DE29500705U1 - Device for determining a certain proportion of gas in the air - Google Patents

Description

Device for determining a specific gas content

the air

The invention relates to a device for determining a specific gas content in the air.

Stationary measuring devices are known with which the gas components of the air are analyzed, recorded and fed into reporting systems in order to be able to trigger an alarm to the affected population in the event of certain gas contamination levels. The measuring stations are large measuring stations that are installed at a great distance from one another and are usually operated by district offices or environmental protection authorities.

The warnings for certain gases, such as monoxide, CO2/chlorine gases, and in particular the warning about excessive ozone levels in the air, are based on average values and assume that limit values are generally harmless to health. Individual limit values and the completely different regional exposure to high gas levels are not taken into account.

The invention is based on the object of designing a measuring device of the generic type that allows at any time and in any place to determine at least the gas content of the air that could cause health damage, e.g. ozone, so that the user of such a measuring device can decide, taking into account his personal tolerance of certain limit values, whether to expose himself to the high gas content or to go to a room in which he is not exposed to these burdens.

The invention solves the problem by the design of a handy measuring device as specified in claim 1.

The invention is based on the use of known gas sensors that change their resistance depending on the gas content. According to a calibration, these deviations are evaluated depending on the gas content of the gas or gas mixture to be measured. Known gas sensors consist, for example, of a sensor material applied to a ceramic substrate using thick film technology and the associated contact electrodes and a platinum heating coil also printed on the ceramic substrate. The sensor and heating coil are connected to the connection pins of the sensor housing using platinum wires, for example. These sensors have the advantage over other known sensors that they are manufactured without additives or catalysts and do not contain any toxic substances. The active sensor material is selected so that it has maximum sensitivity to the gas concentration to be measured, e.g. nitrogen oxide compounds or chlorine. The power loss of such sensors is in the range of approx. 950 mW. When designed accordingly, the sensors show a linear increase in resistance with increasing NO2 and/or CI2 concentration. The sensitivity is given as a percentage of resistance change per ppm gas concentration. Zero point drifts of typically < 5%/year and fast thermal stabilization times are further advantages of such sensors. However, the invention also allows the use of other known sensors.

When using chlorine sensors, it has been shown that the ozone content of the air can also be measured if they are set to a certain sensitivity. To do this, the sensor is heated to approx. 30% of the temperature required to measure chlorine gas. The nominal sensor working temperature for chlorine gas measurement, for example, is approx. 400 ⁰ C, while for ozone gas measurement the working temperature is approx. 130 ⁰ C.

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sufficient. After just a few seconds of preheating, this temperature is reached and the measurement is possible.

The health risks, e.g. caused by ozone, are well known. If the ozone content in the air is over 360 pg/m3, there is an increased health risk. If the content is < 90 ug/m3, the air is completely harmless, at least as far as the ozone content is concerned, so that one can go outside without having to fear any harmful effects on health from too high an ozone content in the air. This of course also applies in reverse to closed rooms, e.g. those in which there are laser printers and copiers, which are known to produce ozone.

In addition, excessive UV radiation is harmful to health, especially when sunbathing outdoors. In a further development of the invention, a combined evaluation and display of both the ozone content and a UV radiation measurement and display of the measured value are therefore provided so that the user of such a device can inform themselves about both harmful effects. This also applies to the isolated or continuous recording of measurement data for other gases and gas components.

Advantageous embodiments of the invention are specified in detail in the subclaims.

The measurement of the gas content, e.g. ozone, or UV light does not need to be carried out permanently, but should be able to be carried out optionally when, for example, the person who owns such a device wants to sunbathe and find out about the current air condition in the area. Due to the relatively high power consumption when heating up the specially specified sensors, only a short-term

Measurement is desirable so that a device can also be operated with batteries. Of course, operation with an additional power supply is also possible. The handy device has a chamber in which the sensor or, in the case of several sensors, these are housed. To prevent them from being damaged, the cover has openings or slots or consists of a grid that is highly permeable to air, so that the measurement can be carried out through the sensor located in the chamber.

Since such a device is also carried in a pocket, it is recommended that the push button for triggering the measurement be recessed or that it be provided with a recess so that none of the parts protrude above the surface. In the event that a push button with the actuating head protrudes from the plane, it cannot be ruled out that a continuous measurement will be carried out due to contact pressure when carried in a pocket and that the battery will therefore lose power very quickly.

Since the subclaims contain self-explanatory features, reference is made to them in addition.

The invention is explained in more detail below using the embodiments shown in Figs. 1 and 2.

In Fig. 1, an ozone measuring device according to the invention is shown in perspective. This small, handy device, which has dimensions of approx. 6 x approx. 4 x approx. 1.5 cm (length x width x height), consists of a lower housing shell 1 and an upper housing shell 2 with a display 4 incorporated into the surface, a reflection display that enables the measured values to be displayed in digital form. In the upper area of the housing, a chamber is provided in which the measuring sensor is arranged. This chamber is covered by the slotted cover of the

Top cap 2 covered. The cover 18 is part of the upper shell of the housing and is provided with slots 3. The housing is expediently made of plastic. Sufficient air can flow into the measuring chamber through the slots 3 for exchange so that the measurements can be carried out at the respective measuring location. The respective measurement is triggered by pressing the push button 5, which in the example has a protruding actuation button but should expediently have a recessed actuation button so that no unintentional measurements can be carried out by contact pressure or by placing the measuring device with the top on a surface.

To make it easier for a person unfamiliar with the measured values to evaluate them, measuring ranges are indicated on a scale 6 which can be highlighted in color, for example for a measurement < 90 μg/m3 the color is green, up to 180 μg/m3 the color is yellow, up to 360 μg/m3 the color is orange and > 560 μg/m3 the color is red. In this way the person can immediately make a comparison and see whether the air is contaminated with ozone in a way that is hazardous to health or not. The sun pictograms 19 are assigned to the measuring ranges and indicate whether it is advisable to sunbathe or whether this is to be avoided. Instead of the range display or the digital display, or in addition to this, light-emitting diodes, preferably colored ones, can be used to display a measured value within a measuring range as a warning.

In order for this measuring device to function, it must have appropriate circuits. The measuring circuit with a sensor is shown in the form of a block diagram in Fig. 2.

The measuring circuit has a microcomputer 7, which has memory areas in which programs for control are stored, as well as RAM memory

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areas/ in which measured values can be saved. The microcomputer has a measuring input to which a signal amplifier input 10 is connected, which feeds the analog measuring signal generated by the ozone sensor 8 to the microcomputer 7 in an amplified form. By means of an integrated analog/digital circuit, the signals are converted into digital measured values, which are processed by the microcomputer according to a registered program, saved and/or shown on the display 6.

This shows the measured ozone content directly or allows stored values to be called up optionally by pressing a corresponding function key, which is not shown. The sensor 8 is, for example, a known sensor, for example one with a heating driver 9, which is provided as an operational amplifier and has a reference voltage 11 on its second input, which sets the sensitivity of the sensor. The measurement is triggered by pressing the switch 17 by pressing the actuation button in Fig. 1. The power supply paths, which are also switched on to the heating circuit in parallel, are not shown for the sake of simplicity. Closing the switch 17 switches the system from standby mode to measuring mode. The standby circuit 12 for supplying power to the microcontroller in the switched-off state is switched off and the power supply 13, e.g. a battery, is switched on. At the same time, the voltage from the power supply 13 to the heater is switched on via connections on the heater driver (not shown). After just a few seconds, the measuring device displays the measured ozone content. The switch 17 can be opened again so that the device returns to standby mode and the measurement is interrupted. It is also possible to set a timer using the microcontroller in such a way that a measurement is triggered when the push button 17 is pressed once and an automatic

automatic shutdown. The power supply 13 can also be replaced by an external power pack 14, for which purpose a corresponding contact socket must be provided in the device according to Fig. 1 in order to be able to connect the power pack. Furthermore, in order to be able to evaluate several measurements, the device can have a parallel or serial interface in order to be able to query the measured values stored in a RAM. It is also possible to carry out, for example, UV measurements, chlorine gas measurements, etc. using additional buttons and sensors. The chlorine gas measurement is easy to implement by increasing the heating of the sensor if the sensor is a combined chlorine gas/ozone sensor.

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Claims (26)

G 395 16.01.95 Protection claims 1. Device for determining certain gas proportions in the air, consisting of a handy housing (1, 2) with a receiving device for at least one sensor for measuring at least one gas or gas mixture in the air, which sensor is arranged behind an air-permeable cover (18), with at least one measuring circuit (7, 8, 9), with a display device (6) for displaying the measured gas or gas mixture content or a measured value within a measuring range and with a voltage supply device (13) and a switch (5, 17), via which, when actuated, the measuring circuit (7, 8, 9) with the sensor (8) can be switched on for the measurement only briefly. 2. Device according to claim 1, characterized in that the display device (6) is a display for displaying the actually measured value of the gas content as a digital value and/or consists of lighting means, in particular light-emitting diodes, which light up depending on a measured value within a measuring range. 3. Device according to claim 1, characterized in that the voltage supply device is batteries or rechargeable accumulators which are arranged in a battery compartment which is accessible from the rear side or one of the side walls or front surfaces. 4. Device according to claim 3, characterized in that the device has a plug contact for connecting an external power supply or a charging circuit and that in the case of connecting an external device a switching contact can be actuated when the plug is inserted into the plug contact, which switches off the internal voltage supply (13) and switches on the external one. 5. Device according to claim 1, characterized in that the switch (5, 17) is a pushbutton switch whose actuating button is recessed or has a recess for actuation. 6. Device according to claim 1 or 5, characterized in that a timer is coupled to the switch (5, 17) which controls the measurement independently of the actuation time of the switch (5, 17). 7. Device according to claim 1, characterized in that below the display on the top side range values (6) are indicated, which enable an assignment to health-relevant magnitudes of the measured values. 8. Device according to claim 7, characterized in that several areas are arranged marked in different colors. 9. Device according to claim 8, characterized in that warning pictograms (19) or warning notices are assigned to the individual areas. 10. Device according to claim 1, characterized in that the display (6) also indicates the unit of measurement. 11. Device according to claim 1, characterized in that the circuit has an analog/digital converter which converts the measured analog value of the sensor into a digital value which is shown on the display (6) as the actual measured value. 12. Device according to claim 1, characterized in that a loop or a clip is provided on the back of the device in order to be able to attach the device to a belt. 13. Device according to claim 1, characterized in that the sensor is a sensor for measuring the ozone content and/or chlorine gas content and/or monoxide content and/or oxygen content and/or carbon dioxide-CO2 content. 14. Device according to claim 13, characterized in that the ozone sensor (8) is a chlorine sensor whose sensitivity is set to the measurement of ozone gases. 15. Device according to claim 14, characterized in that by applying different heating currents, the sensor can be used optionally for chlorine gas measurement or ozone gas content measurement and optionally an evaluation takes place in the measuring circuit. 16. Device according to claim 15, characterized in that a switch is provided with which the corresponding measuring mode is switched over. 17. Device according to claim 1 or 13, characterized in that a UV light measuring sensor is additionally integrated into the device. 18. Device according to claim 17, characterized in that the UV radiation measurement is carried out in parallel, simultaneously or separately. 19. Device according to claim 1, 17 or 18, characterized in that an evaluation circuit is included which evaluates the measured values of the ozone content and those of the UV light according to a predetermined program and outputs the evaluation result to a display control circuit which outputs either the individual values or an indication of environmentally adapted behavior. 20. Device according to claim 1, characterized in that a printer interface is provided. 21. Device according to claim 1 or 13, characterized in that several measured values can be stored and printed out together with the date and time. 22. Device according to claim 1, characterized in that the display is a reflection display. t * 23. Device according to one of the preceding claims, characterized in that the respective measurement signal is applied to an input of a microprocessor μ�R (7) which carries out the measurement value acquisition, evaluation, display and, if necessary, the retrievable storage according to a written program. 24. Device according to claim 23, characterized in that the microprocessor controls all functions. 25. Device according to claim 1, characterized in that the sensor is arranged in the housing and the housing wall has an air-permeable cover (18) in the area of the sensor. 26. Device according to claim 25, characterized in that the housing wall has slots.