Determining fluid density in a pressure pump using bulk modulus measurements

What is claimed is: 1. A system, comprising: a strain gauge positionable on a fluid end of a pressure pump to measure strain in a chamber of the pressure pump and generate a strain signal representing the strain in the chamber; a pulse detection system including one or more pulse generators and one or more pulse detectors, the pulse detection system being positionable on the fluid end of the pressure pump to generate timing signals useable to determine a travel time of a corresponding pulse traversing fluid, wherein the strain signal and the timing signals are useable to determine a density of the fluid. 2. The system of claim 1 , further comprising a computing device communicatively coupled to the strain gauge and the pulse detection system to determine the density of the pressure pump, the computing device including a processing device for which instructions executable by the processing device are useable to cause the processing device to: determine a bulk modulus of the fluid isolated in the chamber of the pressure pump using the strain signal; determine a speed of sound through the fluid using the timing signals; and determine the density of the fluid in the pressure pump by dividing the bulk modulus by a square of the speed of sound. 3. The system of claim 2 , wherein the instructions are executable by the processing device for causing the processing device to determine the bulk modulus of the fluid by: determining actuation points for valves in the chamber by identifying discontinuities in the strain signal, the actuation points including a first point corresponding to a closing time of a first valve in the chamber and a second point corresponding to an opening time of a second valve in the chamber; determining an amount of time between the actuation points; determining a pressure change in internal pressure in the chamber during the amount of time between the actuation points; and determining a fluid volume in the chamber at the first point; and determining a volume change in the fluid volume in the chamber during the amount of time between the actuation points. 4. The system of claim 3 , wherein the instructions are executable by the processing device for causing the processing device to determine the pressure change in the internal pressure by correlating a portion of the strain signal between the actuation points with a predetermined internal pressure in the chamber. 5. The system of claim 3 , wherein the instructions are executable by the processing device for causing the processing device to determine an effective bulk modulus of the fluid using the pressure change in the chamber during the amount of time between the actuation points, the fluid volume in the chamber at the first point, and the volume change in the chamber during the amount of time between the actuation points, and wherein the effective bulk modulus includes the bulk modulus of the fluid and a mechanical bulk modulus of non-fluid components of the pressure pump. 6. The system of claim 3 , further comprising a position sensor positionable on a power end of the pressure pump to sense a position of a rotating member of a rotating assembly of the pressure pump that is mechanically coupled to a displacement member corresponding to the chamber and generate a position signal representing the position of the rotating member during operation of the pressure pump, wherein the instructions are executable by the processing device for causing the processing device to: determine a movement of the displacement member in the chamber by correlating the position of the rotating member with an expression representing a mechanical correlation of the displacement member to the rotating member; and determine the volume change in the fluid volume using a volume of the fluid in the chamber that is displaced by the movement of the displacement member during the amount of time between the actuation points. 7. The system of claim 2 , wherein a pulse generator of the one or more pulse generators is positionable in the fluid end of the pressure pump to generate the corresponding pulse that is detectable by a pulse detector of the one or more pulse detectors subsequent to traversing the fluid, wherein the timing signals include a first timing signal generated by the pulse generator and representing a transmission time that the corresponding pulse was transmitted through the fluid and a second timing signal generated by the pulse detector and representing a detection time that the corresponding pulse was detected by the pulse detector, wherein the instructions are executable by the processing device for causing the processing device to determine a pulse speed of the corresponding pulse by using the timing signals to determine the travel time of the corresponding pulse and dividing a distance between the pulse generator and the pulse detector by the travel time, the pulse speed of the corresponding pulse corresponding to the speed of sound through the fluid. 8. The system of claim 2 , wherein the pulse detection system comprises a first subsystem including a first pulse generator and a first pulse detector and a second subsystem including a second pulse generator and a second pulse detector, the first subsystem being useable to generate first timing signals corresponding to a first pulse traversing the fluid in a first direction, the second subsystem being useable to generate second timing signals corresponding to a second pulse traversing the fluid in an opposing direction, wherein the instructions are executable by the processing device for causing the processing device to determine the speed of sound through the fluid by averaging a first pulse speed corresponding to the first pulse and a second pulse speed corresponding to the second pulse. 9. A pumping system, comprising: a pressure pump including a chamber having a first valve actuatable to a closed position at a first actuation point and a second valve actuatable to an open position at a second actuation point, an amount of time between the first actuation point and the second actuation point being detectable by a strain gauge; and a computing device communicatively couplable to the pressure pump to determine a density of fluid using a bulk modulus measurement of the fluid isolated in the chamber during the amount of time between the first actuation point and the second actuation point and a speed of sound through the fluid, the speed of sound corresponding to a pulse speed that is detectable using a pulse detection system including a pulse generator and a pulse detector positionable in a fluid end of the pressure pump. 10. The pumping system of claim 9 , wherein the computing device comprises a processing device for which instructions executable by the processing device are useable to cause the processing device to determine the first actuation point and the second actuation point by identifying discontinuities in a strain signal received from the strain gauge and representing strain in the chamber. 11. The pumping system of claim 9 , wherein the computing device comprises a processing device for which instructions executable by the processing device are useable to cause the processing device to determine the bulk modulus measurement by: determining a pressure change in internal pressure in the chamber during the amount of time between the first actuation point and the second actuation point; determining a fluid volume in the chamber at the first actuation point; and determining a volume change in the fluid volume in the chamber during the amount of time between the first actuation point and the second actuation point. 12. The pumping system of claim 1