Patent Publication Number: US-11377942-B2

Title: Wellbore hydraulic fracturing through a pump operating in a damage avoidance mode

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application claims priority to U.S. Provisional Patent Application No. 62/873,716, filed on Jul. 12, 2019, entitled “MULTIPLE WELLBORE HYDRAULIC FRACTURING THROUGH A SINGLE PUMPING SYSTEM,” the content of which is incorporated herein by reference in its entirety. 
    
    
     TECHNICAL FIELD 
     The present technology pertains to pumping a wellbore during a hydraulic fracturing job through a pump operating in a damage avoidance mode, and more particularly, to pumping multiple wellbores for conducting the fracturing job using a pump operating in a damage avoidance mode. 
     BACKGROUND 
     Operators at a fracturing job typically pump at the highest rate possible in order to complete the fracturing job faster. For example, operators typically pump at a rate of 90 bpm or more. This is problematic as pumping either or both fracturing fluid and solid particles at these high rates directly leads to pump erosion and fatigue. Specifically, pumping at high rates increases friction pressure in the wellbore caused by drag of the fracturing fluid and the solid particles passing through the wellbore. Friction pressure can include the amount of pressure of a fluid stream that is lost due to drag as the fluid stream passes through the wellbore. As friction pressure in the wellbore increases, the pump has to impart more power on the fluid stream in order to pump the fluid stream through the wellbore at a specific rate. In turn, this can lead to erosion of the pump, e.g. applicable components of the pump, and connections between the pump and the wellbore. Additionally, this can increase fatigue/fatigue cycle loading on the pump. Therefore, in pumping at higher rates current operators at fracturing jobs are actually damaging pumping equipment and wellbore connections through erosion and fatigue. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       In order to describe the manner in which the features and advantages of this disclosure can be obtained, a more particular description is provided with reference to specific embodiments thereof which are illustrated in the appended drawings. Understanding that these drawings depict only exemplary embodiments of the disclosure and are not therefore to be considered to be limiting of its scope, the principles herein are described and explained with additional specificity and detail through the use of the accompanying drawings in which: 
         FIG. 1  is a schematic diagram of an example fracturing system, in accordance with various aspects of the subject technology; 
         FIG. 2  shows a well during a fracturing operation in a portion of a subterranean formation of interest surrounding a wellbore, in accordance with various aspects of the subject technology; 
         FIG. 3  shows a portion of a wellbore that is fractured using multiple fracture stages, in accordance with various aspects of the subject technology; 
         FIG. 4  shows an example fracturing system for concurrently performing fracturing stages in multiple wellbores, in accordance with various aspects of the subject technology; and 
         FIG. 5  illustrates an example computing device architecture which can be employed to perform various steps, methods, and techniques disclosed herein. 
     
    
    
     DETAILED DESCRIPTION 
     Various embodiments of the disclosure are discussed in detail below. While specific implementations are discussed, it should be understood that this is done for illustration purposes only. A person skilled in the relevant art will recognize that other components and configurations may be used without parting from the spirit and scope of the disclosure. 
     Additional features and advantages of the disclosure will be set forth in the description which follows, and in part will be obvious from the description, or can be learned by practice of the principles disclosed herein. The features and advantages of the disclosure can be realized and obtained by means of the instruments and combinations particularly pointed out in the appended claims. These and other features of the disclosure will become more fully apparent from the following description and appended claims or can be learned by the practice of the principles set forth herein. 
     It will be appreciated that for simplicity and clarity of illustration, where appropriate, reference numerals have been repeated among the different figures to indicate corresponding or analogous elements. In addition, numerous specific details are set forth in order to provide a thorough understanding of the embodiments described herein. However, it will be understood by those of ordinary skill in the art that the embodiments described herein can be practiced without these specific details. In other instances, methods, procedures, and components have not been described in detail so as not to obscure the related relevant feature being described. The drawings are not necessarily to scale and the proportions of certain parts may be exaggerated to better illustrate details and features. The description is not to be considered as limiting the scope of the embodiments described herein. 
     Subterranean hydraulic fracturing is conducted to increase or “stimulate” production from a hydrocarbon well. To conduct a fracturing process, pressure is used to pump special fracturing fluids, including some that contain propping agents (“proppants”), down-hole and into a hydrocarbon formation to split or “fracture” the rock formation along veins or planes extending from the well-bore. Once the desired fracture is formed, the fluid flow is reversed and the liquid portion of the fracturing fluid is removed. The proppants are intentionally left behind to stop the fracture from closing onto itself due to the weight and stresses within the formation. The proppants thus literally “prop-apart”, or support the fracture to stay open, yet remain highly permeable to hydrocarbon fluid flow since they form a packed bed of particles with interstitial void space connectivity. Sand is one example of a commonly-used proppant. The newly-created-and-propped fracture or fractures can thus serve as new formation drainage area and new flow conduits from the formation to the well, providing for an increased fluid flow rate, and hence increased production of hydrocarbons. 
     To begin a fracturing process, at least one perforation is made at a particular down-hole location through the well into a subterranean formation, e.g. through a wall of the well casing, to provide access to the formation for the fracturing fluid. The direction of the perforation attempts to determine at least the initial direction of the fracture. 
     A first “mini-fracture” test can be conducted in which a relatively small amount of proppant-free fracturing fluid is pumped into the formation to determine and/or confirm at least some of the properties of the formation, such as the permeability of the formation itself. Accurately knowing the permeability allows for a prediction of the fluid leak-off rate at various pressures, whereby the amount of fracturing fluid that will flow into the formation can be considered in establishing a pumping and proppant schedule. Thus, the total amount of fluid to be pumped down-hole is at least the sum of the hold-up of the well, the amount of fluid that fills the fracture, and the amount of fluid that leaks-off into the formation during the fracturing process itself. Leak-off rate is an important parameter because once proppant-laden fluid is pumped into the fracture, leak-off can increase the concentration of the proppant in the fracturing fluid beyond a target level. Data from the mini-fracture test then is usually used by experts to confirm or modify the original desired target profile of the fracture and the completion process used to achieve the fracture. 
     Fracturing then begins in earnest by first pumping proppant-free fluid into the wellbore or through tubing. The fracture is initiated and begins to grow in height, length, and/or width. This first proppant-free stage is usually called the “pre-pad” and consists of a low viscosity fluid. A second fluid pumping stage is usually then conducted of a different viscosity proppant-free fluid called the “pad.” At a particular time in the pumping process, the proppant is then added to a fracturing and propping flow stream using a continuous blending process, and is usually gradually stepped-up in proppant concentration. The resultant fractures are then filled with proppant to stabilize the fractures. 
     This process can be repeated in a plurality of fracturing stages to form a plurality of fractures through a wellbore, e.g. as part of a well completion phase. In particular and as will be discussed in greater detail later, this process can be repeatedly performed through a plug-and-perf technique to form the fractures throughout a subterranean formation. After the fractures are formed, resources, e.g. hydrocarbons, can be extracted from the fractures during a well production phase. 
     There are a number of variables that can be accounted for in designing and performing a hydraulic fracturing process, e.g. for well completion. However, current operators have overly simplified fracturing processes. Specifically, current fracturing processes are designed and performed without accounting for a large number of the different variables of the hydraulic fracturing process. For example, the trend amongst current operators includes pumping more fracturing fluid and more proppant at higher pumping rates in order to complete a fracturing stage as fast possible. Further, the trend amongst current operators includes increasing the number of perforations formed and pumped through during a fracturing stage in order to increase the number of fractures formed and stabilized during the fracturing stage. The driving force behind these trends is to decrease the amount of time it takes current operators to perform a fracturing job, thereby potentially increasing profitability for the operators. Further these trends do not account for other parameters associated with the hydraulic fracturing process that can actually be used to improve capital efficiency in hydraulic fracturing jobs. 
     It makes logical sense that if a fracturing stage can be completed faster with a higher fracture yield per fracture stage, then an overall fracturing job can be performed faster. However, pumping more fracturing fluid and more proppant at higher rates to more perforations can actually increase the time needed to complete a fracture stage, thereby decreasing overall capital efficiency. Specifically, pumping more fracturing fluid and more proppant at higher rates to a larger number of perforations can lead to premature “screen outs.” A screen out can occur when the solid concentration within a fracture becomes so high that the pumping pressure exceeds the design limits of the system. In essence, the proppant plugs the fracture and stops the fracturing process. In other situations, a screen out can occur when the proppant collects at an obstruction or within a fracture that is too narrow, resulting in a screen out as well. As a result of screen outs, the fracturing process must sometimes be stopped because in many situations, continuing pumping will damage surface equipment or the well casing itself, e.g. rupturing the well casing. Further, this can lead to expensive and time consuming wellbore clean outs, e.g. by coil tubing deployed at the fracturing site. As follows, the fracturing process is actually slowed down leading to slower fracturing jobs. 
     Further, pumping more fluid and more proppant at higher rates can also increase operational costs associated with a fracturing, thereby decreasing overall capital efficiency. In turn, any profit gained by potentially performing the fracturing job faster can actually be negated. Specifically, pumping more fluid and more proppant at higher pumping rates can actually damage pumps and other equipment. This necessitates costly repairs and equipment replacement, in addition to increasing the amount of actual lost time for repairing and replacing the pumps. Specifically, pumping fluid and proppant at higher pumping rates can increase friction pressure within a well. This increased friction pressure can increase fatigue and erosion in pumps and other applicable components used in the fracturing process. As follows, the pumps and the equipment fail faster, thereby increasing operation costs for performing a fracturing job. 
     The disclosed technology addresses the foregoing by pumping one or more wellbores during a fracturing stage through a pump operating in a damage avoidance mode. 
     In various embodiments, a method for conducting a hydraulic fracturing job in a subterranean formation using a pump can include selecting a fluid pump of known operating pump capacity, wherein the operating pump capacity is measureable in barrels per minute. The method can also include fluidly connecting the pump with a cased wellbore in a subterranean formation for providing pumped fracturing fluid to the wellbore. The wellbore can have at least one perforation through a casing of the wellbore and each perforation has a known rate range within which fracturing fluid is required to be provided to the perforation to successfully fracture the subterranean formation outside the perforation through the perforation. The wellbore that is fluidly connected to the pump can be configured so that the pump provides fracturing fluid to each perforation within the known rate range of the respective perforation to successfully fracture the subterranean formation outside the perforation while operating the pump in a damage avoidance mode. 
     In various embodiments, a method for conducting a hydraulic fracturing job in a subterranean formation using a pump can include selecting a fluid pump of known operating pump capacity, wherein the operating pump capacity is measureable in barrels per minute. The method can also include fluidly connecting the pump with a cased wellbore in a subterranean formation for providing pumped fracturing fluid to the wellbore. The wellbore can have at least one passage through a casing of the wellbore and each passage has a known rate range within which fracturing fluid is required to be provided to the passage to successfully fracture the subterranean formation outside the passage through the passage. The wellbore that is fluidly connected to the pump can be configured so that the pump provides fracturing fluid to each passage within the known rate range of the respective passage to successfully fracture the subterranean formation outside the passage while operating the pump in a damage avoidance mode. 
     In various embodiments, a system for conducting a hydraulic fracturing job in a subterranean formation using a pump can include a fluid pump of known operating pump capacity, wherein the operating pump capacity is measureable in barrels per minute. The system can also include one or more fluid coupling that fluidly connect the pump with a cased wellbore in a subterranean formation for providing pumped fracturing fluid to the wellbore. The wellbore can have at least one perforation through a casing of the wellbore and each perforation has a known rate range within which fracturing fluid is required to be provided to the perforation to successfully fracture the subterranean formation outside the perforation through the perforation. The wellbore that is fluidly connected to the pump can be configured so that the pump provides fracturing fluid to each perforation within the known rate range of the respective perforation to successfully fracture the subterranean formation outside the perforation while operating the pump in a damage avoidance mode. 
     Turning now to  FIG. 1 , an example fracturing system  10  is shown. The example fracturing system  10  shown in  FIG. 1  can be implemented using the systems, methods, and techniques described herein. In particular, the disclosed system, methods, and techniques may directly or indirectly affect one or more components or pieces of equipment associated with the example fracturing system  10 , according to one or more embodiments. The fracturing system  10  includes a fracturing fluid producing apparatus  20 , a fluid source  30 , a solid source  40 , and a pump and blender system  50 . All or an applicable combination of these components of the fracturing system  10  can reside at the surface at a well site/fracturing pad where a well  60  is located. 
     During a fracturing job, the fracturing fluid producing apparatus  20  can access the fluid source  30  for introducing/controlling flow of a fluid, e.g. a fracturing fluid, in the fracturing system  10 . While only a single fluid source  30  is shown, the fluid source  30  can include a plurality of separate fluid sources. Further, the fracturing fluid producing apparatus  20  can be omitted from the fracturing system  10 . In turn, the fracturing fluid can be sourced directly from the fluid source  30  during a fracturing job instead of through the intermediary fracturing fluid producing apparatus  20 . 
     The fracturing fluid can be an applicable fluid for forming fractures during a fracture stimulation treatment of the well  60 . For example, the fracturing fluid can include water, a hydrocarbon fluid, a polymer gel, foam, air, wet gases, and/or other applicable fluids. In various embodiments, the fracturing fluid can include a concentrate to which additional fluid is added prior to use in a fracture stimulation of the well  60 . In certain embodiments, the fracturing fluid can include a gel pre-cursor with fluid, e.g. liquid or substantially liquid, from fluid source  30 . Accordingly, the gel pre-cursor with fluid can be mixed by the fracturing fluid producing apparatus  20  to produce a hydrated fracturing fluid for forming fractures. 
     The solid source  40  can include a volume of one or more solids for mixture with a fluid, e.g. the fracturing fluid, to form a solid-laden fluid. The solid-laden fluid can be pumped into the well  60  as part of a solids-laden fluid stream that is used to form and stabilize fractures in the well  60  during a fracturing job. The one or more solids within the solid source  40  can include applicable solids that can be added to the fracturing fluid of the fluid source  30 . Specifically, the solid source  40  can contain one or more proppants for stabilizing fractures after they are formed during a fracturing job, e.g. after the fracturing fluid flows out of the formed fractures. For example, the solid source  40  can contain sand. 
     The fracturing system  10  can also include additive source  70 . The additive source  70  can contain/provide one or more applicable additives that can be mixed into fluid, e.g. the fracturing fluid, during a fracturing job. For example, the additive source  70  can include solid-suspension-assistance agents, gelling agents, weighting agents, and/or other optional additives to alter the properties of the fracturing fluid. The additives can be included in the fracturing fluid to reduce pumping friction, to reduce or eliminate the fluid&#39;s reaction to the geological formation in which the well is formed, to operate as surfactants, and/or to serve other applicable functions during a fracturing job. As will be discussed in greater detail later, the additives can function to maintain solid particle suspension in a mixture of solid particles and fracturing fluid as the mixture is pumped down the well  60  to one or more perforations. 
     The pump and blender system  50  functions to pump fracture fluid into the well  60 . Specifically, the pump and blender system  50  can pump fracture fluid from the fluid source  30 , e.g. fracture fluid that is received through the fracturing fluid producing apparatus  20 , into the well  60  for forming and potentially stabilizing fractures as part of a fracture job. The pump and blender system  50  can include one or more pumps. Specifically, the pump and blender system  50  can include a plurality of pumps that operate together, e.g. concurrently, to form fractures in a subterranean formation as part of a fracturing job. The one or more pumps included in the pump and blender system  50  can be an applicable type of fluid pump. For example, the pumps in the pump and blender system  50  can include electric pumps and/or hydrocarbon and hydrocarbon mixture powered pumps. Specifically, the pumps in the pump and blender system  50  can include diesel powered pumps, natural gas powered pumps, and diesel combined with natural gas powered pumps. 
     The pump and blender system  50  can also function to receive the fracturing fluid and combine it with other components and solids. Specifically, the pump and blender system  50  can combine the fracturing fluid with volumes of solid particles, e.g. proppant, from the solid source  40  and/or additional fluid and solids from the additive source  70 . In turn, the pump and blender system  50  can pump the resulting mixture down the well  60  at a sufficient pumping rate to create or enhance one or more fractures in a subterranean zone, for example, to stimulate production of fluids from the zone. While the pump and blender system  50  is described to perform both pumping and mixing of fluids and/or solid particles, in various embodiments, the pump and blender system  50  can function to just pump a fluid stream, e.g. a fracture fluid stream, down the well  60  to create or enhance one or more fractures in a subterranean zone. 
     The fracturing fluid producing apparatus  20 , fluid source  30 , and/or solid source  40  may be equipped with one or more monitoring devices (not shown). The monitoring devices can be used to control the flow of fluids, solids, and/or other compositions to the pumping and blender system  50 . Such monitoring devices can effectively allow the pumping and blender system  50  to source from one, some or all of the different sources at a given time. In turn, the pumping and blender system  50  can provide just fracturing fluid into the well at some times, just solids or solid slurries at other times, and combinations of those components at yet other times. 
       FIG. 2  shows the well  60  during a fracturing operation in a portion of a subterranean formation of interest  102  surrounding a wellbore  104 . The fracturing operation can be performed using one or an applicable combination of the components in the example fracturing system  10  shown in  FIG. 1 . The wellbore  104  extends from the surface  106 , and the fracturing fluid  108  is applied to a portion of the subterranean formation  102  surrounding the horizontal portion of the wellbore. Although shown as vertical deviating to horizontal, the wellbore  104  may include horizontal, vertical, slant, curved, and other types of wellbore geometries and orientations, and the fracturing treatment may be applied to a subterranean zone surrounding any portion of the wellbore  104 . The wellbore  104  can include a casing  110  that is cemented or otherwise secured to the wellbore wall. The wellbore  104  can be uncased or otherwise include uncased sections. Perforations can be formed in the casing  110  to allow fracturing fluids and/or other materials to flow into the subterranean formation  102 . As will be discussed in greater detail below, perforations can be formed in the casing  110  using an applicable wireline-free actuation. In the example fracture operation shown in  FIG. 2 , a perforation is created between points  114 . 
     The pump and blender system  50  is fluidly coupled to the wellbore  104  to pump the fracturing fluid  108 , and potentially other applicable solids and solutions into the wellbore  104 . When the fracturing fluid  108  is introduced into wellbore  104  it can flow through at least a portion of the wellbore  104  to the perforation, defined by points  114 . The fracturing fluid  108  can be pumped at a sufficient pumping rate through at least a portion of the wellbore  104  to create one or more fractures  116  through the perforation and into the subterranean formation  102 . Specifically, the fracturing fluid  108  can be pumped at a sufficient pumping rate to create a sufficient hydraulic pressure at the perforation to form the one or more fractures  116 . Further, solid particles, e.g. proppant from the solid source  40 , can be pumped into the wellbore  104 , e.g. within the fracturing fluid  108  towards the perforation. In turn, the solid particles can enter the fractures  116  where they can remain after the fracturing fluid flows out of the wellbore. These solid particles can stabilize or otherwise “prop” the fractures  116  such that fluids can flow freely through the fractures  116 . 
     While only two perforations at opposing sides of the wellbore  104  are shown in  FIG. 2 , as will be discussed in greater detail below, greater than two perforations can be formed in the wellbore  104 , e.g. along the top side of the wellbore  104 , as part of a perforation cluster. Fractures can then be formed through the plurality of perforations in the perforation cluster as part of a fracturing stage for the perforation cluster. Specifically, fracturing fluid and solid particles can be pumped into the wellbore  104  and pass through the plurality of perforations during the fracturing stage to form and stabilize the fractures through the plurality of perforations. 
       FIG. 3  shows a portion of a wellbore  300  that is fractured using multiple fracture stages. Specifically, the wellbore  300  is fractured in multiple fracture stages using a plug-and-perf technique. 
     The example wellbore  300  includes a first region  302  within a portion of the wellbore  300 . The first region  302  can be positioned in proximity to a terminal end of the wellbore  300 . The first region  302  is formed within the wellbore  300 , at least in part, by a plug  304 . Specifically, the plug  304  can function to isolate the first region  302  of the wellbore  300  from another region of the wellbore  300 , e.g. by preventing the flow of fluid from the first region  302  to the another region of the wellbore  300 . The region isolated from the first region  302  by the plug  304  can be the terminal region of the wellbore  300 . Alternatively, the region isolated from the first region  302  by the plug  304  can be a region of the wellbore  300  that is closer to the terminal end of the wellbore  300  than the first region  302 . While the first region  302  is shown in  FIG. 3  to be formed, at least in part, by the plug  304 , in various embodiments, the first region  302  can be formed, at least in part, by a terminal end of the wellbore  300  instead of the plug  304 . Specifically, the first region  302  can be a terminal region within the wellbore  300 . 
     The first region  302  includes a first perforation  306 - 1 , a second perforation  306 - 2 , and a third perforation  306 - 3 . The first perforation  306 - 1 , the second perforation  306 - 2 , and the third perforation  306 - 3  can form a perforation cluster  306  within the first region  302  of the wellbore  300 . While three perforations are shown in the perforation cluster  306 , in various embodiments, the perforation cluster  306  can include fewer or more perforations. As will be discussed in greater detail later, fractures can be formed and stabilized within a subterranean formation through the perforations  306 - 1 ,  306 - 2 , and  306 - 3  of the perforation cluster  306  within the first region  302  of the wellbore  300 . Specifically, fractures can be formed and stabilized through the perforation cluster  306  within the first region  302  by pumping fracturing fluid and solid particles into the first region  302  and through the perforations  306 - 1 ,  306 - 2 , and  306 - 3  into the subterranean formation. 
     The example wellbore  300  also includes a second region  310  positioned closer to the wellhead than the first region  302 . Conversely, the first region  302  is in closer proximity to a terminal end of the wellbore  300  than the second region  310 . For example, the first region  302  can be a terminal region of the wellbore  300  and therefore be positioned closer to the terminal end of the wellbore  300  than the second region  310 . The second region  310  is isolated from the first region  302  by a plug  308  that is positioned between the first region  302  and the second region  310 . The plug  308  can fluidly isolate the second region  310  from the first region  302 . As the plug  308  is positioned between the first and second regions  302  and  310 , when fluid and solid particles are pumped into the second region  310 , e.g. during a fracture stage, the plug  308  can prevent the fluid and solid particles from passing from the second region  310  into the first region  302 . 
     The second region  310  includes a first perforation  312 - 1 , a second perforation  312 - 2 , and a third perforation  312 - 3 . The first perforation  312 - 1 , the second perforation  312 - 2 , and the third perforation  312 - 3  can form a perforation cluster  312  within the second region  310  of the wellbore  300 . While three perforations are shown in the perforation cluster  312 , in various embodiments, the perforation cluster  312  can include fewer or more perforations. As will be discussed in greater detail later, fractures can be formed and stabilized within a subterranean formation through the perforations  312 - 1 ,  312 - 2 , and  312 - 3  of the perforation cluster  312  within the second region  310  of the wellbore  300 . Specifically, fractures can be formed and stabilized through the perforation cluster  312  within the second region  310  by pumping fracturing fluid and solid particles into the second region  310  and through the perforations  312 - 1 ,  312 - 2 , and  312 - 3  into the subterranean formation. 
     In fracturing the wellbore  300  in multiple fracturing stages through a plug-and-perf technique, the perforation cluster  306  can be formed in the first region  302  before the second region  310  is formed using the plug  308 . Specifically, the perforations  306 - 1 ,  306 - 2 , and  306 - 3  can be formed before the perforations  312 - 1 ,  312 - 2 , and  312 - 3  are formed in the second region  310 . As will be discussed in greater detail later, the perforations  306 - 1 ,  306 - 2 , and  306 - 3  can be formed using a wireline-free actuation. Once the perforations  306 - 1 ,  306 - 2 , and  306 - 3  are formed, fracturing fluid and solid particles can be transferred through the wellbore  300  into the perforations  306 - 1 ,  306 - 2 , and  306 - 3  to form and stabilize fractures in the subterranean formation as part of a first fracturing stage. The fracturing fluid and solid particles can be transferred from a wellhead of the wellbore  300  to the first region  302  through the second region  310  of the wellbore  300 . Specifically, the fracturing fluid and solid particles can be transferred through the second region  310  before the second region  310  is formed, e.g. using the plug  308 , and the perforation cluster  312  is formed. This can ensure, at least in part, that the fracturing fluid and solid particles flow through the second region  310  and into the subterranean formation through the perforations  306 - 1 ,  306 - 2 , and  306 - 3  within the perforation cluster  306  in the first region  302 . 
     After the fractures are formed through the perforations  306 - 1 ,  306 - 2 , and  306 - 3 , the wellbore  300  can be filled with the plug  308 . Specifically, the wellbore  300  can be plugged with the plug  308  to form the second region  310 . Then, the perforations  312 - 1 ,  312 - 2 , and  312 - 3  can be formed, e.g. using a wireline-free actuation. Once the perforations  312 - 1 ,  312 - 2 , and  312 - 3  are formed, fracturing fluid and solid particles can be transferred through the wellbore  300  into the perforations  312 - 1 ,  312 - 2 , and  312 - 3  to form and stabilize fractures in the subterranean formation as part of a second fracturing stage. The fracturing fluid and solid particles can be transferred from the wellhead of the wellbore  300  to the second region  310  while the plug  308  prevents transfer of the fluid and solid particles to the first region  302 . This can effectively isolate the first region  302  until the first region  302  is accessed for production of resources, e.g. hydrocarbons. After the fractures are formed through the perforation cluster  312  in the second region  310 , a plug can be positioned between the second region  310  and the wellhead, e.g. to fluidly isolate the second region  310 . This process of forming perforations, forming fractures during a fracture stage, followed by plugging on a region by region basis can be repeated. Specifically, this process can be repeated up the wellbore towards the wellhead until a completion plan for the wellbore  300  is finished. 
       FIG. 4  shows an example fracturing system  400  for concurrently performing fracturing stages in multiple wellbores. The example fracturing system  400  can be implemented using one or an applicable combination of the components shown in the example fracturing system  10  shown in  FIG. 1 . Further, the example fracturing system  400  can form fractures according to the example techniques implemented in the well  60  shown in  FIG. 2  and the wellbore  300  shown in  FIG. 3 . 
     The example fracturing system  400  includes a first wellbore  402 - 1 , a second wellbore  402 - 2 , a third wellbore  402 - 3 , and a fourth wellbore  402 - 4 , collectively referred to as the wellbores  402 . While four wellbores  402  are shown, the fracturing system  400  can include three or two wellbores, as long as the fracturing system  400  includes more than one wellbore. Further, the fracturing system  400  can include more than four wellbores. 
     The example fracturing system  400  also includes a first pump  404 - 1 , a second pump  404 - 2 , and a third pump  404 - 3 , collectively referred to as a pumping system  404 . While the pumping system is shown as including three separate pumps, the pumping system  404  can include fewer than three pumps or more than three pumps. For example, the pumping system  404  can include only a single pump. 
     The pumping system  404  is fluidly connected to each of the wellbores  402 . Specifically, the pumping system  404  can be fluidly connected to each of the wellbores  402 , at least in part, through one or more fluid couplings, e.g. fluid coupling  406 . In being fluidly connected to each of the wellbores  402 , the pumping system  404  can pump fracturing fluid and solid particles, e.g. proppant, into the wellbores  402  for forming and stabilizing fractures through the wellbores  402 . Specifically, the pumping system  404  can pump fracturing fluid and solid particles into the wellbores  402  for forming and stabilizing fractures through passages and/or perforations in the wellbores  402 . The pumping system  404  can pump fracturing fluid into the wellbores  402  for forming fractures in the wellbores  402  according to the previously described plug-and-perf technique. Further, the pumping system  404  can pump solid particles, e.g. proppant, in a solid-laden fluid stream into the wellbores  402  for stabilizing the fractures according to the previously described plug-and-perf technique. As will be discussed in greater detail below, in being fluidly connected to each of the wellbores  402 , the pumping system  404  can pump additional components, e.g. additives, into the wellbores  402  for aiding in the formation and/or stabilization of fractures in the wellbores  402 . 
     With specific reference to the example fracturing system  400  shown in  FIG. 4 , the first pump  404 - 1  can pump fracturing fluid to the first wellbore  402 - 1  and the second wellbore  402 - 2 . Specifically, the first pump  404 - 1  can pump fracturing fluid mixed by a fluid blender from a fluid supply to the first wellbore  402 - 1  and the second wellbore  402 - 2 . The third pump  404 - 3  can pump fracturing fluid to the third wellbore  402 - 3  and the fourth wellbore  402 - 4 . Specifically, the third pump  404 - 3  can pump fracturing fluid mixed by a fluid blender from a fluid supply to the third wellbore  402 - 3  and the fourth wellbore  402 - 4 . The third pump  404 - 3  and the first pump  404 - 1  can pump fracturing fluid from the same fluid supply into the wellbores  402 . Alternatively, the third pump  404 - 3  and the first pump  404 - 1  can pump fracturing fluid from different fluid supplies into the wellbores  402 . 
     The pumping system  404 , e.g. the second pump  404 - 2 , can pump solid particles in a solid laden fluid stream to one or more of the wellbores  402 . Specifically, the second pump  404 - 2  can pump proppant in a proppant laden fluid stream to one or more of the wellbores  402  for stabilizing fractures formed through the wellbores  402 . While reference is made throughout this description to pumping solid particles, the solid particles are actually pumped in a slurry or otherwise a solid laden fluid stream. The solid laden fluid streams can be pumped by the pumping system  404  to wellheads of one or more of the wellbores  402 . One or more liquid-phase-only fluid streams, e.g. fracturing fluid, can also be pumped by the pumping system  404 , e.g. the first pump  404 - 1  and the third pump  404 - 3 , to the wellheads of the one or more wellbores  402 . In turn, the solid laden fluid stream can be mixed with the liquid-phase-only fluid stream(s) at or near the corresponding wellheads of the one or more wellbores  402  to form a mixed fluid stream of both solid particles, e.g. proppant, and fluid, e.g. fracturing fluid. After the mixed fluid stream is formed at or near the corresponding wellheads of the one or more wellbores  402 , the mixed fluid stream can flow into the one or more wellbores  402  for forming and/or stabilizing fractures through the wellbores  402 . The solid laden fluid streams and the liquid-phase-only fluid streams can be simultaneously pumped to wellheads of the one or more wellbores  402 . This can facilitate effective mixing of the solid laden fluid streams and the liquid-phase-only fluid streams at or near the wellheads to form the mixed fluid stream. 
     The solid laden fluid stream can have an applicable concentration of solid particles, e.g. proppant. For example, the solid laden fluid stream can have a solid particle concentration of 8 pounds per gallon of liquid. Further, the solid laden fluid stream and the liquid-phase-only fluid stream can be mixed at applicable proportions to form the mixed fluid stream. For example, the solid laden fluid stream and the liquid-phase-only fluid stream can be mixed at one part solid laden fluid stream to two parts liquid-phase-only fluid stream proportions, one part solid laden fluid stream to three parts liquid-phase-only fluid stream proportions, one part solid laden fluid stream to four parts liquid-phase-only fluid stream proportions, or one part solid laden fluid stream to five parts liquid-phase-only fluid stream proportions. 
     The solid laden fluid stream can be pumped at a lower rate, e.g. with respect to a rate at which the liquid-phase-only fluid stream is pumped by the pumping system  404 , e.g. the first pump  404 - 1  and the third pump  404 - 3 . For example, the solid laden fluid stream can be pumped at around 10 barrels per minute (bpm) while the liquid-phase-only fluid stream is pumped around 30 bpm. More specifically, the solid laden fluid stream can be pumped by the pumping system  404 , e.g. the second pump  404 - 2 , at a rate from 5 to 15 bpm and the liquid-phase-only fluid stream can be pumped by the pumping system  404 , e.g. the first pump  404 - 1  and/or the third pump  404 - 3 , at rates from 25 to 35 bpm. A resultant pump/flow rate of the mixed fluid stream of the solid laden fluid stream and the liquid-phase-only fluid stream is a combination of the pump rates of both the solid laden fluid stream and the liquid-phase-only fluid stream. For example, when the solid laden fluid stream is pumped at a rate of 10 bpm and the liquid-phase-only fluid stream is pumped at a rate of 30 bpm, the flow rate of the mixed fluid stream can be 40 bpm. 
     Pumping the solid laden fluid stream at a reduced rate with respect to the liquid-phase-only fluid stream can reduce erosion and fatigue in the pumping system  404  and connections, e.g. valves, between the pumping system  404  and the wellbores  402 . Specifically, the solid particles in the solid laden fluid stream increase friction pressure, e.g. due to drag, in the pumping system  404  and the connections to the wellbores  402 . Accordingly, pumping the solid laden fluid stream at the reduced rate reduces friction pressure created by the flow of the solid laden fluid stream through the pumping system  404  and the connections between the pumping system  404  and the wellbores  402 . In turn, reducing friction pressure in the pumping system  404  and the connections between the pumping system  404  and the wellbores  402  can effectively reduce erosion and fatigue in the pumping system  404  and the connections. Reducing erosion and fatigue in the pumping system  404  is advantageous as the pumping system  404  is one of the most expensive components of a fracturing job. Therefore, reducing erosion and fatigue in the pumping system  404  can save operators from costly repair and replacement of the pumping system  404 . Further, reducing erosion and fatigue in the pumping system  404  can increase operator efficiency by reducing the amount of time that the pumping system  404  is down on a fracturing job due to repair and replacement. 
     The pumping system  404  can pump fracturing fluid and solid particles, e.g. in a solid laden fluid stream, down multiple wellbores of the wellbores  402 . Specifically, the pumping system  404  can pump fracturing fluid and/or solid particles simultaneously down multiple wellbores of the wellbores  402 . More specifically, the pumping system  404  can pump fracturing fluid and/or solid particles simultaneously down multiple wellbores to concurrently form and stabilize fractures in the wellbores. The pumping system  404  can pump solid particles down multiple wellbores using the previously described technique of pumping a solid laden fluid stream and a liquid-phase-only fluid stream to wellheads of the wellbores  402 . In turn, the solid laden fluid stream and the liquid phase-only fluid streams can mix at the wellheads of the wellbores  402 , and the resultant mixed fluid stream can flow down each of the multiple wellbores to form and stabilize fractures through the wellbores. 
     In pumping fracturing fluid and solid particles down the wellbore  402 , the pumping system  404  can pump the fracture fluid and/or solid laden fluid to a reservoir formed between the wellbores  402  and the pumping system  404 . The reservoir can be formed through valves between the wellbores  402  and the pumping system  404 , e.g. at the wellheads of the wellbores  402 . The valves can be controlled to prevent passage of the fracture fluid and/or the solid laden fluid into the wellbores thereby accumulating the fracture fluid and/or the solid laden fluid within the reservoir. In turn the valves can be operated to selectively control fluid flow of the fracturing fluid and/or the solid laden fluid into the wellbores  402  for forming and stabilizing fractures through the wellbores  402 . 
     The pumping system  404  can operate in a damage avoidance mode to pump fracturing fluid and solid particles down the wellbores  402  for forming and stabilizing fractures through the wellbores  402 . Operating a pump in a damage avoidance mode can include operating the pump according to one or more applicable operational parameters for reducing or otherwise eliminating operational damage to the pump. Specifically, operating a pump in a damage avoidance mode can include operating the pump at a fluid pressure at around or below a fatigue-inducing value associated with the pump, e.g. a fatigue-inducing value associated with the fluid end of the pump. For example, operating a pump in a damage avoidance mode can include operating the pump at a pumping rate of less than 60 bpm and a corresponding fluid pressure, in order to prevent fatigue in the pump. Further, operating a pump in a damage avoidance mode can include operating the pump at a fluid velocity at around or below an erosion-inducing value associated with the pump, e.g. an erosion-inducing value associated with components of the pump. For example, operating a pump in a damage avoidance mode can include operating the pump at a pumping rate of less than 60 bpm and a corresponding fluid velocity, in order to prevent erosion of applicable components of the pump. 
     In operating the pumping system  404  in a damage avoidance mode, the pumping system  404  can be controlled to pump fracturing fluid and solid particles down the wellbores at a reduced rate compared to typical pumping rates used by operators at fracturing jobs. As discussed previously, operators at a fracturing job typically pump at the highest rate possible in order to complete the fracturing job faster. For example, operators typically pump at a rate of 90 bpm or more. This is problematic as pumping either or both fracturing fluid and solid particles at these high rates directly leads to pump erosion and fatigue. Specifically, pumping at high rates increases friction pressure in the wellbore caused by drag of the fracturing fluid and the solid particles passing through the wellbore. Friction pressure can include the amount of pressure of a fluid stream that is lost due to drag as the fluid stream passes through the wellbore. As friction pressure in the wellbore increases, the pump has to impart more power on the fluid stream in order to pump the fluid stream through the wellbore at a specific rate. In turn, this can lead to erosion of the pump, e.g. applicable components of the pump, and connections between the pump and the wellbore. Additionally, this can increase fatigue/fatigue cycle loading on the pump. Therefore, in pumping at higher rates current operators at fracturing jobs are actually damaging pumping equipment and wellbore connections through erosion and fatigue. The pumping system  404 , however, can be configured to operate in a damage avoidance mode and pump at a rate lower than 90 bpm, e.g. a rate around or lower than 60 bpm. Accordingly, erosion and fatigue of the pumping system  404  can be reduced by operating the pumping system  404  at the reduced rate in the damage avoidance mode. 
     Further, in operating in a damage avoidance mode to fracture a subterranean formation through perforations, the pumping system  404  can limit erosion of the perforations through the fracturing job. Specifically, pumping proppant through perforations at high rates, as is done in current fracturing jobs, can actually erode the perforations. Perforation erosion can lead to the formation of runaway fractures and create non-uniform fractures within perforation clusters during a fracturing job. Specifically, as eroded perforations grow in size, more proppant can flow in to eroded perforations starving other perforations in a perforation cluster. In turn, this can lead to non-uniform fracture formation through the perforation cluster, which may then result in frac hit/well bashing to adjacent wells. However, pumping in a damage avoidance mode, e.g. at a reduced rate, can limit or otherwise eliminate erosion of perforations caused by proppant passing through the perforations. In turn, this can lead to more uniform fracture formation, e.g. according to a completion plan, during a fracture job. 
     The pumping system  404  can be controlled to operate in the damage avoidance mode for a specific amount of time with respect to a duration of the fracturing job. A duration of the fracturing job can include the period of time measured from when fracturing fluid is first simultaneously provided to all of the wellbores  402  by the pumping system  404  and continue as long as the pumping system  404  provides fracturing fluid simultaneously to all of the wellbores  402 . Further, a duration of the fracturing job can include the period of time measured from when fracturing fluid is first simultaneously provided to any of the wellbores  402  and continue as long as the pumping system  404  provides fracturing fluid to any of the wellbores  402 . Additionally, a duration of the fracturing job can include the period of time measured from when fracturing fluid is first simultaneously provided to all of the wellbores  402  by the pumping system  404  and continue as long as the pumping system  404  provides fracturing fluid to any of the wellbores  402 . 
     In controlling operation of the pumping system  404  in the damage avoidance mode based on the duration of the fracturing job, the pumping system  404  can be operated in the damage avoidance mode during a predominance of the duration of the fracturing job. For example, the pumping system  404  can be operated in the damage avoidance mode for seventy percent of the duration of the fracturing job, ninety percent of the duration of the fracturing job, or ninety-five percent of the duration of the fracturing job. Further, the pumping system  404  can be operated in the damage avoidance mode for a substantial entirety of the duration of the fracturing job. For example, the pumping system  404  can be operated in the damage avoidance mode for around ninety-nine percent of the duration of the fracturing job. 
     One or more pumps of the pumping system  404  have specific operating capacities. An operating capacity of a pump can include an applicable metric for measuring operational limits of the pump. For example, an operating capacity of a pump can include a maximum or threshold pumping rate, e.g. in bpm, of the pump. An operating capacity can include metrics for measuring operational limits at which a pump can safely operate, e.g. without damaging itself. Specifically, an operating capacity of a pump can occur at a substantial operating speed of the pump that is less than a peak operating speed of the pump. One or more pumps of the pumping system  404  can be selected based on corresponding operating capacities of the one or more pumps. Further, one or more pumps of the pumping system  404  can be selected based on their corresponding operating capacities and characteristics of a fracturing job. For example, if a pumping rate of 40 bpm is needed to form fractures in the wellbores  402 , then pumps having an operating capacity of at least 80 bpm can be selected for the pumping system  404 . Operating capacities of the one or more pumps of the pumping system  404  can be specified by pump manufactures. 
     A pump can operate in a damage avoidance mode based on an operating capacity of the pump. Specifically, a fluid velocity of a pump operating in a damage avoidance mode can be selected based on an operating capacity of the pump. For example, the pump can operate at a reduced velocity while pumping at a full operating capacity. Additionally, a fluid pressure of a pump operating in a damage avoidance mode can be selected based on an operating capacity of the pump. For example, the pump can operate at a reduced fluid pressure while pumping at a full operating capacity. Further, a reduced rate of a pump operating in a damage avoidance mode can be selected based on an operating capacity of the pump. 
     The pumping system  404  is configured to pump fracturing fluid and solid particles, as part of a solid laden fluid stream, to perforations or passageways within the wellbores  402  to form and stabilized fractures through the perforations and passageways within the wellbores  402 . A passageway, as used herein, includes any type of aperture or conduit across the casing of a wellbore that exposes, e.g. fluidly connects, an interior of the wellbore to a surrounding subterranean formation. For example, a passageway can be formed by activating a sliding sleeve to create an opening that exposes an interior of the wellbore to a surrounding subterranean formation. The perforations and passageways can extend through casings of the wellbores to a surrounding subterranean formation in which fractures can be formed and stabilized. The perforations and passageways can have known rate ranges of fracturing fluid within the perforations and passageways for successfully forming fractures through the subterranean formation. For example, a flow rate of 40 bpm of fracturing fluid through a perforation can be required to form a fracture outside of the perforation through the subterranean formation. In turn, the pumping system  404  can be configured to pump fracturing fluid to a perforation or passageway within a known rate range of the perforation or passageway to successfully form a fracture in the subterranean formation. Specifically, the pumping system  404  can be configured to pump fracturing fluid to a perforation or passageway to achieve a target flow rate per perforation or passageway for successfully fracturing through the perforation or passageway. The pumping system  404  can be configured to pump fracturing fluid to a perforation or passageway within a known rate range for successfully forming a fracture in the subterranean formation through the perforation or passageway while operating in a damage avoidance mode. For example, if a rate of 40 bpm is needed to successfully fracture a subterranean formation through perforations, then the pumping system  404  can operate in a damage avoidance mode while pumping fracturing fluid to the perforation at a rate of 40 bpm to form a fracture in the subterranean formation through the perforations. 
     The wellbores included in the wellbores  402  that are fluidly connected to the pumping system  404  can be selected based on known rate ranges needed to fracture perforations and passageways in the wellbores. Specifically, a wellbore can be selected for inclusion in the wellbores  402  if it includes a perforation or passageway with a known rate range of fracturing fluid that is capable of being met by the pumping system, e.g. while operating in the damage avoidance mode. For example, if a wellbore includes perforations that require 90 bpm of fluid flow to form fractures in a subterranean formation through the perforations and the pumping system  404  lacks an operational capacity of 90 bpm, then the wellbore can be excluded from the wellbores  402 . In another example if a wellbore includes perforations that require 40 bpm of fluid flow to form fractures in a subterranean formation through the perforations and the pumping system  404  has an operational capacity over 40 bpm in a damage avoidance mode, then the wellbore can be included in the wellbores  402 . 
     Perforations and passages in the wellbores  402  can be prepared and designed based on a specific rate range of fracturing fluid for forming fractures through the perforations and passages. For example, perforations in the wellbores  402  can be designed to allow for the successful formation of fractures through the perforations at a fracturing fluid flow rate of 60 bpm or less. In another example, perforations in the wellbores  402  can be designed to allow for the successful formation of fractures through the perforations at a fracturing fluid flow rate of 40 bpm or less. In turn, the specific rate ranges of the perforations and passages for successfully forming fractures can be known based on how the perforations and passages are prepared and designed. 
     Further, perforations and passages in the wellbores  402  can be prepared and designed based on characteristics of the pumping system  404 . The perforations and passages can be sized, shaped, spaced, and formed in perforation clusters, e.g. according to the plug-and-perf technique, in order to facilitate the formation and stabilization of fractures in a subterranean formation through the perforations and passages using the pumping system  404 . Specifically, the perforations and passages can be prepared and designed so that at least a majority of the pumping system&#39;s  404  known operating capacity is required to successfully fracture the subterranean formation through the perforations and passages during at least a portion of the fracturing job. The perforations and passages can also be prepared and designed such that the pumping system  404  can form and stabilize fractures in a subterranean formation through the perforations and passages while the pumping system  404  operates in a damage avoidance mode. Specifically, the perforations and passages can be prepared and designed such that the pumping system  404  can form and stabilize fractures while operating in a damage avoidance mode at a portion or a majority of the pumping system&#39;s  404  know operation capacity. For example, if the pumping system  404  can pump around 40 bpm in a damage avoidance mode, then the perforations in the wellbores  402  can be shaped to facilitate formation of fractures at a flow rate at or less than 40 bpm. 
     Further, the perforations and passages in the wellbores  402  can be prepared and designed for achieving a target fluid velocity/velocity range of a fluid stream for successfully fracturing a subterranean formation through the perforations and passages. Specifically, the perforations and passages can be designed to achieve a target fluid velocity/velocity range of a fluid stream through the perforations and passages for successfully forming fractures when the fluid stream is pumped at a specific rate. For example, a stream of fracturing fluid can be pumped into a perforation at a rate within the range of 2-5 bpm. Further in the example, the perforation can be sized to create a fluid velocity through the perforation sufficient to fracture a subterranean formation, based on the rate of the fracturing fluid within the range of 2-5 bpm. 
     Perforations can be formed in perforation clusters in the wellbores  402 . A perforation cluster can include an applicable number of perforations with respect to a number of perforations that are typically formed per perforation cluster when operating in a normal pump operation mode, e.g. between 15 and 20 perforations. For example, a perforation cluster can include about six perforations. More specifically, a perforation cluster can include one to four perforations. This is in contrast to fracturing designs used by current operators which typically include more than ten perforations per perforation cluster. Additionally, perforation clusters can be formed amongst a plurality of perforation clusters that are all pumped during a single fracturing stage. The number of perforation clusters that are formed and pumped during a single fracturing stage can be reduced with respect to a typical number of perforation clusters that are formed and pumped during a single fracturing stage. For example, a reduction of about 30 to 40% of the typical number of perforations clusters that are formed during a fracturing stage can be formed and pumped during a single fracturing stage. Specifically, operators typically pump between fifteen and twenty perforation clusters during a single fracturing stage. However, through the techniques and systems described herein, between about eight through thirteen perforation clusters can be pumped and formed during a single fracturing stage. 
     Forming perforation clusters with fewer perforations and/or forming and pumping less perforation clusters during a fracturing stage is advantageous over the perforation cluster designs used by current fracturing operators. Specifically and as discussed previously, current operators typically form and pump over 15 perforation clusters, each perforation cluster having as many as ten perforations, during a fracturing stage. However, this can lead to the formation of non-uniform fractures across perforation clusters, e.g. when the plug-and-perf technique is used to form the fractures. Specifically, when a large number of perforation clusters with a large number of perforations in each cluster are pumped during a single fracturing stage, perforation clusters in the end of the perforated interval, e.g. further away from the wellhead/heel of the wellbore, do not receive as much fracturing fluid or receive fracturing fluid at a rate below a sufficient rate for fracturing. This can lead to the formation of smaller fractures, e.g. not according to a completion plan, through the perforations in the end perforation clusters. Conversely, perforations in the beginning perforation clusters, e.g. closer to the wellhead/heel of the wellbore, dominate and receive more fracturing fluid and potentially at increased rates when compared to the perforations in the end perforation clusters. This can lead to the formation of runaway fractures through those perforations in the beginning perforation clusters. In turn, the perforations in the end perforation clusters do not receive enough fracture fluid and proppant. As a result, fractures formed through the perforations in the end perforation clusters are smaller than planned or otherwise desired fracture sizes. Therefore, forming perforation clusters with fewer perforations, e.g. about 1 to 4 perforations formed in each perforation cluster, and/or forming and pumping less perforation clusters e.g. about 30 to 40% reduction in total perforation clusters during a fracturing stage can prevent these deficiencies that are often observed in fracturing stages where a large number of perforation clusters with a large number of perforations are formed and pumped. 
     Perforations can be formed, e.g. in perforation clusters, through the wellbores  402  using one or more wireline-free actuations. Specifically, a predominance of the perforations in the wellbores  402  can be formed using one or more wireline-free actuations. A wireline-free actuation includes an applicable mechanism for forming perforations within a wellbore, e.g. through a casing within a wellbore without the use of wireline and/or coil tubing. Examples of wireline-free actuations include sliding sleeves, casing-conveyed perforation shaped charges, apertures plugged with water soluble material within a casing of a wellbore, apertures plugged with formation-fluid soluble material within a casing of a wellbore, and apertures plugged with chemically dissolvable material within a casing of a wellbore. Casing-conveyed perforation shaped charges, as part of a wireline-free actuation, can be integrated within a casing of a wellbore, along an interior of a casing of a wellbore, or along an exterior of a casing of a wellbore. 
     Using a wireline-free actuation to form perforations is advantageous as it is quicker than forming perforations through a wireline or coil tubing technique. Specifically, the process of feeding a wireline and a perforation gun to a desired location in a wellbore, setting off charges on the perforation gun to form perforations in a well casing, and then pulling the wireline and the perforation gun out of the wellbore is extremely time consuming. In particular, feeding a perforation gun and an attached wireline through a horizontal portion of the wellbore is a time consuming process that is prone to error and creates additional safety risks. Specifically, feeding a perforation gun and an attached wireline through a horizontal portion of the wellbore is typically accomplished in one of two ways. In one way, fluid is pumped at a reduced rate, e.g. with respect to a rate at which perforations are pumped in forming and stabilizing fractures, to create drag around the perforation gun and push the perforation gun through the horizontal portion of the wellbore. However, this can be a problematic technique, as pumping the fluid at too high or a rate can create too much tension on the wireline, thereby causing the wireline to disengage from the perforation gun. As a result, coil tubing is needed to retrieve the perforation gun, thereby halting all other fracturing operations on the wellbore. Further, retrieving unfired perforation guns from the wellbore is a safety issue that poses additional risks to operators at the fracturing site. In another way of feeding a perforation gun and a wireline through a horizontal portion of the wellbore, an electrically powered tractor is included on a tool string to drive the perforation gun and attached wireline through the horizontal portion of the wellbore. However, electrically power tractors are prone to failure while increasing operational costs. 
     Further, wireline or coil tubing techniques typically cannot be performed while hydraulic fracturing treatment is actually pumped into the wellbore to form and stabilize fractures. Therefore, such techniques can consume time that a fracturing crew could otherwise use to actually pump a hydraulic fracture treatment into a wellbore. Specifically, as the wireline is actually fed into the wellbore, a fracturing treatment generally cannot be pumped during the time that the wireline is in the wellbore. Therefore, using wireline-free actuation to form perforations in the wellbores  104  can decrease the amount of time needed to form the actual perforations while increasing the amount of time that can be dedicated to pumping the hydraulic fracture treatments into wellbores  104  during a fracturing job. In turn, this can improve operational efficiency of a fracturing crew in performing the fracturing job. For example, by using wireline-free actuation to perforate the wellbores  402 , the pumping system  404  can pump the hydraulic fracturing treatments into wellbores  402  during a predominance of the duration of the fracturing job. In another example, by using wireline-free actuation to perforate the wellbores  402 , the pumping system  404  can pump the hydraulic fracturing treatments into wellbores  402  during as much as seventy percent of the duration of the fracturing job. In yet another example, by using wireline-free actuation to perforate the wellbores  402 , the pumping system  404  can pump the hydraulic fracturing treatments into wellbores  402  during as much as ninety percent of the duration of the fracturing job. In another example, by using wireline-free actuation to perforate the wellbores  402 , the pumping system  404  can pump the hydraulic fracturing treatments into wellbores  402  during as much as ninety-five percent of the duration of the fracturing job. In yet another example, by using wireline-free actuation to perforate the wellbores  402 , the pumping system  404  can pump the hydraulic fracturing treatments into wellbores  402  substantially continuously through the entire duration of the fracturing job. 
     The pumping system  404  can function to pump one or more additives in fluid streams into the wellbores  402 . Specifically, the pumping system  404  can pump additives as part of a liquid phase-only fluid stream into the wellbores  402 . Alternatively, the pumping system  404  can pump additives as part of a solid laden fluid stream into the wellbores  402 . The fracturing system  400  can include an additives blender, not shown, for mixing one or more additives into a volume of fluid, e.g. a fluid stream, pumped by the pumping system  404 . For example, the fracturing system  400  can include an additives blender for mixing additives with fracturing fluid which can subsequently be pumped by the pumping system  404 . In another example, the fracturing system  400  can include an additives mixer for blending additives with proppant laden fluid which can subsequently be pumped by the pumping system  404 . Further, the pumping system  404  can pump one or more additives to wellheads of the wellbores  402 , where the additives can be mixed with a fluid stream and subsequently pumped down the wellbores  402 . 
     An additive mixed with a fluid stream that is then pumped by the pumping system  404  into the wellbores  402  can include a solids-suspension-assistance additive. The solids-suspension-assistance additive can be an applicable additive for aiding in the suspension of solids, e.g. proppant, in a fluid, e.g. fracturing fluid. For example, the solids-suspension-assistance additive can comprise one or more of guar gum and hydroxyethyl cellulose. The solid-suspension-assistance additive can function to ensure that solids, e.g. proppant, remain suspended in a fluid stream as the fluid stream is pumped by the pumping system  404  down to perforations or passages in the wellbores  402  to form and stabilize fractures. In turn, addition of the solid-suspension-assistance additive can ensure that volumes of solids, e.g. proppant, do not collect in the wellbores  402 , e.g. in the perforations or passages, and cause screen outs within the wellbores  402 . 
     The solids-suspension-assistance additive can function as a viscosifier. Specifically, the solids-suspension-assistance additive can increase the viscosity of a fluid stream, e.g. a solid laden fluid stream, pumped through the wellbores  402  by the pumping system  404 . By increasing the viscosity of a fluid stream pumped through the wellbores  402 , the solids-suspension-assistance additive can reduce friction pressure within the wellbores  402 . In turn, the viscosifier can reduce the likelihood of screen outs occurring in the wellbores  402  during the fracturing job. This is particularly important when the fluid stream is pumped by the pumping system  404  in a damage avoidance mode, e.g. at a lower rate, during which the chances of solid particles settling or becoming trapped in the wellbores  402  can increase. 
     Specific wellbores of the wellbores  402  can be used to monitor fracturing job effects on the wellbores  402 . Specifically, an off-set wellbore of the wellbores  402  can be monitored to identify remote effects in the off-set wellbore that occur as a result of performing a fracturing job in a different wellbore in the wellbores  402 . For example, the first wellbore  402 - 1  can be monitored to measure pressures that are created in the first wellbore  402 - 1  as a result of a fracturing job performed in the second wellbore  402 - 2 . Further, an off-set wellbore of the wellbores  402  can be monitored to identify localized effects that occur in a wellbore in response to a fracturing job performed in the \wellbore. For example, the second wellbore  402 - 2  can be monitored to identify micro seismic events occurring in the first wellbore  402 - 1  as a result of performing a fracturing job in the first wellbore  402 - 1 . 
     The fracturing system  400  can be configured to commence pumping into at least one of the wellbores  402  before complete removal of a drilling rig associated with the wellbores  402 . Specifically, the pumping system  404  can begin pumping at least one of the wellbores  402 , while drilling continues to complete all of the wellbores  402 . For example, the first wellbore  402 - 1  can be drilled and the pumping system  404  can be fluidly connected to the first wellbore  402 - 1  while the second wellbore  402 - 2  is drilled. Further in the example, the pumping system  404  can begin pumping in the first wellbore  402 - as the second wellbore  402 - 2  is drilled. As follows, once the second wellbore  402 - 2  is drilled, the pumping system  404  can be fluidly connected to the second wellbore  402 - 2  and begin or continue to pump on either or both of the first wellbore  402 - 1  and the second wellbore  402 - 2 . The process of pumping before complete removal of a drilling rig associated with the wellbores  402  can improve operational efficiency in performing the fracturing job. 
     One or more of the wellbores  402  can be formed through four and one-half inch and smaller casing. The use of four and one-half inch and smaller casing in the wellbores  402  can be facilitated by operating the pumping system  404  in the damage avoidance mode to form and stabilize fractures through the wellbores  402 . Specifically, as smaller casing sizes lead to increased friction pressure as fluid flow rate increases, pumping at reduced rates can allow for the use of four and one-half inch casing or smaller casing without incurring prohibitively high friction pressure. For example, fluid pumped at 90 bpm through a four and one-half inch casing will experience greater friction pressure than fluid pumped at the same rate through a five and one-half inch casing. However, by pumping in the damage avoidance mode, the harmful impact of increased friction pressure caused by pumping through smaller casings is minimized. 
     The use of smaller casing, e.g. four and one-half inch and smaller casing, is in contrast to current industry trends where larger casing sizes are used. Specifically, current fracturing operators typically use five and one-half inch diameter casing and have begun using six inch diameter casing or seven inch diameter casing. The rationale behind using bigger casing is that fluid can be pumped through the larger casing at faster rates when compared to smaller casing. Specifically, as friction pressure at a given fluid rate decreases as casing size increases, operators can use larger casings to pump fracturing fluid and proppant at faster rates during a fracture job. However, the use of smaller casing has numerous advantageous over using larger casing in fracturing jobs and well completions. For example, smaller casing is cheaper from a material perspective and also cheaper to install, e.g. smaller less expensive wellbores can be drilled. Further, it requires less work to draw fluids out of wellbores having smaller casing. Specifically, it is easier to pump hydrocarbon liquid during a production phase out of wells that are formed with smaller casing because the fluid column is higher. 
     While the description has made reference to performing fracturing jobs as part of well completion activities, the techniques and systems described herein can be applied to any applicable situation where a fracturing job is performed. Specifically, the techniques and systems for performing a fracturing job, as described herein, can be applied to perform well workover activities. For example, the techniques and systems described herein can be applied in well workover activities to change a completion based on changing hydrocarbon reservoir conditions. In another example, the techniques and systems described herein can be applied in well workover activities to pull and replace a defective completion. 
       FIG. 5  illustrates an example computing device architecture  500  which can be employed to perform various steps, methods, and techniques disclosed herein. Specifically, the techniques described herein can be implemented in an applicable fracturing system, e.g. the fracturing system  400 , through a control system. The control system can be implemented, at least in part, through the computing device architecture  500  shown in  FIG. 5 . The various implementations will be apparent to those of ordinary skill in the art when practicing the present technology. Persons of ordinary skill in the art will also readily appreciate that other system implementations or examples are possible. 
     As noted above,  FIG. 5  illustrates an example computing device architecture  500  of a computing device which can implement the various technologies and techniques described herein. The components of the computing device architecture  500  are shown in electrical communication with each other using a connection  505 , such as a bus. The example computing device architecture  500  includes a processing unit (CPU or processor)  510  and a computing device connection  505  that couples various computing device components including the computing device memory  515 , such as read only memory (ROM)  520  and random access memory (RAM)  525 , to the processor  510 . 
     The computing device architecture  500  can include a cache of high-speed memory connected directly with, in close proximity to, or integrated as part of the processor  510 . The computing device architecture  500  can copy data from the memory  515  and/or the storage device  530  to the cache  512  for quick access by the processor  510 . In this way, the cache can provide a performance boost that avoids processor  510  delays while waiting for data. These and other modules can control or be configured to control the processor  510  to perform various actions. Other computing device memory  515  may be available for use as well. The memory  515  can include multiple different types of memory with different performance characteristics. The processor  510  can include any general purpose processor and a hardware or software service, such as service  1   532 , service  2   534 , and service  3   536  stored in storage device  530 , configured to control the processor  510  as well as a special-purpose processor where software instructions are incorporated into the processor design. The processor  510  may be a self-contained system, containing multiple cores or processors, a bus, memory controller, cache, etc. A multi-core processor may be symmetric or asymmetric. 
     To enable user interaction with the computing device architecture  500 , an input device  545  can represent any number of input mechanisms, such as a microphone for speech, a touch-sensitive screen for gesture or graphical input, keyboard, mouse, motion input, speech and so forth. An output device  535  can also be one or more of a number of output mechanisms known to those of skill in the art, such as a display, projector, television, speaker device, etc. In some instances, multimodal computing devices can enable a user to provide multiple types of input to communicate with the computing device architecture  500 . The communications interface  540  can generally govern and manage the user input and computing device output. There is no restriction on operating on any particular hardware arrangement and therefore the basic features here may easily be substituted for improved hardware or firmware arrangements as they are developed. 
     Storage device  530  is a non-volatile memory and can be a hard disk or other types of computer readable media which can store data that are accessible by a computer, such as magnetic cassettes, flash memory cards, solid state memory devices, digital versatile disks, cartridges, random access memories (RAMs)  525 , read only memory (ROM)  520 , and hybrids thereof. The storage device  530  can include services  532 ,  534 ,  536  for controlling the processor  510 . Other hardware or software modules are contemplated. The storage device  530  can be connected to the computing device connection  505 . In one aspect, a hardware module that performs a particular function can include the software component stored in a computer-readable medium in connection with the necessary hardware components, such as the processor  510 , connection  505 , output device  535 , and so forth, to carry out the function. 
     For clarity of explanation, in some instances the present technology may be presented as including individual functional blocks including functional blocks comprising devices, device components, steps or routines in a method embodied in software, or combinations of hardware and software. 
     In some embodiments the computer-readable storage devices, mediums, and memories can include a cable or wireless signal containing a bit stream and the like. However, when mentioned, non-transitory computer-readable storage media expressly exclude media such as energy, carrier signals, electromagnetic waves, and signals per se. 
     Methods according to the above-described examples can be implemented using computer-executable instructions that are stored or otherwise available from computer readable media. Such instructions can include, for example, instructions and data which cause or otherwise configure a general purpose computer, special purpose computer, or a processing device to perform a certain function or group of functions. Portions of computer resources used can be accessible over a network. The computer executable instructions may be, for example, binaries, intermediate format instructions such as assembly language, firmware, source code, etc. Examples of computer-readable media that may be used to store instructions, information used, and/or information created during methods according to described examples include magnetic or optical disks, flash memory, USB devices provided with non-volatile memory, networked storage devices, and so on. 
     Devices implementing methods according to these disclosures can include hardware, firmware and/or software, and can take any of a variety of form factors. Typical examples of such form factors include laptops, smart phones, small form factor personal computers, personal digital assistants, rackmount devices, standalone devices, and so on. Functionality described herein also can be embodied in peripherals or add-in cards. Such functionality can also be implemented on a circuit board among different chips or different processes executing in a single device, by way of further example. 
     The instructions, media for conveying such instructions, computing resources for executing them, and other structures for supporting such computing resources are example means for providing the functions described in the disclosure. 
     In the foregoing description, aspects of the application are described with reference to specific embodiments thereof, but those skilled in the art will recognize that the application is not limited thereto. Thus, while illustrative embodiments of the application have been described in detail herein, it is to be understood that the disclosed concepts may be otherwise variously embodied and employed, and that the appended claims are intended to be construed to include such variations, except as limited by the prior art. Various features and aspects of the above-described subject matter may be used individually or jointly. Further, embodiments can be utilized in any number of environments and applications beyond those described herein without departing from the broader spirit and scope of the specification. The specification and drawings are, accordingly, to be regarded as illustrative rather than restrictive. For the purposes of illustration, methods were described in a particular order. It should be appreciated that in alternate embodiments, the methods may be performed in a different order than that described. 
     Where components are described as being “configured to” perform certain operations, such configuration can be accomplished, for example, by designing electronic circuits or other hardware to perform the operation, by programming programmable electronic circuits (e.g., microprocessors, or other suitable electronic circuits) to perform the operation, or any combination thereof. 
     The various illustrative logical blocks, modules, circuits, and algorithm steps described in connection with the examples disclosed herein may be implemented as electronic hardware, computer software, firmware, or combinations thereof. To clearly illustrate this interchangeability of hardware and software, various illustrative components, blocks, modules, circuits, and steps have been described above generally in terms of their functionality. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the overall system. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present application. 
     The techniques described herein may also be implemented in electronic hardware, computer software, firmware, or any combination thereof. Such techniques may be implemented in any of a variety of devices such as general purposes computers, wireless communication device handsets, or integrated circuit devices having multiple uses including application in wireless communication device handsets and other devices. Any features described as modules or components may be implemented together in an integrated logic device or separately as discrete but interoperable logic devices. If implemented in software, the techniques may be realized at least in part by a computer-readable data storage medium comprising program code including instructions that, when executed, performs one or more of the method, algorithms, and/or operations described above. The computer-readable data storage medium may form part of a computer program product, which may include packaging materials. 
     The computer-readable medium may include memory or data storage media, such as random access memory (RAM) such as synchronous dynamic random access memory (SDRAM), read-only memory (ROM), non-volatile random access memory (NVRAM), electrically erasable programmable read-only memory (EEPROM), FLASH memory, magnetic or optical data storage media, and the like. The techniques additionally, or alternatively, may be realized at least in part by a computer-readable communication medium that carries or communicates program code in the form of instructions or data structures and that can be accessed, read, and/or executed by a computer, such as propagated signals or waves. 
     Other embodiments of the disclosure may be practiced in network computing environments with many types of computer system configurations, including personal computers, hand-held devices, multi-processor systems, microprocessor-based or programmable consumer electronics, network PCs, minicomputers, mainframe computers, and the like. Embodiments may also be practiced in distributed computing environments where tasks are performed by local and remote processing devices that are linked (either by hardwired links, wireless links, or by a combination thereof) through a communications network. In a distributed computing environment, program modules may be located in both local and remote memory storage devices. 
     In the above description, terms such as “upper,” “upward,” “lower,” “downward,” “above,” “below,” “downhole,” “uphole,” “longitudinal,” “lateral,” and the like, as used herein, shall mean in relation to the bottom or furthest extent of the surrounding wellbore even though the wellbore or portions of it may be deviated or horizontal. Correspondingly, the transverse, axial, lateral, longitudinal, radial, etc., orientations shall mean orientations relative to the orientation of the wellbore or tool. Additionally, the illustrate embodiments are illustrated such that the orientation is such that the right-hand side is downhole compared to the left-hand side. 
     The term “coupled” is defined as connected, whether directly or indirectly through intervening components, and is not necessarily limited to physical connections. The connection can be such that the objects are permanently connected or releasably connected. The term “outside” refers to a region that is beyond the outermost confines of a physical object. The term “inside” indicates that at least a portion of a region is partially contained within a boundary formed by the object. The term “substantially” is defined to be essentially conforming to the particular dimension, shape or another word that substantially modifies, such that the component need not be exact. For example, substantially cylindrical means that the object resembles a cylinder, but can have one or more deviations from a true cylinder. 
     The term “radially” means substantially in a direction along a radius of the object, or having a directional component in a direction along a radius of the object, even if the object is not exactly circular or cylindrical. The term “axially” means substantially along a direction of the axis of the object. If not specified, the term axially is such that it refers to the longer axis of the object. 
     Although a variety of information was used to explain aspects within the scope of the appended claims, no limitation of the claims should be implied based on particular features or arrangements, as one of ordinary skill would be able to derive a wide variety of implementations. Further and although some subject matter may have been described in language specific to structural features and/or method steps, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to these described features or acts. Such functionality can be distributed differently or performed in components other than those identified herein. The described features and steps are disclosed as possible components of systems and methods within the scope of the appended claims. 
     Moreover, claim language reciting “at least one of” a set indicates that one member of the set or multiple members of the set satisfy the claim. For example, claim language reciting “at least one of A and B” means A, B, or A and B. 
     Statements of the disclosure include: 
     Statement 1. A method for conducting a hydraulic fracturing job in a subterranean formation using a pump comprises selecting a fluid pump of known operating pump capacity, wherein the operating pump capacity is measurable in barrels per minute. The method also comprises fluidly connecting the pump with a cased wellbore in a subterranean formation for providing pumped fracturing fluid to the wellbore. The wellbore has at least one perforation through a casing of the wellbore and each perforation has a known rate range within which fracturing fluid is required to be provided to the perforation to successfully fracture the subterranean formation outside the perforation through the perforation. The wellbore that is fluidly connected to the pump is configured so that the pump provides fracturing fluid to each perforation within the known rate range of the respective perforation to successfully fracture the subterranean formation outside the perforation while operating the pump in a damage avoidance mode. 
     Statement 2. The method of statement 1, wherein the wellbore is part of a plurality of cased wellbores in the subterranean formation, the method further comprising fluidly connecting the pump with each of the plurality of wellbores in the subterranean formation for providing pumped fracturing fluid to each of the wellbores. Each of the plurality of wellbores has at least one perforation through a casing of the wellbore and each perforation has a known rate range within which fracturing fluid is required to be provided to the perforation to successfully fracture the subterranean formation outside the perforation, through the perforation. Further, the wellbores constituting the plurality of wellbores that are fluidly connected to the pump are configured so that the pump provides fracturing fluid to each of the perforations within the known rate range of the respective perforation to successfully fracture the subterranean formation outside the perforation while operating the pump in the damage avoidance mode. 
     Statement 3. The method of statements 1 and 2, wherein operation of the pump in the damage avoidance mode is characterized by operating the pump at a fluid pressure at about or below a fatigue-inducing value associated with the fluid end of the pump. 
     Statement 4. The method of statements 1 through 3, wherein operation of the pump in the damage avoidance mode is characterized by operating the pump at a fluid velocity at about or below an erosion-inducing value associated with components of the pump. 
     Statement 5. The method of statements 1 through 4, wherein operation of the pump in the damage avoidance mode is characterized by operating the pump at: (i) a fluid velocity at about or below an erosion-inducing value associated with components of the pump and (ii) a fluid pressure at about or below a fatigue-inducing value associated with the fluid end of the pump. 
     Statement 6. The method of statements 1 through 5, wherein operation of the pump in the damage avoidance mode occurs during a predominance of a duration of the fracturing job of at least the wellbore. 
     Statement 7. The method of statements 1 through 6, wherein operation of the pump in the damage avoidance mode occurs during a substantial entirety of a duration of the fracturing job of at least the wellbore. 
     Statement 8. The method of statements 1 through 7, further comprising mixing a plurality of separately pumped fluid streams at or near a head of the wellbore, the streams comprising: (i) a liquid-phase-only fluid stream and (ii) a solids-laden fluid stream. The method also comprises pumping the solids-laden fluid stream at a rate less than a rate at which the liquid-phase-only fluid stream is pumped thereby avoiding pump erosion. 
     Statement 9. The method of statements 1 through 8, further comprising mixing a plurality of separately pumped fluid streams at or near a head of the wellbore, the streams comprising: (i) a liquid-phase-only fluid stream and (ii) a solids-laden fluid stream. The solids-laden fluid stream is pumped at a rate range of approximately five to fifteen barrels per minute to the wellbore and the liquid-phase-only fluid stream is pumped at a rate range of approximately twenty-five to thirty-five barrels per minute to the wellbore and thereby avoiding pump fatigue and erosion. 
     Statement 10. The method of statements 1 through 9, wherein operation of the pump in the damage avoidance mode facilitates the utilization of four and one-half inch and smaller casing in the construction of the wellbore. 
     Statement 11. A method for conducting a hydraulic fracturing job in a subterranean formation using a pump comprises selecting a fluid pump of known operating pump capacity, wherein the operating pump capacity is measurable in barrels per minute. The method also comprises fluidly connecting the pump with a cased wellbore in a subterranean formation for providing pumped fracturing fluid to the wellbore. The wellbore has at least one passage through a casing of the wellbore and each passage has a known rate range within which fracturing fluid is required to be provided to the passage to successfully fracture the subterranean formation outside the passage through the passage. The wellbore that is fluidly connected to the pump is configured so that the pump provides fracturing fluid to each passage within the known rate range of the respective perforation to successfully fracture the subterranean formation outside the passage while operating the pump in a damage avoidance mode. 
     Statement 12. The method of statement 11, wherein the wellbore is part of a plurality of cased wellbores in the subterranean formation, the method further comprising fluidly connecting the pump with each of the plurality of wellbores in the subterranean formation for providing pumped fracturing fluid to each of the wellbores. Each of the plurality of wellbores has at least one passage through a casing of the wellbore and each passage has a known rate range within which fracturing fluid is required to be provided to the passage to successfully fracture the subterranean formation outside the passage, through the passage. Further, the wellbores constituting the plurality of wellbores that are fluidly connected to the pump are configured so that the pump provides fracturing fluid to each of the passage within the known rate range of the respective passage to successfully fracture the subterranean formation outside the passage while operating the pump in the damage avoidance mode. 
     Statement 13. The method of statements 11 and 12, further comprising utilizing at least one of: (i) sliding sleeves, (ii) casing-conveyed perforating guns, (iii) apertures plugged with water soluble material; (iv) apertures plugged with formation-fluid soluble material; and (v) apertures plugged with chemically dissolvable material to create at least a portion of the passage through the wellbore. 
     Statement 14. The method of statements 11 through 13, wherein the passage through the wellbore casing is a perforation created using perforating shaped charges. 
     Statement 15. The method of statements 11 through 14, wherein operation of the pump in the damage avoidance mode is characterized by operating the pump at a fluid pressure at about or below a fatigue-inducing value associated with the fluid end of the pump. 
     Statement 16. The method of statements 11 through 15, wherein operation of the pump in the damage avoidance mode is characterized by operating the pump at a fluid velocity at about or below an erosion-inducing value associated with components of the pump. 
     Statement 17. The method of statements 11 through 16, wherein operation of the pump in the damage avoidance mode is characterized by operating the pump at: (i) a fluid velocity at about or below an erosion-inducing value associated with components of the pump and (ii) a fluid pressure at about or below a fatigue-inducing value associated with the fluid end of the pump. 
     Statement 18. The method of statements 11 through 17, wherein operation of the pump in the damage avoidance mode occurs during a predominance of a duration of the fracturing job of at least the wellbore. 
     Statement 19. The method of statements 11 through 18, wherein operation of the pump in the damage avoidance mode occurs during a substantial entirety of a duration of the fracturing job of at least the wellbore. 
     Statement 20. A system for conducting a hydraulic fracturing job in a subterranean formation using a pump comprising a fluid pump of known operating pump capacity, wherein the operating pump capacity is measureable in barrels per minute. The system also comprises one or more fluid couplings that fluidly connect the pump with a cased wellbore in a subterranean formation for providing pumped fracturing fluid to the wellbore. The wellbore has at least one perforation through a casing of the wellbore and each perforation has a known rate range within which fracturing fluid is required to be provided to the perforation to successfully fracture the subterranean formation outside the perforation through the perforation. The wellbore that is fluidly connected to the pump is configured so that the pump provides fracturing fluid to each perforation within the known rate range of the respective perforation to successfully fracture the subterranean formation outside the perforation while operating the pump in a damage avoidance mode.