Method for manufacturing a solid oxide fuel cell device

What is claimed is: 1 . A method for manufacturing a solid oxide fuel cell device comprising a cell array including a plurality of individual fuel cells housed in a fuel cell module, and a current collector electrically connected to electrodes formed on the end portions of the plurality of individual fuel cells constituting the cell array, comprising: a step for respectively forming electrically conductive electrode protective layers on electrodes formed on the end portions of the plurality of individual fuel cells; a modularization step for forming a cell array from the plurality of individual fuel cells; and an attaching step for attaching a current collector to the cell array, wherein the current collector is a metal plate in which a plurality of attaching holes are formed for respectively inserting the end portions of the plurality of individual fuel cells, a plurality of elastic pieces are provided at each attaching hole, and by pressing the current collector into the cell array, the end portions of the individual fuel cells are inserted into the corresponding attaching holes of the current collector, and the current collector is attached to the cell array by the elastic force of the elastic pieces; wherein the electrode protective layer is constituted to prevent damage to the electrode caused by contact of the elastic pieces in the attaching step. 2 . The method of claim 1 , wherein further comprising: after the attaching step, an adhesion step for adhering the elastic pieces and the electrode protective layer. 3 . The method of claim 2 , wherein the electrode protective layer has the function of adhering the elastic pieces and the electrode. 4 . The method of claim 3 , wherein the adhering function is activated by heating the electrode protective layer, the method for manufacturing the solid oxide fuel cell device includes a heating step for heating the cell array to perform a certain process, and the heating step doubles as a step for heating the electrode protective layer in the adhesion step. 5 . The method of claim 4 , wherein the adhering function is activated by heating the electrode protective layer to fluidize and then solidifying at least a portion of the electrode protective layer. 6 . The method of claim 5 , wherein the electrode protective layer includes granular electrically conductive material, and the adhesion step is a step for sintering the granular electrically conductive material.