Composite solid electrolyte without self-discharge, battery unit cell having same, and method of manufacturing composite solid electrolyte

What is claimed is: 1. A composite solid electrolyte comprising: molten salt powder particles having electrical insulating properties at room temperature; and solid electrolyte powder particles on which surfaces thereof the molten salt powder particles are combined, wherein the molten salt powder particles are added in form of powder particles to be interposed between the solid electrolyte powder particles, wherein the solid electrolyte powder particles are garnet solid electrolytes, wherein a composition ratio of the molten salt powder particles is 10 to 70 wt. %, and a composition ratio of the solid electrolyte powder particles is 30 to 90 wt. % to enhance the stability of a thermal cell, wherein the molten salt powder particles comprise at least one of first molten salt powder particles and second molten salt powder particles smaller in size than the first molten salt powder particles, wherein the first molten salt powder particles have a size of +50 to −200 mesh, and the second molten salt powder particles have a size of −325 mesh, wherein the solid electrolyte has a thickness of 0.05 to 1.0 mm, and wherein the molten salt powder particles become a molten salt electrolyte having conductivity when a pyrotechnic heat source layer is activated and thereby temperature rises equal to or greater than a melting point. 2. The composite solid electrolyte of claim 1 , wherein the molten salt powder particles are mixed with the solid electrolyte powder particles in a form of an aqueous molten salt solution and then dried to be combined with the solid electrolyte powder particles. 3. The composite solid electrolyte of claim 1 , wherein the molten salt powder particles and the solid electrolyte powder particles are mixed and subjected to warm uniaxial pressing at a temperature equal to or less than a melting point of the molten salt. 4. A thermal battery unit cell comprising: a current collector layer, an anode layer formed on top of the current collector layer, a composite solid electrolyte layer formed on top of the anode layer, a cathode layer formed on top of the composite solid electrolyte layer, and a pyrotechnic heat source layer formed on top of the cathode layer, wherein the composite solid electrolyte layer comprises molten salt powder particles and having electrical insulating properties at room temperature, and solid electrolyte powder particles on which surfaces thereof the molten salt powder particles are combined, wherein the molten salt powder particles are added in form of powder particles to be interposed between the solid electrolyte powder particles, wherein the solid electrolyte powder particles are garnet solid electrolytes, wherein a composition ratio of the molten salt powder particles is 10 to 70 wt. %, and a composition ratio of the solid electrolyte powder particles is 30 to 90 wt. % to enhance the stability of a thermal cell, wherein the molten salt powder particles comprise at least one of first molten salt powder particles and second molten salt powder particles smaller in size than the first molten salt powder particles, wherein the first molten salt powder particles have a size of +50 to −200 mesh, and the second molten salt powder particles have a size of −325 mesh, wherein the solid electrolyte has a thickness of 0.05 to 1.0 mm, wherein the molten salt powder particles become a molten salt electrolyte having conductivity when a pyrotechnic heat source layer is activated and thereby temperature rises equal to or greater than a melting point. 5. The thermal battery unit cell of claim 4 , wherein the anode layer is made of at least one of a lithium alloy and a lithium-iron mixture. 6. The thermal battery unit cell of claim 4 , wherein the cathode layer is made of any one of sulfide, fluoride, and oxide. 7. A method of manufacturing a composite solid electrolyte, the method comprising: preparing molten salt powder particles having electrical insulating properties at room temperature, and solid electrolyte powder particles; and combining the molten salt powder particles on surfaces of the solid electrolyte powder particles to produce composite solid electrolytes, wherein the molten salt powder particles are added in form of powder particles to be interposed between the solid electrolyte powder particles, wherein the solid electrolyte powder particles are garnet solid electrolytes, wherein a composition ratio of the molten salt powder particles is 10 to 70 wt. %, and a composition ratio of the solid electrolyte powder particles is 30 to 90 wt. % to enhance the stability of a thermal cell, wherein the molten salt powder particles comprise at least one of first molten salt powder particles and second molten salt powder particles smaller in size than the first molten salt powder particles, wherein the first molten salt powder particles have a size of +50 to −200 mesh, and the second molten salt powder particles have a size of −325 mesh, wherein the solid electrolyte has a thickness of 0.05 to 1.0 mm, wherein the molten salt powder particles become a molten salt electrolyte having conductivity when a pyrotechnic heat source layer is activated and thereby temperature rises equal to or greater than a melting point. 8. A method of manufacturing a composite solid electrolyte, the method comprising: preparing molten salt powder particles having electrical insulating properties at room temperature, and solid electrolyte powder particles; dissolving molten salt powder particles by adding a liquid solute which is water or an organic solvent to produce a solution; and mixing the solid electrolyte powder particles into the solution, followed by drying to produce composite solid electrolytes, wherein the molten salt powder particles are added in form of powder particles to be interposed between the solid electrolyte powder particles, wherein the solid electrolyte powder particles are garnet solid electrolytes, wherein a composition ratio of the molten salt powder particles is 10 to 70 wt. %, and a composition ratio of the solid electrolyte powder particles is 30 to 90 wt. % to enhance the stability of a thermal cell, wherein the molten salt powder particles comprise at least one of first molten salt powder particles and second molten salt powder particles smaller in size than the first molten salt powder particles, wherein the first molten salt powder particles have a size of +50 to −200 mesh, and the second molten salt powder particles have a size of −325 mesh, wherein the solid electrolyte has a thickness of 0.05 to 1.0 mm, wherein the molten salt powder particles become a molten salt electrolyte having conductivity when a pyrotechnic heat source layer is activated and thereby temperature rises equal to or greater than a melting point.