Portable flame electric generation device, metal-supported solid oxide fuel cell and manufacturing methods thereof

What is claimed is: 1. A portable flame electric generation device, comprising: a furnace for providing a flame; a heat shield structure, located above the furnace and including a plurality of first ventilation channels; a plurality of metal-supported solid oxide fuel cells, mounted above the furnace, covered by the heat shield structure, an anode side of each said metal-supported solid oxide fuel cell facing the flame provided by the furnace, while a cathode side thereof faces the first ventilation channels of the heat shield structure; a housing structure, covering the heat shield structure and including a plurality of second ventilation channels; and a pad structure being located between the housing structure and the heat shield structure so as to form a thermal insulation gap, air required by cathodes of the metal-supported solid oxide fuel cells flowing to the cathodes of the metal-supported solid oxide fuel cells through the second ventilation channels, the thermal insulation gap and the first ventilation channels; wherein the furnace uses a liquefied gas as a fuel and heat source; wherein the metal-supported solid oxide fuel cells are supported by porous metal substrates with a plurality of straight gas channels that penetrate porous plate bodies of the porous metal substrates and that do not penetrate porous surface layers of the porous metal substrates. 2. The portable flame electric generation device of claim 1 , further including: a high temperature ceramic adhesive and high temperature ceramics plates, the metal-supported solid oxide fuel cells being connected by the high temperature ceramic adhesive or by the high temperature ceramic adhesive and the high temperature ceramic plates, wherein the high temperature ceramic adhesive and the high temperature ceramic plates are used in a temperature less than 1300° C., the high temperature ceramic adhesive serves both connection and sealing functions and the high temperature ceramic plates are Al 2 O 3 or ZrO 2 plates. 3. The portable flame electric generation device of claim 1 , wherein the metal-supported solid oxide fuel cells are located to surround the flame or surround the flame and be above the flame. 4. The portable flame electric generation device of claim 3 , further including: a top metal plate, located over the flame provided by the furnace, wherein the top metal plate is a metal plate made of crofer 22, ZMG232, or a ferritic stainless steel containing Cr. 5. The portable flame electric generation device of claim 4 , wherein the top metal plate includes a room or space for accommodating one of the plural metal-supported solid oxide fuel cells. 6. The portable flame electric generation device of claim 1 , further including: a support structure, located between the heat shield structure and the furnace, to support the heat shield structure and the plurality of metal-supported solid oxide fuel cells above the furnace. 7. The portable flame electric generation device of claim 1 , wherein the furnace includes a fuel tank, a control switch, a fuel delivery device, an air mixer for mixing air with fuel, a voltage/current monitor, a plug-type charging connector and a USB charging connector, the fuel tank being to supply a fuel, the fuel tank being connected with the fuel delivery device, the air mixer being located close to the fuel delivery device, the control switch being to ignite the flame and to control a flow rate of the fuel, the voltage/current monitor being to display an output voltage, an environmental temperature around the metal-supported solid oxide fuel cells and the flow rate of the fuel, the plug-type charging connector or the USB charging connector being to supply electric power. 8. The portable flame electric generation device of 7 , further including: a base, located on the furnace, communicated in space with the fuel delivery device, being to convey the fuel inside the fuel delivery device into the heat shield structure; and an igniter, located on the furnace, electrically connected with the control switch. 9. The portable flame electric generation device of claim 7 , further including: a thermometer, located on the furnace, electrically coupled with the voltage/current monitor, being to detect the environmental temperature around the metal-supported solid oxide fuel cells and then to display the measured environmental temperature on the voltage/current monitor. 10. The portable flame electric generation device of claim 1 , wherein a metallic anode current collector is located to the anode side of each said metal-supported solid oxide fuel cell, and a metallic cathode current collector is located to the cathode side of each said metal-supported solid oxide fuel cell. 11. The portable flame electric generation device of claim 10 , further including: a mesh holder, being to mount the metallic anode current collector and the metallic cathode current collector to the corresponding anode and cathode of metal-supported solid oxide fuel cell.