Method of preparing dry electrode

What is claimed is: 1 . A method of preparing a dry electrode, the method comprising: arranging at least one interlayer on at least one surface of an electrode current collector to prepare a first stack; arranging a dry electrode film, which has an area larger than an area of the at least one interlayer, on the first stack to prepare a second stack, wherein the dry electrode film comprises a first region on the at least one interlayer and a second region extending from the first region beyond an outer periphery of the at least one interlayer; and pulling at least a portion of the second region of the dry electrode film to separate the second region from the first region and provide the dry electrode, wherein the dry electrode film has anisotropic tensile strength, and wherein the dry electrode comprises a dry electrode active material layer on the at least one interlayer, and in the dry electrode, the dry electrode active material layer directly on the electrode current collector is absent. 2 . The method of claim 1 , wherein the second region abuts the first region in a machine direction (MD) of the dry electrode film. 3 . The method of claim 2 , wherein MD tensile strength (MDS) of the dry electrode film is different from transverse direction (TD) tensile strength (TDS) of the dry electrode film, and a ratio (MDS/TDS) of the MD tensile strength (MDS) to the TD strength (TDS) of the dry electrode film is 2 or more. 4 . The method of claim 1 , wherein the second region abuts the first region along the outer periphery of the at least one interlayer. 5 . The method of claim 4 , wherein machine direction (MD) tensile strength (MDS) of the dry electrode film is different from transverse direction (TD) tensile strength (TDS) of the dry electrode film, and a ratio (MDS/TDS) of the MD tensile strength (MDS) to the TD tensile strength (TDS) of the dry electrode film is in a range of about 5 to about 20. 6 . The method of claim 1 , wherein the dry electrode film further comprises a cut line along at least a portion of a boundary between the first region and the second region. 7 . The method of claim 6 , wherein, in the dry electrode film, the cut line is along a portion or an entirety of the outer periphery of the interlayer. 8 . The method of claim 6 , wherein a length of the cut line is 5% or less of a total length of the boundary between the first region and the second region. 9 . The method of claim 1 , wherein the dry electrode film has a first area (S 1 ), and the at least one interlayer has a second area (S 2 ), wherein a ratio (S 2 /S 1 ) of the second area (S 2 ) to the first area (S 1 ) is about 0.5 to about 0.99; and the electrode current collector has a third area (S 3 ), and the at least one interlayer has the second area (S 2 ), wherein a ratio (S 2 /S 3 ) of the second area (S 2 ) to the third area (S 3 ) is in a range of about 0.5 to about 0.99. 10 . The method of claim 1 , wherein: the dry electrode comprises a plurality of dry electrode active material layers which are identical to the dry electrode active material layer and are on the at least one surface of the electrode current collector to be spaced apart from each other in a transverse direction (TD) of the electrode current collector; each of the plurality of dry electrode active material layers has a first machine direction (MD) length (MDL 1 ) and a first TD length (TDL 1 ), and the electrode current collector has a second MD length (MDL 2 ) and a second TD length (TDL 2 ); a ratio (MDL 1 /TDL 1 ) of the first MD length (MDL 1 ) of the dry electrode active material layer to the first TD length (TDL 1 ) of the dry electrode active material layer is 20 or more; a ratio (TDL 1 /TDL 2 ) of the first TD length (TLD 1 ) of the dry electrode active material layer to the second TD length (TDL 2 ) of the electrode current collector is 0.3 or less; each of the plurality of dry electrode active material layers has first MD tensile strength (MDS 1 ) and first TD tensile strength (TDS 1 ); and a ratio (MDS 1 /TDS 1 ) of the first MD tensile strength (MDS 1 ) to the first TD tensile strength (TDS 1 ) is 2 or more. 11 . The method of claim 1 , wherein the dry electrode comprises the dry electrode active material layer on the at least one surface of the electrode current collector along a machine direction (MD) of the electrode current collector, the dry electrode active material layer has a third MD length (MDL 3 ) and a third transverse direction (TD) length (TDL 3 ), the electrode current collector has a fourth MD length (MDL 4 ) and a fourth TD length (TDL 4 ), both ends of the dry electrode active material layer in a transverse direction (TD) are spaced apart from both ends of the electrode current collector in the TD, respectively, the third TD length (TDL 3 ) of the dry electrode active material layer is in a range of about 60% to about 99% of the fourth TD length (TDL 4 ) of the electrode current collector, and the dry electrode active material layer has first MD tensile strength (MDS 1 ) and first TD tensile strength (TDS 1 ), wherein a ratio (MDS 1 /TDS 1 ) of the first MD tensile strength (MDS 1 ) to the first tensile TD strength (TDS 1 ) is 2 or more. 12 . The method of claim 1 , wherein the dry electrode comprises the dry electrode active material layer on the at least one surface of the electrode current collector in a machine direction (MD) of the electrode current collector, the dry electrode active material layer has a fifth MD length (MDL 5 ) and a fifth transverse direction (TD) length (TDL 5 ), the electrode current collector has a sixth MD length (MDL 6 ) and a sixth TD length (TDL 6 ), the fifth TD length (TDL 5 ) of the dry electrode active material layer is in a range of about 99% to about 101% of the sixth TD length (TDL 6 ) of the electrode current collector, and the dry electrode active material layer has first MD tensile strength (MDS 1 ) and first TD tensile strength (TDS 1 ), wherein a ratio (MDS 1 /TDS 1 ) of the first MD tensile strength (MDS 1 ) to the first tensile TD strength (TDS 1 ) is 2 or more. 13 . The method of claim 1 , wherein: the dry electrode comprises a plurality of dry electrode active material layers which are identical to the dry electrode active material layer and are on the at least one surface of the electrode current collector to be spaced apart from each other in a machine direction (MD) of the electrode current collector; the plurality of dry electrode active material layers have a patterned arrangement, and each of the plurality of dry electrode active material layers is spaced apart from each of both ends of the electrode current collector in the MD and both ends of the electrode current collector in a transverse direction (TD); each of the plurality of dry electrode active material layers has a seventh MD length (MDL 7 ) and a seventh TD length (TDL 7 ), and the electrode current collector has an eighth MD length (MDL 8 ) and an eighth TD length (TDL 8 ); a ratio (MDL 7 /TDL 7 ) of the seventh MD length (MDL 7 ) of the dry electrode active material layer to the seventh TD length (TDL 7 ) of the dry electrode active material layer is 5 or less, and the seventh TD length (TDL 7 ) of the dry electrode active material layer is in a range of about 60% to about 99% of the eighth TD length (TDL 8 ) of the electrode current collector; and the dry electrode active material layer has first MD tensile strength (MDS 1 ) and first TD tensile strength (TDS 1 ), wherein a ratio (MDS 1 /TDS 1 ) of the first MD tensile strength (MDS 1 ) to the first tensile TD strength (TDS 1 ) is in a range of about 5 to about 2