Method for producing a flow rich in methane and a flow rich in C2 + hydrocarbons, and associated installation

What is claimed is: 1. A method of producing a flow rich in methane and a flow rich in C 2 + hydrocarbons from a supply flow containing hydrocarbons, the method comprising the following steps: separating the supply flow into a first fraction of the supply flow and at least a second fraction of the supply flow; introducing the first fraction of the supply flow into a first heat exchanger; cooling the first fraction of the supply flow in the first heat exchanger; introducing the cooled first fraction of the supply flow into a first separation flask in order to produce a light upper flow and a heavy lower flow; dividing the light upper flow into a turbine supply fraction and a column supply fraction; pressure reducing the turbine supply fraction in a first dynamic pressure reduction turbine and introducing at least a portion of the turbine supply fraction subjected to pressure reduction into the first turbine in a middle portion of a first distillation column; cooling and at least partially condensing the column supply fraction and pressure reducing and introducing the cooled column supply fraction into an upper portion of the first distillation column; pressure reducing and partial vaporizing the heavy lower flow in the first heat exchanger and introducing the heavy lower flow subjected to pressure reduction into a second separation flask in order to produce an upper gas fraction and a lower liquid fraction; pressure reducing the lower liquid fraction and introducing the lower liquid fraction in the middle portion of the first distillation column; cooling and at least partially condensing the upper gas fraction and introducing the upper gas fraction into the upper portion of the first distillation column; recovering a lower column flow at the bottom of the first distillation column, the flow rich in C 2 + hydrocarbons being formed from the lower column flow; recovering and reheating of an upper column flow rich in methane; compressing at least a fraction of the upper column flow in at least a first compressor coupled to the first dynamic pressure reduction turbine and in at least a second compressor; removing an extraction flow from the reheated and compressed upper column flow; cooling and introducing the cooled extraction flow into an upper portion of the first distillation column; introducing at least a portion of the second fraction of the supply flow into a second dynamic pressure reduction turbine, separate from the first dynamic pressure reduction turbine; forming an effluent from the second dynamic pressure reduction turbine; cooling and at least partly liquefying at least a portion of the effluent from the second dynamic pressure reduction turbine in a second heat exchanger so as to form a cooled reflux flow; and introducing the cooled reflux flow from the second heat exchanger into the first distillation column, wherein the portion of the second fraction of the supply flow introduced into the second dynamic pressure reduction turbine is conveyed from the separation point of the supply flow to the second dynamic pressure reduction turbine without passing through any heat exchanger. 2. The method according to claim 1 , further comprising: removing a reboiling flow from the first distillation column at a removal level; placing the reboiling flow in a heat exchange relationship with the portion of the effluent from the second dynamic pressure reduction turbine in the second heat exchanger in order to cool and at least partially liquefy the portion of the effluent from the second dynamic pressure reduction turbine; and reintroducing the reboiling flow into the first distillation column at a level lower than the removal level. 3. The method according to claim 1 , wherein the method comprises introducing the fraction subjected to pressure reduction from the first dynamic pressure reduction turbine into the second heat exchanger in order to be cooled and partially liquefied therein, the cooled fraction forming an auxiliary cooled reflux stream; and introducing the auxiliary cooled reflux stream in the first distillation column. 4. The method according to claim 1 , further comprising: introducing the effluent from the second dynamic pressure reduction turbine into a downstream separation flask in order to form a third upper gas flow and a third lower liquid flow; and cooling the third upper gas flow in the second heat exchanger in order to form the cooled reflux flow. 5. The method according to claim 1 , wherein an entirety of the second fraction of the supply flow is introduced into the second dynamic pressure reduction turbine. 6. The method according to claim 1 , wherein the method comprises: removing a secondary compression fraction from the upper column flow rich in methane, before the upper column flow rich in methane is passed into the first compressor; passing the secondary compression fraction into a third compressor coupled to the second dynamic pressure reduction turbine; and introducing the compressed secondary compression fraction from the third compressor into the compressed upper column flow, downstream of the first compressor. 7. The method according to claim 1 , comprising: removing a make-up cooling flow from the upper column flow rich in methane or from a flow formed from the upper column flow rich in methane; and pressure reducing and introducing the make-up cooling flow subjected to pressure reduction into a flow flowing upstream of the first pressure reduction turbine. 8. The method according to claim 1 , wherein the second compressor comprises a first compression stage, at least a second compression stage, and a cooler interposed between the first compression stage and the second compression stage, the method comprising: a step of passing the compressed upper column flow from the first compressor successively into the first compression stage, into the cooler, and then into the second compression stage. 9. The method according to claim 1 , wherein the portion of the effluent from the second dynamic pressure reduction turbine, the upper column flow, the column supply fraction and the upper gas fraction are placed in a heat exchange relationship in the second heat exchanger. 10. The method according to claim 7 , wherein the make-up cooling flow is introduced into the turbine supply fraction. 11. The method according to claim 1 , wherein the cooling and at least partially condensing of the column supply fraction is carried out in the second heat exchanger, the cooling and at least partially condensing the upper gas fraction being carried out in the second heat exchanger. 12. An installation for producing a flow rich in methane and a flow rich in C 2 + hydrocarbons from a supply flow containing hydrocarbons, the installation comprising: a supply flow separator configured to separate the supply flow into a first fraction of the supply flow and at least a second fraction of the supply flow; a first heat exchanger configured to cool the first fraction of the supply flow; a first heat exchange introducer configured to introduce the first fraction of the supply flow into the first heat exchanger; a first separation flask and a first separation flask introducer configured to introduce the cooled first fraction of the supply flow into the first separation flask in order to produce a light upper flow and a heavy lower flow; a light upper flow divider configured to divide the light upper flow into a turbine supply fraction and a column supply fraction; a first distillation column; a turbine supply fraction pressure reducer configured to reduce a pressure of the turbine supply fraction comprising a first dyn