Refrigeration system

The invention claimed is: 1. Refrigeration system comprising a refrigerant circuit through which an overall mass flow of a refrigerant is fed, a heat exchanger which is arranged in the refrigerant circuit for cooling refrigerant at a high pressure side, an expander which is arranged in the refrigerant circuit and cools the overall mass flow of the refrigerant in an active state by expansion and thereby produces a main mass flow consisting of liquid refrigerant and an auxiliary mass flow consisting of gaseous refrigerant which enter an intermediate pressure accumulator and are separated therein into the main mass flow and the auxiliary mass flow, at least one normal refrigerating stage which extracts a normal refrigerating mass flow from the main mass flow in the intermediate pressure accumulator and expands the normal refrigerating mass flow to a low pressure in at least one normal refrigerating expander and heat exchanger and thereby makes a refrigerating capacity available for a normal refrigerating process, a refrigerant compressor unit which compresses the normal refrigerating mass flow from low pressure to high pressure, and a parallel compressor which sucks gaseous refrigerant from the intermediate pressure accumulator in a parallel compression mode of operation of the refrigerant circuit and compresses the normal refrigerating mass flow to high pressure, a power of the parallel compressor is controlled by a controller, in that the controller determines at least one reference variable representing a load state of the refrigerant circuit, the controller determines at least one set intermediate pressure value on a basis of the at least one reference variable in the parallel compression mode of operation, and the controller regulates an intermediate pressure in accordance with the set intermediate pressure value at least in the parallel compressor mode of operation; and wherein a relationship between the reference variable and the set intermediate pressure value changing therewith is determined in such a way that, taken with reference to the efficiency in a case of constant intermediate pressure in the parallel compression mode of operation, there is an increase of an efficiency due to a varying set intermediate pressure value. 2. A refrigeration system in accordance with claim 1 , wherein the controller only takes into consideration reference variables lying within an intermediate-pressure-varying range of reference variables for a determination of the set intermediate pressure value. 3. A refrigeration system in accordance with claim 2 , wherein the intermediate-pressure-varying range of reference variables is a sub-range of a load-dependent range of reference variables. 4. A refrigeration system in accordance with claim 1 , wherein the controller only draws on set intermediate pressure values for a regulation of the intermediate pressure which lie in a range extending from a minimum intermediate pressure up to a maximum intermediate pressure. 5. A refrigeration system in accordance with claim 1 , wherein an increase of a value of the reference variable within an intermediate-pressure-varying range of reference variables leads to an increase of a value of the set intermediate pressure value. 6. A refrigeration system in accordance with claim 1 , wherein there is a linear relationship between a value of the reference variable and the set intermediate pressure value within a range of reference variables. 7. A refrigeration system in accordance with claim 1 , wherein a relationship between a value of the reference variable and the set intermediate pressure value is nonlinear within the intermediate-pressure-varying range of reference variables. 8. A refrigeration system in accordance with claim 1 , wherein the values for the set intermediate pressure value are possible values lying along operating limits of the parallel compressor. 9. A refrigeration system in accordance with claim 1 , wherein value of the high pressure in the refrigerant circuit represents the reference variable. 10. A refrigeration system in accordance with claim 1 , wherein a temperature of the refrigerant when emerging from the high pressure side of the heat exchanger represents the reference variable. 11. A refrigeration system in accordance with claim 1 , wherein a value of an ambient temperature of air cooling the heat exchanger on the high pressure side represents the reference variable. 12. A refrigeration system in accordance with claim 1 , wherein an intermediate-pressure-varying range of reference variables comprises therein a thermodynamically critical reference variable value. 13. A refrigeration system in accordance with claim 1 , wherein an intermediate-pressure-varying range of reference variables lies close to a thermodynamically critical reference variable value. 14. A refrigeration system in accordance with claim 1 , wherein an intermediate-pressure-varying range of reference variables extends from an upper reference variable value to a lower reference variable value. 15. A refrigeration system in accordance with claim 14 , wherein the upper reference variable value coincides with the reference variable at full load. 16. A refrigeration system in accordance with claim 14 , wherein the upper reference variable value lies below the reference variable at full load. 17. A refrigeration system in accordance with claim 14 , wherein the lower reference variable value coincides with a parallel-compression-limiting reference variable value. 18. A refrigeration system in accordance with claim 14 , wherein the lower reference variable value lies above a parallel-compression-limiting reference variable value. 19. A refrigeration system in accordance with claim 1 , wherein the controller switches over from a parallel compression mode of operation to a flashgas/bypass mode of operation if the reference variable falls below a parallel-compression-limiting reference variable value. 20. A refrigeration system in accordance with claim 19 , wherein the controller switches off the parallel compressor in the flashgas/bypass mode of operation. 21. A refrigeration system in accordance with claim 19 , wherein in the flashgas/bypass mode of operation, the controller sets the parallel compressor from low pressure to high pressure for purposes of compressing the refrigerant. 22. A refrigeration system in accordance with claim 1 , wherein in a flashgas/bypass mode of operation, the controller expands the refrigerant from the intermediate pressure accumulator to a lower pressure level by means of the expander and holds the intermediate pressure at a predeterminable value. 23. A refrigeration system in accordance with claim 22 , wherein in the flashgas/bypass mode of operation, the expander expands the refrigerant from the intermediate pressure accumulator to low pressure. 24. Refrigeration system comprising a refrigerant circuit through which an overall mass flow of a refrigerant is fed, a heat exchanger which is arranged in the refrigerant circuit for cooling refrigerant at a high pressure side, an expander which is arranged in the refrigerant circuit and cools the overall mass flow of the refrigerant in an active state by expansion and thereby produces a main mass flow consisting of liquid refrigerant and an auxiliary mass flow consisting of gaseous refrigerant which enter an intermediate pressure accumulator and are separated therein into the main mass flow and the auxiliary mass flow, at least o