EXHAUST PURIFICATION DEVICE AND METHOD OF CALCULATING NOX MASS ADSORBED IN LEAN NOx TRAP OF EXHAUST PURIFICATION DEVICE

What is claimed is: 1 . A method of calculating a nitrogen oxide (NOx) mass adsorbed in a lean NOx trap (LNT) of an exhaust purification device, wherein the LNT is mounted at an exhaust pipe, and adsorbs NOx contained in an exhaust gas at a lean air/fuel ratio, releases the adsorbed NOx at a rich air/fuel ratio, and reduces the NOx contained in the exhaust gas or the released NOx using reductant including carbon or hydrogen contained in the exhaust gas, the method comprising: calculating a NOx mass flow stored in the LNT; calculating a NOx mass flow thermally released from the LNT; calculating a NOx mass flow released from the LNT at the rich air/fuel ratio; calculating a NOx mass flow chemically reacting with the reductant at the LNT; and integrating a value obtained by subtracting the NOx mass flow thermally released from the LNT, the NOx mass flow released from the LNT at the rich air/fuel ratio, and the NOx mass flow chemically reacting with the reductant at the LNT from the NOx mass flow stored in the LNT. 2 . The method of claim 1 , wherein the step of calculating a NOx mass flow stored in the LNT comprises: calculating a NOx mass flow flowing into the LNT; calculating a NOx storing efficiency of the LNT; and calculating a NOx mass flow adsorbed in the LNT by multiplying the NOx mass flow flowing into the LNT and the NOx storing efficiency of the LNT, wherein a NOx storing efficiency at the rich air/fuel ratio and a NOx storing efficiency at the lean air/fuel ratio are calculated respectively at the step of calculating a NOx storing efficiency of the LNT. 3 . The method of claim 2 , wherein the NOx storing efficiency at the rich air/fuel ratio is calculated according to a temperature of the LNT and a mass flow of the exhaust gas passing through the LNT. 4 . The method of claim 2 , wherein the NOx storing efficiency at the lean air/fuel ratio is calculated according to a temperature of the LNT and a relative NOx adsorption of the LNT. 5 . The method of claim 4 , wherein the NOx storing efficiency at the lean air/fuel ratio is first corrected according to the temperature of the LNT and the mass flow of the exhaust gas passing through the LNT, and is secondly corrected according to a NOx adsorption in the LNT and the mass flow of the exhaust gas passing through the LNT. 6 . The method of claim 2 , wherein the NOx storing efficiency at the rich air/fuel ratio and the NOx storing efficiency at the lean air/fuel ratio are calculated by taking into account an aging factor of the LNT. 7 . The method of claim 1 , wherein the calculating a NOx mass flow thermally released from the LNT comprises: calculating an excess NOx adsorption that exceeds a maximum NOx adsorption of the LNT; calculating a mass flow of the excess NOx adsorption by dividing the excess NOx adsorption by a sampling time; and multiplying a thermal release characteristic according to the temperature of the LNT to the mass flow of the excess NOx adsorption. 8 . The method of claim 1 , wherein the step of calculating a NOx mass flow released from the LNT at the rich air/fuel ratio comprises: calculating a mass flow of a basic NOx release according to a NOx adsorption at a denitrification (DeNOx) mode; first correcting the mass flow of the basic NOx release according to the temperature of the LNT and the mass flow of the exhaust gas passing through the LNT; and secondly correcting the firstly corrected mass flow of the basic NOx release according to an aging factor of the LNT. 9 . The method of claim 1 , wherein the NOx mass flow chemically reacting with the reductant at the LNT is calculated through a model using C3H6 as the reductant. 10 . An exhaust purification device comprising: an engine including an injector for injecting fuel thereinto, generating power by burning mixture of air and the fuel, and exhausting the exhaust gas generated at combustion process to the exterior thereof through an exhaust pipe; a lean NOx trap (LNT) mounted on the exhaust pipe, for adsorbing nitrogen oxide (NOx) contained in the exhaust gas at a lean air/fuel ratio, for releasing the adsorbed nitrogen oxide at a rich air/fuel ratio, and for reducing the nitrogen oxide contained in the exhaust gas or the released nitrogen oxide using reductant including carbon or hydrogen contained in the exhaust gas; and a controller for controling adsorption and release of the NOx by controlling air/fuel ratio according to the NOx adsorbed in the LNT and a temperature of the exhaust gas, wherein the controller calculates a NOx mass adsorbed in the LNT by integrating a value obtained by subtracting a NOx mass flow thermally released from the LNT, a NOx mass flow released from the LNT at the rich air/fuel ratio, and a NOx mass flow chemically reacting with reductant at the LNT from a NOx mass flow stored in the LNT. 11 . The exhaust purification device of claim 10 , wherein the controller calculates the NOx mass flow stored in the LNT by multiplying NOx mass flow flowing into the LNT and a NOx storing efficiency of the LNT. 12 . The exhaust purification device of claim 11 , wherein the controller calculates a NOx storing efficiency at the rich air/fuel ratio and a NOx storing efficiency at the lean air/fuel ratio, respectively. 13 . The exhaust purification device of claim 12 , wherein the controller calculates the NOx storing efficiency at the rich air/fuel ratio according to the temperature of the LNT and a mass flow of the exhaust gas passing through the LNT. 14 . The exhaust purification device of claim 12 , wherein the controller calculates the NOx storing efficiency at the lean air/fuel ratio according to the temperature of the LNT and a relative NOx adsorption of the LNT. 15 . The exhaust purification device of claim 14 , wherein the controller first corrects the NOx storing efficiency at the lean air/fuel ratio according to the temperature of the LNT and the mass flow of the exhaust gas passing through the LNT, and secondly corrects the NOx storing efficiency at the lean air/fuel ratio according to a NOx adsorption in the LNT and the mass flow of the exhaust gas passing through the LNT. 16 . The exhaust purification device of claim 12 , wherein the controller calculates a NOx storing efficiency at the rich air/fuel ratio and a NOx storing efficiency at the lean air/fuel ratio by considering the aging factor of the LNT. 17 . The exhaust purification device of claim 10 , wherein the controller calculates a mass flow of an excess NOx adsorption by dividing an excess NOx adsorption that exceeds a maximum NOx adsorption in the LNT by a sampling time, and calculates the NOx mass flow thermally released from the LNT by multiplying a thermal release characteristic according to the temperature of the LNT to the mass flow of the excess NOx adsorption. 18 . The exhaust purification device of claim 10 , wherein the controller calculates the NOx mass flow released from the LNT at the rich air/fuel ratio by first correcting a mass flow of a basic NOx release according to a NOx adsorption at a denitrification (DeNOx) mode according to the temperature of the LNT and the mass flow of the exhaust gas passing through the LNT, and secondly correcting the mass flow of the basic NOx release according to the aging factor of the LNT. 19 . The exhaust purification device of claim 10 , wherein the controller calculates the NOx mass flow chemically reacting with the reductant at the LNT through a model using C3H6 as the reductant.