AT521796A1 - Procedure for determining the contamination or impairment of people by pollutants - Google Patents

Abstract

The invention relates to a method for determining the contamination or impairment of people by pollutants, a) whereby by means of a number of sensors (S1, ..) arranged within a predetermined locally limited area (R1, ..., R4) which are sensitive to the respective pollutants. ., S15) a pollutant value (n; n1, ..., n4) is determined at predetermined times, b) being based on the pollutant values (n; n1, ..., n4) thus determined and the position and time of their determination a dispersion calculation is carried out so that a pollutant value is available for individual positions and times within the specified localized area (R1, ..., R4), c) whereby at least one person is localized within the localized area at individual times and position information for the person is thus created for these points in time, and d) wherein on the basis of the position information and the determined pollutants erte (n; n1, ..., n4) the pollutant load of the person at their respective position is determined over time.

Description

The measurement of safety-critical parameters such as biological, chemical or radioactive environmental variables are currently only feasible in a few cases, personal or object-related. It is known from the prior art that people carry sensors with them, for example to determine radioactive environmental variables. Such sensors worn on the body are limited with regard to their use, however, since larger or heavier sensors, which would be required for the measurement of more complex environmental variables, cannot be used. Environment variables that are easy to measure, such as the radioactive exposure of a person, are typically manually a posteriori for each person, e.g. evaluated after a finished shift. The sensors worn on the body are also additional equipment that the person must wear. This means that real-time monitoring of safety-relevant environment variables and thus the safety of people and the taking of preventive or anticipatory measures have so far been carried out

Measures only possible to a very limited extent.

The object of the invention is therefore to remedy this and to enable real-time monitoring of the contamination or impairment of people by a large number of biological, chemical or radioactive pollutants.

The invention solves this problem with a method for determining the contamination or impairment of people by pollutants, wherein

a) a pollutant value is determined at predefined times by means of a number of sensors which are arranged within a predefined, locally limited range and are sensitive to the respective pollutants,

b) on the basis of the pollutant values determined in this way and the position and time of their determination, a dispersion calculation is carried out, so that a pollutant value is available for individual positions and times within the specified locally limited area,

c) at least one person is located within the locally limited area at individual points in time and position information for the person is created for these points in time, and

By using in suitable places e.g. Fixed or mobile physical sensors as well as various numerical methods can be inferred from the pollution at the location of individual people as if the person had carried a virtual sensor with them. This makes it possible to record the pollution of individual people without using sensors. This expands the area of application of safety-critical environment variables to be monitored considerably, since those can also be measured, the measurement of which would require large or heavy sensors for meaningful information, as is particularly the case with chemical or biological

Contamination is the case.

In order to be able to integrate the sensors sensitive to the respective pollutants, for example in the surrounding infrastructure, it can be provided that in step a) the pollutant load is determined by means of sensors, in particular sensor boxes, which are arranged in a spatially distributed manner.

In order to be able to freely select the position of the sensors sensitive to the respective pollutants within the predetermined locally limited range, it can be provided that the pollutant load is determined by means of mobile sensors in step a), the current position of the sensors being continuously determined.

These sensors, which are arranged stationary or mobile within the predefined locally limited area, allow ambient variables to be measured with greater precision in their immediate vicinity than is the case, for example, with sensors which

be carried by one person.

In order to be able to reliably indicate the pollutant pollution prevailing at a position within the predetermined locally limited area, it can be provided that a spatial distribution, in particular in the form of a function, of the respective pollutant is created in step b) to determine the pollution caused by the individual pollutants , it being provided in particular that the spatial distribution is determined by interpolation between the individual stationary sensors

Pollutant values is determined.

This procedure enables precise localization of people in closed rooms or outdoors, so that due to the precisely localized position, the exposure of the person to the measured and spatially located environmental variable can be measured in real time.

An alternative form of localization with which meter-accurate position information of the person can be provided simply and inexpensively can be achieved if the person carries a portable terminal device with him to determine the position information in step c), the position of the terminal device and the person being passive is determined via a network of localization elements, in particular by means of triangulation, preferably continuously or at predetermined time intervals,

it is provided in particular that the signal strength and / or field strength of individual, in particular all, localization elements of the network, in particular radio-capable, localization elements is detected by means of the terminal device and the position of the terminal device and the person based on the detected signal strength and / or field strength

is determined.

Cost-effective localization of people in rooms or outdoors with location of the person accurate to the meter can be ensured if the person is located in step c) by means of satellite navigation or Bluetooth Low Energy

becomes..

A reliable statement as to whether a person has been exposed to contamination or impairment by pollutants is guaranteed if, in order to determine the person's pollutant load in step d), a total load on the person by summation or other accumulation over the individual from the determined pollutant values for a person for the person at their respective position over time determined pollution levels, especially for one

certain period, is determined.

Since the method according to the invention enables real-time measurement of safety-relevant environmental variables, it is advantageously also possible to take preventive or anticipatory measures so that people can be alerted in good time before they are exposed to a total health hazard, as a single or one-time exposure to pollutants. that exceeds a predetermined threshold.

A particularly reliable alarming of the person with little technical effort is guaranteed if, if a threshold value for the total load on the person is determined, alarming information is transmitted to the person, in particular a terminal device carried, and the latter issues an alarm message.

According to the invention, a system for determining the contamination or impairment of people by pollutants is also provided, comprising - a number of sensors sensitive to the respective pollutants, which are designed to determine a pollutant value for the respective pollutant at predetermined times, - at least one portable one Person-carried terminal, which is designed in particular for data communication via a wireless data connection, - a network of localization elements which are designed to locate the at least one terminal, in particular by means of Bluetooth low energy, and preferably to provide position information relating thereto, and - one with the sensors, and in particular the localization elements, in a data communication processing unit which is designed to - based on the pollutant values determined by the sensors and the position and time of their determination, a spread perform calculation and provide a pollutant value for individual positions and points in time within a specified local area,

- Based on the position information and the determined pollutant values, the pollutant load of the person at their respective position, in particular continuously

or at predetermined times.

Such interaction of the different hardware components enables real-time control and monitoring of safety-critical environment variables in industrial, public or private areas, as has been the case up to now

Using sensors worn on the body was not possible.

A real-time conclusion on the exposure of a person or an object with regard to measured environmental variables in a predetermined, locally limited area is ensured if the sensors are arranged in a spatially distributed, stationary manner, in particular as sensor boxes, within a predetermined locally limited area, or are arranged to be mobile, the localization elements and / or the processing unit is designed to keep the current position of the sensors running

ascertain.

In order to develop a spatial understanding of, for example, the spread of the pollutants in a predetermined, localized area, it can be provided that the processing unit is designed to determine the spatial distribution, in particular in the form of a function, of the individual pollutants to determine the load respective pollutant, in particular by interpolation between those of individual

stationary sensors to determine pollutant values.

In order to precisely predict whether a person is exposed to contamination or impairment by pollutants, it can be provided that the processing unit is designed to determine a person's total exposure to the person through summation or other accumulation to determine the person's pollutant load from the determined pollutant values the individual pollution levels determined over time for the person at their respective position, in particular for

a certain period of time.

To promptly alert people who are exposed to pollutants,

carry out or initiate a countermeasure, it can be provided that the

With such a system, an easy to implement alarming of the person can be ensured if it comprises at least one terminal carried by the person, the processing unit being designed to transmit alarm information to the terminal upon detection of a threshold value exceeding the total load on the person and that Terminal is designed to issue a corresponding alarm message.

Further advantages and refinements of the invention result from the description and the accompanying drawings.

The invention is shown schematically in the following with reference to particularly advantageous, but not restrictive, exemplary embodiments in the drawings and is described by way of example with reference to the drawings.

Show below:

1 schematically shows a predetermined, locally limited area equipped with sensors,

2 schematically shows an example of the result of a dispersion calculation in the predetermined range at a time,

3 schematically shows the path of a person who was localized at individual points in time within the predetermined range,

4 shows a first example of the determined total load on a person,

5 shows a second example of the determined total load of a person,

6 shows an example of an industrial plant with four areas or rooms with sensors, FIG. 7 shows another example of an industrial plant with one area or machine hall with sensors,

8 shows an example of a concentration curve along a section through the machine hall in FIG. 7.

Fig. 1 shows a first example of an industrial plant with a room or a predetermined local area R +, which is equipped with a system according to the invention for determining the contamination or impairment of people by pollutants. The area R; + comprises five doors T4, ..., Ts, in order, for example, to enter the industrial plant or the area R; to get or

7127

In the embodiment shown, the impairment of people in the R; the industrial plant are busy, are determined by carbon dioxide. As an alternative to this, the procedure according to the invention can be used to determine the impairment of people by any other pollutants such as nitrogen or ammonia.

Since the known sensors for determining CO 2 contamination or impairment are sometimes large and unwieldy, it is particularly advantageous that, due to the use of a system according to the invention, they do not have to be carried by the persons to be monitored. In the exemplary embodiment shown, a pollutant or CO> »2 source is located on the side wall W +.

In the exemplary embodiment shown, there is also a network of localization elements L;,. "., L7 on the side walls W + ;, ..., Wı or intermediate walls of the area R; the industrial plant. The localization elements L;,..., L7 are designed to localize at least one terminal E and to provide positional information relating thereto. The terminal E is a portable device that can be carried by a person and is designed for data communication via a wireless data connection. If the person moves in the R + area of the industrial plant and carries such a terminal E with him, the person can be located at any position in the R + ı area. For this purpose, the localization elements L4, ..., L- are used by a portable terminal E in order to use this e.g. GPSBluetooth Low Energy, NFC or RFID technology, localize continuously in real time or at predetermined intervals.

When using Bluetooth Low Energy to locate the person or the end device E of the person, there is not necessarily a bidirectional data exchange between the localization elements L ;, ..., L7, i.e. the Bluetooth low energy beacons and the terminal E. Rather, it is sufficient if only the field strengths of the beacons, which the terminal E is approaching, for triangulation-based determination of the position of the terminal E, i.e. of the person to be used. The determination of the position of the terminal E can be determined continuously in real time, or it can also be carried out in a postprocessing step, e.g. at the end of a worker’s shift.

As an alternative to this, the localization elements L;, ..., L7 can be designed to actively or passively locate the terminal E in each case by means of satellite navigation (e.g. GPS) or other technologies and related position information

to provide.

In the exemplary embodiment shown, the system for determining the contamination or impairment of persons by pollutants further comprises a processing unit 1 which is in data communication with the sensors S-, ..., Ss and the localization elements L;, .., L7. This is in the exemplary embodiment shown arranged outside the area R + of the industrial plant. In the exemplary embodiment shown, the processing unit 1 is arranged, for example, in a control center from which the machines which are located in the region R + of the industrial plant are monitored or controlled.

Alternatively, the processing unit 1 can also be located directly in the area R; arranged

be in which the people move for whom contamination or

Impairment from pollutants should be determined.

The processing unit 1 can optionally also the position of the terminal E, i.e. determine the person using triangulation, e.g. if as localization elements L ;, ..., L-,

Bluetooth low energy beacons are used.

FIG. 2 shows the result of a dispersion calculation which was carried out for one point in time on the basis of the pollutant values determined by the pollutant sensors S;, ..., S + 45. 2 shows the contamination by CO 2 in the form of isolines of the same CO 2 concentration for one point in time on a floor plan of the region R + of the industrial plant shown in FIG. 1.

As can be seen in FIG. 2, the contamination source Q shown in FIG. 1 prevails; the highest CO »concentration, which spreads in the direction of the side wall W3 of the area R; ı of the industrial plant, which lies opposite the side wall W +, on which the contamination source Q + is located. The CO concentration falls, as shown in FIG. 2, in the direction of the side wall W; or the side wall W », W ,, which are arranged normal to the two side walls W +, W3 of the area R + ı.

The spatial distribution of the individual pollutants or CO is shown in the embodiment shown in the form of a function of the pollutant, the spatial distribution by interpolation between those of the stationary

Sensors S- +, ..., Sı5 determined pollutant values is determined. In Fig. 3 is on the plan of the area shown in Fig. 1 R + ı of the industrial plant

the movement path of a person who carries a terminal E with them. The person moves from the door T; on the side wall W + towards the

Sidewall W; 3, then in the direction of the sidewall W ,, then again in the direction of the sidewall W + and then again in the direction of the sidewall W before it stops at the current position of the terminal E, which is shown in FIG. 1.

While the person is moving in the R + area, he is localized with the help of the terminal device E carried along at predetermined times and position information for the person is created for these times by the localization elements L;, ..., L7 or the processing unit 1. On the basis of this position information and the determined pollutant values, which are measured by the sensors S-;, ..., Sıs, the pollutant load of the person at their respective position is determined over time. The exposure with respect to the measured and spatially located environment variable can thus be measured in real time, which is carried out in the exemplary embodiment shown with triangulation around existing sensors.

In the exemplary embodiment shown, the total load is determined by summing the pollutant loads determined for the individual positions and times in the form of a total load to which the person is exposed. FIG. 3 shows such a total load for the person on their way shown in FIG. 1 through the area R + ı of the industrial plant to the current position at which the terminal E in FIG. 1 is located. As an alternative to this, the one-time load or the point load of a person at individual positions and times can also be used

be determined.

It can be seen from FIGS. 2 and 3a that while the person is or is in the vicinity of the pollutant source Q +, the greatest impairment of the person by the CO 2 that is emitted by the pollutant source Q + is greatest. so that the total exposure determined by summation of the individual pollution levels of the person at their respective position or at a particular time increases sharply, whereas it increases more slowly when the person moves away from the pollutant source Q +.

In the exemplary embodiment shown, the processing unit 1 is advantageously designed to continuously examine whether the total load on the person exceeds a predetermined threshold value Th and, if this is the case, one

Alert or take an alternative action.

As can be seen in FIG. 3 a, the cumulative total load on the person at the position at which he is currently in the R + range exceeds the predetermined threshold value Th for the total load, which is determined by the processing unit 1. The processing unit 1 is designed to, when such a threshold value exceeding the total load on the person is detected

Submit alarm information.

In the exemplary embodiment shown, the alarming information is transmitted to a terminal E carried by the person, for example a smartphone or tablet, which is designed to emit an alarm message corresponding to the alarming information. This is particularly advantageous since the system or method according to the invention for determining the contamination or impairment of people by pollutants enables monitoring of the person in real time and the total load on the person does not have to be evaluated manually, for example, after a shift has ended. Preventive or anticipatory measures are therefore possible and the person can be alerted before they occur

Total exposure assumes a harmful level.

This embodiment of the processing unit 1 advantageously also enables integration in or combination with existing security control systems, such as for fire protection.

FIG. 4 and FIG. 5 show two further examples for the determined total exposure of a person through summation or accumulation over the individual pollutant loads determined over time for the people at their respective positions. For this purpose, the local pollution of the person with CO and the total pollution are shown in FIGS. 4 and 5.

As can be seen in FIG. 4, the person was exposed to a high level of CO pollutants for a short period of time, so that the person's total exposure rose rapidly from an initially low level, which led to the predetermined threshold value Th being exceeded by that with an arrow marked time, whereby an alarm message was sent to the person and the person moved away from the area of the pollutant source, so that the total exposure of the person subsequently returned to the initial, low rate of increase.

In FIG. 5 it can be seen that the person has repeatedly passed smaller sources of pollutants in the course of their movement within the predetermined locally limited area, at which the local CO »concentration reaches local peak values. This led from the initially constant, slight increase in the total exposure to a sharp increase in the period in which the person was exposed to local pollutant sources, the total exposure to the person when he was exposed to the local CO »source for the third time, the threshold Th has exceeded for the total load, so that an alarm message has been sent to the person and the person has left the danger area or the area of the pollutant source.

Fig. 6 shows an example of an industrial plant with four rooms or delimited areas R-ı, ..., Rı. Each of the areas R-ı, ..., Rı is accessible from a hall F via a door T +, ..., T1. Furthermore, in each of the rooms or areas Rı, ..., Rı there is a sensor S- ;, ..., Sı, which is sensitive to pollutants of interest and is designed to determine the pollutant load by the respective pollutant (s) . The sensors S- ;, ..., Sı determine the respective pollutant values for the respective area R-ı, ..., Rı and a dispersion calculation is carried out on the basis of these pollutant values and the position and time information.

Since the rooms or areas R-ı, ..., R4 are comparatively small rooms, the next information source or the closest sensor S- + ;, ..., Sı is used for the propagation calculation and the respective certain pollutant value is used, the concentration n;, ..., na of the pollutant in such small areas R-ı, ..., Rı being regarded as constant in the respective area Rı; ı, ..., Rı. Thus, for example, for individual positions and times within the range R; each a concentration n; of the pollutant of interest.

FIG. 7 shows an example of a machine hall in which the spatially limited area R; has a comparatively large footprint. The area R + ı or the machine hall in the exemplary embodiment shown has a door T + through which the machine hall can be entered and an exhaust air system AL through which exhaust air from the machine hall is transported to the outside. Furthermore, two sensors S +, S, which are stationary sensor boxes and a pollutant source Q, are located in the machine hall near the sensor S- +.

In the exemplary embodiment shown, the air flow generated by the exhaust air system AL is used for the expansion calculation when air comes out of the machine hall or

the area R + ı is transported outdoors. 8 shows the concentration curve in the machine hall along a section AA. It can be seen that the sensor S; near the source of the pollutant Q + the measured concentration of the pollutant or the CO »is highest, while it drops in the direction of the position of the exhaust air system and

on the sensor S, has a comparatively low value.

The examples of industrial plants shown in FIG. 6 and FIG. 7 each represent extreme situations with their arrangement on many small, predetermined, locally limited areas R-ı, ..., Ra or a single, large area R + ı, which in large industrial complexes of course also occur in combination and also with a method or system according to the invention for determining the contamination or

Impairment of people can be monitored by pollutants.

As an alternative to stationary sensors, in a system or method according to the invention, the pollution can also be determined by means of mobile sensors S-, ..., Sı5, the current position of the sensors S-;, ..., Sı15 being continuously ascertained. This can be done, for example, using the network of localization elements L4, ..., L7. In this case, the sensors S-;, ..., S15 can be designed for data communication via a wireless data connection. The localization elements L;, ..., L- or the processing unit 1 can in this case be designed to locate the sensors Sı, ..., S15, in particular by means of NFC or RFID technology and provide relevant position information for each sensor S; , ..., Sı5 available. As an alternative, the position of the sensors S-, ..., Sı15 can be determined by triangulation, as already described at the beginning.

Claims (5)

1. method for determining the contamination or impairment of persons by pollutants, a) whereby by means of a number of sensors (S-, ..., Sı5) arranged for a particular pollutant within a predetermined locally limited area (R-ı, ..., Rı) each a pollutant value (n; n + ;, ..., Nnı) at predetermined times, b) whereby on the basis of the pollutant values determined in this way (n; n +, ..., Nnı) and the position and time of their determination, a dispersion calculation is carried out so that for individual positions and times within the specified locally limited range (R- ;, .. ., Rı) a pollutant value is available, c) wherein at least one person is localized within the locally limited area at individual times and position information for the person is created for these times, and d) where, based on the position information and the determined pollutant values (n; n4, ..., ns), the pollution level of the person at their respective position over time is determined. 2. The method according to claim 1, characterized in that in step a) the pollution by means of sensors (S +;, ..., S + 45), in particular sensor boxes, the spatially distributed stationary are determined. 3. The method according to claim 1, characterized in that in step a) the pollution is determined by means of mobile sensors (S +, ..., Sıs), the current position of the sensors (S-, ..., S15) being continuously determined becomes. 4. The method according to claim 2, characterized in that in order to determine the exposure to the individual pollutants in step b), a spatial distribution, in particular in the form of a function, of the respective pollutant is created, it being provided in particular that the spatial distribution by interpolation between the pollutant values (n) determined by the individual stationary sensors (S-, ..., S {5) is determined. 5. The method according to any one of the preceding claims, characterized in that to determine the position information in step c), the person carries a portable terminal (E) with him, the position of the terminal (E) and the person being active via a Person is determined. 6. The method according to any one of the preceding claims, characterized in that to determine the position information in step c) the person carries a portable terminal (E) with him, the position of the terminal (E) and the person passively via a network of localization elements (L +, ..., L45), in particular by means of triangulation, preferably continuously or at predetermined time intervals, it is provided in particular that the signal strength and / or field strength of individual, in particular all, localization elements (L;, ..., L; 5) of the network, in particular radio-capable localization elements (L;,. .., L45) is detected and the position of the terminal (E) and the person is determined on the basis of the detected signal strength and / or field strength. 7. The method according to any one of the preceding claims, characterized in that the person is localized in step c) by means of satellite navigation or Bluetooth Low Energy becomes. 8. The method according to any one of the preceding claims, characterized in that to determine the pollution level of the person in step d) from the determined pollutant values for a person a total exposure (> n) of the person by summation or other accumulation over the individual for the person their respective position over time determined pollution levels, especially for a certain period of time. 9. The method according to claim 8, characterized in that it is continuously examined whether the total load on the person exceeds a predetermined threshold value (Th) and if this is the case, an alarm is given. 10. The method according to claim 9, characterized in that, if a threshold value exceeding the total load (Xn) of the person is determined, alarm information is transmitted to the person, in particular a terminal device (E) carried along, and the latter emits an alarm message. 12. System according to claim 11, characterized in that the sensors (S-;, ..., Sı15) within a predetermined locally limited range (R-, ..., Ra) - Arranged spatially distributed, in particular as sensor boxes, or - Are arranged mobile, the localization elements (L +, ..., L-) and / or the processing unit (1) are designed to continuously determine the current position of the sensors (S- +, ..., S + 5) . 13. System according to claim 11 or 12, characterized in that the processing unit (1) is designed to - To determine the exposure to the individual pollutants, a spatial distribution, in particular in the form of a function, of the respective pollutant, in particular by - to determine the person's pollution from the determined pollutant values (n; n +, ..., Na) for a person, a total pollution (Xn) of the person by summation or other accumulation over the individual for the person at their respective position over time determined pollution levels, especially for one determined period. 14. System according to one of claims 11 to 13, characterized in that the processing unit (1) is designed to continuously examine whether the total load (Xn) of the person exceeds a predetermined threshold value (Th) and if this is the case, send an alarm. 15. The system as claimed in claim 11, comprising at least one terminal (E) carried by the person, the processing unit (1) being designed to send alarm information to the terminal when the total load (> Xn) of the person is exceeded. E) will be transmitted and that Terminal (E) is designed to issue a corresponding alarm message.