System and method for determining bottomhole conditions during flowback operations of a shale reservoir

What is claimed is: 1. A method of determining at least one bottomhole condition in a well, the method comprising: measuring fluid properties, via one or more sensors, of fluids produced at a surface-location of the well, wherein the well traverses a hydraulically fractured reservoir, wherein the measured fluid properties include flow rates of different fluid phases that are part of the fluids, and wherein the different fluid phases are selected from the group including an oil phase, a gas phase, a water phase, and a solid phase; using a transient fluid flow simulator to determine composition and properties of the fluids in the well between a surface-location of the well and at least one bottomhole-location of the well based on the measured fluid properties and based on calculations involving data characterizing mineralogy of the hydraulically fractured reservoir; calculating at least one bottomhole condition in the well based on the determined composition and properties of the fluids in the well between the surface-location and the at least one bottomhole-location of the well; and controlling a flowback operation in the well based at least in part on the at least one bottomhole condition; wherein controlling the flowback operation in the well further comprises: calculating a drawdown pressure in the well at a particular time, wherein the drawdown pressure in the well is a function of a rate of a bottomhole pressure change and a bottomhole fluid rate; determining when the calculated drawdown pressure is outside a particular safe zone defined by upper and lower limits on drawdown pressure as a function of time; and adjusting a surface-located choke in response to determining the calculated drawdown pressure is outside the particular safe zone. 2. The method according to claim 1 , wherein: the measured fluid properties include pressure before or at the surface-located choke. 3. The method according to claim 2 , wherein: the surface-located choke includes a variable sized aperture, and the measured fluid properties include pressure downstream of the variable sized aperture of the surface-located choke. 4. The method according to claim 2 , wherein: the surface-located choke includes a variable sized aperture, and the measured fluid properties include pressure upstream of the variable sized aperture of the surface-located choke. 5. The method according to claim 1 , wherein: the transient fluid flow simulator determines the composition and properties of the fluids in the well between the surface-location of the well and the at least one bottomhole-location of the well based further on calculations involving a set point or other predefined parameter. 6. The method according to claim 1 , wherein: the transient fluid flow simulator determines the composition and properties of the fluids in the well between the surface-location of the well and the at least one bottomhole-location of the well based further on calculations involving data from at least one other well. 7. The method according to claim 1 , wherein: the transient fluid flow simulator determines the composition and properties of the fluids in the well between the surface-location of the well and the at least one bottomhole-location of the well based further on calculations involving data derived during drilling the well. 8. The method according to claim 1 , wherein: the at least one bottomhole condition includes pressure in the well at at least one bottomhole location of the well. 9. The method according to claim 1 , wherein: the transient fluid flow simulator determines the composition and properties of the fluids in the well between the surface-location of the well and the at least one bottomhole location of the well for a first period of time based on the measured fluid properties measured over a second period of time that precedes the first period of time. 10. The method according to claim 9 , wherein: the transient fluid flow simulator determines the composition and properties of the fluids in the well for the first period of time based on an extrapolation of the measured fluid properties during the second period of time. 11. The method according to claim 1 , further comprising: using a plurality of transient fluid flow simulators to individually determine the composition and properties of the fluids in the well between the surface-location of the well and at least one bottomhole-location of the well based on the measured fluid properties; comparing the measured fluid properties, respectively, with sets of properties determined by each of the transient fluid flow simulators; and selecting at least one of the transient fluid flow simulators based on the comparing, wherein the at least one bottomhole condition in the well is calculated based on the determination of the composition and properties of the fluids in the well determined by the selected at least one of the transient fluid flow simulators, wherein the plurality of transient fluid flow simulators reflect different flowback scenarios. 12. The method according to claim 1 , wherein: the fluid properties of the fluids produced at a surface-location of the well are measured in real-time; the transient fluid flow simulator determines in real-time the composition and properties of the fluids in the well between the surface-location of the well and at least one bottomhole-location of the well based on the real-time measurement of the fluid properties; and the at least one bottomhole condition in the well is calculated in real-time based on the real-time determination of the composition and properties of the fluids in the well, wherein the transient fluid flow simulator is updated in real-time such that determined properties of the fluids at the surface-location in the well matches the measured fluid properties at the surface-location in the well. 13. The method according to claim 1 , wherein: calculating the at least one bottomhole condition in the well includes calculating multiple estimates of bottomhole pressure and a statistical distribution of the bottomhole pressure. 14. The method according to claim 1 , wherein: adjusting the surface-located choke comprises closing the surface-located choke when the calculated drawdown pressure is above the particular safe zone or opening the surface-located choke when the calculated drawdown pressure is below the particular safe zone. 15. A method of determining fracture properties in a hydraulically fractured reservoir, the method comprising: measuring fluid properties, via one or more sensors, of fluids produced at a surface-location of a well that traverses the hydraulically fractured reservoir, wherein the measured fluid properties include flow rates of different fluid phases that are part of the fluids, and wherein the different fluid phases are selected from the group including an oil phase, a gas phase, a water phase, and a solid phase; using a transient fluid flow simulator to determine at least one fracture property at at least one bottomhole location of the well over time based on the measured fluid properties, wherein the at least one fracture property characterizes fracture conductivity of a fracture in a near-wellbore region adjacent the well; and controlling a flowback operation in the well based at least in part on the at least one fracture property; wherein controlling the flowback operation in the well further comprises: calculating a drawdown pressure in the well at a particular time, wherein the drawdown pressure in the well is a function of a rate of a bottomhole pressure change and a bottomhole fluid rate; deter