Frame assembly and method for manufacturing same

What is claimed is: 1. A frame assembly for fixing a plurality of stacked battery cells, the frame assembly comprising: a frame including an upper surface, a first side surface connected to a first end of the upper surface and a second side surface connected to a second end of the upper surface, the frame being configured to enclose the plurality of stacked battery cells; a plurality of first bus bars coupled to the first side surface; a plurality of second bus bars coupled to the second side surface; and a flexible printed circuit board disposed along the upper surface, the first side surface, and the second side surface of the frame, the flexible printed circuit board being configured to sense the plurality of stacked battery cells, wherein the flexible printed circuit board comprises: a circuit portion disposed on the upper surface; a first connection circuit portion disposed on the first side surface, the first connection circuit portion extending from a first end of the circuit portion and coupled to the plurality of first bus bars; and a second connection circuit portion disposed on the second side surface, the second connection circuit portion extending from a second end of the circuit portion and coupled to the plurality of second bus bars, wherein each of the first and second connection circuit portions comprises: a substrate layer made of a flexible material; a first insulating layer disposed on a first surface of the substrate layer and having at least one first opening formed therien so as to expose the first surface of the substrate layer; and a second insulating layer disposed on a second surface of the substrate layer and having at least one second opening formed at a position opposite the at least one first opening with respect to the substrate layer so as to expose the second surface of the substrate layer, wherein the exposed second surface of the substrate layer of the first connection circuit portion is disposed to be adjacent to the first bus bars, and bonded to the first bus bars by applying a bonding method to the first surface of the substrate layer of the first connection circuit portion, and wherein the exposed second surface of the substrate layer of the second connection circuit portion is disposed to be adjacent to the second bus bars, and bonded to the second bus bars by applying the bonding method to the first surface of the substrate layer of the second connection circuit portion. 2. The frame assembly of claim 1 , wherein the frame comprises: a first frame forming the upper surface; a second frame forming the first side surface and pivotably coupled to a first end of the first frame, the plurality of first bus bars being disposed on the second frame; and a third frame forming the second side surface and pivotably coupled to a second end of the first frame, the plurality of second bus bars being disposed on the third frame. 3. The frame assembly of claim 1 , wherein the plurality of first bus bars comprise a first recess configured to seat the first connection circuit portion therein, and the plurality of second bus bars comprise a second recess configured to seat the second connection circuit portion therein. 4. The frame assembly of claim 1 , wherein, in a state in which the first connection circuit portion is bonded to the first bus bars, a conformal coating process is performed so as to cover the first connection circuit portion and some of the first bus bars in a vicinity of the first connection circuit portion, and wherein, in a state in which the second connection circuit portion is bonded to the second bus bars, a conformal coating process is performed so as to cover the second connection circuit portion and some of the second bus bars in a vicinity of the second connection circuit portion. 5. The frame assembly of claim 1 , wherein the at least one second opening is formed to be larger than the at least one first opening, and a portion of the first insulating layer partially overlaps an area in which the at least one second opening is formed in a cross section of the first and second connection circuit portions. 6. The frame assembly of claim 1 , wherein each of the first and second connection circuit portions comprises a first plating layer plated to cover at least a portion of the first surface, and a second plating layer plated to cover at least a portion of the second surface. 7. The frame assembly of claim 6 , wherein thicknesses of the first and second plating layers correspond to thicknesses of the first and second insulating layers, respectively. 8. The frame assembly of claim 6 , wherein each of the first and second connection circuit portions further comprises: a third insulating layer attached to a portion of the first insulating layer and to a portion of the first plating layer adjacent to the portion of the first insulating layer; and a fourth insulating layer attached to a portion of the second insulating layer and to a portion of the second plating layer adjacent to the portion of the second insulating layer. 9. The frame assembly of claim 8 , wherein the third insulating layer is attached to be in close contact with a position where the first insulating layer and the first plating layer are in contact with each other, and the fourth insulating layer is attached to be in close contact with a position where the second insulating layer and the second plating layer are in contact with each other. 10. The frame assembly of claim 8 , wherein an end of the fourth insulating layer is disposed to be in contact with ends of the first and second bus bars. 11. The frame assembly of claim 1 , wherein each of the first and second connection circuit portions further comprises a third insulating layer disposed on the first insulating layer and having at least one third opening formed therein at a position corresponding to the at least one first opening. 12. A frame assembly manufacturing method of manufacturing the frame assembly of claim 1 , the frame assembly manufacturing method comprising: manufacturing the frame manufacturing the flexible printed circuit board bonding of the first connection circuit portion to the plurality of first bus bars; and bonding the first surface of the second connection circuit portion to the plurality of second bus bars, wherein the manufacturing the flexible printed circuit board comprises: manufacturing the substrate layer by cutting a flexible conductive material into a predetermined shape; manufacturing the first insulating layer disposed on the first surface of the substrate layer by cutting an insulating material into a shape having a size that covers the substrate layer; manufacturing the second insulating layer disposed on the second surface of the substrate layer by cutting the insulating material into a shape having a size that covers the substrate layer; forming, in each of the first and second connection circuit portions, the at least one first opening in the first insulating layer at a predetermined position so as to expose the first surface of the substrate layer; forming, in each of the first and second connection circuit portions, the at least one second opening in the second insulating layer at a position opposite the at least one first opening with respect to the substrate layer so as to expose the second surface of the substrate layer; and disposing the first insulating layer on the first surface of the substrate layer, disposing the second insulating layer on the second surface of the substrate layer, and integrally coupling the first insulating layer, the substrate layer, and the second insulating layer, wherein the bonding the first connection