Device and method for operating parallel centrifugal pumps

What is claimed is: 1. Apparatus comprising: multiple centrifugal pumps, wherein the centrifugal pumps are of a same type and size and are to be operated at a same speed: a device for operating the centrifugal pumps, the device comprising: a communication interface for receiving at least one input information on a state of operation of the centrifugal pumps and for transmitting at least one output information to at least one driving unit of the centrifugal pumps, wherein the at least one output information reflects a reference value for a number of the centrifugal pumps to be operated in parallel and wherein the communication interface is arranged to receive as input information: (i) an instantaneous pressure drop (H_i) across the centrifugal pumps which are to be currently operated in parallel and (ii) an instantaneous flow rate per pump (Q_i) or speed (n_i) of the centrifugal pumps which are to be currently operated in parallel: a data storage unit for storing as additional information: an actual number (m_a) of currently operated centrifugal pumps, a rated speed (n_r) of the centrifugal pumps, an efficiency characteristic versus flow rate at the rated speed (n_r), and a pump performance characteristic at the rated speed (n_r) of the centrifugal pumps; and a processor for generating the at least one output information from the at least one input information and the additional information, the processor being configured (i) to determine from the at least one input information and the additional information an instantaneous efficiency (E_i) if a first expected efficiency (E_1) where the actual number (m_a) is reduced by one, and a second expected efficiency (E_e2) where the actual number (m_a) is increased by one, (ii) to generate a reference value (m) depending on which of the instantaneous efficiency (E_i) if the first expected efficiency (E_e1), and the second expected efficiency (E_e2) has a highest value, and (iii) to determine from the input information and the additional information, a scaled instantaneous flow rate per pump (Q_s1), a scaled first expected flow rate per pump (Q_s1) and a scaled second expected flow rate per pump (Q_s2), where the scaling is performed using the rated speed (n r) for the centrifugal pumps while keeping efficiency at a same level as the instantaneous efficiency (E_i), the first expected efficiency (E_i1), and the second expected efficiency (E_i2), respectively, from the efficiency characteristic versus flow rate, wherein the multiple centrifugal pumps are configured to be operated in response to the at least one output information. 2. The apparatus according to claim 1 , wherein the processor is configured to determine the scaled first expected flow rate per pump (Q_s1) and the scaled second expected flow rate per pump (Q_s2), respectively, by finding a crossing point between the pump performance characteristic and a first affinity law for a fixed impeller diameter of centrifugal pumps to be operated, where the centrifugal pumps are operated at rated speed (n_r), the pressure drop is kept constant at the instantaneous pressure drop (H_i), and the flow rate per pump is increased or decreased linearly from the level of the instantaneous flow rate per pump (Q_i) by decreasing or increasing the actual number (m_a) by one, respectively, thereby resulting in a first (Q_i1) or second (Q_i2) expected instantaneous flow rate per pump, respectively, and wherein the first affinity law is: H =( Q/Q _ i )^2· H _ i. 3. The apparatus according to claim 2 , wherein the processor is configured to determine the first and second expected instantaneous flow rates per pump (Q_i1, Q_i2) by multiplying the instantaneous flow rate per pump (Q_i) with the actual number (m_a) divided by the actual number reduced by one (m_a−1) or by the actual number increased by one (m_a+1), respectively, and, in a case that no instantaneous flow rate per pump (Q_i) is available, to determine the instantaneous flow rate per pump (Q_i) from the instantaneous pressure drop (H_i), the instantaneous speed (n_i) and the rated speed (n_r) by applying a second affinity law and a third affinity law for a fixed impeller diameter of the centrifugal pumps to be operated and the pump performance characteristic, wherein the second affinity law is: H _ si =( n _ r/n _ i )^2* Hi and the third affinity law is: Q _1= n _ i/n _ r*Q _ si. 4. The apparatus according to claim 3 , wherein the processor is configured to determine the instantaneous flow rate per pump (Q_i) by determining: firstly a rated instantaneous pressure drop (H_si) from the second affinity law applied to the instantaneous pressure drop (H_i); secondly the scaled instantaneous flow rate per pump (Q_si) from the pump performance characteristic at the scaled instantaneous pressure drop (H_si); and thirdly the instantaneous flow rate per pump (Q_i) from the third affinity law applied to the scaled instantaneous flow rate per pump (Q_si). 5. The apparatus according to claim 2 , wherein the processor is configured to determine the scaled instantaneous flow rate per pump (Q_si) by finding a crossing point between the pump performance characteristic and the first affinity law for a fixed impeller diameter of the centrifugal pumps where the centrifugal pumps are operated at rated speed (n_r) and where the first affinity law is applied to the instantaneous pressure drop (H_i) and the instantaneous flow rate per pump (Q_i). 6. The apparatus according to claim 2 , wherein the processor is configured to determine the scaled instantaneous flow rate per pump (Q_si) by finding a crossing point between the pump performance characteristic and the first affinity law for a fixed impeller diameter of the centrifugal pumps where the centrifugal pumps are operated at rated speed (n_r) and where the first affinity law is applied to the instantaneous pressure drop (H_i) and the instantaneous flow rate per pump (Q_i). 7. The apparatus according to claim 1 , wherein the processor is configured to determine an updated reference value (m_u) for the number of centrifugal pumps to be operated in parallel after having successfully changed the number of centrifugal pumps operated in parallel to the reference value (m). 8. The apparatus according to claim 1 , wherein the processor is configured to check whether at least one of the first and/or second expected instantaneous flow rates per pump (Q_i1, Q_i2) is outside of a minimum or a maximum threshold (Qmin, Qmax) and, if so, to not take the corresponding expected efficiency (E_e1, E_e2) into account when generating the reference value (m). 9. The apparatus according to claim 1 , wherein the processor is configured to determine which of the centrifugal pumps has a lowest number of operating hours and, in case that the reference value (m) indicates that the actual number is to be increased by one, to generate as output information, an activation information for this particular centrifugal pump. 10. A method for operating multiple centrifugal pumps, the method comprising: receiving as input information (i) an instantaneous pressure drop (H_i) across the centrifugal pumps currently operated in parallel and (ii) an instantaneous flow rate per pump (Q_i) or speed (n_i) of the centrifugal pumps currently operated in parallel, wherein the centrifugal pumps are of a same type and size; determining, using the instantaneous pressure drop (H_i): the instantaneous flow rate per pump or the instantaneous speed (Q_i, n_i); an actual number (m_a) of currently operated centrifugal pumps and a rated speed (n_r) of the centrifugal pumps; and an instantaneous efficiency (E_i), a first expected efficiency (E_e1) where the actual number (m_a) is reduced