DE3242967A1 - Method and measuring instrument for measuring and processing characteristic quantities of the environmental atmosphere, particularly below ground - Google Patents

Abstract

In this method, in which the respective characteristic quantity is measured by means of a measuring instrument and indicated and then stored, clear informative information is obtained and can be processed rapidly and effectively in that the measurement value, after the characteristic quantity has been measured, is normalised to one or a number of parameters in the measuring instrument - triggered manually or automatically, and the normalised and possibly also the absolute measurement value are displayed and/or stored. In this connection, it is possible to input a normalising function or first to carry out calibration measurements and to calculate the normalising function from the calibration measurements. Apart from a power source, a measuring arrangement, an operating unit and a display unit, a corresponding measuring instrument has a normalising stage which is connected, on the one hand, to the measuring arrangement and, on the other hand, to the display unit. Given a correspondingly constructed normalising stage, adjustments at the measuring instrument itself can be omitted since all corrections can be done "mathematically".

Description

concerning a

"Method and measuring device for measuring and processing parameters the ambient atmosphere, especially underground " The invention relates to a method for measuring and processing parameters of the surrounding atmosphere, especially underground, in which the respective parameter is determined by means of a measuring device measured and displayed and then saved. The subject of the invention is also a veining device for performing such a procedure with an internal Power source, a measuring arrangement, an actuation unit and a display unit.

The measurement and processing of parameters of the ambient atmosphere is necessary in many applications, be it long-term information about the ambient atmosphere, be it for short-term information received, which are evaluated immediately. Especially in gas-polluted ambient atmospheres are measurements of this type in many cases for the safety of the surrounding atmospheres working people of crucial importance, namely to take security measures, if necessary, For example, venting or the like or being able to initiate rescue measures.

Such methods have been known for a long time, especially underground and are practiced all the time.

In the known method from which the invention is based, takes place the storage of the measured values of the respective parameter in writing, the Measured values of the respective parameters are thus od in evaluation sheets.

like. entered. In the mining industry, that is to say, in the case of ambient atmospheres Days the measured values are entered in a so-called weather book. These entries occur depending on the location, d. H. dn different places underground, so that in the long term recurring measurements made use of extensive comparison values can be.

An evaluation of the measured values of the corresponding parameters of the ambient atmosphere takes place at a later point in time, for example via comparison tables or like

In many cases it is the case that the measured and processed parameters the ambient atmosphere as such do not have an optimal information content because the boundary conditions under which the measurement took place are not or not exactly are known. In terms of occupational physiology, for example, it plays a role whether a specific air temperature measured at high or low humidity has been, a certain gas concentration in the surrounding atmosphere can be at different other conditions be differently dangerous, etc. The previous methods for measuring and processing parameters of the ambient atmosphere unfortunately do not yet provide sufficiently clear and meaningful information Specification, so that it is the object of the invention to provide a method of the in question Specify type with which clear, meaningful information is obtained and as quickly as possible and can be processed effectively.

The method according to the invention, in which the above task is solved, is characterized in that after the measurement of the parameter, the measured value in the measuring device - triggered manually or automatically - on one or more parameters is normalized and the normalized, possibly also the absolute measured value, is displayed and / or get saved. The term normalization is used here in a relatively broad sense to understand should also include a calibration of measured values, a linearization of measurement curves. How it is standardized in detail also and in particular depends on the respective measured parameter and on which parameter or parameters is normalized. For example, there is a normalization of the measured air temperature underground on the air pressure on the surface of the earth and on a certain, given air speed possible, so that a meaningful relative working temperature as a standardized measured value obtained the immediate conclusions on the physical load of each working people. Under certain circumstances, however, a standardization is only a zero point correction: ine sensitivity correction for a measuring arrangement od. like. Include. In any case, it is important to immediately consider one the boundary conditions meaningful measured value of a parameter of the To gain ambient atmosphere.

There are now a multitude of possibilities for the To design and develop the method, which is explained in the following only by way of example shall be.

First of all, it should be noted that the. .Normalization of measured values a parameter that not only depends on different parameters in the surrounding atmosphere depends, but also, for example, on the response curve of the corresponding Depending on the measuring device, mostly not only through computational consideration a constant can be done. Rather, it is mostly necessary to standardize in the form of a function, be it in the form of a function of the parameter or the parameter, be it in the form of a function "Correction value of the parameter in Dependence on the absolute value of the parameter ". Accordingly, a Embodiment of the method according to the invention, in which the normalization -ents-prec.hend a specifiable normalization function takes place.

It will not always be possible to use a normalization function from the outset to pretend. On the contrary, in most cases one becomes a normalization function first find it empirically. In this context, a further embodiment of the method according to the invention, which is of particular importance, consists of certain, to calculate a normalization function carried out in advance for calibration measurements of a parameter, to convert subsequently measured measured values of the parameter according to the normalization function and then display and / or store the measured values standardized in this way. Is how that If a zero point correction is often the case, this is the procedure expediently designed so that the calibration measurement is a zero point correction measurement is carried out. For the calculation of more complicated normalization functions, for example with a sensitivity that changes with the absolute value of the parameter to be measured of the measuring device, an embodiment of the method according to the invention is also recommended, the characterized in that at least one intermediate value calibration measurement is used as the calibration measurement is carried out. For example, it is used in addition to the zero point correction measurement If an intermediate value calibration measurement is carried out, it can be used as a normalization function calculate a straight line with an axis section corresponding to the zero point correction and one from the intermediate value calibration measurement compared to the zero point correction measurement determined slope.

In practice, the calibration measurements explained above can be used, for example perform so that a measurement is made in an ambient atmosphere in which the relevant parameter is exactly zero. The measured in this ambient atmosphere The measured value is saved as a zero point correction and when calculating the normalization function considered. Another calibration measurement at one both in terms of the actual Value as well as the state of the known with regard to the expected measured value Parameter as an intermediate value calibration measurement leads to a further correction value, which can be saved and used to calculate the normalization function. A straight line can be calculated as a normalization function on the basis of these two measured values.

This embodiment of the method according to the invention supports the fact Calculation that it is operationally often intended, with the actually present one Value "zero" of a parameter nevertheless to specify a measured value other than zero, thus possibly. Errors, breaks, module failures or the like safely can be determined.

With the purely computational correction implemented here according to the invention systematic, metrological and other errors in the measurement of parameters there is the very considerable advantage that the iterative Settings - correction of the zero point shift, correction of the sensitivity, Post-correction of the zero point shift, post-correction of the sensitivity, etc. - become superfluous.

The normalization explained above sometimes requires a measurement, the parameters necessary for this normalization in addition to the measurement of the actual parameter. Such measurements can take place simultaneously or one after the other.

It has already been indicated above that each parameter is a different one Normalization required, -some parameters will not require normalization at all, because they are meaningful enough when measured directly. In any case, should that is, the measured values of each parameter are normalized in a parameter-specific manner.

Sometimes it is advantageous if the measured values of the respective parameter can be linearized.

As far as the storage of the measured values of the respective parameter is concerned, a time-dependent storage is recommended, so that the time is also used as a parameter to win. Such a time-dependent storage can be done indirectly, namely via a predetermined path on which successive measurements take place, to a location-dependent one Measurement to be converted. However, it is more advantageous to use the measured values for the respective Parameter also location-dependent, if necessary by entering location code numbers or the like to save.

The storage of the standardized and possibly also the absolute measured values different parameters can basically, as before, in writing, underground for example in a weather book. With modern electronic However, it is possible to use a corresponding memory in a corresponding one To integrate measuring device. In this case, the stored measured values of the Transfer parameters to a central computer and from the central computer evaluated, possibly saved. and, if applicable, can be displayed.

The subject of the invention is of course also a measuring device for implementation of the method according to the invention. Lir A1tß (aerät of this kind has long been known (cf. DE-PS 15 98 520). The measuring device according to the invention is to solve the above specified task characterized in that a normalization stage is provided and connected on the one hand to the tleß arrangement, on the other hand to the display unit is. The normalization stage is expediently an electronic one Component, for example a microprocessor or the like. Appropriately is in the rest of a memory unit is provided in the measuring device, which is connected to the tleß arrangement and / or is connected to the normalization stage. In this storage unit you can the measured values of the various parameters, be they absolute or standardized, can be saved immediately, without having to be written down by hand. Between the lighting arrangement and the storage unit or

the normalization level and the storage unit can, if necessary is, an analog / digital converter can be provided, with the help of which the Measurement arrangement analog measured values in digital and thus storable signals can be implemented.

The measuring arrangement of the measuring device according to the invention should have a plurality be able to measure parameters. For this purpose, the measuring arrangement can be switchable so that the individual parameters or parameters can be measured one after the other, but it can also contain a plurality of different types of measuring elements, so that different Characteristic quantities or parameters can be measured simultaneously.

In connection with the method according to the invention it has been explained that the measured values of each parameter can be normalized for a specific parameter and should. Accordingly, the measuring device according to the invention is preferable so designed that a plurality of normalization functions in the normalization stage is adjustable. If the actuation unit now has a plurality of characteristic variable-specific Actuating elements, it recommends s: ch, the measuring arrangement and the standardization level to switch synchronously by actuating one actuator each, so that automatically the respective normalization function when the corresponding parameter is measured is set.

According to a further teaching of the invention is of particular importance, is in the normalization stage on the basis of the measured values from previously carried out calibration measurements a normalization function can be calculated. The normalization stage is then expedient for this purpose designed so that it is from a first switch position to carry out the calibration measurements can be brought into a second switching position to carry out the useful measurements. Here are finally preferably the calibration setpoints required for the calibration measurements Can be entered via the actuation unit For time-dependent measurement of parameters a timer is preferably provided. the time then automatically to The measured value of each parameter can be stored and, if necessary, also displayed t: aMn.

For location-dependent measurements of key sizes, as is usually the case should take place., a location input keypad should be provided for the code number be, the actuating unit preferably at the same time as a local input keyboard will be trained. Natural can also be used instead of a local keypad in every other conceivable way an entry of code numbers of the measuring locations is provided be.

In order to reduce the risk that it is sometimes carried out by an operator If you forget to enter the code number of a measurement location, it is advisable to use the Release the measuring arrangement only after entering a location.

According to a further teaching of the invention, which is of particular importance, a threshold value stage is provided in the measuring device and the measuring arrangement and possibly downstream of the normalization level. The threshold level is preferably with one acoustic and / or optical warning device connected and synchronized with the measuring arrangement and, if necessary, the normalization level switchable. via the threshold level, in connection with the warning device immediately and acutely triggered and emitted a warning signal through which the operator of the measuring device, e.g. underground, informed about a dangerous development of a parameter of the surrounding atmosphere will. Especially in connection with the normalization level, the threshold level is special Significance too, since when standardized measured values are specified, threshold values are readily available beforehand for maximum permissible gas concentrations etc. can be specified.

It has previously been explained that with the measuring device according to the invention With an appropriate configuration of the measuring arrangement, a large number of parameters are measured can be. Here it is advisable to design the display unit accordingly, so that the display unit not only has a numerical display, but is also provided with a parameter display. The parameter display can, for example using corresponding symbols that display the parameter that has just been measured.

In order to make it clear to the outside whether the measuring device is currently set to calibration measurement or just to useful measurement, the display unit expediently also a calibration / use function display.

It is advisable to connect the measuring device to a central computer an interface connection is provided. It is particularly practical> if that is otherwise yes portable, so can be carried by an operator Measuring device has on a narrow side a possibly coverable connector strip, via which it as such can be plugged into a socket on the interface of the central computer. The central computer can then also reprogram the measuring device, for example the normalization level, at least when the normalization level has a programmable microprocessor. The normalization level can of course also be part of a programmable microprocessor. Reference is made to this above been that the measuring device according to the invention has an internal power source. so However, it is easily possible that the internal power source once fails. In any case, it is recommended to equip the storage unit with a to provide its own internal power source or to design it in such a way that a failure the power source cannot destroy the contents of the memory. Appropriate Storage units are well known in modern electronics.

With the method according to the invention and the corresponding measuring device it is possible to quickly and effectively provide clear and meaningful information on a large number of of parameters and parameters, with modern electronics in addition offers the possibility to carry out extensive and multi-layered evaluations, For example, to create real "weather maps" for an area underground, which was far too time-consuming with the previous methods, i.e. practically impossible is.

In the following the invention is based on only one embodiment illustrative drawing explained in more detail; it shows Fio. 1 in a schematic Diagram of the func- tional relations t) when measuring and processing parameters of the ambient atmosphere, here in the subterranean weather stream, FIG. 2 is a block diagram a system for measuring and processing parameters of the ambient atmosphere, 3 shows a block diagram of a measuring device for a system according to FIGS. 2, 4 an embodiment of a measuring device according to FIG. 3, FIG. 5 and FIG. 6 diagrams for possible normalizations or calibrations in a measuring device according to FIG. 3.

In the schematic representation according to FIG. 1, a plurality can be seen of parameters or parameters of the ambient atmosphere, namely different gas concentrations 1 to 4, air temperature 5, air pressure 6, relative humidity 7, air speed 8 and an unspecified parameter 9. All these characteristics or parameters are fed to a measuring device 10. Except those previously mentioned and shown schematically Characteristic quantities and parameters are also the time 11 and the location in the measuring device 10 of measurement 12 recorded. All of these data are stored in a storage unit 13 saved, possibly after previous processing, display, etc., and can be accessed by the Memory unit 13 is called up in each case in a central unit (not shown here) will.

Fig. 2 shows more clearly how a corresponding system for measuring and processing of parameters of the ambient atmosphere can be set up are for measuring devices 10, which, like a number of other, non-illustrated liter measuring devices, Can be connected to the interface 15 of a central computer 16 via interface connections 14 are. In this central computer 16 can also be stored in the memory 13 of the Pcoßgeräte 10 stored data about the various parameters and par'anieter 1 to 9, 11, 12 are evaluated, worked up, sorted, corrected, standardized, etc. The central computer 16 for its part can be connected to an external computer 1'7, a printer 18, a memory inlet 19 and a user terminal 20, so conventional peripheral devices connected by computers. Assign the measuring devices 10 corresponding programmable Memory as it is extensively contained in microprocessors today, so can each measuring device, if necessary, from the central computer 16

program, save with evaluation data, etc.

A block diagram of a measuring device 10 for a system according to FIG. 2 is shown in FIG. A current source 21 is initially indicated here Supply of the entire measuring device 10, which as such, especially when in use under Taye, of course, must be freely movable, namely portable. At terhin points the measuring device 10 has a measuring arrangement 22, which, as not shown here is, a measuring chamber and a pump for sucking a gas sample into the measuring chamber, may also have several measuring chambers. How such measuring arrangements work is known from the prior art and does not require a detailed explanation here.

An actuating unit 23 is connected to the measuring arrangement 22 and the memory unit 13 already mentioned at the beginning. The actuation unit 23 has a plurality of actuating elements 24, which are only indicated in outline in the form of a keyboard. The measuring arrangement 22 is also provided with a normalization stage 25 and a threshold value stage 26 connected downstream of the normalization stage 25. The actuation unit 23, the normalization stage 25 and the threshold value stage 26 are connected to a display unit 27, the display unit 27 being a numeric Display 28 for displaying the measured value of a Parameter, a parameter display 29 and an optical warning device 30, actually a warning lamp. In the end A timer 31 is still connected and the memory unit 13 is connected to the time. so that the corresponding time mi @ is saved for all saved data can be.

The actuation unit 23 allows the measuring arrangement 22 to To switch measurement of different parameters and parameters. This switchover can of course also be done automatically, for example if you have a special Wants to measure the parameter, but has the corresponding parameters for this desired parameter, that are important for their classification should be measured. The actuation unit 23 with the button-like actuating elements 24 also serves as a local input keyboard, i.e. Via the actuation elements 24 of the actuation unit 23, location data, L) e.g. special code numbers are entered. That way it is possible to assign measured values of certain parameters to certain locations, which in particular is of considerable importance.

It cannot be seen in FIG. 3 that the measured by the measuring arrangement 22 Measured values, if they are measured in analog, via an analog / digital converter out and can be digitally stored in the memory unit 13 is that with the measuring device 10 shown in Fig. 3 via the parameter display 29 it can be seen immediately which parameter is being measured and indicated that the numerical display 28 of the display unit 27 clearly and the respective measured value clearly shows that via the warning device 30 from the threshold level 26 ago the respective operator when the threshold value of the respective is exceeded Characteristic can be acutely warned that any notes of measured values are not more must be done and that an optimal evaluability of the measured, processed and stored data is given.

It is not shown in FIG. 3 that the memory unit 13 has a own energy buffer, so that even if the power source fails 21 the memory content of the memory unit 13 stored up to that point is not lost goes.

FIG. 4 shows a front view of a measuring device 10 according to FIG. 1. Can be seen is the actuation unit 23 of the measuring device 10 with the actuation elements 24.

The actuating elements 24 are recognizable double occupied here, that is Executed as double-assigned function keys, namely, on the one hand, allow a selection the parameter to be measured in each case or the parameter of interest in each case allow, on the other hand, a coded entry of the measurement location in the form of code numbers. The display unit 27 with the numerical display 28 and the Warning device 30, has previously been explained in connection with FIG. 3 that the Measuring device 10 has a normalization stage 25. This normalization level 25 is natural in particular easily foreseeable when modern microelectronic Components, such as microprocessors, are used. About the normalization level 25 can normalize the respective measured value of a parameter to one or several parameters take place. In the diagram in Fig. 5, the measured value gas concentration, for example CH4> corresponding to the concentration of the to be measured Gas changing sensitivity of the measuring arrangement 22 corrected. That's about that Normalization stage 25 with a given sensitivity curve f of the measuring arrangement 22 easily possible.

In the diagram in Fig. 6, a linearization is one of the measuring arrangement 22 measured measured value recognizable, which is also via the normalization stage 25 can be done.

Not shown in the figures or not recognizable in detail is that in the normalization stage 25 on the basis of the measured values of previously carried out Calibration measurements a normalization function can be calculated that the normalization stage 25 of a first switch position for performing calibration measurements in a second switch position to carry out useful measurements can be brought that the necessary for the calibration measurements Calibration setpoints can be entered via the actuation unit 23 and that the display unit 27 has a calibration / use function display.

Finally, for the sake of completeness, it should be pointed out that that of course the number of parameters and parameters according to your preference and area of application can be chosen, which is ultimately a question of cost.

Finally, the function of the previously in various Context explained measuring device 10 in the context of the system according to FIG. 2 be: The corresponding operator, for example an underground riser, checked on a tour a plurality of measuring locations, each through a permanently affixed code number are identified. Arrived at a certain place gives this operator via the actuating elements 24 of the actuating unit 23 enter the code number of the location, this code number is stored in the memory unit 13 saved. Then the measuring arrangement 22 is released and the operator selects the parameter to be measured, for example the air temperature 5. Simultaneously with the air temperature 5, which represents the actual parameter, are used for extraction a relative working temperature of the air pressure 6, the relative humidity 7 and the air speed 8 measured as parameters. Then on the one hand the air temperature 5 absolute, on the other hand a via the normalization level 25 on the parameters air pressure 6, relative humidity 7 and air speed 8 normalized measured value of the air temperature 5 is stored. The latter standardized The measured value is also displayed as it gives an indication of the actual physical Load of the people in this place.

This normalized measured value is also fed to the threshold value stage 26, so that when this-relative measured value at some place an absolute upper limit exceeds, emitted an optical warning signal immediately by the warning device 30 will. With the explained measuring device 10 can therefore be a for the operator gain current statements, while at the same time longer-term investigations and Observations via the central computer 16 to which the measuring device 10 is later connected can be realized. The measuring device 10 sets, on the underground operation related, to a certain extent represents an electronic weather book.

Claims (30)

Claims: Method for measuring and processing parameters the ambient atmosphere, especially underground, by means of a measuring device the respective parameter is measured and displayed and then saved, d a d u r c h g e -k e n n n z e i c h n e t that after the measurement of the parameter the measured value in the measuring device - triggered manually or automatically - on one or more parameters is normalized and the normalized, possibly also the absolute measured value, is displayed and / or get saved. 2. The method according to claim 1, characterized in that the normalization takes place in accordance with a specifiable normalization function. 3. The method according to claim 1 or 2, characterized in that a normalization function from specific, previously performed calibration measurements of a parameter calculated, then measured values of the parameter according to the normalization function converted and the standardized measured values displayed and / or saved. 4. The method according to claim 3, characterized in that the calibration measurement a zero point correction measurement is carried out. 5. The method according to claim 3 or 4, characterized in that at least one intermediate value calibration measurement is carried out as a calibration measurement. 6. The method according to any one of claims 1 to 5, characterized in that that in addition to the respective parameter also the parameters necessary for the normalization be measured. 7. The method according to any one of claims l to 6, characterized in that that the measured values of those parameters are normalized for specific parameters. 8. The method according to any one of claims 1 to 7, characterized in that that the measured values of the respective parameter are linearized, 9. Procedure according to one of claims 1 to 8, characterized in that the measured values of the respective Parameter can be saved as a function of time. 10. The method according to any one of claims 1 to 9, characterized in, that the measured values of the respective parameter are location-dependent, if necessary by entering location code numbers or the like. 11. The method according to any one of claims 1 to 10, characterized in, that the stored measured values of the parameters are transferred to a central computer and evaluated by the central computer, ggt. saved and displayed if necessary. 12. Measuring device for performing the method according to one of the claims 1 to 11, with an internal power source, a measuring device, an actuation unit and a display unit, characterized in that a normalization stage (25) provided and on the one hand with the measuring arrangement (22), on the other hand with the display unit (27) is connected 13 .. Measuring device according to claim 12, characterized in that one Storage unit (13) provided and the storage unit (13) with the measuring arrangement (22) and / or the normalization stage (25) is connected. 14. Measuring device according to claim 12 or 13, characterized in that With the measuring arrangement (22), a plurality of .Kennizens or parameters can be measured. 15. Measuring device according to one of claims 12 to 14, characterized in that that a plurality of normalization functions can be set in the normalization stage (25) is. 16. Measuring device according to claim 15, characterized in that the actuating unit (23) has a plurality of characteristic variable-specific actuating elements (24) and that the measuring arrangement (22) and the normalization stage (25) by actuating one Actuating element (24) simultaneously to the respective parameter or the respective Normalization function are switchable. 17. Measuring device according to one of claims 12 to 16, characterized in that that in the normalization stage (25) on the basis of the measured values from previously carried out Calibration measurements a normalization function can be calculated. 18. Measuring device according to claim 17, characterized in that the normalization stage (25) from a first switch position to carry out the calibration measurements into a second switch position can be brought to carry out the useful measurements. 19. Measuring device according to claim 17 or 18, characterized in that the calibration setpoints required for the calibration measurements via the actuation unit can be entered. 20. Measuring device according to one of claims 12 to 19, characterized in that that a timer (31) is provided and automatically for the measured value of each parameter Time can be saved and, if necessary, displayed. 21. Measuring device according to one of claims 12 to 20, characterized in that that a local input keyboard is provided and preferably the operating unit (23) is designed at the same time as a local input keyboard. 22. Meter after. Claim 21, characterized in that the measuring arrangement (22) can only be released after entering a code. 23. Measuring device according to one of claims 12 to 22, characterized in that that a threshold value stage (26) is provided and the measuring arrangement (22) and possibly the Normalization level (25) is switched on 24. Measuring device according to claim 23, characterized characterized in that the threshold level (26) with an acoustic and / or optical Warning device (30) is connected. 25. Measuring device according to claim 23 or 24, characterized in that the threshold value stage (26) synchronous with the measuring arrangement (22) and possibly the normalization stage (25) is switchable. 26. Measuring device according to one of claims 12 to 25, characterized in that that the display unit (27) has a parameter display (29). 27. Measuring device according to one of claims 17 to 19 and optionally one of the Claims 20 to 26, characterized in that the display unit is a calibration / use function display having. 28. Measuring device according to one of claims 12 to 27, characterized in that that an interface connection (14) for connecting the measuring device (10) to a central computer (16) is provided. 29. Measuring device according to claim 28, characterized in that the normalization stage (25) can be reprogrammed from the central computer (16). 30. Measuring device according to one of claims 12 to 29, characterized in that that the normalization stage (25) is a microprocessor, preferably a freely programmable one Microprocessor.