Curing die for manufacturing gel polymer electrolyte, and method for manufacturing gel polymer battery cell by using same

The invention claimed is: 1. A curing die for manufacturing a gel polymer electrolyte, comprising: a first die including a recessed part in which a processing battery cell is mounted, the processing battery cell including an electrode assembly and a composition for forming a gel polymer electrolyte inside a battery case, the battery case including an unsealed part at one side portion is mounted; and a second die coupled to the first die so as to close the processing battery cell mounted in the recessed part, wherein at least one of the first die or the second die is partly or entirely formed of a heat conductive material, and a portion of the recessed part is formed of the heat conductive material and a portion of the recessed part is not formed of the heat conductive material. 2. The curing die for manufacturing a gel polymer electrolyte of claim 1 , wherein: a portion of the second die that faces the recessed part of the first die is partly or entirely formed of a heat conductive material. 3. The curing die for manufacturing a gel polymer electrolyte of claim 1 , wherein: at least one of the first die and the second die includes a heating wire connected to a temperature controller. 4. The curing die for manufacturing a gel polymer electrolyte of claim 1 , wherein: the first die and the second die each include die terminals formed of a conductive material at positions in contact with electrode terminals of the processing battery cell, and the die terminals are connected to an external charge and discharge device. 5. The curing die for manufacturing a gel polymer electrolyte of claim 4 , wherein: the die terminals formed on the first die and the die terminals formed on the second die are formed at corresponding positions so that the first die and the second die are in contact with each other at the same polarity when the first die and the second die are coupled. 6. The curing die for manufacturing a gel polymer electrolyte of claim 4 , wherein: the die terminals include a (+) die terminal in contact with a cathode terminal of the processing battery cell and a (−) die terminal in contact with an anode terminal of the processing battery cell. 7. The curing die for manufacturing a gel polymer electrolyte of claim 6 , wherein: in the first die, the (+) die terminal and the (−) die terminal are independently formed on an outer surface of one side end part of the recessed part. 8. The curing die for manufacturing a gel polymer electrolyte of claim 6 , wherein: in the first die, the (+) die terminal and the (−) die terminal are formed on the outer surface of one side end part of the recessed part and on an outer surface of the other side end part opposite to the outer surface of the one side end part, respectively. 9. The curing die for manufacturing a gel polymer electrolyte of claim 1 , wherein: the second die includes as an additional recessed part formed at a position corresponding to the recessed part of the first die. 10. The curing die for manufacturing a gel polymer electrolyte of claim 1 , wherein: the second die has a flat structure without the recessed part. 11. The curing die for manufacturing a gel polymer electrolyte of claim 1 , wherein: the one side end parts of the first die and the second die are interconnected by a hinge. 12. A method for manufacturing a gel polymer battery cell using the curing die of claim 1 , comprising: (i) preparing the processing battery cell including the electrode assembly and the composition for forming a gel polymer electrolyte inside the battery case; (ii) mounting the processing battery cell in the recessed part of the first die and closing the processing battery cell; (iii) controlling the curing die to thereby gel the composition for forming a gel polymer electrolyte in the battery case by a cross-linking reaction. 13. The method of claim 12 , wherein: in step (iii), the curing die is placed in an oven and a temperature in the oven is controlled, or a current is applied to a heating wire of the curing die, thereby heating the curing die to gel the composition for forming a gel polymer electrolyte. 14. The method of claim 12 , wherein: a temperature for the cross-linking reaction is 30 to 100 degrees Celsius. 15. The method of claim 12 , further comprising: (iv) connecting die terminals of the curing die to a charge and discharge device to perform an activation process of the processing battery cell. 16. The method of claim 12 , wherein: the unsealed part of the processing battery cell is extended from a side surface of a battery cell body where electrode terminals are not formed, and maintains a sealed state by the first die and the second die outside of the recessed part. 17. The method of claim 12 , wherein: the composition for forming a gel polymer electrolyte includes an electrolytic solution solvent, a lithium salt, a reactive monomer or oligomer, and an initiator.