Microvalve using surface tension, microfluidic chip comprising same, and method for manufacturing same

The invention claimed is: 1. A microfluidic chip comprising (1) a first layer comprising an air channel, (2) a second layer comprising a microvalve and (3) a third layer comprising a coaxial sample channel, wherein one end of the air channel serves as an air inlet and the other end is connected to an upper end of the microvalve such that air pressure can be applied from the air channel to the microvalve, the upper end of microvalve is connected to the air channel and a lower end is blocked by a polymer thin membrane, the polymer thin membrane is positioned on the coaxial sample channel and the sample amount is controlled by the pressure applied to the microvalve as the polymer thin membrane swells downward and presses the coaxial sample channel, wherein the coaxial channel is a cylinder channel generating a coaxial flow and comprises one or more sample channel, a main channel and one or more external channel, at least one of the one or more sample channel, the main channel and the one or more external channel is a cylinder channel having a circular or oval cross section, a terminal end of the one or more sample channel is connected to an initial end of the main channel, the terminal end portion of the one or more sample channel connected to the main channel is tapered and the remaining portion is constant in size and shape of the cross section and the one or more external channel is connected to a side of the main channel. 2. The microfluidic chip according to claim 1 , wherein the width of the coaxial channel (i) is constant in size along a longitudinal direction, (ii) decreases or increases linearly in size along the longitudinal direction or (iii) is constant and then decreases or increases linearly in size along the longitudinal direction as a combination of (i) and (ii). 3. The microfluidic chip according to claim 1 , wherein (i) the sample channel is tapered toward the terminal end portion or (ii) only the terminal end portion of the sample channel is tapered toward the portion connected with the main channel and the remaining portion is constant in size and shape of the cross section. 4. The microfluidic chip according to claim 1 , wherein a longitudinal axis in the main channel is in line with a longitudinal axis in the sample channel, a longitudinal axis in the external channel crosses with a longitudinal axis in the main channel and, particularly, all the longitudinal axes in the main channel, the sample channel and the external channel are in the same plane.