In particular, this method provides that step a) includes the following underpasses:

- regulation of the quantity? of dispensed liquid, - adjustment of the dispensing time,

- regulation of the supply pressure.

As anticipated, the different delivery parameters are adjusted in order to simulate all the possible conditions to which the masks are subjected when they are worn.

Advantageously, the method object of the present invention provides for a step c) for detecting the transpiration of the fabric sample.

Preferably step c) comprises the following underpasses:

- positioning of the tissue sample inside a chamber, in order to divide this chamber into two areas,

- pressure regulation in one of the two areas,

- pressure measurement inside the said two zones.

Finally, step b) provides for a first weighing of the tissue sample and of the liquid not retained by the tissue and a second weighing without the tissue sample.

The double weighing makes it possible to obtain an important verification of the liquid dispensed.

In fact, as anticipated, the system and the method object of the present invention allow to have a precise control of the liquid dispensed by the unit? of dispensing.

However, part of the liquid being dispensed can? get trapped inside the dispensing nozzle due to surface tensions.

The quantity trapped not? negligible, as the quantities? of liquid involved necessary to generate the droplets are minimal.

The double weighing therefore allows to discern between the actual quantity? of liquid dispensed, obtained from the first weighing, and the quantity? of absorbed liquid, obtained from the difference between the first weighing and the second weighing.

These and other features and advantages of the present invention will be more apparent. clearly from the following description of some executive examples illustrated in the attached drawings in which:

Figures 1 illustrates a principle diagram for functional blocks, of a possible embodiment of the system object of the present invention;

Figures 2a and 2b illustrate a possible embodiment of the unit? dispensing unit belonging to the system object of the present invention;

Figures 3a and 3b illustrate a possible embodiment of the nozzle belonging to the unit? adjustment of figures 2a and 2b.

It is specified that the figures attached to the present patent application illustrate some possible embodiments of the system system for qualifying and testing tissue samples object of the present invention, in order to better understand the advantages and characteristics described.

These embodiments are therefore to be understood purely for illustrative purposes and not limitative to the inventive concept of the present invention, that is to create a system for qualifying and testing fabrics for the production of masks, capable of optimally simulating the various conditions of use. of the mask.

In particular, figure 1 illustrates a basic diagram of the system object of the present invention.

The system comprises an insertion chamber 1, inside which the tissue sample 2 to be tested is positioned, on a support surface, so that the insertion chamber 1 is divided into two parts, a dispensing part 10 and a survey part 11.

The dispensing chamber 10? in communication with means for generating a flow of nebulized liquid, configured to spray a determined quantity? of liquid drops on the tissue sample 2.

Said generation means comprise a tank 31 for the liquid to be dispensed, a pump 32 and a unit? dispensing 33.

The pump 32 sucks the liquid from the tank 31 and inserts it inside the unit? dispensing unit 33 which delivers the nebulized liquid through one or more? nozzles 34.

A possible executive form of the unit? delivery 33 verr? described later with reference to Figures 2a to 3b, but this unit? dispensing unit 33 comprises means for adjusting the quantity? dispensing liquid, dispensing time adjustment means and dispensing pressure adjustment means.

Whenever the nozzle 34 sprays the nebulized liquid on the fabric sample 2,? possible to establish a priori the size of the droplets of the liquid, the quantity? of liquid, and the speed? impact that the droplets will have on the fabric sample 2.

It is evident that it is possible to simulate the various conditions of droplet emission in the case of normal breathing, wheezing, coughing, sneezing.

The operation and the various adjustments of the unit? delivery pump 33 and pump 32 can be managed by the unit? control 4 that, how will it come? described later, can? supervise the operation of all the system components illustrated in figure 1.

The unit? control 4 pu? present processor means for the execution of a logic program, such as software, loaded inside unit? of storage of the unit? control 4.

The execution of this logic program generates command signals to be sent to the pump 32 and to the unit? of dispensing 33, in such a way that in a determined period of time a certain quantity is disbursed? of fluid at a certain pressure.

The logic program contains within it all the values to set the operating parameters in order to modify the quantity, pressure and delivery time based on the conditions of interest, breath, cough, sneeze or a combination of these conditions.

To evaluate size and speed? of the droplets delivered, alternatively or in combination with the unit? supply 33,? It is possible to provide an optical system 5, consisting of a high definition camera and computer vision software configured to analyze in real time the images acquired by the camera relating to the droplets and extrapolate size, speed? and further data of interest.

Regardless of the system used, once dispensed, the nebulized liquid impacts on the tissue sample 2, at least a part of this liquid is absorbed by the tissue sample, while? possible that the remaining part passes through the fabric, according to the capacity? absorption of the fabric.

To establish the quantity? of absorbed liquid, the system object of the present invention provides suitable detection means.

According to the variant illustrated in the figure, these means consist of a balance 6, in particular a high-precision balance known in the state of the art.

According to a general concept, the balance 6 can? weigh the tissue sample 2 before dispensing and after dispensing, so that the difference between the two weighings corresponds to the quantity? of absorbed liquid.

However, to have a precise comparison between quantity? of liquid dispensed and quantity? of absorbed liquid,? It is preferable that, upon dispensing, the scale 6 is placed in contact with the tissue sample 2.

Once the liquid is dispensed, tissue sample 2 is lifted and the remaining weight on scale 6 will indicate? the quantity? of liquid not absorbed by the fabric.

Also, if you compare the weight difference between tissue sample 2 before and after dispensing the liquid, you can? get a feedback about the actual quantity? of liquid dispensed and the quantity? desired (ie assumed before dispensing and calculated by the control unit 4) of dispensed liquid.

The balance 6 will present? therefore specific means for lifting exclusively the sample of fabric 2, maintaining the plane on which it is? deposited the non-absorbed liquid, in contact with the balance 6.

What? as the unit? of delivery 33 also the scale 6 pu? be controlled by the unit? control 4.

Alternatively or in combination with scale 6,? It is possible to provide an optical system quite similar to system 5.

In this case for? the camera and the computer vision software are responsible for analyzing the images of the droplets which are not retained by the fabric sample 2, in order to establish their quantity, dimensions and weight.

As anticipated, the system object of the present invention also comprises means for detecting the transpiration of the fabric sample 2.

These means comprise a pressure regulation system inside the insertion chamber 1 and pressure measurement sensors.

With particular reference to Figure 1,? there is an aspirator 70 which creates a depression in the sensing part 11 and in the dispensing part 10.

The delivery part 10 has an opening 100 towards the outside, so that the aspirator 70 creates a forced motion of the air, which enters from the opening 100 in the direction indicated by the arrow A, passes through the fabric sample 2, exiting at the aspirator 70 in the direction indicated by arrow B.

In combination with the aspirator 70, two pressure sensors are provided, in particular a pressure sensor 71 for the dispensing part and a pressure sensor 72 for the sensing part.

It is evident that the difference between the two pressures recorded in the delivery part 10 and in the sensing part 11 is directly linked to the degree of transpiration. of the tissue under examination: minor? the difference in pressure, the greater it will be? the breathability? of the fabric.

Also in this case the unit? control 4 pu? supervise the operation of the aspirator 70 and the sensors 71 and 72.

The unit? control 4 potr? then automate the operation of the entire system.

In this way it will be? Is it possible to carry out the examination of absorption by the fabric and the examination of breathability? either alternatively or in combination.

In the same way it will be? possible to measure the breathability? of the tissue before and after dispensing the liquid.

Figures 2a to 3b illustrate a possible embodiment of the unit? of disbursement 33, in order to highlight how this unit? can adjust the delivery of the liquid in order to establish the size and quantity? of the droplets delivered and the speed? impact with the fabric.

In particular, the unit? delivery valve 33 comprises an injector cylinder 8, of which figure 2b shows a section along the longitudinal plane, connected to an activation motor 9, which moves the piston 81 which moves inside the chamber of the injector cylinder 8.

The injector cylinder 8 further comprises the nozzle 34 from which the liquid is dispensed.

In particular, the piston 81 is connected to the electric activation motor 9 according to any of the ways known to the state of the art.

The activation motor 9 has the task of moving the piston 81 and making it slide along the length of the cylinder 8.

The piston 81 also has the task, during its stroke, of measuring the volume of the liquid to be injected.

According to the direction of movement, the piston 81 can? suck the liquid coming from the supply duct 82 to bring it inside the chamber 83 of the cylinder 8, or can it? push the liquid towards the injector 34.

The unit? control 4 obviously supervises the operation of the engine 9, of the piston 81 and of the various components which will be described later.

In addition to measuring the volume of liquid, the piston 81 has the task of generating and maintaining the pressure in the cylinder 8.

The nozzle 34 comprises a poppet valve 341 held closed by an elastic element, such as the helical spring 342 of figure 3a,

and a seat valve 343 that can? move axially through the threaded coupling with the injector body 34 modifying the preload of the spring 342 itself.

The seal between the valve seat 343 and the injector body 34 is ensured by a gasket 344. The relative position of the valve seat 343? managed by a second actuator 345, type electric motor, also controlled by the unit? control 4.

The opening of the poppet valve 341 occurs when the force of the pressure of the liquid under test, which insists on the poppet of the valve, overcomes the force of the spring 342.

The passage of the liquid through the meatus that forms between the mushroom valve 341 and its seat generates the nebulized form of the liquid delivered.

The dimensions of the meatus, which depend on the force generated by the closing spring 342, in combination with the pressure in the cylinder 81, determine the speed? and the size of the droplets during spraying.

From what has just been described it is evident how the unit? control 4 can control time, volume and pressure for droplet formation.

The weather ? managed by the activation motor 9, i.e. the stroke time of the piston 81.

The volume ? the volume of the liquid moved inside the chamber 83, while the pressure? obtained through pressure sensor 346.

Based on the size of the droplets to be obtained and based on the speed? supply, the unit? control 4 modify? these parameters generating command signals for the various components of the system, just described.

While the invention? susceptible of various modifications and alternative constructions, some preferred embodiments have been shown in the drawings and described in detail.

It must be understood, however, that there? no intention of limiting the invention to the specific embodiment illustrated, but, on the contrary, it intends to cover all modifications, alternative constructions, and equivalents that fall within the scope of the invention as defined in the claims.

The use of? For example ?,? Etc.?,? Or? indicates non-exclusive alternatives without limitation unless otherwise indicated.

The use of? Includes? means? includes, but not limited to? unless otherwise indicated.

Claims (10)

CLAIMS 1. A system for qualifying and testing tissue samples (2), comprising means for generating a flow of atomized liquid configured to spray a certain amount of liquid. of drops of liquid on said tissue sample (2), means of detection (6) of the quantity? of liquid absorbed by said tissue sample (2), at least one unit? control (4) configured to control the operation of said generating means and / or of said detection means (6), characterized by the fact that said generation means comprise a liquid tank (31) connected to a unit? supply (33), which unit? of dispensing includes means for regulating the quantity? dispensing liquid means for adjusting the dispensing time and means for adjusting the dispensing pressure. 2. System according to claim 1, in which means are provided for detecting the transpiration of said fabric sample. System according to claim 1 or claim 2, wherein? an insertion chamber (1) of said fabric sample (2) is provided, since said fabric sample (2) is positioned on a plane configured to divide said insertion chamber (1) into two parts, of which a part of supply (10) and a survey part (11), being the said delivery part (10) in communication with the said unit? dispensing (33). 4. System according to one or more? of the preceding claims, in which said means for detecting (6) the quantity? of liquid include a balance. 5. System according to one or more? of the preceding claims, in which said transpiration detection means comprise a pressure adjustment device (70) inside said insertion chamber (1) and at least a first pressure sensor (71) communicating with the dispensing part (10) and at least a second pressure sensor (72) communicating with said sensing part (11). 6. System according to one or more? of the preceding claims, wherein said unit? delivery comprises an injection cylinder (8), which injection cylinder (8) has a piston (81) moved by an activation motor (9), inside an internal chamber (83) in communication with means of opening / closing a dispensing valve (34), comprising said cylinder at least one pressure sensor (346) for the liquid present in said internal chamber (82). 7. Method for Qualifying and Testing Fabric Samples, which method involves the following steps: a) dispensing a flow of nebulized liquid on said tissue sample, b) detection of the quantity? of liquid absorbed by said fabric sample, characterized in that step a) comprises: - regulation of the quantity? of dispensed liquid, - adjustment of the dispensing time, - regulation of the supply pressure. Method according to claim 7, wherein? a step c) is provided for detecting the transpiration of said fabric sample. Method according to claim 8, wherein step c) comprises: - positioning of the tissue sample inside a chamber, in order to divide this chamber into two areas, - pressure regulation in one of the two areas, - measurement of the pressure inside the said two zones. 10. Method according to one or more? of claims 7 to 9, wherein step b) provides for a first weighing of the tissue sample and of the liquid not retained by the tissue and a second weighing without the tissue sample.