Heating component to reduce solidification in a cryogenic distillation system

What is claimed is: 1. A method comprising: feeding a feed gas comprising methane (CH4) and carbon dioxide (CO2) to a cryogenic distillation column during start-up of the cryogenic distillation column; producing an acid gas rich bottom stream and a freeze zone vapor stream; flowing the freeze zone vapor stream into a freezing section of the cryogenic distillation column, wherein the freeze zone vapor stream exits the cryogenic distillation column as an overhead stream, and wherein the overhead stream has a temperature and a CO2 concentration; heating the overhead stream via a heating component to form a heated overhead stream to reduce or prevent solidification of the CO2 in the overhead stream; regulating an amount of heat emitted by the heating component via a control system, wherein the control system maintains a temperature margin of the heated overhead stream using a measured temperature as an input into a control scheme, wherein the temperature margin is a temperature difference between the temperature of the overhead stream and a temperature at which CO2 solidification would occur in the overhead stream given the CO2 concentration of the overhead stream; and flowing the heated overhead stream into a heat exchanger, wherein the heated overhead stream substantially prevents solidification of CO2 in the heat exchanger. 2. The method of claim 1 , wherein the heating of the overhead stream comprises raising a temperature of the overhead stream by 0.5° F. to 10° F. 3. The method of claim 1 , comprising measuring a temperature of the heated overhead stream at an inlet of the heat exchanger. 4. The method of claim 1 , comprising recycling the overhead stream back to the cryogenic distillation column, wherein the overhead stream enters a cooling cycle comprising compression, heat exchange, and reduction in pressure and temperature in the recycle. 5. The method of claim 1 , comprising recycling the overhead stream back to the cryogenic distillation column until a concentration of the CO2 is lowered to a non-solidifying range. 6. The method of claim 1 , comprising diverting the overhead stream to a reflux accumulator after a non-solidifying range for the CO2 is reached. 7. The method of claim 1 , wherein heating the overhead stream via the heating component comprises disposing an inline heater in a flow line of the overhead stream, wherein the inline heater is disposed upstream of the heat exchanger. 8. The method of claim 1 , wherein heating the overhead stream via the heating component comprises disposing heat tracing on a flow line of the overhead stream, wherein the heating tracing is disposed upstream of the heat exchanger. 9. The method of claim 1 , wherein heating the overhead stream via the heating component comprises diverting a portion of the overhead stream to an external heat exchanger to form a heated diverted portion and blending the heated diverted portion into the overhead stream. 10. A method comprising: feeding a feed gas comprising carbon dioxide (CO2) and methane (CH4) into a cryogenic distillation column during start-up; producing an acid gas rich bottom stream and a freeze zone vapor stream in the cryogenic distillation column; flowing the freeze zone vapor stream into a freezing section of the cryogenic distillation column, wherein the freeze zone vapor stream exits the cryogenic distillation column as an overhead stream, and wherein the overhead stream has a temperature and a CO2 concentration; heating the overhead stream via a heating component to form a heated overhead stream; regulating an amount of heat emitted by the heating component via a control system, wherein the control system uses a measured temperature as an input into a control scheme to maintain a temperature margin of the heated overhead stream, wherein the temperature margin is a temperature difference between the temperature of the overhead stream and a temperature at which CO2 solidification would occur in the overhead stream given the CO2 concentration of the overhead stream; flowing the heated overhead stream into a heat exchanger, wherein solidification of the CO2 in the heat exchanger is substantially reduced or prevented; compressing the heated overhead stream via an overhead compressor to produce a high-pressure vapor, wherein the heated overhead stream is compressed to a pressure beyond solidification conditions for CO2; reducing pressure and temperature of the high-pressure vapor via a Joule-Thomson (J-T) valve to produce a liquid-vapor stream; flowing the liquid-vapor stream into the cryogenic distillation column, wherein the liquid-vapor stream is introduced into the cryogenic distillation column to lower a concentration of the CO2 in the overhead stream; cycling the liquid-vapor stream back to the cryogenic distillation column, wherein the cycling comprises a cooling cycle comprising compression, heat exchange, and reduction in pressure and temperature; and continuously recycling the liquid-vapor stream back to the cryogenic distillation column until a concentration of the CO2 in the liquid-vapor stream is lowered to a non-solidifying range.