System and method for generation of oxygen by low-temperature air separation

What we claim is: 1. A system for generation of oxygen by low-temperature air separation comprising a high-pressure column and a low-pressure column, a main condenser which is constructed as a condenser-evaporator, wherein a liquefaction space of the main condenser is flow-connected to the top of the high-pressure column and an evaporation space of the main condenser is flow-connected to the low-pressure column, an oxygen product line that is connected to the low-pressure column, an auxiliary column, introducing a gaseous fraction, the oxygen content of which is equal to that of air or higher, into a sump region of the auxiliary column and having a reflux liquid line for introducing a liquid stream from the high-pressure column, the main condenser, or the low-pressure column as reflux to the top of the auxiliary column, wherein the liquid stream has a nitrogen content that is at least equal to that of air, characterized by an argon removal column that is flow-connected to an intermediate site of the low-pressure column, an argon removal column top condenser that is constructed as a condenser-evaporator, wherein a liquefaction space of the argon removal column top condenser is flow-connected to the top of the argon removal column, a crude oxygen line for introducing liquid crude oxygen from a sump of the high-pressure column into an evaporation space of the argon removal column top condenser and wherein the low-pressure column is arranged beside the high-pressure column, the main condenser is arranged over the high-pressure column, the auxiliary column is arranged over the main condenser, the argon removal column is arranged over the auxiliary column and the argon removal column top condenser is arranged over the argon removal column. 2. The system according to claim 1 , characterized by recovering a first gaseous overhead fraction from the auxiliary column as first gaseous nitrogen product. 3. The system according to claim 2 , characterized by recovering a second gaseous overhead fraction from the low-pressure column as a second gaseous nitrogen product. 4. The system according to claim 3 , characterized by separately passing the first and second overhead fractions through a main heat exchanger for warming the first and second overhead fractions against feed air for the high-pressure column. 5. The system according to claim 1 , characterized by introducing gas from the evaporation space of the argon removal column top condenser into the auxiliary column. 6. The system according to claim 1 , characterized in that the introducing a gaseous fraction, the oxygen content of which is equal to that of air or higher, into the auxiliary column includes introducing turbine-expanded air into the auxiliary column. 7. A method or generation of oxygen by low-temperature air separation in a distillation column system that comprises a high-pressure column and a low-pressure column, a main condenser which is constructed as a condenser-evaporator, wherein a liquefaction space of the main condenser is flow-connected to the top of the high-pressure column and an evaporation space of the main condenser is flow-connected to the low-pressure column and an auxiliary column, wherein an oxygen stream is taken off from the low-pressure column and is recovered as oxygen product, a gaseous fraction, the oxygen content of which is equal to that of air or higher, is introduced into a sump region of the auxiliary column, a liquid stream from the high-pressure column, the main condenser or the low-pressure column is applied as reflux to the top of the auxiliary column, wherein the liquid stream has a nitrogen content that is at least equal to that of air, characterized in that an argon-rich stream is introduced from an intermediate site of the low-pressure column into an argon removal column, reflux for the argon removal column is generated in an argon removal column top condenser that is constructed as a condenser-evaporator, wherein a liquefaction space of the argon removal column top condenser is flow-connected to the top of the argon removal column, crude oxygen is introduced from a sump of the high-pressure column into an evaporation space of the argon removal column top condenser, wherein the low-pressure column is arranged beside the high-pressure column, the main condenser is arranged over the high-pressure column, the auxiliary column is arranged over the main condenser, the argon removal column is arranged over the auxiliary column and the argon removal column top condenser is arranged over the argon removal column. 8. The method according to claim 7 , in which a first gaseous overhead fraction is recovered from the auxiliary column as first gaseous nitrogen product. 9. The method according to claim 8 , in which a second gaseous overhead fraction is recovered from the low-pressure column as second gaseous nitrogen product. 10. The method according to claim 9 , in which the first and second overhead fractions are passed separately through a main heat exchanger for warming these fractions against feed air for the high-pressure column. 11. The method according to claim 7 , in which gas from the evaporation space of the argon removal column top condenser is introduced into the auxiliary column. 12. The method according to claim 7 , characterized in that the gaseous fraction, the oxygen content of which is equal to that of air or higher, is formed by turbine-expanded air.