DE19535819A1 - Determination of at least one determined characteristic Z of combustible gas mixture e.g. natural gas - Google Patents

Abstract

The method is firstly based on known data regarding this characteristic. A correlation is formed between the heat conductivity (X) with one of the measuring temps. The conductivity difference (Y) resulting from the two measuring temps. and the determined characteristic (Z). Then this correlation is determined in a three dimensional space and is approximately described by a spatial surface (Z = SIGMA SIGMA aid.x<i>.y<i>) where a,i and j are the constants of this surface. Finally the equation of the surface for determining the sought characteristic (Z) from the measured values of the heat conductivity (X) with one of the measuring temps. and the heat conductivity difference (Y) is used with the two measuring temps. One or more heat conductivity sensors are screwed in to the earth gas line.

Description

The invention relates to a method for Determination of at least one specific characteristic of a fire gas mixture that sets them apart from others Gas mixtures differs, the thermal conductivity the gas mixture at two different temperatures is measured and the characteristic sought is derived from it.

The chemical composition of fuel gases, ins special natural gas, is not constant. It varies from one Source to another and within a particular source with currently. The gas customer buys the energy content of the gas. The price is calculated from the total volume of the delivered ten gas corresponds to an average over long periods Calorific value. To improve this situation would be a price Values Real-time measurement of the calorific value is useful.

A method is known from the publication DE 37 11 511 C. to determine the gas concentration in a gas mixture by measuring the thermal conductivity of the gas mixture knows, in which the thermal conductivity at different Temperatures is measured. The number of measurements at different temperatures depends on the number of com components of the gas mixture. The determined thermal conductivity Ability measurements are in as many non-linear equations how components exist, and then the system of equations using known mathematical metho that dissolved.

Because the number of components in natural gas in practice not exactly known and can be relatively high, the Calculating the systems of equations in such a time and costly way manoeuvrable that this method has apparently not been practically could be used. Rather, one uses for such  Analyzes usually a gas chromatograph, so too a very expensive Ge and unsuitable for real-time measurements advises. By the invention, this effort should ver be reduced, so that continuous monitoring gas quality becomes possible in real time.

This object is achieved by the in the Proof 1 defined procedures solved. Regarding Merkma len preferred forms of application of this method is based on referred to the subclaims.

The invention is now based on a preferred management example and the accompanying figures tert.

Fig. 1 shows schematically an apparatus for performing the method according to the invention.

Fig. 2 shows a graphical analogue of the method for determining the methane number.

Fig. 3 shows a graphical analogue of the method for determining the calorific value.

The specific feature mentioned in the introduction is described in the In practice, the calorific value of the gas is usually the main reason Gas consumers primarily interested. This calorific value is not directly related to the methane number or the proportion of Me correlated with the mixture, there are definitely others flammable hydrocarbons and non-flammable gases (e.g. Nitrogen) may be present, which affects the calorific value rivers. After all, this particular characteristic could also simply form information about the origin of the gas, about the operation of gas distribution networks and consumption devices depending on the known but different Composition of natural gas deliveries of different pro optimize venence.

The method according to the invention uses that from the Known methods of measuring the above patent Thermal conductivity at different temperatures, each but the number of temperatures is limited to two,  regardless of how many different compos are included in the mixture.

The invention is based on the surprising findings nis, which has been confirmed by numerous test measurements that the certain features mentioned all in some way are correlated with a pair of measurements to which the Thermal conductivity at any given temperature structure and the derivation of thermal conductivity over the temperature rature belong, d. H. the change in thermal conductivity between measurements at the two assumed tempera doors.

A prerequisite for the method according to the invention is knowledge of the correlation between the specific feature, which is, for example, the methane number and is generally referred to below as Z, and a pair of measured values from the thermal conductivity (in mW per meter and degree), which is subsequently referred to as X. is and is measured at a first temperature, and the difference in thermal conductivity between the two temperatures, which is hereinafter referred to as Y and is measured in mW per meter and degree squared. For practical reasons, a nitrogen-related, i.e. dimensionless value λ _{rel of} the thermal conductivity for X and (λ _rel1 - λ _rel2 ) · 10³ for Y is used _below .

The correlation is plotted in FIG. 2. In a three-dimensional room, the base of which is formed by the x-axis (thermal conductivity) and the y-axis (temperature dependence of the thermal conductivity), the measured values for some known natural gas qualities have been determined in accordance with the following table.

The measured value pairs each result in a point in the x-y plane. For these qualities are due due or data obtained in another way also the methane number len (MZ) is known, which is above the measuring points in the z direction are worn, so that space points in the given Koor form dinate system.

It has now been shown that these spatial points are included with the same accuracy than lying on a room level can be tet. Such a spatial level can be mathematical can be described by an equation of the following form:

z = a₁₀ · x + a₀₁ · y + a₀₀

The three constants a₁₀, a₀₁ and a₀₀ describe the Location of this level and thus define the correlation between the methane number and the measured values of the thermal conductivity speed and the temperature dependence of this thermal conductivity speed. If you know this level and thus the constants, then the methane number can be obtained from the measurement of the values mentioned to calculate.

The method according to the invention is shown schematically in FIG. 1. It uses a thermal conductivity sensor 1 , such as is described in the above-mentioned patent. It consists of a heatable, thermally well insulated membrane 2 which is surrounded by a very small amount of measurement gas in a miniaturized chamber-like arrangement made of silicon. The power requirement of the membrane heater is a measure of the thermal conductivity λ of the gas at a given membrane temperature. The sensor element is housed in a measuring head which is screwed into the gas line 7 to be monitored. The gas exchange between the pipeline and the sensor takes place by diffusion. The set temperature of the membrane is cyclically keyed between a temperature T1 (e.g. 50 ° C) and a temperature T2 (e.g. 80 ° C) by a clock generator 3 . The heating power (heating current) required for the respective temperature is a measure of the thermal conductivity. The measured values are amplified (operational amplifier 8 ) and recorded in the rhythm of the clock generator 3 in a key and hold circuit 4 a for the lower temperature or a key and hold circuit 4 b for the higher temperature.

The value X results directly from the one holding circle, e.g. B. 4 a. The value Y, on the other hand, is formed from the difference of the assigned value pairs in the two holding circuits with the aid of a differential amplifier 5 . After the constants a₁₀, a₀₁ and a₀₀ have been predetermined as mentioned on the basis of existing data and entered into an evaluation unit 6 , the value of Z, ie the methane number, can now be determined simply and in real time.

In a variant, two sensors could also be present be the one that is permanently set to one of the temperatures are and then deliver the two measured values simultaneously. Then the touch and hold circles are of course no longer necessary.

In another variant, the measured values can be digita be lized and then in a data processing system linked and evaluated.

In the table above, the actual methane number (MZ _ist ) and the methane number, which results from the correlation according to the invention (MZ _kor ), are given for each gas of a known provenance. It can be seen that the deviations are within very narrow limits. In this way, the resolution of a system of polynomial equations according to the prior art is avoided.

From Fig. 2 it can also be seen that the method according to the Invention leads directly to the identification of the provenance of a supplied gas, not even the spatial plane being required, but already in the XY plane from the position of the measuring point to the provenance of the gas can be closed.

In a concrete example, the constants for the spatial level according to FIG. 2 are as follows:
a₀₀ = -163.11
a₁₀ = 266.56
a₀₁ = -1.76

Fig. 3 shows in a similar representation the room level, which depicts the correlation between the measured values of the thermal conductivity and the temperature dependence of this thermal conductivity and the calorific value (in MJ / m³). Since the position of this plane in space differs significantly from that in FIG. 2, the coordinate network has been rotated accordingly for better illustration.

For the calculation of the calorific value in the device according to FIG. 1, one only has to use the correct constants a₁₀, a₀₁, a₀₀, which of course differ from the corresponding constants for the methane number. These constants are again determined as above using available data.

As already mentioned, the invention is not limited to the gas provenances shown in the figures. These are only used to determine the correlation constants a _{i, j} . Fluctuations in quality in the delivery of a gas of known provenance are noticeable by a deviation of the measuring point in the XY plane from the standard value of the gas of this provenance. When this measured value is projected into the room level, this deviation also gives a different point on this level than the standard value, so that the current methane number or the current calorific value can be read therefrom.

There is no need to mention that the Dar positions according to FIG. 2 and FIG. 3 only serve to explain the invention and should in no way give the impression that the method is a graphic method.

The invention was based on an approximation one room level is explained, but it is under the Erfin  also possible, instead of the plane z = a₀₀ + a₁₀x + a₀₁y one Area of higher order as the common location of all measured values (X, Y, Z) to choose. That makes the evaluation a bit difficult, but may improve the accuracy of the proximity tion.

Claims (5)

1. A method for determining at least one specific characteristic (Z) of a combustible gas mixture, by which it differs from other similar gas mixtures, where the thermal conductivity of the gas mixture is measured at two different temperatures and the desired characteristic is derived therefrom, characterized that

• a correlation between the thermal conductivity (X) at one of the measuring temperatures, the thermal conductivity difference (Y), which results at the two measuring temperatures, and the specific feature (z) is first formed on the basis of known data about this feature,
• - then this correlation is recorded in a three-dimensional space (x, y, z) and described approximately by a surface area (z = ΣΣ a _ÿ · x ⁱ · y ^j ) (a _ÿ are constants of this area),
• - And finally the equation of this area for determining the desired feature (Z) from the measured values of the thermal conductivity (X) at one measuring temperature and the thermal conductivity difference (Y) is used at the two measuring temperatures.

2. The method according to claim 1, characterized in that the particular characteristic is the methane number. 3. The method according to claim 1, characterized in that the particular characteristic is the calorific value. 4. The method according to claim 1, characterized in that the particular characteristic is the Wobbe index. 5. The method according to any one of the preceding claims, characterized characterized in that the surface is a plane (i, j <2).