Process for reforming hydrocarbons

The invention claimed is: 1. Process for the production of synthesis gas from a hydrocarbon feedstock, comprising the steps of: a. reforming at least a portion of said hydrocarbon feedstock in an endothermic reforming stage in a heat exchange reformer and withdrawing from the heat exchange reformer an effluent stream of primary reformed gas; b. passing the primary reformed gas from the heat exchange reformer through an autothermal reforming stage (ATR), catalytic partial oxidation stage (CPO) or partial oxidation stage (POX), and withdrawing a stream of hot effluent synthesis gas; and c. splitting the hot effluent synthesis gas into at least a first synthesis gas stream and a second synthesis gas stream, wherein said first synthesis gas stream is used as heating medium in indirect heat exchange in the heat exchange reformer of step (a) with an exit temperature in the range of from 450-800° C.; and wherein said second synthesis gas stream is directed to a second heat exchanger and cooled by indirect heat exchange to produce a cooled second synthesis gas stream. 2. Process according to claim 1 , further comprising the step of: adding a stream comprising steam to either said hot effluent synthesis gas from step (b) or to said first synthesis gas stream. 3. Process according to claim 1 , wherein the hydrocarbon feedstock is subjected to a step of pre-reforming, preferably adiabatic pre-reforming before being directed to the heat exchange reformer. 4. Process according to claim 1 , wherein the process comprises a further step after the first synthesis gas stream has passed through the heat exchange reformer of: cooling the first synthesis gas stream to a temperature sufficiently low for the steam to condense, and separating the synthesis gas from said condensate. 5. Process according to claim 1 , further comprising mixing the primary reformed gas with tail gas from a Fischer-Tropsch synthesis stage or downstream process for the production of gasoline. 6. Process according to claim 1 , wherein a bypass ratio of the flow of second synthesis gas stream to the flow of the effluent stream from the autothermal reformer is between 1% and 30%. 7. Process according to claim 6 , wherein—as the process proceeds—the bypass ratio is reduced with time. 8. Process according to claim 1 , comprising mixing the primary reformed gas or the hydrocarbon feedstock with a gas stream comprising at least 90 vol% CO 2 . 9. Process according to claim 1 , wherein the heat exchange reformer is selected from a tube and shell heat exchanger, and double-tube reactor with catalyst disposed inside the double tubes, catalyst disposed outside the double tubes, and/or catalyst disposed outside and inside the double tubes. 10. Process according to claim 1 , wherein the primary reformed gas from the heat exchange reformer is passed through an autothermal reforming stage (ATR). 11. Process according to claim 1 , further comprising the step of converting the separated synthesis gas into ammonia synthesis gas, methanol synthesis gas, dimethyl ether (DME) synthesis gas, synthesis gas for production of hydrocarbons by Fischer-Tropsch synthesis, or synthesis gas for the production of hydrogen, and further converting said synthesis gas into the respective product in the form of ammonia, methanol, DME, liquid hydrocarbons in a downstream process for production of gasoline, or hydrogen. 12. Process according to claim 1 , wherein a portion of the hydrocarbon feedstock is led directly as a by-pass stream to the primary reformed gas to form a combined stream before entering the ATR, CPO or POX. 13. Process according to claim 1 , wherein the process steam-to-carbon ratio (S/C process ) is in the range 0.4-3.0. 14. Process according to claim 1 , wherein the H 2 /CO-molar ratio in said stream of cooled synthesis gas in the first synthesis gas stream is in the range of 1.7 to 2.3. 15. Process according to claim 1 , wherein, after the heat exchange reformer, cooled syngas or further cooled syngas, first synthesis gas stream and the cooled second synthesis gas stream are mixed together to provide a raw synthesis gas product stream. 16. Process according to claim 1 , wherein: a. at least a second portion of said hydrocarbon feedstock is reformed in an endothermic reforming stage in at least a second heat exchange reformer and an second effluent stream of primary reformed gas is withdrawn from said second heat exchange reformer; b. said second effluent stream of primary reformed gas is combined with the effluent stream of primary reformed gas hydrocarbon feedstock; c. the combined primary reformed gases from the heat exchange reformers are passed through an autothermal reforming stage (ATR), catalytic partial oxidation stage (CPO) or partial oxidation stage (POX), and a stream of hot effluent synthesis gas is withdrawn; d. the hot effluent synthesis gas from the autothermal reforming stage (ATR), catalytic partial oxidation stage (CPO) or partial oxidation stage (POX), is split into at least a first synthesis gas stream, a second synthesis gas stream and a third synthesis gas stream, and wherein said first synthesis gas stream is used as heating medium in indirect heat exchange in the heat exchange reformer of step (a) with an exit temperature in the range of from 450-800° C.; and wherein said second synthesis gas stream is directed to a second heat exchanger and cooled by indirect heat exchange to produce a cooled second synthesis gas stream; and wherein said third synthesis gas stream is used as heating medium in indirect heat exchange in the second heat exchange reformer. 17. A method of using the process of claim 1 , comprising starting a Fischer-Tropsch synthesis for producing hydrocarbons or a downstream process for production of gasoline by using the process of claim 1 . 18. Process for the production of synthesis gas from a hydrocarbon feedstock, comprising the steps of: a. dividing the hydrocarbon feedstock into at least a first and a second hydrocarbon feedstock stream; b. reforming said first hydrocarbon feedstock stream in an endothermic reforming stage in one or more heat exchange reformers and withdrawing from the heat exchange reformer an effluent stream of reformed gas; c. passing the second hydrocarbon feedstock stream through an autothermal reforming stage (ATR), catalytic partial oxidation stage (CPO) or partial oxidation stage (POX), and withdrawing a stream of hot effluent synthesis gas; characterised in that the process comprises the step of splitting said hot effluent synthesis gas into at least a first synthesis gas stream and a second synthesis gas stream, wherein said first synthesis gas stream is used as heating medium in indirect heat exchange in the heat exchange reformer of step (b)) with an exit temperature in the range of from 450-800° C.; and wherein said second synthesis gas stream is directed to a second heat exchanger and cooled by indirect heat exchange to produce a cooled second synthesis gas stream. 19. Process according to claim 18 , wherein the first synthesis gas stream is combined with reformed gas from the heat exchange reformer prior to delivering heat to said heat exchange reformer. 20. Process for starting up the hydrocarbon synthesis section of a gas-to-liquid process comprising: a. reforming at least a portion of a hydrocarbon feedstock in an endothermic reforming stage in a heat exchange reformer and withdrawing from the heat exchange reformer an effluent stream of primary reformed gas; b