Relative density is a dimensionless number.

The gas may be a fuel gas, for example natural gas. The natural gas may be methane and may further comprise nitrogen and/or carbon dioxide. In addition to methane the natural gas may comprise at least one other hydrocarbon gas, for example ethane, propane, butane, pentane or hexane.

According to a first aspect of the invention a method of measuring the relative density of a gas comprises making a measure of the speed of sound in the gas, making a measure of a first thermal conductivity of the gas at a first temperature, making a measure of a second thermal conductivity of the gas at a second temperature which differs from the first temperature, and using the speed of sound and the first and second thermal conductivities in an operation producing the relative density of the gas corresponding to said speed of sound and said first and second thermal conductivities.

According to a further aspect of the invention an apparatus for measuring the relative density of a gas comprises means for making a measure of the speed of sound in the gas, means for making a measure of a first thermal conductivity of the gas at a first temperature, means for making a measure of a second thermal conductivity of the gas at a second temperature which differs from the first temperature, and means for using the speed of sound and the first and second thermal conductivities in an operation producing the relative density of the gas corresponding to said speed of sound and said first and second thermal conductivities.

The invention will now be further described, by way of example, with reference to the accompanying drawings in which: Figure 1 diagrammatically shows an apparatus in which the invention can be performed.

Figure 2 shows a diagrammatic example of a feed forward air/fuel gas control system utilising the present invention.

With reference to Figure 1 an apparatus 2 to measure the relative density of a gas has a chamber 4 into which the gas is supplied through an inlet conduit 6 and leaves through an outlet conduit 8. The inlet conduit 6 includes heat exchange means 6A, for example a copper coil by which the temperature of the incoming gas can be adjusted to a value substantially the same as that of the ambient temperature of the external atmosphere whereby the gas in the chamber 4 is of substantially uniform temperature throughout. The chamber 4 includes an ultra-sound emitter transducer 10 and an ultra sound receiver transducer 12. An electronic control means 14 including computer means is connected to a signal generator 16 so that under the control of the control means 14 the signal generator causes the transducer 10 to emit ultra-sound signals 18 as desired. The ultra-sound signals 18 are received by the transducer 12 and their reception signalled to the control means 14 via line 20. The time of flight of the ultra-sonic signals between transducers 10 and 12 is measured by the control means 14 which is arranged to calculate SOS which is the speed of sound in metres/second (m/s).

If desired some other means of measuring the speed of sound in the gas may be used, such as that disclosed in US4938066.

However, the most preferable method is that disclosed in UK patent application Nos. GB 9813509.8, GB 9813513.0 and GB 9813514.8. These applications disclose the use of a resonator to measure the speed of sound of a gas within the resonator. A driving electronic circuit which may include or be in the form of a microprocessor is arranged to produce a sinusoidal signal over a suitable range of frequencies to drive a loudspeaker. The loudspeaker is arranged to apply an acoustic signal to the interior of a resonator. A microphone is arranged to detect the magnitude of the acoustic signal within the resonator. The signal from the microphone is filtered and amplified by an appropriate electronic circuit and a processing means determines the resonant frequency relating to the gas within the resonator to determine its speed of sound.

A temperature sensor 22 in the chamber 4 provides the control means with data on line 24 representing the value of the ambient temperature.

The ambient temperature sensor 22 may be part of a thermal conductivity sensor 28 comprising thermal conductivity observation means 30. The thermal conductivity sensor 28 may be a miniature thermal conductivity microsensor model type TCS208 available from Hartmann & Braun AG of Frankfurt am Main, Germany.

The thermal conductivity observation means 30 to observe the thermal conductivity of the gas has heater means which in response to signals on line 32 from the control means 14 can operate at more than one selected desired temperature above the ambient temperature observed by the sensor 22, and a signal representative of the thermal conductivity of the gas at the desired temperature is sent to the control means on line 34.

The control means 14 is arranged to cause the thermal conductivity sensor 28 to measure the thermal conductivity of the gas at two different desired temperatures tH and tL in which tH is a pre-determined desired number of temperature degrees t, above the ambient temperature observed by the sensor 22 and tL is a predetermined desired number of temperature degrees t., above ambient temperature; the number tl being greater than the number t2.

Using the observed or measured values of the speed of sound in the gas, the thermal conductivity of the gas at temperature tll and tL and the observed value of the ambient temperature of the gas by sensor 22, the control means 14 calculates the relative density of the gas using the formula RD = g. ThCH + h. ThCL + i. SoS + j. Ta + k. Ta2 + 1 in which RD is the relative density; ThCH is the thermal conductivity of the gas at temperature tH; ThCL is the thermal conductivity of the gas at temperature tL; SoS is the speed of sound in the gas at the ambient temperature; Tn is the ambient temperature of the gas, observed by the sensor 22, and g, h, i, j, k and 1 are respective constants.

The gas in question may be a mixture of two or more gases in which the composition of the mixture may be of variable proportions. For example the gas in question may be a fuel gas.

Such a fuel gas may be natural gas. The natural gas may comprise methane and at least one of ethane, propane, butane, pentane or hexane, and may further comprise nitrogen and/or carbon dioxide.

In order to derive the constants g, h, i, j, k, and 1 in equation I, the mathematical technique known as regression analysis may be used in respect of data collected in connection with the gas in question. The proportions of gases in the mixture may be varied to form a number of different samples. Using chromatographic methods the relative density RD of a sample is obtained, the ambient temperature Ta of the sample is measured and the thermal activities ThCIl and ThCL of the sample are measured. This is done for each sample in turn to obtain a set of measured values corresponding to each sample. The sets of values are inserted in equation I and the"best-fit"values for constants g, h, i, j, k and 1 are derived. In the case of natural gas coming ashore at a number of locations in the United Kingdom regression analysis was performed on samples from the different locations and also on gas equivalence groups which are artificial replications in the laboratory of mixtures of methane and ethane, methane and butane, methane and pentane, and methane and hexane in which, in the laboratory, those mixtures are represented by different mixtures of methane and propane.

When equation I was applied to natural gas and to gas equivalence groups and regression analysis used, the following values for the constants were derived, namely:- g = 0.017955, h =-0. 02812, <BR> i =-0. 00189,<BR> j = 0.001807, k =-0. 0000026, and 1 = 1.73041, when RD is the relative density of gas in MJ/m3st (Megajoules/standard cubic metres); ThCH is the thermal conductivity of the gas in W/m. K (where K is degrees in Kelvin) at a temperature tl which is substantially 70 degrees Celsius above ambient temperature T,; ThCL is the thermal conductivity of the gas in W/m. K at a temperature tL which is substantially 50 degrees Celsius above ambient temperature Ta; SoS is the speed of sound in the gas in m/s, and Ta is the ambient temperature of the gas in degrees Celsius.

In the above application of equation I to natural gas the value of tl is substantially 70"C and the value of t, is substantially 50"C. Thus the difference between the temperatures tp and tL at which the thermal conductivities ThCH and ThCL are measured differ by substantially 20"C [(Ta + 70)- (T, + 50) = 20] The value of the relative density RD of the gas calculated by the control means 14 may be visually displayed and/or printed or otherwise recorded by recording means 36 in response to signals from the control means.

By any suitable technique know per se the control means 16 may be provided with information representing the calorific value RD of the gas or the control means may be provided with information enabling it to calculate the calorific value of the gas. The control means 14 may calculate or otherwise obtain the value of the Wobble Index WI of the gas using the formula When fuel gas is combusted in a process (e. g. furnace, kiln, compressor, engine, etc.) some form of control system is used to set the oxygen (in this case in the form of air)/fuel gas ratio to ensure optimum combustion. An allowance is made in the amount of excess air to account in part, for variations in fuel gas composition changes. This allowance means that the process is running less efficiently than it could do because extra air is being heated and vented.

However, a measure of the relative density or Wobbe Index, which is indicative of the fuel gas quality and which may be found according to the present invention, may be used in a feed forward control strategy to improve the accuracy of control available and achieve better efficiency.

An apparatus to perform such control is shown in Fig. 2. Fuel gas is supplied via a conduit 40, such as a pipe, to a gas fired process 41 such as a furnace, kiln, a compressor or an engine and oxygen in the form of air is supplied to the process 41 via another conduit 42. Any suitable device 43 which may be in the form of one or more probes temporarily insertable into the conduit 40 or as one or more permanent fixtures is arranged to measure the speed of sound of the fuel gas passing through the conduit 40, the thermal conductivities of the gas ThCH, ThCL at two temperatures tlland tL and the ambient temperature of the gas Ta. The speed of sound of the fuel gas SOS, the thermal conductivities ThCH and ThCL and the ambient temperature of the gas T, are measured by device 43 and passed via a connection 44 to a control means 45, which may be a microprocessor or a computer for example. Control means 45 determines the relative density of the fuel gas from the received measurements from device 43 as explained earlier. Having determined a measure of the gas quality, the control means is able to adjust the air/fuel gas ratio setpoint using an oxygen/fuel gas ratio control system 46,47 to achieve better efficiency. In this case the oxygen/fuel gas control system comprises two variable opening valves 46,47 one in each of the fuel gas and air conduits 40,42 respectively and both controlled by the control means 45 via connections 48, 49. Alternatively the oxygen/fuel gas control system could comprise a variable opening valve on just one of conduits 40,42.