Refrigerant compressor

The invention claimed is: 1 . A refrigerant compressor for refrigeration systems, comprising an electric motor, at least two cylinder banks, each of which has at least one cylinder unit having in each case at least one cylinder housing and at least one reciprocating-movement piston driven by the electric motor, and a cylinder head that is associated with each cylinder bank and has an inlet chamber, through which an inlet stream flows, and an outlet chamber, through which an outlet stream flows, and a mechanical performance control unit for activating and deactivating at least one of the cylinder banks in order to activate or deactivate its refrigerant output, wherein, for the purpose of operation in a primary partial performance condition, the refrigerant compressor is operable in at least two different operating modes, of which each provides an activation or deactivation of the cylinder banks that is different from another of the at least two different operating modes, wherein associated with the refrigerant compressor is a frequency converter for controlling the speed of the electric motor, wherein associated with the refrigerant compressor is an operating condition controller that, in accordance with a performance request signal supplied to it for operation of the refrigerant compressor in the primary partial performance condition corresponding to this performance request signal, operates the refrigerant compressor in the operating mode that is selected from the at least two different operating modes and at a speed of the electric motor adapted to the selected operating mode, for the purpose of achieving the primary partial performance condition; wherein, in order to determine the quality grade or COP value of the at least two different operating modes, partial performance conditions, including the primary partial performance condition, to be achieved are divided into partial performance conditions that are above a boundary value and those below a boundary value, and wherein, in the case of the partial performance conditions above the boundary value in any of the at least two different operating modes that requires a higher speed of the electric motor than other operating modes, the assumption is made of a high quality grade or COP value or a low electrical power consumption, and thus these operating modes are selected, and in the case of the partial performance conditions below the boundary value in any of the at least two different operating modes that require a lower speed of the electric motor than the other operating modes, the assumption is made of a high quality grade or COP value or a low electrical power consumption and thus these operating modes are selected. 2 . The refrigerant compressor according to claim 1 , wherein the operating condition controller operates the refrigerant compressor in a first operating mode of the at least two different operating modes, with activation of all the cylinder banks and with adaptation of the speed of the electric motor to the first operating mode. 3 . The refrigerant compressor according to claim 1 , wherein the operating condition controller operates the refrigerant compressor in at least one further operating mode of the at least two different operating modes, with deactivation of at least one of the cylinder banks and with activation of at least one of the cylinder banks and with adaptation of the speed of the electric motor to the at least one further operating mode. 4 . The refrigerant compressor according to claim 1 , wherein, in the case of partial performance conditions, including the primary partial performance condition, that are achievable by a plurality of the at least two different operating modes, the operating condition controller selects the one of the plurality of the at least two different operating modes that results in the highest quality grade or Coefficient of Performance (COP) value or the lowest electrical power consumption of the electric motor in the partial performance condition. 5 . The refrigerant compressor according to claim 4 , wherein the operating condition controller determines, for the at least two different operating modes that are, in each case, possible for achieving the partial performance condition, the quality grade or the COP value or the electrical power consumption of the electric motor, and selects the operating mode by comparing the determined quality grades or COP values or electrical power consumption. 6 . The refrigerant compressor according to claim 4 , wherein the operating condition controller has stored data for the purpose of determining the quality grade or COP value or electrical power consumption for each of the at least two different operating modes. 7 . The refrigerant compressor according to claim 4 , wherein the quality grade or COP value or electrical power consumption is determined by the operating condition controller by the detection of at least one of a suction pressure and a high pressure at the refrigerant compressor. 8 . The refrigerant compressor according to claim 4 , wherein the operating condition controller makes use of at least one of a refrigerant, the partial performance condition, the electrical power consumption and the speed of the electric motor in order to determine the quality grade or COP value. 9 . The refrigerant compressor according claim 1 , wherein, in the case that one of the at least two different operating modes is a first type of operating mode, the operating condition controller permanently maintains the first type of operating mode with a deactivation and activation of the cylinder banks in order to achieve the partial performance condition that is required by the performance request signal. 10 . The refrigerant compressor according to claim 1 , wherein, in case that the at least two different operating modes is a second type of operating mode, the operating condition controller operates the refrigerant compressor by clocked deactivation and activation of at least one of the at least two cylinder banks at defined switching intervals, wherein, in this operating mode, the proportion of time for which at least one of the cylinder banks is deactivated and activated at the switching intervals is constant when the partial performance condition that is required by the performance request signal is achieved. 11 . The refrigerant compressor according to claim 1 , wherein activation and deactivation of each cylinder bank is performed with the aid of the mechanical performance control unit that is controlled by the operating condition controller. 12 . The refrigerant compressor according to claim 11 , wherein the mechanical performance control unit is associated with a cylinder head of the cylinder bank. 13 . The refrigerant compressor according to claim 11 , wherein the mechanical performance control unit controls an inlet stream into the inlet chamber of the cylinder head for the purpose of activating or deactivating the respective cylinder bank. 14 . The refrigerant compressor according to claim 1 , wherein the performance control unit connects the outlet chamber to the inlet chamber in the cylinder head for the purpose of activating or deactivating the respective cylinder bank. 15 . The refrigerant compressor according to claim 1 , wherein the operating condition controller is an operating condition controller that is separate from the frequency converter. 16 . The refrigerant compressor according to claim 1 , wherein the operating condition controller is arranged in a housing that receives the frequency converter. 17 . The refriger