Lithium-air battery system

What is claimed is: 1 . A lithium-air battery system, comprising: a lithium-air battery; an oxygen bombe configured to store oxygen gas that participates in a lithium-oxygen reaction; a first mass flow controller (MFC) configured to adjust a flow rate of oxygen gas supplied from the oxygen bombe to lithium-air battery cells; a blower configured to repeatedly supply oxygen gas flowing from the first MFC into the lithium-air battery cells; a compressor configured to compress oxygen generated from the lithium-air battery cells and passes through a second MFC, to a high pressure state to charge the oxygen bombe with the compressed oxygen during a charge operation, wherein the second MFC is configured to adjust a flow rate when oxygen gas generated from the lithium-air battery cells is supplied to the compressor during the charge operation; and an external power source configured to supply electric power to the compressor to charge the oxygen bombe. 2 . The lithium-air battery system of claim 1 , wherein a bombe pressure sensor, configured to monitor oxygen gas pressure, is mounted at an inlet of the oxygen bombe. 3 . The lithium-air battery system of claim 1 , further comprising: a regulator configured to reduce high pressure of oxygen gas, which flows from the oxygen bombe to the first MFC, to predetermined pressure. 4 . The lithium-air battery system of claim 1 , wherein the first MFC is configured to supply an amount of oxygen gas to the lithium-air battery cells at a level sufficient for an electric current currently required for a load, while being operated by a controller. 5 . The lithium-air battery system of claim 1 , further comprising: a first valve opened and closed to allow oxygen gas to flow from the oxygen bombe to a regulator during a discharge reaction, and opened and closed to allow oxygen gas to flow from the compressor to the oxygen bombe during the charge operation. 6 . The lithium-air battery system of claim 1 , further comprising: a second valve configured to block a flow of oxygen directed toward the second MFC during a discharge reaction to automatically circulate oxygen gas, and permit a flow of oxygen directed toward the second MFC when the oxygen bombe is charged. 7 . The lithium-air battery system of claim 1 , further comprising: a first pressure sensor and a second pressure sensor configured to measure a pressure change of oxygen at a front end at which oxygen flows to the lithium-air battery cells and a pressure change of oxygen at a rear end at which oxygen is discharged from the lithium-air battery cells, respectively, and transfer the measurement result to a controller.