DE102012221436A1 - Method for establishing gas sensor in gas phase for detecting concentration of specific gas, involves evaluating measured value of concentration of gas with aid of calibration performed in gas sensor, and transmitting evaluated result - Google Patents

Abstract

The method involves calibrating the gas sensor according to reference gas concentration of specific gas. The reference gas concentration is known, and measured time is less than duration of measurement in steady state for the calibration. A measuring time shorter than time period for the measurement in steady state is measured using calibrated gas sensor. A measured value of the concentration of gas is evaluated with aid of calibration, and the result of evaluation is transmitted. An independent claim is included for a gas analysis apparatus.

Description

The invention relates to a method for a gas sensor or sensor in the gas phase.

Background of the invention

From the prior art bottling plants for food are known. In these filling systems, the containers must be largely germ-free, depending on the product to be filled. For this purpose, the containers to be filled are usually sterilized directly before the filling process to inactivate germs that adhere to the surface during the manufacture of the container or the transport of the material.

This ensures that the packaged foods over a longer period of time and sometimes also be kept frozen.

For sterilization, in principle, different processes, such as e.g. Irradiation by UV or ionizing radiation, or fumigation with ethylene oxide or rinsing with peroxyacetic acid, can be used.

By far the most common sterilization process uses hydrogen peroxide (H ₂ O ₂ ) at different concentrations and in different exposure times. The effectiveness can also be increased by an increased temperature.

However, an increase in the temperature is not everywhere possible, otherwise the material is attacked and / or more residues of the sterilizing agent adhere.

Due to the cycle times during filling a low exposure time is required. Critical parameter is therefore the concentration of the sterilizing agent, which should preferably be achieved throughout the container at least over a partial period.

To ensure this, measurements are taken.

Although one could look at individual containers downstream in terms of their germ load, but this method would not be able to respond quickly to contamination, so that the shelf life could not be guaranteed.

It would therefore be desirable to be able to measure the concentration directly. However, previous gas sensors are not able to do so because they require a measurement in the steady state, the settling time being above the cycle times of the filling plants.

It is therefore an object of the invention to provide an improved method and apparatus which solves the disadvantages of the prior art in an inventive manner.

The object is achieved by a method for a gas sensor, wherein the gas sensor is set up to detect the concentration of a certain gas or a plurality of specific gases or a composition of a gas mixture, wherein the gas sensor for the measurement in a steady state requires a period of time that is greater than the available gas concentration time. The method includes a step of calibrating the gas sensor using at least a reference gas concentration of the particular gas, the reference gas concentration being known and the measurement time for calibration being less than the time period for the measurement in a steady state, a step of measuring by the calibrated gas sensor a gas concentration of the determined gas, wherein the measurement time is less than the time period for the measurement in a steady state, and a step of evaluating the measured value by using the calibration and passing the result of the evaluation on.

This allows the invention to provide a fast and direct measurement.

In an advantageous embodiment of the invention, the step of calibrating a plurality of measurements, wherein the total time of the measurements is smaller than the time duration for the measurement in a steady state.

As a result, the invention achieves that the measurement accuracy is increased.

According to yet another embodiment of the invention, the step of measuring comprises a plurality of measurements, wherein the total time of the measurements is less than the time duration for the measurement in a steady state.

This makes it possible to also detect the dynamic behavior of gases in terms of their concentration.

In yet another advantageous embodiment of the invention, the method comprises the step of forwarding a measured value by means of wireless connection technology.

This makes it possible to carry out measurements within a process line without the measurement being disturbed by cabling.

Furthermore, the object is achieved by a gas analyzer, wherein the gas analyzer is arranged to measure the concentration of a certain gas or gases or the composition of a gas mixture, the gas analyzer for measuring in a steady state requires a time larger than the available time of the gas concentration. The gas analyzer has at least one gas sensor for measuring a gas concentration of the particular gas, the measurement time being smaller than the time period for the measurement in a steady state, calibration data generated by at least one reference gas concentration of the specific gas, the reference gas concentration being known, and the Measuring time for calibration is smaller than the time duration for the measurement in a steady state, and an evaluation unit for evaluating measured values of the at least one gas sensor with the aid of calibration and for passing on the result of the evaluation.

This makes it possible for the invention to provide a fast and direct measurement.

In an advantageous embodiment of the invention, the gas sensor is a calorimetric gas sensor.

As a result, the invention achieves that gas sensors can be used with a flat design, which are easy to integrate and therefore only marginally affect the measurement environment.

According to yet another embodiment of the invention, the gas to be measured reacts exothermically during the measurement.

In an advantageous embodiment of the invention, the at least one gas sensor is connected to the evaluation unit by means of a wireless interface.

In accordance with yet another embodiment of the invention, the at least one gas sensor is by means of a wireless ZigBee interface, eg an interface according to standard IEEE 802.15.4 or a successor to this, connected to the evaluation unit.

This makes it possible to carry out measurements within a process line without the measurement being disturbed by cabling.

In an advantageous embodiment of the invention, the gas analysis device has a plurality of gas sensors.

This makes it possible to provide measurements at different locations at the same time, whereby the measurement effort can be minimized.

According to yet another embodiment of the invention, the gas analysis device has a plurality of gas sensors, wherein the plurality of gas sensors is placed in a test container or space.

In this way, the invention enables the measurement of gases or gas concentrations during operation of a filling plant for food or medical devices.

The invention will be explained in more detail with reference to the figures. In these shows:

1 _{4 is} a graphical representation of a temperature profile of an exemplary calorimetric gas sensor and an associated volume concentration of an exemplary H ₂ O ₂ gas to be measured;

2 a graphical interpolated representation of a temperature difference with respect to a volume concentration of an exemplary H ₂ O ₂ gas to be measured,

3 an exemplary course of a temperature on an exemplary calorimetric gas sensor over time,

4 an exemplary container with points for measuring the concentration of a certain gas or gases or the composition of a gas mixture, and

5 an exemplary arrangement of devices according to the invention in functional terms.

Hereinafter, the invention will be illustrated in more detail with reference to the figures.

First, it is believed that a gas sensor to be used, eg, a calorimetric gas sensor and / or a thin film gas sensor, typically requires a relatively long settling time to provide a stable measurement result. However, this settling time is longer than the available measuring time. That is, the measurement setup would not be useful in the classical sense. Typical cycle times depend on the product and the size of the container. A Exemplary size used in the following is a tact time of about 2 seconds or less. An exemplary container size is 1 dm ³ or 1 l and a typical product is, for example, a saline solution of an infusion, milk or juice.

An example of this is an implementation of a gas sensor CGS via a remote unit RU, which is connected to a base unit BU and an evaluation site UI, as shown schematically in FIG 5 shown.

Without being limited to a specific type of wireless interface, particularly wireless interfaces from the Nahfunktechnik are, with W-LAN, ZigBee, RFID and UWB are cited as representative. This makes it possible to carry out measurements within a process line without the measurement being disturbed by cabling.

For example, the gas sensor CGS may be provided as a calorimetric gas sensor with a thin-film resistor or a thermopile as a temperature-sensitive element or as a polyimide-based gas sensor. Depending on the sensitivity and speed, a suitable sensor can be selected here. The gas sensor has for this purpose an activated and a passivated gas sensor element.

Calorimetric gas sensors, and in particular thin-film sensors, allow easy integration due to their flat design and therefore only marginally influence the measurement environment.

The gas to be measured is then preferably a gas which reacts exothermically during the measurement, so that a higher temperature occurs on the activated gas sensor element than on a passivated gas sensor element.

Furthermore, for example, the evaluation site UI can be a suitable terminal, e.g. a computer or microcontroller equipped with appropriate application software. In particular, the application software can also be part of an automation computer, which otherwise also performs control tasks, e.g. a filling plant takes over.

The remote unit RU may also have a control unit PU to control the gas sensor CGS accordingly or to prepare the data obtained for the transmission to the evaluation site UI. Furthermore, the control unit PU, with a suitable selection, can also carry out an evaluation of the data obtained.

For example, the control unit PU may include a microcontroller, e.g. 8051 or 6805 or the like, the corresponding digital-to-analog converter drives to form current sources of, for example, 1 mA. By means of the power sources, the gas sensor CGS is supplied. By analog-to-digital converter, e.g. a delta-sigma converter, with a corresponding resolution, e.g. 20 bit, one of the sensor interfaces is read out. From the different signals of the active and the passive gas sensor element, a difference value can be formed, wherein a sampling in the range of, for example, 1 KHz can be realized. Depending on the concentration of a particular gas, the temperature of the active gas sensor element and thus the resistance changes.

However, since the available measurement time is less than the time that would be necessary to achieve the stable, steady state, now the temperature difference .DELTA.T _signal between the activated gas sensor element T _active and the passivated gas sensor element T _{passive is used} as a measurement signal. Exemplary is in 1 the corresponding temperature profile of the active gas sensor element and the passive gas sensor element superimposed shown in the upper part of the figure, while in the lower part of the figure, the corresponding temperature difference is shown. The concentration of the gas to be measured H ₂ O _{2 was changed} according to the dashed curve. It can be clearly seen that when the concentration of the gas to be measured H ₂ O ₂ changes, the difference in temperature changes, with the difference increasing with increasing concentration. Furthermore, it can also be seen that due to the hot gas flow (here about 240 ° C) although so warming of the sensor elements occurs, but this heating at a gas flow, which is free of gas to be measured, show essentially no difference.

In 2 is the corresponding assignment of different concentration values for the measured temperature difference .DELTA.T _signal between the activated gas sensor element T _active and the passivated gas sensor element T _passive indicated, it can be seen that the course in the specified concentration spectrum of the gas to be measured is substantially linear, where it - the difference at concentration 0% v / v off 1 apparent - only a minimal offset needs.

In 3 is the temperature difference _signal .DELTA.T _signal between the activated gas sensor element T _active and the passivated gas sensor element T _passive for a fixed concentration of the gas to be measured from here 7.6% v / v shown, the repeatability at least with respect to the respective Peak values for three measurements under the same concentration conditions is shown.

In order nevertheless to obtain an allocation to a concentration value under these circumstances, the gas sensor is now calibrated under calibration conditions.

For this purpose, the gas sensor is calibrated by means of at least one reference gas concentration of the particular gas, wherein the reference gas concentration is known and the measurement time for calibration is less than the time duration for the measurement in a steady state. For example, in the presentation of the 1 a constant gas flow of about 10 m ³ / h at the same temperature of about 240 ° C set, and each measured three signal peaks. It should be noted that, of course, dynamic measurements are possible, which allow an improved allocation.

In an advantageous embodiment of the invention, the step of calibrating a plurality of measurements, wherein the total time of the measurements is smaller than the time duration for the measurement in a steady state.

This increases the measurement accuracy.

Subsequently, the now calibrated gas sensor CGS can be used for the measurement.

For this purpose, by means of the calibrated gas sensor CGS, the measurement of a gas concentration of the specific gas, wherein the measurement time is smaller than the time duration for the measurement in a steady state. Subsequently, the measured value or the measured values are processed with the aid of the calibration and passing on the result in the evaluation unit.

This makes it possible for the invention to provide a fast and direct measurement. Advantageously, a plurality of measurements can also be performed within a clock interval, wherein the total time of the measurements is less than the time duration for the measurement in a steady state.

This makes it possible to also detect the dynamic behavior of gases in terms of their concentration.

Without this in 5 In more detail, the remote unit RU can also control more than one gas sensor CGS and process the received data. This allows different measuring points, as in 4 sketched on the example of a test container, so that measurements within a process cycle of different measuring points are available.

For example, using the example of a test container, which is embodied here as a gable container, a measuring point, ie a gas sensor, could be arranged at the height of the lid T to be folded. Other hard-to-reach points, such as corners on the ground BE ₁ and BE ₂ , and / or more easily accessible measuring points, such as on the center of the bottom BM or on the center of a side wall M, may also be supplied with measuring points. Typically, a gas nozzle G is introduced into the container in the test container in the sterilization process and within the cycle time, the container is blown out by a sterilizing gas escaping.

This makes it possible to provide measurements at different locations at the same time, whereby the measurement effort can be minimized. For example, gases or gas concentrations can be measured during operation of a filling plant for food or medical devices.

Depending on the embodiment, it can be provided that the remote unit RU also has a local power supply PWR. Alternatively or additionally, it can be provided that the supply of the remote unit and thus of the gas sensor CGS is provided by induction.

ZigBee is particularly advantageous because ZigBee provides a cost-effective solution that also has low power requirements and at the same time enables a fast and secure connection or connection.

It is also advantageous if the energy supply of the calorimetric gas sensor CGS and the remote unit RU can also be provided by means of the wireless interface used at the same time. This can be provided in a particularly simple manner, a test system that is independent of the state of charge of a battery or in which the test container by the elimination of a battery is substantially equal to a real container and thus more realistic measurements can be provided.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• IEEE 802.15.4 [0026]

Claims (11)

A method for a gas sensor or sensor in the gas phase, wherein the gas sensor is adapted to detect the concentration of a certain gas or more specific gases or a composition of a gas mixture, the gas sensor for the measurement in a steady state requires a period of time greater than the available gas concentration time, comprising the steps of: Calibrating the gas sensor by means of at least one reference gas concentration of the particular gas, the reference gas concentration being known and the measurement time for calibration being less than the time duration for the measurement in a steady state, Measuring by means of the calibrated gas sensor a gas concentration of the specific gas, the measuring time being less than the time duration for the measurement in a steady state, • Evaluation of the measured value with the aid of calibration and passing on the result of the evaluation. The method of claim 1, wherein the step of calibrating comprises a plurality of measurements, wherein the total time of the measurements is less than the time duration for the measurement in a steady state. The method of claim 1 or 2, wherein the step of measuring comprises a plurality of measurements, wherein the total time of the measurements is less than the time period for the measurement in a steady state. The method according to one of the preceding claims, further comprising the step of forwarding a measured value by means of wireless connection technology. A gas analyzer, wherein the gas analyzer is configured to measure the concentration of a particular gas or gases or the composition of a gas mixture, the gas analyzer for measuring in a steady state requires a time greater than the available time Gas concentration is having At least one gas sensor for measuring a gas concentration of the particular gas, the measurement time being less than the time duration for the measurement in a steady state, Calibration data generated by means of at least one reference gas concentration of the particular gas, the reference gas concentration being known and the measurement time for calibration being less than the time duration for the measurement in a steady state, An evaluation unit for evaluating measured values of the at least one gas sensor with the aid of the calibration and for passing on the result of the evaluation. Gas analyzer according to claim 5, wherein the gas sensor is a calorimetric gas sensor. Gas analyzer according to claim 5 or 6, wherein the gas to be measured is exothermic in the measurement. Gas analysis device according to one of the preceding claims 5 to 7, wherein the at least one gas sensor is connected by means of a wireless interface with the evaluation unit. Gas analysis device according to one of the preceding claims 5 to 8, wherein the at least one gas sensor is connected by means of a wireless ZigBee interface with the evaluation unit. Gas analyzer according to one of the preceding claims 5 to 9, wherein the gas analyzer comprises a plurality of gas sensors. Gas analyzer according to one of the preceding claims 5 to 10, wherein the gas analyzer comprises a plurality of gas sensors, wherein the plurality of gas sensors are placed in a test container or room.

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