EP4136629A1

EP4136629A1 - Measuring system for determining the risk of infection

Info

Publication number: EP4136629A1
Application number: EP21725378.0A
Authority: EP
Inventors: Christian Noe; Peter Lechner; Norbert NOWOTNY
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-04-15
Filing date: 2021-04-15
Publication date: 2023-02-22
Also published as: WO2021207775A1

Abstract

The invention relates to a measuring system for determining the risk of infection by viral infections in rooms, in which system one or more measuring devices are provided for the measurement parameters of the room air (CO₂ content of the room air, air temperature, humidity, if applicable number of particles per unit volume of the room) for determining a measurement value factor, and input devices (3) are provided for input of further parameters for determination and input of associated factors, the parameters and the factors being selected from the groups comprising seasonal parameters for the seasonal factor, room parameters for the room factor, personal parameters for the personal factor and infection parameters for the infection factor. A computer unit (2) is provided for calculation of the final evaluation value by combining the determined or input factors, and a display device for displaying the evaluation factor and, if applicable, a control system for controlling the parameters in order to reduce the risk of infection are also provided.

Description

Measuring system to determine the risk of infection

The invention relates to a measuring system for determining the risk of infection by viral infections in rooms and a method for this.

Seasonal viral diseases appear regularly in spring and autumn when the seasons change. The evolutionary stability of these mostly flu-like illnesses is explained on the one hand by a special combination of infectivity - measurable as the minimum infectious dose (MID) - and the severity of the course of the disease.

On the other hand, it is the clear indication that the climatic factors temperature and humidity play an important role at the moment of infection. Empirical values for temperature and humidity ranges with a particular risk of infection are known. On the other hand, no conclusive concept has yet become known about molecular mechanisms that determine virus infectivity from these points of view. The present patent application is based, among other things, on the hypothesis that the infectivity of a virus is primarily determined by the spatial structure of its outer shell. This outer shell is made up of proteins. In the case of the corona viruses, the very complex arrangement has even given its name. It is known that the arrangement of proteins in space (quaternary structure) is decisively influenced by more or less firmly bound water molecules. If such water molecules are missing, then the virus envelope loses its ordered structure and thus its ability to adhere to the host's tissue and its infectivity. The condition for maintaining the infectious structure is accordingly an at least monomolecular layer of water that adheres to the virus.

The size of a single virus particle is in the micrometer range and corresponds to the particle size of ultra-fine dust. Viruses also occur as single particles in aerosols. The water cover of such a small particle dries quickly at higher temperature and lower humidity, which means that it is no longer infectious. Last but not least, this explains the extensive disappearance of seasonal viral diseases in the warm season. This hypothesis is confirmed, among other things, by immission measurements on the spread of swine flu viruses, which were emitted from infected pig stalls. By means of PCR, the presence of the virus genome could be shown at a distance of about 2 km. However, the virus particles were no longer infectious.

The airborne spread of aerosols has been well studied in the course of environmental research and has been defined in a number of laws and regulations. Among other things, the quality of the room air itself, including the dust load, is also determined for a wide variety of types of rooms. Even if there is currently no analogous regulation for virus particles in this regard, a systematic recording of the viral load in the air with infectious and / or non-infectious virus particles is to be expected or at least to be desired. However, the current technical possibilities are hardly suitable for an ongoing routine monitoring of the room air.

The routes of infection of influenza illnesses are usually classified as droplet infection, smear infection and infection via the air (aerosol). Ultimately, all of these paths can be traced back to the basic requirement of a water cover around an infectious virus particle. Many viruses are found in the droplet in an aqueous environment; a smear infection is possible as long as there is residual moisture. In all cases - depending on the immune and health status of the person affected - a certain number of viral particles (MID) is required in order to overcome the natural defenses and trigger the infection. The dominant source of emissions of viral particles is the exhausted breath of an infected person, which constantly generates an emission of viral particles, which is either abruptly released into the environment as a cough or sneeze or regularly through the breath. This electricity generates around 1 cubic meter of air contaminated with virus particles per person within 2 hours. The immission of virus particles takes place - apart from the mechanical introduction of viruses through contact - initially in the nasopharynx or via the mucous membrane of the eyes. Ultimately, however, the immission in the lungs is decisive, in which very small virus particles in very small droplets can even penetrate deep into the alveoli when breathing.

The parameters used to assess the air quality include not only the dust content, but also the C0 ₂ content of the air. The virus flow in the exhaled air of an infected person is in direct correlation with the amount of air exhaled by them. This in turn is at the same time in direct correlation with the amount of CO contained in it. The value is quite constant at 4 percent, i.e. 40 milliliters of CO ₂ per liter of air. Therefore, the assessment of the risk of a virus infection via the room air can, as a first approximation, be based directly on known and partially fixed values for determining the C0 ₂ content in the room air.

In the risk assessment, it should be noted that there is generally a greater risk for people who stay in a room for a long time, such as for salespeople in a shop, than for people who only stay in the room for a short time, such as business customers.

The present invention relates to a measuring system for determining the risk of infection from viral infections and a method for this. _{The C0 2} content of the air is used as the basic measurement parameter.

In the simplest embodiment, the present invention comprises C0 measuring devices which at the same time contain an indication of their use for estimating the risk of viral infection. The criteria according to which the limit values for are uncritical or critical, should be specified. This results in different risk situations: a. For rooms in which there are always largely the same people, such as apartments, school classes and offices, limit values can be entered with a standard setting. Guideline values for the quality of indoor air are already partly recorded in existing ordinances. b. For publicly accessible rooms in which there are a limited number of changing people, such as waiting rooms in ordinations or cloakrooms in sports clubs, basic values can be set, which can be adjusted depending on the general risk situation with regard to infectious diseases. c. For rooms in which a specific number of people are added to those who are permanently present and who stay in a room in a changing composition for a limited period of time, such as lecture halls, theaters, concert halls, cinemas and other event rooms, the protection of those permanently present must also be taken into account . d. The situation in public spaces, such as business premises, offices with party traffic or public transport, in which people are permanently present and a larger number of changing people is present at the same time, must be viewed in a differentiated manner. In this case, the risk situation is particularly high, since the statistical probability of the presence of an infected person in the room increases with the total number of visitors to the room. There are additional factors to assess the risk of infection in these rooms. These are, on the one hand, the number of visits per hour with average length of stay and, on the other hand, the area of the room, since in small rooms in which it is not possible to maintain a corresponding distance, the risk of infection through smear infection or droplet infection is increased even further. Slightly exceeding the specified limit values could be used as a recommendation for wearing a face mask, larger excesses for entry bans.

The _{CO 2} content of the ambient air in the open air is 400 ppm. Usually, a value of 1000 ppm CO2 (Pettenkofer number) is assumed to be acceptable as a guide value for indoor air quality. However, the permitted value varies depending on the type of room use. Another guideline is that around 25 to 36 m ³ / h of fresh air are required per person. Measurements of the C0 ₂ content of the room air are currently being carried out primarily with regard to the necessary ventilation measures. These consist primarily of defining a minimum number of air changes. With regard to the actual use as warning devices against viral infections, there are also further tightening criteria for determining the required air quality.

According to the invention, relevant parameters for determining the limit values with regard to a viral infection risk are recorded and are preferably used to determine the limit values, which is preferably done by calculation. Such parameters are:

1. The room temperature

2 The humidity in the room

3 The area and the air volume of the room

4 The number of people in the room.

Another object of the invention in relation to the use of the devices for warning of the risk of infection is the automatic adaptation of the limit values on the basis of changes in the specified parameters. The warning can be given either acoustically or visually, with a "remote control", for example as a traffic light system, regulating access to the room as a special embodiment.

Furthermore, the warning system described can be used to control room ventilation, primarily by regulating the number of air changes, as well as the room temperature and humidity. In order to be able to estimate the risk of infection by virus particles more precisely, the warning system of the present invention can be connected in a further embodiment with devices for particle measurement.

The present invention can also be applied to air-conditioned rooms with circulating air under the condition that no devices are available which _{reduce the C0 2} content and / or - for example through humidification - the number of virus particles in the air.

The present invention of the measuring system for determining the risk of infection through viral infection in rooms is characterized as follows: that one or more measuring devices are provided for the following measuring parameters of the room air to determine a measured value factor:

C0 ₂ content of the room air

Air temperature

humidity

Possibly the number of particles per volume of the room; that input devices are provided for entering further parameters for determining and entering assigned factors, the parameters and their factors being selected from the following groups:

Seasonal parameters for the seasonal factor,

Room parameters for the room factor,

Person parameters for the person factor and infection parameters for the infection factor; that an arithmetic unit is provided for calculating the final evaluation value by combining the determined or entered factors; and that a display device for displaying the evaluation factor and possibly a control system for controlling the parameters for reducing the risk of infection are provided.

Furthermore, the parameters are assigned a factor of 1.0 for normal cases, a factor> 1.0 for positive conditions with a reduced risk of infection and a factor of <1.0 for negative conditions with an increased risk of infection.

It is preferably provided that the computing unit has a self-learning artificial intelligence for calculating the factors.

It is preferably provided that the following factor matrix is defined to determine the measured value factor from air temperature and air humidity: and that the following factor values are provided for the measured C0 ₂ content of the room air:

The final factor is calculated using the factor ^* weight and that the measured value factor is formed by multiplying the factor values. It is preferably provided that a neutral value of 1.0 is used for the particle number.

According to the present invention, a factor value between 1.0 and 0.5 is used for the seasonal parameter, with the for seasons with a low virus risk Factor value is set to 1.0, medium risk 0.9, and high risk 0.5.

According to the present invention, the following values are provided for the space parameter and its space factor, from which the space factor can be obtained by multiplication:

According to the present invention, the following determinations are made for the determination of the person parameter and the factors are multiplicatively combined to form the person factor: a) Number and throughput of people with a small number of people to a high number of people: b) Length of exposure: c) Activity:

According to the present invention, one of the following factors is displayed for the infection parameter, with the infections from the previous week being evaluated:

1 schematically illustrates the apparatus units with the parameters measured and entered therein and their computational evaluation.

The figure is self-explanatory.

Fig. 2 shows the scheme of a measuring system.

The measuring system is software-controlled and can be written in any suitable programming language.

The following parameters are transmitted by the measuring sensors via an interface. As soon as a value changes by more than 10%, this value is transmitted together with a timestamp:

Temperature, relative humidity, C0 ₂ content ppm, particles ppm. The following parameters are entered via a user interface:

Seasonality (can also be determined from the system time)

Geometry, room size, room height, elevator power concept, data on people (throughput, number of people and length of exposure, activity).

The viral factor is also entered via a user interface, but there is also the option of automatically referring to this factor using the geographical coordinates.

As soon as one of the parameters changes, the calculation algorithm delivers a V-Risk value (final evaluation) and writes this, together with all current parameters including timestamp and unique version designation of the algorithm, in a database and can also use this value to control other components. The logging of all parameters and score values in the database creates the possibility of further analyzes and the application of mathematical models for the development, calibration and validation of the calculation algorithm.

The calculation algorithm includes the functional relationship of the parameters and the determination of the factors (individual factors and total factors).

The equipment design must be selected in accordance with the equipment and modules available. For example, according to FIG. 2, the computing unit 2 with the power supply 1 and data transmission devices can be combined to form a device unit. The data transmission from and to the sensors for temperature, humidity and C0 ₂ content and possibly for the number of particles, and to an input unit 3 for the parameters can be wired or wireless via radio or internet connection or the like.

The sensor unit 5 supplies the measurement data for air temperature, air humidity and C0 ₂ content. Furthermore, the sensor unit 5 also has a display for displaying the measured data and also for displaying the evaluation factor as a risk display. The particle sensor 6 can also be provided. The data is entered, for example, via the input unit 3 using 4G remote and local access (via VPN). Connection to a cloud server is possible. One Connection and data transfer via WIFI can be done via the WIFI Access Point 4.

Some advantageous features of the invention are listed below by way of example:

The invention relates to a measuring device for determining the risk of infection by viral infections, the C0 ₂ content of the air being used as the basic measuring parameter.

Another feature is that relevant parameters for setting limit values with regard to a viral risk of infection, especially the room temperature, the humidity in the room and the air volume in the room, are recorded and used to set the limit values.

The limit values are recorded automatically and the limit values are adjusted if necessary on the basis of a computational evaluation.

The warning can be given either acoustically or visually.

As a special embodiment, a “remote control”, for example as a traffic light system, can regulate access to the room.

The recorded measured values can be used to control the room ventilation, primarily by regulating the number of air changes, as well as the room temperature and the humidity.

The invention includes the use of C0 ₂ air measuring devices as a warning system against the risk of viral infection and also the use of a continuous particle measuring device as a warning system against the risk of viral infection.

The invention also includes the use of a C0 ₂ air meter in conjunction with devices for particle measurement. Here are some examples:

Claims

1. Measuring system for determining the risk of infection from viral infections in

Spaces, characterized

A) that one or more measuring devices are provided for the following measuring parameters of the room air to determine a measured value factor:

C0 ₂ content of the room air

Air temperature

humidity

Possibly the number of particles per volume of the room;

B) and that input devices (3) are provided for entering further parameters for determining and entering associated factors, the parameters and their factors being selected from the following groups:

Seasonal parameters for the seasonal factor,

Room parameters for the room factor,

Person parameters for the person factor and infection parameters for the infection factor;

C) and that a computing unit (2) is provided for calculating the final evaluation value by combining the determined or entered factors;

D) and that a display device for displaying the evaluation factor and, if necessary, a control system for controlling the parameters for reducing the risk of infection are provided.

2. Measuring system according to claim 1, characterized in that the parameters for the normal case each have a factor of 1.0 and a factor> 1.0 for positive conditions with a reduced risk of infection and a factor of <1.0 for negative conditions with an increased risk of infection.

3. Measuring system according to claim 1 or 2, characterized in that the computing unit (2) has a self-learning artificial intelligence for calculating the factors.

4. Measuring system according to one of claims 1 to 3, characterized in that the following matrix of factors is defined to determine the measured value factor from air temperature and air humidity: g— - 30.9-25.1 25.0-21.7 äl daily 18.2-13.9 14.9- 11.7 11.6-8.3 8.2-p.1 3.0-8

S91% -18 & 0.64 0.79 0.75 0.70 9.62 0.33 0.45 ö, 30 0.23

! 81% -98% 0.92 0.07 0.82 0.77 0.07 0.58 0.4S 0.40 0.31 ki% M% 1.00 0.94 0. $ 9.9.83 0.73 0.63 0.53 0.43 0.33 1.13 1.07 1 .00 O.SS 0.76 0.04 0.52 0.40 1.01 0.95 0.39 9.78 0.97 057 9.46 0.36 _ OJg_ Ö S_ 0.70 0.02_ 0 3_ 02j5_ 0.36_ 023 _, and that the following factor values are provided for the measured C0 ₂ content of the room air:

The final factor is calculated using the factor ^* weight and that the measured value factor is formed by multiplying the factor values.

5. Measuring system according to claims 1 to 4, characterized in that a neutral value of 1.0 is used for the particle number.

6. Measuring system according to claims 1 to 5, characterized in that a factor value between 1, 0 and 0.5 is used for the seasonal parameter, with the for seasons with a low virus risk Factor value is set to 1.0, medium risk 0.9, and high risk 0.5.

7. Measuring system according to claims 1 to 6, characterized in that the following values are provided for the space parameter and its space factor, from which the space factor can be obtained by multiplication:

8. Measuring system according to claims 1 to 7, characterized in that the following determinations are made for the determination of the person parameter and the factors are multiplicatively combined to form the person factor. a) Number and throughput of people with small or high numbers of people

Number of people: b) Length of exposure: c) Activity:

9. Measuring system according to claims 1 to 8, characterized in that one of the following factors is displayed for the infection parameter, the infection of the previous week being assessed: