High-sensitivity flexible strain sensor based on direct printing of mixture of metal nanoparticles and carbon nanotubes and method of manufacturing the same

What is claimed is: 1. A method of manufacturing a flexible strain sensor, comprising: placing a flexible substrate on a movable stage in a working chamber in which the movable stage capable of a desired movement according to a control signal, and an nozzle capable of jetting toward an upper surface of the movable stage are installed therein, and with which a first pressure control unit capable of controlling an internal pressure of the working chamber is combined, and preparing a printing material mixture including metal nanoparticles and carbon nanotubes (CNTs) in a form of powder to be input into a printing material tank provided with an upper outlet communicating with a nozzle through a first communication pipe and a lower inlet to which a second pressure control unit capable of controlling pressure is combined; controlling, by a control unit, a movement of the movable stage by providing a predetermined movement control signal to the movable stage to move the flexible substrate at a desired speed along a path corresponding to a predetermined conductive line pattern of a strain sensor; forming a relatively low pressure atmosphere inside the working chamber by operating the first pressure control unit, and simultaneously a relatively high pressure atmosphere at a lower inlet of the printing material tank by operating the second pressure control unit; in parallel with the controlling the movement of the movable stage, forcibly conveying the printing material mixture in an aerosolized state through the first communication pipe from the printing material tank, to be jetted out through the nozzle toward a surface of the flexible substrate by a compression wave caused by a pressure difference between the low pressure atmosphere and the high pressure atmosphere; directly printing a predetermined conductive line pattern of the strain sensor on the flexible substrate through a process in which the printing material mixture jetted out through the nozzle collides with the surface of the flexible substrate to create cracks on the surface, and the CNTs penetrate into the cracks and are mechanically locked with the flexible substrate, and then following metal nanoparticles and CNTs of the printing material mixture are deposited to a predetermined width and height on the surface of the flexible substrate; connecting first and second lead wires, which electrically extend to protrude out of the flexible substrate, to both ends of the predetermined conductive line pattern of the strain sensor; and bonding a flexible cover having a same size as the flexible substrate to the surface of the flexible substrate on which the predetermined conductive line pattern is printed, so that the predetermined conductive line pattern is sandwiched between the flexible substrate and the flexible cover. 2. The method of claim 1 , wherein the flexible substrate and the flexible cover have a same shore hardness of 10 to 70 based on shore A or have a same shore hardness of 22 or less based on shore D. 3. The method of claim 1 , wherein the flexible substrate and the flexible cover are made from polydimethylsiloxane (PDMS). 4. The method of claim 1 , wherein the predetermined conductive line pattern includes a plurality of linear conductive lines each of which extends linearly by a predetermined length in a first direction, and the plurality of linear conductive lines are arranged side by side to form a series connection while maintaining a predetermined distance between each other in a second direction perpendicular to the first direction, and wherein a cross-sectional structure of the plurality of linear conductive lines includes a seed layer, mechanically locked on the surface of the flexible substrate, formed by making the CNTs penetrate and fix into cracks irregularly formed on the surface of the flexible substrate; and a mixture layer of the metal nanoparticles and the CNTs formed by depositing the metal nanoparticles and the CNTs on the seed layer to have a predetermined width and height. 5. The method of claim 1 , wherein the directly printing of the predetermined conductive line pattern includes: forming a seed layer mechanically locked on the surface of the flexible substrate by making the printing material mixture of the metal nanoparticles and the CNTs from the nozzle collide the surface of the flexible substrate to form irregular cracks so that the CNTs penetrate and fix into the cracks on the surface of the flexible substrate; and printing the predetermined conductive line pattern on the surface of the flexible substrate by applying the printing material mixture subsequently jetted to the seed layer at a high speed to be deposited on the seed layer to a predetermined width and height through bonding with the CNTs of the seed layer. 6. The method of claim 5 , wherein the directly printing of the predetermined conductive line pattern includes: monitoring, by a monitoring unit, a size of the printing material mixture deposited on the surface of the flexible substrate to be provided to the control unit; and controlling, by the control unit, movement speed of the movable stage on which the flexible substrate is placed based on the monitored information from the monitoring unit. 7. The method of claim 1 , wherein the relatively low pressure atmosphere in the working chamber is a pressure atmosphere of 1 torr to 10 torr. 8. The method of claim 1 , wherein the controlling of the movement of the movable stage includes adjusting, by the control unit, a distance from the nozzle to the movable stage so that the printing material mixture is aerodynamically focused on the surface of the flexible substrate when the printing material mixture is jetted out through the nozzle. 9. The method of claim 1 , wherein the mixing ratio between the metal nanoparticles and the CNTs in the printing material mixture is in a range of 60%-90% by weight to 40%-10% by weight. 10. A flexible strain sensor, comprising: a flexible substrate; a predetermined conductive line pattern directly printed on a surface of the flexible substrate; and a flexible cover covering and bonded to the surface of the flexible substrate on which the predetermined conductive line pattern is printed so that the predetermined conductive line pattern is sandwiched between the flexible cover and the flexible substrate, wherein the predetermined conductive line pattern includes a plurality of linear conductive lines each of which extends linearly by a predetermined length in a first direction, and the plurality of linear conductive lines are arranged side by side to form a series connection while maintaining a predetermined distance between each other in a second direction perpendicular to the first direction, and wherein a cross-sectional structure of the plurality of linear conductive lines includes a seed layer, mechanically locked on the surface of the flexible substrate, formed by making the CNTs penetrate and fix into cracks formed on the surface of the flexible substrate; and a mixture layer of the metal nanoparticles and the CNTs formed by depositing the metal nanoparticles and the CNTs on the seed layer to have a predetermined width and height. 11. The flexible strain sensor of claim 10 , wherein the flexible substrate and the flexible cover have a same shore hardness of 10 to 70 based on shore A or have a same shore hardness of 22 or less based on shore D. 12. The flexible strain sensor of claim 10 , wherein the flexible substrate and the flexible cover are made from PDMS. 13. The flexible strain sensor of claim 10 , wherein the mixing ratio between the metal nanoparticles and the CNTs in the mixture layer is in a range of 60%-90% by weig