Control of an ammonia synthesis loop at partial load

1 - 16 . (canceled) 17 . A process for synthesis of ammonia, the process comprising: producing an ammonia make-up synthesis gas in a front-end; raising a pressure of said ammonia make-up gas in a first compressor; feeding high-pressure make-up synthesis gas delivered by said first compressor to an ammonia synthesis loop; wherein said ammonia synthesis loop includes at least: a converter where ammonia is synthesized catalytically; a circulator, which is a compressor configured to maintain circulation in the loop and to deliver a feed gas, which includes the make-up synthesis gas, to said converter; a converter feed line from the circulator to the converter; a condensation section arranged downstream the synthesis section to receive an ammonia-containing gaseous product; a separation section wherein a condensate produced in said condensation section is separated into an ammonia liquid product and a gaseous recycle stream; a recycle line from the separation section to the suction of the circulator; wherein the ammonia synthesis loop has a full load condition corresponding to the processing of a nominal flow rate of ammonia make-up gas transferred from the front end to the synthesis loop, controlling the loop at a partial load condition, wherein the flow rate of ammonia make-up gas transferred from the front end to the loop is smaller than said nominal flow rate, by: separating a gas stream from said converter feed line, at a point upstream of the converter, to form a bypass stream; reintroducing said bypass stream at the suction side of the circulator or into the ammonia synthesis loop at a point downstream of said separation section. 18 . The process according to claim 17 , further comprising: detecting the synthesis pressure in the converter or at another location of the ammonia synthesis loop; and determining the amount of gas in the bypass stream so that the difference between the detected synthesis pressure at partial load and the synthesis pressure at full load is maintained within a target range. 19 . The process according to claim 17 , further comprising: detecting the difference of temperature across the converter, by detecting the difference between the temperature of the gas feed entering the converter and the temperature of an ammonia-containing product withdrawn from the converter; determining the amount of gas in the bypass stream so that said difference of temperature across the converter is maintained within a target range. 20 . The process according to claim 17 , further comprising: determining the amount of gas in the bypass stream as a function of the instant amount and/or of the variation over time of the flow rate of makeup gas transferred from the front end to the ammonia synthesis loop. 21 . The process according to claim 17 , wherein at partial loads the amount of gas in the bypass stream is controlled so that the pressure in the converter is not less than 90% of the nominal synthesis pressure. 22 . The process according to claim 21 , wherein at partial loads the amount of gas in the bypass stream is controlled so that the pressure in the converter is not greater than 110% of the nominal synthesis pressure. 23 . The process according to claim 17 , wherein said condition of partial load include loads until the ammonia make-up gas transferred from the frontend to the synthesis loop is 15% of the nominal flow rate. 24 . The process according to claim 17 , further comprising: detecting a drop or surge of the flow rate of flow rate of makeup gas transferred from the front end to the synthesis loop, and reacting to said drop or surge of flow by: a) increasing the amount of gas in the bypass stream in the event of a drop of flow or decreasing said amount in the event of a surge of flow; b) after the above step a), controlling the amount of gas in the bypass stream to keep the pressure in the converter, or the difference of temperature across the converter, at a constant value or within a target narrow range. 25 . The process according to claim 17 , including the step of cooling the bypass stream before its reintroduction at the suction of the circulator or in the loop. 26 . The process according to claim 17 , wherein the production of makeup gas in the front end includes the production of hydrogen from a renewable energy source. 27 . A method for controlling an ammonia synthesis loop running at a partial load, wherein: said ammonia synthesis loop includes: a converter where ammonia is synthesized catalytically; a circulator, which is a compressor configured to maintain circulation in the loop and to deliver a feed gas, which includes the make-up synthesis gas, to said converter; a converter feed line from the circulator to the converter; a condensation section arranged downstream the synthesis section to receive an ammonia-containing gaseous product; a separation section wherein a condensate produced in said condensation section is separated into an ammonia liquid product and a gaseous recycle stream; a recycle line from the separation section to the suction of the circulator; wherein the ammonia synthesis loop has a full load condition corresponding to the processing of a nominal flow rate of make-up gas transferred from the front end to the synthesis loop, and said partial load corresponds to a condition wherein an amount less than said nominal flow rate is transferred from the front end to the loop, the method comprising: separating a gas stream from said converter feed line, at a point upstream of the converter, to form a bypass stream and reintroducing said bypass stream at the suction side of the circulator or into the ammonia synthesis loop at a point downstream of said separation section. 28 . The method according to claim 27 , wherein the amount of gas in the bypass stream, at said condition of partial load, is determined as a function of one or more of the following: the instant amount and/or of the variation over time of the flow rate of makeup gas transferred from the front end to the ammonia synthesis loop; the pressure in the synthesis loop or in the converter; the difference of temperature across the converter, detected as the difference between the temperature of the gas feed entering the converter and the temperature of the ammonia-containing product withdrawn from the converter. 29 . The method according to claim 27 , wherein the amount of gas in the bypass stream is determined in such a way that the pressure in the converter is: not less than 90% of the nominal synthesis pressure, preferably not less than 95% and more preferably not less than 98%, and not greater than 110% of the nominal synthesis pressure, preferably not greater than 105% and more preferably not greater than 102%. 30 . The method according to claim 27 , wherein the amount of gas in the bypass stream is determined to keep the difference of temperature across the converter, detected as the difference between the temperature of the gas feed entering the converter and the temperature of an ammonia-containing product withdrawn from the converter, within a target range. 31 . The method according to claim 27 , further comprising: detecting a drop or surge of the flow rate of flow rate of makeup gas transferred from the front end to the synthesis loop, increasing the amount of gas in the bypass stream in the event of a drop of flow or decreasing said amount in the event of a surge of flow; after the above increasing the amount of gas, controlling the amount of gas in the bypass stream to keep the pressure in the converter, or the di