FR3132437A1 - Test box for air and surface contamination by microorganisms, in particular bacteria and/or contaminating moulds/yeasts; Associated method of operation. - Google Patents

Abstract

Test box for air and surface contamination by microorganisms, in particular bacteria and/or contaminating moulds/yeasts; Associated method of operation. The invention essentially consists of a test box fitted with bio-collectors and/or electronic nose(s) which allow access to contamination by microorganisms completely from outside the internal test volume. Bio-collectors and/or electronic noses make it possible to reliably qualify and quantify microbiological contamination continuously, without the need for heavy and/or delicate implementation devices as shown in the aforementioned ISO standard. Associated method of operation. Figure for abstract: Fig. 1

Description

Test box for air and surface contamination by microorganisms, in particular bacteria and/or contaminating moulds/yeasts; Associated method of operation.

The present invention relates to the general technical field of contamination by aerosol, more particularly by aerosols likely to contain microorganisms, in particular bacteria or contaminating moulds/yeasts.

It relates more particularly to the production of a contamination test box in order to qualify devices for the purification and/or disinfection of air and surfaces.

By "bacteria", we mean here and in the context of the invention, any microscopic and prokaryotic living organism, most often unicellular, sometimes multicellular, present in all environments.

By "mold" is meant here and in the context of the invention, any spore resulting from a biological mold consisting of a fungus of microscopic size which grows in the form of multicellular or unicellular filaments.

By "yeast" is meant here and in the context of the invention, any spore from a unicellular fungus capable of causing the fermentation of animal or vegetable organic matter.

The new global epidemic linked to the SARS-CoV-2 coronavirus, known as COVID-19, is the most serious infectious disease pandemic in the world since the end of the Second World War.

The new coronavirus is mainly transmitted by aerosol, and the sterilization, treatment or purification of the air using an air sterilization product or modification of the physicochemical characteristics of the air is a way effective in resisting the transmission of the novel coronavirus.

Thus, in order to deal with this epidemic situation, various manufacturers of air purification and/or disinfection systems have reacted quickly and developed various devices for cleaning and/or disinfecting the air in public places such as hospitals and schools and in private environments such as family homes.

According to the requirements of the state health administrations, in order to guarantee the health and safety of people, these air cleaning and/or disinfection devices must obtain certification by independent third parties before they can be marketed.

One of the certification standards for air disinfection devices requires quantification of the rate of sterilization, treatment or purification, namely the effectiveness of killing microorganisms (pathogenic bacteria, viruses and others) in the air , so as to reflect the performance of sterilization or action on the air of said devices.

In fact, the quantification of a sterilization/purification rate requires specific equipment.

At present, the international standard ISO 16000-36 (part 36) relating to a standardized method for evaluating the reduction rate of airborne cultivable bacteria by air purifiers using a test chamber is a method active by impaction for the sampling of airborne culturable bacteria by inertial separation on a solid surface of agar.

This active method is based on the principle of air aspiration, and impaction of biological particles on a collection support (Petri dish) which can then be incubated to feed the bacteria, in order to proceed to counting. and identifications of these bacteria.

This method makes it possible to quickly qualify and quantify the microbiological contamination in Colony Forming Units per volume of air (CFU/m ³ ). The impacted Petri dishes are incubated for a colony count.

As specified in this standard, the effectiveness of the air purifiers that are tested is thus evaluated by using nebulized bacterial suspensions in a test chamber at constant temperature and relative humidity of the air. Efficacy is calculated from the reduction rate of airborne cultivable bacteria over a given period of time, taking into account the homogeneity and the natural decomposition rate of the bacteria.

To carry out the collection of air ensuring the sampling of a known volume of air by aspiration to carry out the microbiological analysis, the standard defines devices qualified as bio-collectors or impactors, which each consist of a set of orifices (circular or slits), through which the aspirated air flow passes, and the collection surface (Petri dish).

And as shown in of the ISO 16000-36 standard (part 36), it is recommended to house a number of three bio-collectors (impactors) inside the test chamber.

In such a configuration, the manipulation of the bio-collectors is delicate if it must be done through known devices of the glove finger type, which implies, depending on the method, the presence of airlocks to recover the Petri dishes used. , and impossible without at best risking distorting the data of the samples and interrupting the continuity of the sample; if an operator must enter inside the test chamber to take them away.

Consequently, there remains a need to propose a solution for testing the efficiency of air purification and/or disinfection devices, in particular in order to comply with the aforementioned ISO 16000-36 (part 36) standard, which make it possible to qualify and to reliably quantify the microbiological contamination continuously, without the need for heavy and/or delicate implementation devices.

The object of the invention is to meet this need at least in part.

To do this, the subject of the invention is, according to a first alternative, a contamination test box comprising:

- a plurality of sealed walls defining between them an internal test volume;

- at least one device for generating an aerosol of contaminating microorganisms, in particular bacteria or contaminating moulds/yeasts, inside the internal test volume;

- at least one test support, arranged in the internal volume and intended to support at least one air purification and/or disinfection device to be tested, the device comprising an air inlet to be purified and/or disinfected and at the at least one purified and/or disinfected air outlet;

- at least one air circulation fan, arranged in the internal test volume and adapted to stir the air in the internal test volume;

- at least three independent subassemblies each forming a bio-collector, each bio-collector comprising a sealed box comprising an air inlet and an air outlet, the box being intended to house at least one micro culture support -organisms, a first fluid conduit connected to the air inlet, a second fluid conduit connected to the air outlet, and at least one suction fan for sucking air from the first conduit so that it impinges the culture medium housed in the box and is extracted by the second duct, the first and second ducts each being arranged outside the internal volume of the box and opening into the latter through a through opening made in one of the walls, the box also being arranged outside the internal test volume;

- at least three other independent fluidic ducts, each connected to one of the through openings located on the casing onto which one of the first ducts opens, one of the other three fluidic ducts being arranged in the internal volume by opening out into a zone intended to be opposite the air outlet of the device to be tested, the other two fluid conduits being arranged in the internal test volume and opening out into a zone intended to be remote from the air outlet of the device to be tested.

According to an advantageous configuration, the internal volume of the box is a rectangular parallelepiped, the box comprising five bio-collectors and five other fluidic conduits, one of the five other fluidic conduits being arranged in the internal volume by opening out into a zone intended to be opposite from the air outlet of the device to be tested, the other four fluid conduits being arranged in the internal test volume and each opening into one of the corners of the rectangular parallelepiped.

According to an advantageous embodiment, the sealed case of each bio-collector comprises a removable drawer between a deployed position in which the culture medium can be inserted therein or extracted manually or automatically and a depressed position in which the culture medium can be impacted by air drawn through the first duct.

According to this mode, each bio-collector preferably comprises at least two flaps arranged on either side of the location of the removable drawer, and adapted to block any circulation of air in the location when the drawer is operated from its retracted position, so as to avoid any contamination outside the casing.

Preferably again, each bio-collector box comprises a non-return valve arranged so that when the suction fan is stopped, no air circulates in the bio-collector.

Advantageously, the sealed box is fixed to one of the walls, outside the internal volume.

Advantageously, the other fluid conduits are flexible conduits, preferably made of smooth material, which can be moved as desired.

According to a variant embodiment, each culture support being a Petri dish capable of receiving microorganisms by impact from the air located in the internal volume of the box.

According to a second alternative, the subject of the invention is a test box for contamination by microorganisms, comprising:

- a plurality of sealed walls defining between them an internal test volume;

- at least one device for generating an aerosol of contaminating microorganisms, in particular bacteria or contaminating moulds/yeasts, inside the internal test volume;

- at least one test support, arranged in the internal volume and intended to support at least one air purification and/or disinfection device to be tested, the device comprising an air inlet to be purified and/or disinfected and at the at least one purified and/or disinfected air outlet;

- at least one air circulation fan, arranged in the internal test volume and adapted to stir the air in the internal volume;

- at least one electronic nose adapted to carry out the analysis by chemical fingerprint of the micro-organisms present in the internal test volume.

By "electronic nose" is therefore meant here and in the context of the invention, an electronic device whose detection, sampling and data processing components are configured for analysis by chemical fingerprint of microorganism(s). ) contaminants.

This second electronic nose alternative can be in addition to or instead of bio-collectors.

In the context of the invention, it is possible to envisage dispensing with bio-collectors, provided that the electronic nose implemented has been validated beforehand to determine bio-contaminant over time and without there being any need precision on microorganisms.

According to an advantageous embodiment, the box comprises at least one heat exchanger housed in at least one of the walls to regulate the temperature of the air inside the internal test volume solely by radiation.

According to another advantageous embodiment, the box comprises at least two fans, separate from the air circulation fan, one of the two fans being adapted to put the internal test volume under overpressure with respect to the outside, the other of the two fans being adapted to draw air from the internal volume to the outside.

According to this other mode, each of the two fans preferably comprises a non-return valve arranged so that when it is stopped no air circulates from or to the outside of the internal test volume.

Advantageously, each of the two fans is equipped with one or more anti-microbial filters.

According to yet another advantageous embodiment, the box comprises at least one airlock comprising an access door from the outside, the airlock being attached to one of the walls of the internal test volume which incorporates an access door from aces.

According to an advantageous variant embodiment, the airlock comprises at least two fans, separate from the air circulation fan, one of the two fans being adapted to put the airlock under overpressure with respect to the outside, the other of the two fans being adapted to draw air from the airlock to the outside.

The invention also relates to a method of operating a box which has just been described, comprising the following steps:

a/ installation of an air purification and/or disinfection device to be tested on the test support and installation of a sample of microorganisms in each culture support;

b/ closing the internal test volume;

c/ operation of the air purification and/or disinfection device to be tested from outside the internal test volume;

d/ generation of an aerosol of contaminating microorganisms, in particular bacteria and/or contaminating moulds/yeasts, inside the test volume and circulation of air within it;

e/ sampling at predetermined time intervals from outside the internal test volume, of at least part of the samples from the culture supports with a view to their culture so as to determine the purification and/or the disinfection of the air performed by the device under test.

Step d/ can be carried out before or after step c/: when step d/ is carried out before step c/, the air circulation takes place without disturbance.

According to an advantageous embodiment, the method comprises beforehand steps a/ to e/, calibration steps consisting of:

a0/ placement of a culture medium, preferably a Petri dish;

d0/ generation of an aerosol of contaminating microorganisms, in particular bacteria or/ contaminating yeasts/molds, inside the test volume and circulation of air within it;

e0/ sampling at predetermined time intervals from outside the internal test volume, of at least part of the samples from the culture supports with a view to their culture so as to determine the kinematics of absorption of the aerosol by the box itself.

Steps a0/ and d0/ can also be performed in the opposite direction, i.e. step d0/ before step a0/.

According to another advantageous embodiment, the method comprises, prior to step a/, the following steps:

a1/ opening then closing of the airlock access door to the outside;

a2/ preferably simultaneously with step a1/, operation of the overpressure and suction fans of the airlock;

a3/ opening of the airlock access door to the internal test volume;

a4/ preferably simultaneously with step a3/, operation of the overpressure and suction fans of the internal test volume, the airlock suction fan still being in operation.

To carry out the method according to the invention, each biocollector can be provided with an ON-type command which triggers a contaminant sampling cycle: this command can be in the form of a push button or a logic input of piloting. This action triggers for a predefined time the suction of air from the internal volume of the box so that it is impacted on the culture support, preferably a Petri dish and returns to the internal volume of the box. A light and/or sound indicator can advantageously inform this cycle start until the end of the sampling.

It is possible to envisage that each bio-collector has a sampling cycle duration different from the other bio-collectors. Each sampling cycle duration specific to a bio-collector can preferably be configured beforehand, in particular according to the length of the conduit connected to said bio-collector. This makes it possible to compensate for the volume of trapped air which is specific to each duct, which differs from the others.

Thus, the invention essentially consists of a test box fitted with bio-collectors and/or electronic nose(s) which allow access to contamination by microorganisms completely from outside the internal test volume.

Bio-collectors and/or electronic noses make it possible to reliably qualify and quantify microbiological contamination continuously, without the need for heavy and/or delicate implementation devices as shown in the aforementioned ISO standard.

Other advantages and characteristics of the invention will emerge better on reading the detailed description of examples of implementation of the invention given by way of illustration and not limitation with reference to the following figures.

there is a schematic view of an example of a test box for contamination by microorganisms according to the invention.

there is a schematic view in longitudinal section of a bio-collector mounted on the wall as it is implemented in a test box according to the invention.

there is a photographic reproduction of a bio-collector according to the invention with its fluid conduits before it is mounted on the wall of the box, its drawer housing a Petri dish being in its deployed position.

there is a photographic reproduction of the drawer housing the bio-collector according to the .

there is a photographic reproduction of the part of the housing drawer of the bio-collector according to the or 4 which supports and maintains a Petri dish.

there is a photographic reproduction of a fluid conduit connected to a bio-collector according to the invention and arranged directly opposite the air outlet of an air purification device to be tested.

there is a diagram of an advantageous embodiment of the test box for contamination by microorganisms according to the invention which comprises an airlock attached to a wall delimiting the internal test volume.

there illustrates in the form of curves the kinematics of absorption in microbiological contamination in Colony Forming Units per volume of air of the test box alone without any device to be tested within the internal volume of the box.

Claims (18)

Microorganism contamination test box, comprising:
- a plurality of sealed walls defining between them an internal test volume;

• at least one device for generating an aerosol of contaminating microorganisms, in particular bacteria or contaminating moulds/yeasts, inside the internal test volume;
• at least one test support, arranged in the internal volume and intended to support at least one air purification and/or disinfection device to be tested, the device comprising an air inlet to be purified and/or disinfected and at least a purified and/or disinfected air outlet;
• at least one air circulation fan, arranged in the internal test volume and adapted to stir the air in the internal test volume;

• at least three independent subassemblies each forming a bio-collector, each bio-collector comprising a sealed box comprising an air inlet and an air outlet, the box being intended to house at least one micro-organism culture medium organisms, a first fluidic conduit connected to the air inlet, a second fluidic conduit connected to the air outlet, and at least one suction fan for sucking air from the first conduit so that it impacts the culture medium housed in the box and is extracted by the second duct, the first and second ducts each being arranged outside the internal volume of the box and opening into the latter through a through opening made in one of the walls, the box also being arranged outside the internal test volume;
• at least three other independent fluidic ducts, each connected to one of the through openings located on the casing onto which one of the first ducts opens, one of the three other fluidic ducts being arranged in the internal volume by opening out into a zone intended to be in next to the air outlet of the device to be tested, the other two fluid conduits being arranged in the internal test volume and opening out into a zone intended to be remote from the air outlet of the device to be tested.

Casing according to claim 1, the internal volume of the casing being a rectangular parallelepiped, the casing comprising five bio-collectors and five other fluidic ducts, one of the five other fluidic ducts being arranged in the internal volume by opening out into a zone intended to be in next to the air outlet of the device to be tested, the other four fluid conduits being arranged in the internal test volume and each opening into one of the corners of the rectangular parallelepiped. Box according to claim 1 or 2, the sealed box of each bio-collector comprising a removable drawer between a deployed position in which the culture support can be inserted therein or extracted manually or automatically and a depressed position in which the culture can be impacted by the air drawn through the first duct. Box according to claim 3, each bio-collector comprising at least two valves arranged on either side of the location of the removable drawer, and adapted to block any circulation of air in the location when the drawer is operated from its retracted position, so as to avoid any contamination outside the casing. Box according to one of the preceding claims, each bio-collector box comprising a non-return valve arranged so that when the suction fan is stopped, no air circulates in the bio-collector. Casing according to one of the preceding claims, the sealed casing being fixed to one of the walls, outside the internal volume. Casing according to one of the preceding claims, the other fluid conduits being flexible conduits, preferably of smooth material, which can be moved as desired. Box according to one of the preceding claims, each culture support being a Petri dish capable of receiving microorganisms by impact from the air located in the internal volume of the box. Microorganism contamination test box, comprising:
- a plurality of sealed walls defining between them an internal test volume;
- at least one device for generating an aerosol of contaminating microorganisms, in particular bacteria or contaminating moulds/yeasts, inside the internal test volume;

• at least one test support, arranged in the internal volume and intended to support at least one air purification and/or disinfection device to be tested, the device comprising an air inlet to be purified and/or disinfected and at least a purified and/or disinfected air outlet;
• at least one air circulation fan, arranged in the internal test volume and adapted to stir the air in the internal volume;
• at least one electronic nose adapted to perform the chemical fingerprint analysis of the microorganism(s) present in the internal test volume.

Box according to one of the preceding claims, comprising at least one heat exchanger housed in at least one of the walls to regulate the temperature of the air inside the internal test volume solely by radiation. Box according to one of the preceding claims, comprising at least two fans, separate from the air circulation fan, one of the two fans being adapted to place the internal test volume under overpressure with respect to the outside, the other of the two fans being adapted to draw air from the internal volume to the outside. Casing according to claim 11, each of the two fans, comprising a non-return valve arranged so that when it is stopped, no air circulates from or towards the outside of the internal test volume. Box according to claim 11 or 12, each of the two fans being equipped with one or more anti-microbial filters. Box according to one of the preceding claims, comprising at least one airlock comprising an access door from the outside, the airlock being attached to one of the walls of the internal test volume which incorporates an access door from the airlock . Box according to claim 14, the airlock comprising at least two fans, separate from the air circulation fan, one of the two fans being adapted to put the airlock under overpressure with respect to the outside, the other of the two fans being adapted to draw air from the airlock to the outside. Method of operating a box according to one of the preceding claims, with the exception of claim 9, comprising the following steps:
a/ placing an air purification and/or disinfection device to be tested on the test support and placing a sample of microorganisms in each culture support;
b/ closing the internal test volume;
c/ operation of the air purification and/or disinfection device to be tested from outside the internal test volume;
d/ generation of an aerosol of contaminating microorganisms, in particular bacteria and/or contaminating moulds/yeasts, inside the test volume and mixing of air within it;
e/ sampling at predetermined time intervals from outside the internal test volume, of at least part of the samples from the culture supports with a view to their culture so as to determine the purification and/or the disinfection of the air performed by the device under test. Operating method according to claim 16, comprising beforehand steps a/ to e/, calibration steps consisting of:
a0/ placement of a culture support, preferably a Petri dish;
d0/ generation of an aerosol of contaminating microorganisms, in particular bacteria or/ contaminating yeasts/molds, inside the test volume and mixing of air within it;
e0/ sampling at predetermined time intervals from outside the internal test volume, of at least part of the samples from the culture supports with a view to their culture so as to determine the kinematics of absorption of the aerosol by the box itself. Method of operating according to claim 17 or 18 of a box according to claim 14 in combination with claim 16, comprising, prior to step a/, the following steps:
a1/ opening then closing of the airlock access door to the outside;
a2/ preferably simultaneously with step a1/, operation of the overpressure and suction fans of the airlock;
a3/ opening of the airlock access door to the internal test volume;
a4/ preferably simultaneously with step a3/, operation of the overpressure and suction fans of the internal test volume, the airlock suction fan still being in operation.