Gas flowmeter having inline calibrating

The invention claimed is: 1. A method, comprising: providing a static gas flowmeter installed to sense a flow of a gas in a pipe section of a gas pipeline, the gas flowmeter including an outer housing that includes an inlet, an outlet, a flow tube coupled to the outlet or the inlet, and at least one flow sensor positioned for sensing the gas flowing through the flow tube, a controller including an associated memory communicatively coupled to the sensor for receiving a sensing signal from the sensor, and for controlling operation of the sensor; wherein at least one of i) the gas flowmeter further comprises an integrated gas valve connected to the inlet or to the outlet, and ii) an external valve positioned outside the housing coupled to the inlet that provides at least two state operation; creating a zero-flow condition using at least one of closing or bypassing the integrated gas valve or manually closing the external valve; during the zero-flow condition measuring a measured gas flow; determining a flow offset correction factor, from the measured gas flow, and determining that the flow offset correction factor is different than a predetermined limit, and then calibrating in-line, using flow calibration hardware or software, by adding the flow offset correction factor to the flow measurement algorithm. 2. The method of claim 1 , wherein a corrected flow rate output by the gas flowmeter after the in-line calibrating is calculated by the flow measurement algorithm as a measured flow rate of the gas multiplied by a constant slope for the gas flowmeter adjusted by the flow offset correction factor. 3. The method of claim 2 , further comprising before installing the gas flowmeter in the gas pipeline off-line calibrating of the gas flowmeter comprising determining the constant slope correction factor. 4. The method of claim 1 , wherein the in-line calibrating is exclusively run automatically by the gas flowmeter, and wherein the method further comprises the controller providing a control signal for the integrated gas valve to close for providing the zero-flow condition. 5. The method of claim 1 , wherein the flow sensor includes a first ultrasonic transducer and at least a second ultrasonic transducer, and wherein the gas flowmeter comprises an ultrasonic flowmeter. 6. The method of claim 1 , wherein the creating the zero-flow condition comprises closing the external valve. 7. The method of claim 1 , wherein the integrated gas valve comprises at least one valve arrangement that provides an open position, a closed position where the gas flowmeter will not count gas flow and a downstream installation will not receive the gas, and a bypass position where the gas flowmeter will not count the gas flow and the downstream installation will receive the gas, and wherein the determining of the flow offset correction factor is performable while the valve arrangement is in the closed position or in the bypass position. 8. The method of claim 7 , wherein the valve arrangement comprises a three-way valve, or wherein the valve arrangement comprises a first and a second 2-way valve. 9. The method of claim 1 , wherein the gas flowmeter further comprises a radio frequency (RF) communications unit including a transmitter and receiver coupled to an antenna and coupled to the controller, and a battery for powering the gas flowmeter, where the controller includes a low-power mode, the method further comprising automatically generating an alarm and sending a wireless signal using the RF communications unit when the correction factor is determined to be greater than a predetermined limit for the correction factor. 10. A static gas flowmeter, comprising: an outer housing that includes an inlet, an outlet, a flow tube coupled to the outlet or to the inlet, an integrated gas valve connected to the inlet or to the outlet that provides at least two state operation and at least one sensor positioned for sensing a gas flowing through the flow tube, a controller including an associated memory including a flow calibration algorithm and a flow measurement algorithm communicatively coupled to the sensor for receiving a sensing signal from the sensor, and for controlling operation of the sensor; wherein the flowmeter is configured for being installed to sense a flow of a gas in a pipe section of a gas pipeline, and the flow calibration algorithm is configured for closing the integrated gas valve to create a zero-flow condition, wherein the controller provides a signal to the integrated gas valve to close for providing the zero-flow condition; during the zero-flow condition, the flow measurement algorithm is configured for measuring a measured gas flow; from the measured gas flow, the flow calibration algorithm: determining a flow offset correction factor, and if the flow offset correction factor is determined to be different than a predetermined limit, in-line calibrating by adding the flow offset correction factor to the flow measurement algorithm. 11. The gas flowmeter of claim 10 , wherein a corrected flow rate output by the gas flowmeter after the in-line calibrating is calculated as a measured flow rate of the gas multiplied by a constant slope correction factor for the gas flowmeter adjusted by the flow offset correction factor. 12. The static gas flowmeter of claim 10 , wherein the sensor comprises a first ultrasonic transducer and at least a second ultrasonic transducer, and wherein the gas flowmeter comprises an ultrasonic flowmeter. 13. The gas flowmeter of claim 10 , wherein the integrated gas valve comprises at least one valve arrangement that provides an open, a closed position where the gas flowmeter will not count gas and the installed flowmeter will not receive the gas, and a bypass position where the gas flowmeter will not count the gas and the installed flowmeter will receive the gas, and wherein the determining of the flow offset correction factor is performable while the valve arrangement is in the closed position or in the bypass position. 14. The gas flowmeter of claim 13 , wherein the valve arrangement comprises a three-way valve, or wherein the valve arrangement comprises a first and a second 2-way valve. 15. A system comprising: a gas flowmeter configured for being installed to sense a flow of a gas in a pipe section of a gas pipeline including an outer housing, an inlet and an output, a flow tube coupled to the outlet or to the inlet, with inlet piping coupled to the inlet, and outlet piping coupled to an outlet, and at least one sensor positioned for sensing the gas flowing through the flow tube, a controller including an associated memory communicatively coupled to receive a sensing signal from the sensor, and for controlling operation of the sensor; wherein at least one of the gas flowmeter further comprises an integrated gas valve connected to the inlet or to the outlet, and an external valve positioned in-line outside the housing coupled to the inlet piping, to provide at least two position operation; wherein the memory includes flow measurement software, and flow calibration hardware or software run by the controller; wherein the flow calibration hardware or software is configured to create a zero-flow condition by at least one of closing or bypassing the integrated gas valve or manually closing the external valve, and the flow measurement software is configured to measure a measured gas flow during the zero-flow condition; from the measured gas flow, the flow calibration hardware or software is further configured to: determine a flow offset correction factor; determine if the flow offset correction factor is differen