RU2000104868A - METHOD FOR MEASURING GAS CONSUMPTION AND A GAS METER FOR IT - Google Patents

Claims (12)

1. The method of determining the gas flow rate in the channel (6) in which the first sensor (8) is located, which is connected to the data processing means (12) to actuate the first sensor (8), which contains the following steps, alternatively actuate the first a sensor (8) in order to heat it and allow it to cool; measure the magnitude of the cooling rate (MX) of the first sensor (8) in the continuation of its cooling; in the continuation of the calibration stage, calibration gas is supplied at various costs to the channel (6), a pair of values is measured for each of the specified calibration gas costs: the flow rate (⌀j) and the cooling rate (Mj) of the first sensor (8) and compile a calibration table, containing such pairs of quantities (⌀j, Mj); after calibration and for gas flow, a calibration table is used to determine the flow rate (⌀) for the value of the flow cooling rate (MX) of the first sensor (8); characterized in that the axial flow is diverted from the gas stream from the channel (6) to the chamber (16), wherein the axial flow is substantially close to zero with respect to the main stream in the channel (6) in order to contain gas in the chamber ( 16) basically stationary, while the second sensor (22) of the same type as the first sensor (8) is located in the camera (16) and connected to the data processing means (12) and must be activated by them; alternatively, a second sensor (22) is activated in order to heat it and allow it to cool; measure the value of the cooling rate (Zx) of the second sensor (22) during its cooling; compensate the value of the cooling rate by the flow (MX) of the first sensor (8) in order to provide a compensated value of the cooling rate (My) based on the values of the cooling rates (Ma, Za) of both sensors (8, 22) obtained previously for the gas flow, and values of cooling rates (Mj, Zj) of both sensors (8, 22) obtained previously with a stationary gas in channel (6) and chamber (16), and this compensated value of cooling rate (My) is used to determine the corresponding flow rate ( ⌀Y) of gas in the channel (6).  2. The method according to p. 1, characterized in that when determining the gas flow rate (⌀y) of the gas in the channel (6), the data processing means (12) calculate and use the average value (Zа) of a number of previously measured values of the cooling rates (Zx) second sensor (22).  3. The method according to p. 1 or 2, characterized in that when determining the gas flow rate (⌀y) of the gas in the channel (6), the data processing means (12) calculate and use the fictitious value of the cooling rate (MO) of the first sensor (8) with a fictitiously stationary gas flow in the channel (6) based on one or more previous values of the cooling rate (Za) of the second sensor (22) and the cooling rates (Mg, Zg) of both sensors (8, 22) obtained earlier when inside the channel (6) no gas flow.  4. The method according to p. 3, characterized in that when determining the gas flow rate (⌀y) of the gas inside the channel (6), the data processing means (12) calculate and use the initial correction factor (FO) for the value of the cooling rate by the flow of the first sensor ( 8), based on the calibration calibration cooling rate (Ms) of the first sensor (8) for the specified calibration gas, which is mostly stationary and at the indicated fictitious cooling cooling rate (MO) of the first sensor (8).  5. The method according to p. 3 or 4, characterized in that when determining the gas flow rate (⌀y) of the gas in the channel (6), the data processing means (12) calculate the time correction factor (Ft) containing the average value (Ma) of the series values of cooling rates by flow (MX) of the first sensor (8) with respect to the indicated fictitious value of cooling rate (MO) of the first sensor (8).  6. The method according to the preceding paragraph, characterized in that the interval between successive heating periods of the second sensor (22) is greater than the interval between successive heating periods of the first sensor (8).  7. A gas meter containing a channel (6) for passing a gas stream through it, a first sensor (8), which is located in the specified channel (6), and data processing means (12), which are connected to the first sensor (8), to actuate the first sensor (8), to alternatively heat it and allow it to cool, measure the cooling rate (MX) of the first sensor (8) while it is cooling, and determine the gas flow rate in the channel (6) corresponding to indicated measured cooling rate (MX) of the first d sensor (8) by using a calibration table containing pairs of different flow rates (⌀j) and related cooling rates (Mj) of the first sensor (8), previously determined for calibration gas, characterized in that it contains a chamber (16), which communicates with the specified channel (6) so that gas flows from it and is kept essentially stationary with respect to the flow of incoming gas, the second sensor (22) is of the same type as the first sensor (8), which is located inside the specified chamber (16), and which is connected to means of processing data (12), which alternatively actuate the second sensor (22) in order to heat it and allow it to cool, and determine the value of the cooling rate (Zx) while cooling the second sensor (22), and the data processing means ( 12) compensate the measured value of the cooling rate by the flow (Mx) of the first sensor (8) to provide a compensated value of the cooling rate (My) based on the values of the cooling rates (Ma, Za) of both sensors (8, 22) obtained previously for the gas flow, and speed values oh deposition (Mg, Zg) of both sensors (8, 22) previously obtained with a stationary gas in the channel (6) and chamber (16), and in which the compensated value of the cooling rate (My) is used to determine the corresponding flow rate (расхода y) gas in channel 6.  8. The gas meter according to claim 1, characterized in that when determining the gas flow rate (⌀y) of the gas in the channel (6), the data processing means (12) calculate and use the average value (Za) of a number of previously measured values of the cooling rates (Zz ) of the second sensor (22).  9. Gas meter according to claim 7 or 8, characterized in that when determining the amount of gas flow rate (⌀y) of gas in the channel (6); data processing means (12) calculate and use a fictitious value of the cooling rate (MO) of the first sensor (8) with a fictitiously stationary gas syrup in the channel (6) based on one or more previous values of the cooling rate (Za) of the second sensor (22) and values cooling rates (MD, Zg) of both sensors (8, 22), obtained earlier, when there is no gas flow in the channel (6).  10. The gas meter according to claim 9, characterized in that when determining the gas flow rate (⌀y) of the gas in the channel (6), the data processing means (12) calculate and use the initial correction factor (FO) for the value of the cooling rate by the flow of the first sensor (8), based on the value of the calibration cooling rate (Ms) of the first sensor (8) for the specified calibration gas, which is mostly stationary, and the value of the indicated fictitious cooling rate (MO), the indicated first sensor (8).  11. Gas meter according to claim 9 or 10, characterized in that when determining the gas flow rate (⌀y) of the gas in the channel (6), the data processing means (12) calculate the time correction factor (Ft) containing the average value (Ma) a number of values of the cooling rates by the flow (MX) of the first sensor (8) with respect to the indicated fictitious value of the cooling rate (MO) of the first sensor (8).  12. Gas meter according to any one of paragraphs. 7-11, characterized in that the interval between successive heating periods of the second sensor (22) is greater than the interval between successive heating periods of the first sensor (8).