Process for producing hydrogen, carbon monoxide, and carbon from methane-containing feedstock

What is claimed is: 1 . A rotary kiln-type reactor comprises: a tube configured to accommodate solid particles and gas and to be rotatable; a heater configured to supply controlled heat to an inner space of the tube; a helix baffle configured to extend along an inner circumferential surface of the tube to induce the accommodated solid particles to move forward in a longitudinal direction of the tube according to rotation of the tube; and at least one lifter provided on the inner circumferential surface of the tube to disperse the accommodated solid particles in the tube. 2 . The reactor of claim 1 , wherein the solid particles are iron oxide-containing catalysts, and the gas is a methane-containing feedstock. 3 . The reactor of claim 2 , wherein the iron oxide-containing catalysts are supplied from a catalyst storage device, and introduced together with the methane-containing feedstock into the tube. 4 . The reactor of claim 1 , wherein the tube is made of at least one selected from the group consisting of alumina, SiC, FeCrAl alloy, Inconel (NiCr), and heat-resistant stainless steel. 5 . The reactor of claim 1 , wherein the heater is provided in a way to surround at least a portion of the outside of the tube, whereby heat is transferred to the inner space through the wall of the tube. 6 . The reactor of claim 2 , wherein the rotary kiln-type reactor is configured to introduce the methane-containing feedstock and the iron oxide-containing catalysts into the tube in a co-current flow manner. 7 . The reactor of claim 6 , wherein the tube is configured such that an inner buffer tube and an outlet buffer tube, respectively, are connected or linked to both sides of a central work tube. 8 . The reactor of claim 1 , wherein lifters of up to 12 are provided per pitch of the helix baffle. 9 . The reactor of claim 1 , wherein the at least one lifter has at least one of a straight shape or a bent shape. 10 . The reactor of claim 9 , wherein the bent shape is a shape bent in an oblique line or a shape bent at a right angle. 11 . The reactor of claim 1 , wherein a helix angle of the helix baffle is adjusted to range from 30 to 60°. 12 . The reactor of claim 1 , wherein a pitch length of the helix baffle ranges from 1/60 to ⅙ of a length of the tube. 13 . The reactor of claim 1 , wherein a height of the helix baffle is adjusted to range from 1/10 to ½ of an inner diameter of the tube, and a height of the lifter is adjusted to range from 1/10 to ½ of the inner diameter of the tube. 14 . The reactor of claim 1 , wherein a ratio of a length of the tube to an inner diameter of the tube (L/D) ranges from 5 to 50. 15 . The reactor of claim 2 , wherein a rotational speed of the tube is adjusted to range from of 0.05 to 5 rpm and a residence time of the iron oxide-containing catalysts is adjusted to range from 1 to 150 hours. 16 . The reactor of claim 6 , wherein an inlet for the methane-containing feedstock and the iron oxide-containing catalysts is provided at one end of the tube. 17 . A system for pyrolysis of methane, which comprises: a rotary kiln-type reactor which is connected to a storage device of iron oxide-containing catalysts and a supply line of methane-containing feedstock, respectively, and forms pyrolysis products containing unreacted methane, carbon, hydrogen, and carbon monoxide by pyrolyzing methane in the methane-containing feedstock in the presence of the iron oxide-containing catalysts; a gas-solid separator for separating a gas mixture containing the unreacted methane, the hydrogen, the carbon monoxide, and an iron (Fe)-containing carbon-based solid from the pyrolysis products; a gas separation unit for separating the gas mixture into methane, hydrogen and carbon monoxide, respectively, wherein the rotary kiln-type reactor comprises: a tube configured to accommodate the iron oxide-containing catalysts as solid particles and the methane-containing feedstock as gas, and to be rotatable; a heater configured to supply controlled heat to an inner space of the tube; a helix baffle configured to extend along an inner circumferential surface of the tube to induce the accommodated iron oxide-containing catalysts to move forward in a longitudinal direction of the tube according to rotation of the tube; and at least one lifter provided on the inner circumferential surface of the tube to disperse the accommodated iron oxide-containing catalysts in the tube. 18 . The system of claim 17 , which further comprises a splitter for recycling methane, disposed downstream of the gas separation unit, such that the recycled methane is combined with the methane-containing feedstock. 19 . The system of claim 17 , wherein the gas separation unit is a pressure swing adsorption (PSA) unit, a vacuum swing adsorption (VSA), or a membrane separation unit. 20 . The system of claim 18 , which further comprises a post-processing unit to subject the iron (Fe)-containing carbon-based solid to purification for other end uses.