Hydraulic fracturing with modulating injection flow rate

What is claimed is: 1 . A system for hydraulic fracturing with a modulating flow rate, comprising: a first electric pump system electrically coupled to a power supply and fluidly coupled to one or more first wellbores; a second electric pump system electrically coupled to the power supply and fluidly coupled to one or more second wellbores; and a controller configured to control the first electric pump system to increase a flow rate of the first electric pump system and concurrently control the second electric pump system to decrease a flow rate of the second electric pump system such that a combined rate of change of electric power demand of the first electric pump system and the second electric pump system is less than a stiffness of the power supply. 2 . The system of claim 1 , wherein a rate of change of electric power demand of the first electric pump system individually exceeds the stiffness of the power supply, and a rate of change of electric power demand of the second electric pump system individually exceeds the stiffness of the power supply. 3 . The system of claim 1 , wherein the increase in the flow rate of the first electric pump system is part of a flow rate oscillation executed by the first electric pump system, and the decrease in the flow rate of the second electric pump system is part of a flow rate oscillation executed by the second electric pump system. 4 . The system of claim 1 , wherein the first electric pump system comprises a first group of electric pumps fluidly coupled to a first wellbore of the one or more first wellbores and a second group of electric pumps fluidly coupled to a second wellbore of the one or more first wellbores, and the second electric pump system comprises a third group of electric pumps fluidly coupled to a third wellbore of the one or more second wellbores. 5 . The system of claim 1 , wherein the first electric pump system comprises a first group of electric pumps fluidly coupled to a first wellbore of the one or more first wellbores and a second group of electric pumps fluidly coupled to a second wellbore of the one or more first wellbores, and the second electric pump system comprises a third group of electric pumps fluidly coupled to a third wellbore of the one or more second wellbores and a fourth group of electric pumps fluidly coupled to a fourth wellbore of the one or more second wellbores. 6 . The system of claim 1 , wherein the first electric pump system and the second electric pump system are fluidly coupled to a common fluid supply. 7 . The system of claim 6 , wherein a rate of change of the flow rate of the first electric pump system and a rate of change of the flow rate of the second electric pump system combined is less than a stiffness of the fluid supply. 8 . A system for hydraulic fracturing with an oscillating flow rate, comprising: a first electric pump system electrically coupled to a power supply and fluidly coupled to one or more first wellbores; a second electric pump system electrically coupled to the power supply and fluidly coupled to one or more second wellbores; and a controller configured to control the first electric pump system to oscillate a flow rate of the first electric pump system and control the second electric pump system to oscillate a flow rate of the second electric pump system such that there is a phase shift between the oscillation of the flow rate of the first electric pump system and the oscillation of the flow rate of the second electric pump system. 9 . The system of claim 8 , wherein the phase shift prevents a combined rate of change of power demand of the first electric pump system and the second electric pump system from exceeding a stiffness of the power supply. 10 . The system of claim 9 , wherein a maximum rate of change of power demand of the first electric pump system during the oscillation of the flow rate of the first electric pump system individually exceeds the stiffness of the power supply, and a maximum rate of change of power demand of the second electric pump system during the oscillation of the flow rate of the second electric pump system individually exceeds the stiffness of the power supply. 11 . The system of claim 8 , wherein the first electric pump system comprises a first group of electric pumps fluidly coupled to a first wellbore of the one or more first wellbores and a second group of electric pumps fluidly coupled to a second wellbore of the one or more first wellbores, and the second electric pump system comprises a third group of electric pumps fluidly coupled to a third wellbore of the one or more second wellbores. 12 . The system of claim 8 , wherein the first electric pump system and the second electric pump system are fluidly coupled to a common fluid supply. 13 . The system of claim 12 , wherein the phase shift prevents a rate of change of flow rate of the first electric pump system and a rate of change of flow rate of the second electric pump system combined from exceeding a stiffness of the fluid supply. 14 . A system for sending pulses into wellbores, comprising: a first electric pump system electrically coupled to a power supply and fluidly coupled to one or more first wellbores; a second electric pump system electrically coupled to the power supply and fluidly coupled to one or more second wellbores; and a controller configured to control the first electric pump system to execute a first positive pulse and control the second electric pump system to execute a first negative pulse concurrently with the first positive pulse. 15 . The system of claim 14 , wherein the controller is further configured to control the first electric pump system to execute a second negative pulse, and control the second electric pump system to execute a second positive pulse concurrently with the second negative pulse. 16 . The system of claim 15 , wherein a rate of change of power demand of the first electric pump system and a rate of change of power demand of the second electric pump system combined remains less than a stiffness of the power supply during the first positive pulse, the first negative pulse, the second positive pulse, and the second negative pulse. 17 . The system of claim 14 , wherein the first electric pump system and the second electric pump system are fluidly coupled to a common fluid supply. 18 . The system of claim 17 , wherein a maximum rate of change of flow rate of the first electric pump system during the first positive pulse and a maximum rate of change of flow rate of the second electric pump system during the first negative pulse combined is less than a stiffness of the fluid supply. 19 . The system of claim 18 , wherein the maximum rate of change of the flow rate of the first electric pump system during the first positive pulse is individually greater than the stiffness of the fluid supply, and the maximum rate of change of the flow rate of the second electric pump system during the first negative pulse is individually greater than the stiffness of the fluid supply. 20 . The system of claim 14 , wherein the first electric pump system comprises a first group of electric pumps fluidly coupled to a first wellbore of the one or more first wellbores and a second group of electric pumps fluidly coupled to a second wellbore of the one or more first wellbores, and the second electric pump system comprises a third group of electric pumps fluidly coupled to a third wellbore of the one or more second wellbores.