Method and system for locating and quantifying fugitive emission leaks

What is claimed is: 1 . A method for detecting emission leaks, comprising: simultaneously receiving, by a processor, gas sensor data from each gas sensor of a plurality of gas sensors positioned at a plurality of locations, and wind direction data from at least one weather station, during a predetermined time interval, wherein the reception of the gas sensor data and the wind direction data is time synchronized; determining, by the processor, a distribution of the gas sensor data of each gas sensor of the plurality of gas sensors at each of the plurality of locations based on a predetermined distribution of wind direction data at each location of the plurality of locations; determining, by the processor, at least one location indicative of a source of an emission leak based on projecting the distribution of the gas sensor data of each gas sensor of the plurality of gas sensors using at least triangulation; controlling, by the processor, at least one gas sensor of the plurality of gas sensors and the at least one weather station based on the at least one determined location for selectively receiving the gas sensor data and the wind direction data; and quantifying, by the processor, a value of an actual leak rate based at least on the gas sensor data and the wind direction data selectively received from the at least one gas sensor and the at least one weather station associated with the at least one determined location. 2 . The method of claim 1 , wherein determining the at least one location indicative of the source of the emission leak, comprises: dividing an area of interest into a grid comprising a plurality of cells; projecting the distribution of the gas sensor data of each gas sensor of the plurality of gas sensors based on a corresponding representation of the predetermined distribution of wind direction data on the grid for each gas sensor location using at least the triangulation; grouping one or more cells of the grid into one or more contiguous grid cells, wherein each of the one or more contiguous grid cells have aggregated concentration of gas levels above a predefined level; calculating a boundary area containing the one or more contiguous grid cells with the aggregated concentration of gas levels above a threshold to identify a potential leak area; and matching the potential leak area with a prior calculated leak area to identify the source of the emission leak. 3 . The method of claim 1 , further comprising: determining, by the processor, an initial estimate of a leak size at the source of the emission leak, a magnitude of the emission leak detected around the at least one location and a gas sensor type specific calibration model. 4 . The method of claim 3 , further comprising: solving, by the processor, a simplified gas dispersion model using the initial estimate of the leak size to obtain an initial estimate of a rate of the emission leak; and quantifying, by the processor, a value of an actual leak rate using the initial estimate of the leak size. 5 . The method of claim 1 , further comprising: projecting, by the processor, on a display monitor each of the predetermined distribution of wind direction data along with a representation of respective distribution of the gas sensor data of each gas sensor of the plurality of gas sensors at each of the plurality of locations using a geospatial triangulation. 6 . The method of claim 1 , wherein determining the distribution of the gas sensor data of each gas sensor of the plurality of gas sensors at each of the plurality of locations, comprises: defining a moving time window for determining the distribution of the gas sensor data of each gas sensor of the plurality of gas sensors at each of the plurality of locations based at least on a wind speed for each gas sensor; determining a maximum wind direction and a minimum wind direction within the moving time window; determining a difference between the maximum wind direction and the minimum wind direction of the moving time window; determining if the difference is greater than a discrete wind direction interval, wherein the discrete wind direction interval is determined based on at least the predetermined distribution of wind direction data; on determining the difference is greater than the discrete wind direction interval, distribute the gas sensor data equally across a set of wind direction bins of a plurality of wind direction bins based on the maximum wind direction and the minimum wind direction, wherein the plurality of wind direction bins correspond to the predetermined distribution of wind direction data; and determining a gas level in each wind direction bin over a predefined interval by integrating a concentration of gas sensor data of each wind direction bin of the plurality of wind direction bins associated with each of the plurality of gas sensors. 7 . The method of claim 6 , wherein defining the moving time window, comprises: adapting a length of the moving time window based on at least the wind speed, a detection time of a gas corresponding to each of the plurality of gas sensors and an expected travel time of the gas from the at least one location indicative of the source of the emission leak to a corresponding location associated with the gas sensor. 8 . The method of claim 7 , wherein the discrete wind direction interval is configurable. 9 . A system for detecting emission leaks, comprising: a plurality of gas sensors positioned at a plurality of locations proximate an area of interest in a manufacturing plant; at least one weather station located proximate the area of interest; a data server communicatively coupled to the plurality of gas sensors and to the at least one weather station, the data server comprising: a data processing program, and a processor configured to execute the data processing program which causes the processor to: simultaneously receive gas sensor data from each gas sensor of the plurality of gas sensors and wind direction data from the at least one weather station, during a predetermined time interval, wherein the reception of the gas sensor data and the wind direction data is time synchronized; determine a distribution of the gas sensor data of each gas sensor of the plurality of gas sensors at each of the plurality of locations based on a predetermined distribution of wind direction data at each location of the plurality of locations; and determine at least one location indicative of a source of an emission leak based on projecting the distribution of the gas sensor data of each gas sensor of the plurality of gas sensors using at least triangulation; control at least one gas sensor of the plurality of gas sensors and the at least one weather station based on the at least one determined location for selectively receiving the gas sensor data and the wind direction data; and quantify a value of an actual leak rate based at least on the gas sensor data and the wind direction data selectively received from the at least one gas sensor and the at least one weather station associated with the at least one determined location. 10 . The system of claim 9 , wherein for determining the at least one location indicative of the source of the emission leak, the processor is further configured to: divide the area of interest into a grid comprising a plurality of cells; project the distribution of the gas sensor data of each gas sensor of the plurality of gas sensors based on a corresponding representation of the predetermined distribution of wind direction data on the grid for each gas sensor location using at least the triangulation; grouping one or more cells of the grid into one or more contiguous grid cells, wherein e