Accurate flow-in measurement by triplex pump and continuous verification

What is claimed is: 1. A method, comprising: determining a first rotational position of a crankshaft in a multiplex pump from one or more sensors disposed on the crankshaft; determining a second rotational position of the crankshaft in the multiplex pump from the one or more sensors disposed on the crankshaft, including a complete turn of the crankshaft; determining a first position of each of a plurality of pistons along a corresponding bore in relation to a total stroke length of each piston and a connecting rod length; determining a second position of each of the plurality of pistons along the corresponding bore in relation to the total stroke length of each piston and the connecting rod length; calculating an individual theoretical volume of fluid contained within each of the bores in the multiplex pump for the corresponding rotational positions of the crankshaft; and summing the individual theoretical volumes to determine a total theoretical pumped volume by the multiplex pump after the crankshaft rotates an angular distance; calibrating the multiplex pump based at least in part on the total theoretical pumped volume and a known value of fluid volume pumped by the multiplex pump; and modifying an operation of the multiplex pump or performing maintenance on the multiplex pump in response to the calibrating. 2. The method of claim 1 , further comprising: calculating individual theoretical instantaneous flow rates of fluid from each of the bores in the multiplex pump based on a derivative value of a pumped volume by each piston versus time; and summing the individual theoretical instantaneous flow rates to determine a total theoretical flow rate from the multiplex pump. 3. The method of claim 1 , further comprising correcting the total theoretical pumped volume by a pump efficiency. 4. The method of claim 1 , further comprising measuring an external leakage of fluid from the pistons in the multiplex pump, wherein the measuring comprises: providing a collection box under the pistons; and measuring a volume of fluid collected in the collection box versus time. 5. A method, comprising: determining a first rotational position of a crankshaft in a multiplex pump from one or more sensors disposed on the crankshaft; determining a second rotational position of the crankshaft in the multiplex pump from the one or more sensors disposed on the crankshaft, including a complete turn of the crankshaft; determining a first position of each of a plurality of pistons along a corresponding bore in relation to a total stroke length of each piston and a connecting rod length; determining a second position of each of the plurality of pistons along the corresponding bore in relation to the total stroke length of each piston and the connecting rod length; calculating an individual theoretical volume of fluid contained within each of the bores in the multiplex pump for the corresponding rotational positions of the crankshaft; summing the individual theoretical volumes to determine a total theoretical pumped volume by the multiplex pump after the crankshaft rotates an angular distance; calibrating the multiplex pump, wherein the calibrating comprises: comparing a known value of fluid volume pumped from a calibration tank to the total theoretical pumped volume by the multiplex pump; and determining a pump efficiency as a ratio between the fluid volume pumped from the calibration tank and total theoretical pumped volume by the multiplex pump. 6. The method of claim 5 , wherein the known value of fluid volume is measured with a Coriolis meter. 7. The method of claim 5 , further comprising: pumping the multiplex pump at different flow rates; and determining a relationship between the pump efficiency and pumping speed. 8. The method of claim 7 , wherein the different flow rates are obtained at a constant discharge pressure. 9. The method of claim 5 , further comprising: pumping the multiplex pump with a discharge pressure set at different values; measuring pressure in a discharge line from the multiplex pump; and determining a set of relationships of the pump efficiency versus the discharge pressure. 10. The method of claim 9 , further comprising: obtaining compressibility of pumped fluid from the multiplex pump; determining dead volume of the chamber and the theoretical displaced volume of fluid per stroke; determining a reduced pumped volume corrected for the compressibility at the discharge pressure; estimating a corrected pumped volume for an incompressible fluid; and determining the pump efficiency of the multiplex pump pumping the incompressible fluid at a defined discharge pressure. 11. The method of claim 10 , wherein the pump efficiency of the multiplex pump pumping the incompressible fluid is defined versus pumping speed and for one or multiple values of the discharge pressure. 12. The method of claim 10 , further comprising: processing pump efficiency data versus a period of the crankshaft rotation for multiple pumping speeds and discharge pressures; selecting a pair of hypothetical leak rate and closing delay for pump efficiency data for a set value discharge pressure; calculating estimated pump efficiencies based on the hypothetical pair of leak rates and closing delays corresponding to a period of the calibration; determining a mean error between the estimated pump efficiencies and the determined pump efficiency from calibration; conducting the calculating estimated pump efficiencies and determining the mean error over a wide range of hypothetical pairs of leak rate and closing delay; selecting the hypothetical pair of leak rate and closing delay that provides a minimum mean error as a best fit to the processed efficiency data versus a period of the crankshaft rotation; and selecting the best fit hypothetical pair of leak rate and closing delay as a current leak rate and closing delay for the multiplex pump operating at the discharge pressure of the calibration. 13. The method of claim 9 , further comprising: determining an effect of leakage on pump efficiency for the different discharge pressures; normalizing the pump efficiency for an incompressible fluid, taking in account fluid compressibility of fluid pumped by the multiplex pump; determining a relationship of a leak rate versus discharge pressure; and fitting the relationship of the leak rate as a linear function or a square root function of the discharge pressure. 14. The method of claim 13 , wherein the fitting depends either on fluid viscosity when the relationship fits best with the linear function, or on fluid density when the relationship fits best with the square root function. 15. The method of claim 14 , wherein an estimated pump efficiency is corrected for at least one of fluid compressibility, fluid density, and fluid viscosity during a pumping sequence following a calibration period. 16. The method of claim 15 , further comprising: performing calibration sequences during pumping; obtaining from a rig information system data comprising the fluid compressibility, the fluid density or the fluid viscosity; determining an estimated normalized efficiency for the data of the short calibration sequences; determining if the estimated normalized efficiency data obtained by the short calibration sequences matches normalized efficiency data obtained during a complete calibration sequence; and determining from the normalized efficiency data of the complete calibration sequence if a new complete calibration sequence is to be re-acquired. 17. The method of claim 5