Electrochemical cell unit, electrochemical cell stack, method for producing electrochemical cell unit, and method for producing electrochemical cell stack

What is claimed is: 1 . An electrochemical cell stack comprising: units each containing: a flat plate type membrane electrode assembly having a structure in which an electrolyte membrane, a first electrode layer disposed on a first surface of the electrolyte membrane, and a second electrode layer disposed on a second surface of the electrolyte membrane are laminated; a first current collector in contact with the first electrode layer of the membrane electrode assembly; an interconnector electrically connected to the first current collector, a second current collector in contact with the second electrode layer of the membrane electrode assembly; and an outer peripheral part made of a metal material that surrounds an outer periphery of the first electrode layer together with the interconnector and the electrolyte membrane to form a gas introduction space for guiding internal gas to the first electrode layer, and an attachment base part having a fixing part made of an electrically insulating member and fixes the units in which the second current collector of a first one of adjacent two of the units and the interconnector of a second one of the adjacent two of the units are electrically connected. 2 . The electrochemical cell stack according to claim 1 , wherein the outer peripheral part has an inlet part through which the internal gas flows into the gas introduction space and an outlet part through which internal gas used for an electrochemical reaction of the membrane electrode assembly is discharged from the gas introduction space; and the attachment base part has a gas supply path that is communicated with the gas introduction space through the inlet part and supplies the internal gas to the gas introduction space. 3 . The electrochemical cell stack according to claim 1 , wherein the electrically insulating member is a ceramic member. 4 . The electrochemical cell stack according to claim 2 , further comprising a gas collecting part that collects the internal gas discharged from the gas introduction space through the outlet part. 5 . The electrochemical cell stack according to claim 2 , wherein the inlet part and the outlet part of the outer peripheral part are provided symmetrically with respect to the membrane electrode assembly when the units are viewed in plan view in a direction in which the units are laminated. 6 . The electrochemical cell stack according to claim 5 , wherein the membrane electrode assembly has a circular shape. 7 . The electrochemical cell stack according to claim 2 , wherein opening width dimensions of the inlet part and the outlet part are within a range of a projection width of the membrane electrode assembly in a direction in which the internal gas flows. 8 . The electrochemical cell stack according to claim 1 , wherein the outer peripheral part is joined to the electrolyte membrane with any one selected from the group consisting of glass, ceramics, and silver solder interposed therebetween. 9 . The electrochemical cell stack according to claim 1 , wherein the metal material of which the outer peripheral part is made is stainless steel. 10 . An electrochemical cell unit comprising: a flat plate type membrane electrode assembly having a structure in which an electrolyte membrane, a first electrode layer disposed on a first surface of the electrolyte membrane, and a second electrode layer disposed on a second surface of the electrolyte membrane are laminated; a first current collector in contact with the first electrode layer of the membrane electrode assembly; an interconnector electrically connected to the first current collector, a second current collector in contact with the second electrode layer of the membrane electrode assembly; and an outer peripheral part made of a metal material that surrounds an outer periphery of the first electrode layer together with the interconnector and the electrolyte membrane to form a gas introduction space for guiding internal gas to the first electrode layer, 11 . The electrochemical cell unit according to claim 10 , wherein the outer peripheral part has an inlet part through which the internal gas flows into the gas introduction space and an outlet part through which internal gas used for an electrochemical reaction of the membrane electrode assembly is discharged from the gas introduction space. 12 . The electrochemical cell unit according to claim 11 , wherein the inlet part and the outlet part of the outer peripheral part are provided symmetrically with respect to the membrane electrode assembly when the units are viewed in plan view in a direction in which the units are laminated. 13 . The electrochemical cell unit according to claim 10 , wherein the membrane electrode assembly has a circular shape. 14 . The electrochemical cell unit according to claim 11 , wherein opening width dimensions of the inlet part and the outlet part are within a range of a projection width of the membrane electrode assembly in a direction in which the internal gas flows. 15 . The electrochemical cell unit according to claim 10 , wherein the outer peripheral part is joined to the electrolyte membrane with any one selected from the group consisting of glass, ceramics, and silver solder interposed therebetween. 16 . A method for producing the electrochemical cell unit according to claim 10 , the method comprising: applying first paste, which is any one selected from the group consisting of a glass sealing agent, a ceramic adhesive, and a silver soldering agent, to a first joint part where the outer peripheral part and a surface of the electrolyte membrane that faces the second electrode layer are joined; applying second paste having electric conductivity to a second joint part where a surface of the second electrode layer on which the second current collector is provided and the second current collector are joined; joining the outer peripheral part and the electrolyte membrane in the first joint part by application of pressure; joining the second electrode layer and the second current collector in the second joint part by application of pressure; and heat-treating the first joint part and the second joint part together at 800° C. to 900° C. to form the units. 17 . A method for producing the electrochemical cell stack according to claim 1 the method comprising; applying first paste, which is any one selected from the group consisting of a glass sealing agent, a ceramic adhesive, and a silver soldering agent, to a first joint part where the outer peripheral part and a surface of the electrolyte membrane that faces the second electrode layer are joined; applying second paste having electric conductivity to a second joint part where a surface of the second electrode layer on which the second current collector is provided and the second current collector are joined; joining the outer peripheral part and the electrolyte membrane in the first joint part by application of pressure; joining the second electrode layer and the second current collector in the second joint part by application of pressure; heat-treating the first joint part and the second joint part together at 800° C. to 900° C. to form the units; applying a glass sealing agent or a ceramic adhesive to a third joint part where the units formed in the heat-treating and the attachment base part are joined; and heat-treating the third joint part at a temperature lower than the temperature for the heat treatment in the heat-treating.